Latest revision as of 16:04, 3 February 2026

REVISION REQUEST 4036

106.3.2.93.1 Means of Evaluating Aggregate Alkali Carbonate Reactivity

1. Chemical Analysis

The chemical analysis of aggregate reactivity is an objective, quantifiable and repeatable test. MoDOT will perform the chemical analysis per the process identified in ASTM C 25 for determining the aggregate composition. The analysis determines the calcium oxide (CaO), magnesium oxide (MgO), and aluminum oxide (Al₂O₃) content of the aggregate. The chemical compositions are then plotted on a chart with the CaO/MgO ratio on the y-axis and Al₂O₃ percentage on the x-axis per Fig. 2 in AASHTO R 80. Aggregates are considered potentially reactive if the Al₂O₃ content is greater than or equal to 1.0% and the CaO/MgO ratio is either greater than or equal to 3.0 or less than or equal to 10.0 (see chart below). See flow charts in 106.3.2.93.2 for approval hierarchy. CaO, MgO and Al2O3 shall be analyzed by instrumental analysis only.

* MoDOT’s upper and lower limits of potentially reactive (shaded area) aggregates.

2. Petrographic Examination

A petrographic examination is another means of determining alkali carbonate reactivity. The sample aggregate for petrographic analysis will be obtained at the same time as the source sample. MoDOT personnel shall be present at the time of sample. The petrographic sample shall be placed in an approved tamper-evident container (provided by the quarry) for shipment to petrographer. Per ASTM C 295, a petrographic examination is to be performed by a petrographer with at least 5 years of experience in petrographic examinations of concrete aggregate including, but not limited to, identification of minerals in aggregate, classification of rock types, and categorizing physical and chemical properties of rocks and minerals. The petrographer will have completed college level course work in mineralogy, petrography, or optical mineralogy. MoDOT does not accept on-the-job training by a non-degreed petrographer as qualified to perform petrographical examinations. MoDOT may request petrographer’s qualifications in addition to the petrographic report. The procedures in C 295 shall be used to perform the petrographic examination. The petrographic examination report to MoDOT shall include at a minimum:

Quarry name and ledge name; all ledges if used in combination
MoDOT District quarry resides
Date sample was obtained; date petrographic analysis was completed
Name of petrographer and company/organization affiliated
Lithographic descriptions with photographs of the sample(s) examined
Microphotographs of aggregate indicating carbonate particles and/or other reactive materials
Results of the examination
All conclusions related to the examination

See flow charts in EPG 106.3.2.93.2 for the approval hierarchy. See EPG 106.3.2.93.3 for petrographic examination submittals. No direct payment will be made by the Commission for shipping the petrographic analysis sample to petrographer, or for the petrographic analysis performed by the petrographer.

3. Concrete Prism/Beam Test

ASTM C 1105 is yet another means for determining the potential expansion of alkali carbonate reactivity in concrete aggregate. MoDOT will perform this test per C 1105 at its Central Laboratory. Concrete specimen expansion will be measured at 3, 6, 9, and 12 months. The test specimens will be considered alkali carbonate reactive (expansive) if the specimens expand greater than 0.015% at 3 months, 0.025% at 6 months, or 0.030% at 12 months. See flow chart in EPG 106.3.2.93.2 for the approval hierarchy.

REVISION REQUEST 4143

751.36.5 Design Procedure

Structural Analysis
Geotechnical Analysis
Drivability Analysis

751.36.5.1 Design Procedure Outline

Determine foundation load effects from the superstructure and substructure for Service, Strength and Extreme Event Limit States.
If applicable, determine scour depths, liquefaction information and pile design unbraced length information.
Determine if downdrag loadings should be considered.
Select preliminary pile size and pile layout.
Perform a Static Pile Soil Interaction Analysis. Estimate Pile Length and pile capacity.
Based on pile type and material, determine Resistance Factors for Structural Strength ( $ϕ_{c}$ and $ϕ_{f}$ ).
Determine:
- Maximum axial load effects at toe of a single pile
- Maximum combined axial & flexural load effects of a single pile
- Maximum shear load effect for a single pile
- Uplift pile reactions
Determine Nominal and Factored Structural Resistance for single pile
- Determine Structural Axial Compression Resistance
- Determine Structural Flexural Resistance
- Determine Structural Combined Axial & Flexural Resistance
- Determine Structural Shear Resistance
Determine method for pile driving acceptance criteria
Determine Resistance Factor for Geotechnical Resistance ( $ϕ_{s t a t}$ ) and Driving Resistance ( $ϕ_{d y n}$ ).
If other than end bearing pile on rock or shale, determine Nominal Axial Geotechnical Resistance for pile.
Determine Factored Axial Geotechnical Resistance for single pile.
Determine Nominal pullout resistance if pile uplift reactions exist.
Check for pile group effects.
Resistance of Pile Groups in Compression
Check Drivability of all pile (bearing and friction pile) using the Wave equation analysis.
Review Static Pile Soil Interaction Analysis and pile lengths for friction pile.
Show proper Pile Data on Plan Sheets (Foundation Data Table).

751.36.5.2 Structural Resistance Factor (ϕ_c and ϕ_f) for Strength Limit State

LRFD 6.5.4.2

For integral end bent simple pile design, use Φ_c = 0.35 for CIP steel pipe piles and HP piles. See Figure 751.35.2.4.2.

For pile at all locations where integral end bent simple pile design is not applicable, use the following:

The structural resistance factor for axial resistance in compression is dependent upon the expected driving conditions. When the pile is subject to damage due to severe driving conditions where use of pile point reinforcement is necessary:

Steel Shells (Pipe):

ϕ_{c}

= 0.60

HP Piles:

ϕ_{c}

= 0.50

When the pile is subject to good driving conditions where use of pile point reinforcement is not necessary:

Steel Shells (Pipe) Piles:

ϕ_{c}

= 0.70

HP Piles:

ϕ_{c}

= 0.60

For HP piles, pile point reinforcement is always required when HP piles are anticipated to be driven to rock and proofed. Driving HP piles to rock is considered severe driving conditions for determination of structural resistance factor. However, driving HP piles through overburden not likely to impede driving to deep rock or preboring to rock for setting piles are two situations that could be considered as less than severe. Further, driving any steel pile through soil without rubble, boulders, cobbles or very dense gravel could be considered good driving conditions for determination of structural resistance factor. Consult the Structural Project Manager or Structural Liaison Engineer.

The structural resistance factor for combined axial and flexural resistance of undamaged piles:

Axial resistance factor for HP Piles:

ϕ_{c}

= 0.70

Axial resistance for Steel Shells (Pipe):

ϕ_{c}

= 0.80

Flexural resistance factor for HP Piles or Steel Shells:

ϕ_{f}

= 1.00

For Extreme Event Limit States, see LRFD 10.5.5.3.

751.36.5.3 Geotechnical Resistance Factor (ϕ_stat) and Driving Resistance Factor (ϕ_dyn)

The factors for Geotechnical Resistance ( $ϕ_{s t a t}$ ) and Driving Resistance ( $ϕ_{d y n}$ ) may be different because of the reliability of the different methods used to determine the nominal bearing resistance. Caution should be used if the difference in factors for Geotechnical Resistance and Driving Resistance are great as it can lead to issues with pile overruns. Also see EPG 751.36.5.9.

Geotechnical Resistance Factor, ϕ_stat:

The Geotechnical Resistance factor is based on the static method used by the designer in determining the nominal bearing resistance. Unlike the Driving Resistance factor the Geotechnical Resistance factor can vary with the soil layers. If Geotechnical Resistance factors are not provided by the Geotechnical Engineer, the static method and resistance factors shall be selected from the table below. The values provided in LRFD Table 10.5.5.2.3-1 are only applicable if the end of drive criteria is based off the total pile penetration which is not recommended. For Extreme Event Limit States see LRFD 10.5.5.3.

**Table - Static Analysis Resistance Factors used for Pile Length Estimates**
Pile Type	Soil Type	Static Analysis Method	Side Friction¹ $ϕ_{s t a t}$	End Bearing $ϕ_{s t a t}$
CIP Piles - Steel Pipe Shells	Clay	Alpha - Tomlinson	$ϕ_{d y n}$ ²	$ϕ_{d y n}$ ²
	Sand	Nordlund³	0.45 - Gates 0.45 - WEAP 0.55 - PDA	0.45 - Gates 0.45 - WEAP 0.55 - PDA
		LCPC⁴	0.70	0.45
		Schmertmann⁵	0.50	0.50

¹ For mixed soil profiles the lowest applicable resistance factor for clay or sand may be used to simplify the analysis.

² ϕ_dyn = see following section.

³The Nordlund method is recommended for sand layers in mixed soil profiles where CPT data is not available.

⁴The resistance factors associated with the LCPC method are not statistically calibrated for reliability, but studies have shown this method to be one of the most reliable methods for predicting soil behavior from CPT data.

⁵Per LRFD 10.7.3.8.6g the Schmertmann method shall only be used for sands and nonplastic silts with CPT data.

For more detailed guidance see SEG 25-001 New Policy for Friction Pile.

Driving Resistance Factor, ϕ_dyn:

The Driving Resistance factor shall be selected from LRFD Table 10.5.5.2.3-1 based on the method to be used in the field during construction to verify nominal axial compressive resistance.

Pile Driving Verification Method	Resistance Factor, $ϕ_{d y n}$
FHWA-modified Gates Dynamic Pile Formula (End of Drive condition only)	0.40
Wave Equation Analysis (WEAP)	0.50
Dynamic Testing (PDA) on 1 to 10% piles	0.65
Other methods	Refer to LRFD Table 10.5.5.2.3-1

Use EPG 751.50 Standard Detailing Note G7.3 on plans as required for end bearing piles driven to rock. This requirement shall apply to any type of rock meaning weak to strong rock including stronger shales where HP piling is anticipated to meet refusal. The verification method shown on the plans is only used to verify the nominal axial compressive resistance prior to reaching practical refusal. If the practical refusal criterion is met the field verification method shown on the plans is no longer considered valid.

For end bearing piles tipped in shale, sandstone, or rock of uncertain strength at any loading where the likelihood of pile damage is increased, the Foundation Investigation Geotechnical Report (FIGR) should give a recommendation for dynamic pile testing (PDA) or no PDA. For most end bearing piles, where a recommendation for field verification is not given in the FIGR, the designer will need to determine whether gates or WEAP is required for the pile driving verification method based on the loading demands on the pile or other factors.

For piles bearing on hard rock with MNACR less than 600 kips, FHWA-modified Gates Dynamic Pile Formula should be listed as verification method, and practical refusal criterion should control end of driving criteria. FHWA-modified Gates Dynamic Pile Formula is not considered accurate for pile loading (Minimum Nominal Axial Compressive Resistance) exceeding 600 kips. When pile loading exceeds 600 kips, use wave equation analysis, dynamic testing, or other method. Consideration should be given to using additional piles to reduce the MNACR below 600 kips.

Under special circumstances when rock limits or conditions are nonuniform, WEAP should be considered in order to limit pile damage since it requires further scrutiny of the site conditions with the proposed pile driving system.

Dynamic Testing is recommended for projects with friction piles where the soil profile is comprised primarily of sand. For bridges where the soil profile is comprised primarily of clays or evenly mixed clays and sands the recommended verification method is WEAP. When WEAP is specified as the pile driving criteria for friction pile, provide standard note E2.28 below the foundation table. For more detailed guidance see SEG 25-001 New Policy for Friction Pile.

751.36.5.4 Downdrag and Losses to Geotechnical Resistance due to Scour and Liquefaction

Downdrag and Losses to Geotechnical Resistance due to Scour and Liquefaction (kips), LRFD 10.7.3.6, 10.7.3.7, and AASHTO Guide Specifications for LRFD Seismic Bridge Design (SGS) 6.8.

Downdrag, liquefaction and scour all reduce the available skin friction capacity of piles. Downdrag $(D D)$ is unique because it not only causes a loss of capacity, but also applies a downward force to the piles. This is usually attributed to embankment settlement. However, downdrag can also be caused by a non-liquefied layer overlying a liquefied layer. Review geotechnical report for downdrag and liquefaction information.

751.36.5.5 Preliminary Structural Nominal Axial Design Capacity (PNDC) of an individual pile

The PNDC equations provided herein assume the piles are continually braced. This assumption is applicable for the portion of piling below ground or confined by solid wall encasement. If designing a pile bent structure, scour exists or liquefaction exists, then the pile shall be checked considering the appropriate unbraced length.

Structural Steel HP Piles

P N D C = 0.6 6^{λ} F_{y} A_{S}

Since we are assuming the piles are continuously braced, then

λ

= 0.

$F_{y}$	is the yield strength of the pile
$A_{S}$	is the area of the steel pile

Welded or Seamless Steel Shell (Pipe) Cast-In-Place Piles (CIP Piles)

P N D C = 0.85 f'_{c} A c + F_{y} A_{s t}

$F_{y}$	is the yield strength of the pipe pile
$A_{s t}$	is the area of the steel pipe (deducting 12.5 % ASTM tolerance and 1/16 inch corrosion where appropriate.)
$f'_{c}$	is the concrete compressive strength at 28 days
$A c$	is the area of the concrete inside the pipe pile

Maximum Load during pile driving =

0.90 (f_{y} A_{s t})

Welded or Seamless Steel Shell shall be ASTM A252 Modified Grade 3 (50 ksi). ASTM A252 states “the wall thickness at any point shall not be more than 12.5% under the specified nominal wall thickness.” AASHTO recommends deducting 1/16” of the wall thickness due to corrosion (LRFD 5.13.4.5.2). Corrosion need not be considered at construction stage and for drivability analysis and static analysis. For drivability analysis and static analysis deduct 12.5% of specified nominal wall thickness (ASTM A252). For structural design deduct 12.5 % (ASTM A252) and 1/16” for corrosion (LRFD 5.13.4.5.2) from specified nominal wall thickness.

751.36.5.6 Preliminary Factored Axial Design Capacity (PFDC) of an Individual Pile

PFDC = Structural Factored Axial Compressive Resistance – Factored Downdrag Load

751.36.5.7 Design Values for Steel Pile

751.36.5.7.1 Integral End Bent Simple Pile Design

The following design values may be used for integral end bents where the simple pile design method is applicable per EPG 751.35.2.4.2 Pile Design. These values are not applicable for soils subject to liquefaction or scour where unbraced lengths may alter the design.

751.36.5.7.1.1 Design Values for Individual HP Pile

F_y = 50 ksi. End Bearing Piles (HP piles) anticipated to be driven to rock.

Pile Size	A_s Area, sq. in.	Structural Nominal Axial Compressive Resistance PNDC^1,2, kips	Φ_c Structural Resistance Factor^4,5, LRFD 6.5.4.2	Structural Factored Axial Compressive Resistance^2,3,4, kips	0.9ϕ_daF_y Maximum Nominal Driving Stress, LRFD 10.7.8, ksi
HP 12x53	15.5	775	0.35	271	45.00
HP 14x73	21.4	1070	0.35	375	45.00
¹ Structural Nominal Axial Compressive Resistance for fully embedded piles only. Minimum Nominal Axial Compressive Resistance = Required nominal driving resistance, R_ndr = (Maximum factored axial loads / ϕ_dyn) ≤ Structural nominal axial compressive resistance, PNDC LRFD 10.5.5.2.3 ² Axial Compressive Resistance values shown above shall be reduced when downdrag is considered. ³ Maximum factored axial load per pile ≤ Structural factored axial compressive resistance. ⁴ Values are applicable for Strength Limit States. ⁵ Use (Φ_c) = 0.35 instead of 0.5 for structural resistance factor (LRFD 6.5.4.2) Notes: ϕ_dyn = Resistance factor of the dynamic method to be used to estimate nominal pile resistance during pile installation. LRFD Table 10.5.5.2.3-1 For more information about selecting pile driving verification methods refer to EPG 751.36.5.3 Geotechnical Resistance Factor (ϕ_stat) and Driving Resistance Factor (ϕ_dyn). Drivability analysis shall be performed for all HP piles using Delmag D19-42. Do not show minimum hammer energy on plans. Check drivability for all HP Pile in accordance with EPG 751.36.5.11 For additional design requirements, see EPG 751.36.5.1.

751.36.5.7.1.2 Design Values for Individual Cast-In-Place (CIP) Pile

Modified Grade 3 F_y = 50 ksi; F'_c = 4 ksi; Structural Axial Compressive Resistance Factor, (Φ_c)^1,3 = 0.35

Unfilled Pipe For Axial Analysis²
Pile Outside Diameter O.D., in.	Pile Inside Diameter I.D., in.	Minimum Wall Thickness, in.	Reduced Wall thick. for Fabrication (ASTM A252), in.	A_s,⁴ Area of Steel Pipe, sq. in.	Structural Nominal Axial Compressive Resistance P_n^5,6,7, kips	Structural Factored Axial Compressive Resistance^1,7,8, kips	0.9ϕ_daF_y*A_s Maximum Nominal Driving Resistance⁶, LRFD 10.7.8, kips
14	13	0.5	0.44	18.47	923	323	831
14	12.75	0.625⁹	0.55	22.84	1142	400	1028
16	15	0.5	0.44	21.22	1061	371	955
16	14.75	0.625⁹	0.55	26.28	1314	460	1183
20	19	0.5	0.44	26.72	1336	468	1202
20	18.75	0.625	0.55	33.15	1658	580	1492
24	23	0.5	0.44	32.21	1611	564	1450
	22.75	0.625	0.55	40.03	2001	700	1801
	22.5	0.75	0.66	47.74	2387	835	2148
¹Values are applicable for Strength Limit States. ² Use to determine preliminary number of pile and pile size. For piles predominantly embedded and tipped in cohesionless soils the maximum loads provided in EPG 751.36.5.10 will control. ³ Use (Φ_c) = 0.35 instead of 0.6 for structural axial compressive resistance factor (LRFD 6.5.4.2). Since ϕ_dyn >> Φ_c the maximum nominal driving resistance may not control. ⁴ Corrosion NOT considered at construction stage and for drivability analysis and static analysis. For drivability analysis and static analysis use reduced pipe nominal wall thickness, 12.5%, for fabrication (ASTM A252). ⁵ Structural Nominal Axial compressive resistance for fully embedded piles only. ⁶ Minimum Nominal Axial Compressive Resistance = Required nominal driving resistance, R_ndr = Maximum factored axial loads / ϕ_dyn ≤ Structural nominal axial compressive resistance, P_n and LRFD 10.5.5.2.3 ≤ Maximum nominal driving resistance. ⁷ Axial Compressive Resistance values shown above shall be reduced when downdrag is considered. ⁸ Maximum factored axial load per pile ≤ Structural factored axial compressive resistance. ⁹ 5/8” wall thickness is less commonly available than the smaller wall thicknesses of pipe pile. Notes: Drivability analysis shall be performed for all CIP piles (unfilled pipe) using Delmag D19-42. Do not show minimum hammer energy on plans. Check drivability for all CIP Pile in accordance with EPG 751.36.5.11. Require dynamic pile testing for field verification for all CIP piles on the plans. ϕ_dyn = 0.65 = Dynamic Testing resistance factor to be used to estimate nominal pile resistance during pile installation. This value may be increased if static load testing is specified per LRFD Table 10.5.5.2.3-1. For additional design requirements, see EPG 751.36.5.1.

751.36.5.7.2 General Pile Design

The following design values are recommended for general use where the simple pile design method is not applicable per EPG 751.35.2.4.2 Pile Design. These values are not applicable for soils subject to liquefaction or scour where unbraced lengths may alter the design.

751.36.5.7.2.1 Design Values for Individual HP Pile

F_y = 50 ksi. End Bearing Piles (HP piles) anticipated to be driven to rock.

Pile Size	A_s Area, sq. in.	Structural Nominal Axial Compressive Resistance PNDC^1,2, kips	Φ_c Structural Resistance Factor⁴, LRFD 6.5.4.2	Structural Factored Axial Compressive Resistance^2,3,4, kips	0.9ϕ_daF_y Maximum Nominal Driving Stress, LRFD 10.7.8, ksi
HP 12x53	15.5	775	0.5	388	45.00
HP 14x73	21.4	1070	0.5	535	45.00
¹ Structural Nominal Axial Compressive Resistance for fully embedded piles only. Structural Nominal Axial Compressive Resistance for unsupported piles shall be determined in accordance with LRFD 10.7.3.13.1. (i.e., intermediate pile cap bent). Minimum Nominal Axial Compressive Resistance = Required nominal driving resistance, R_ndr = (Maximum factored axial loads / ϕ_dyn) ≤ Structural nominal axial compressive resistance, PNDC LRFD 10.5.5.2.3 ² Axial Compressive Resistance values shown above shall be reduced when downdrag is considered. ³ Maximum factored axial load per pile ≤ Structural factored axial compressive resistance. ⁴ Values are applicable for Strength Limit States. Modify value for other Limit States. Notes: ϕ_dyn = Resistance factor of the dynamic method to be used to estimate nominal pile resistance during pile installation. LRFD Table 10.5.5.2.3-1 For more information about selecting pile driving verification methods refer to EPG 751.36.5.3 Geotechnical Resistance Factor (ϕ_stat) and Driving Resistance Factor (ϕ_dyn). Drivability analysis shall be performed for all HP piles using Delmag D19-42. Do not show minimum hammer energy on plans. Check drivability for all HP Pile in accordance with EPG 751.36.5.11 For additional design requirements, see EPG 751.36.5.1.

751.36.5.7.2.2 Design Values for Individual Cast-In-Place (CIP) Pile

Modified Grade 3 F_y = 50 ksi; F'_c = 4 ksi; Structural Resistance Factor, (Φ_c)¹ = 0.6

Unfilled Pipe For Axial Analysis²								Concrete Filled Pipe For Flexural Analysis³
Pile Outside Diameter O.D., in.	Pile Inside Diameter I.D., in.	Minimum Wall Thickness, in.	Reduced Wall thick. for Fabrication (ASTM A252), in.	A_s,⁴ Area of Steel Pipe, sq. in.	Structural Nominal Axial Compressive Resistance, P_n^5,6,7, kips	Structural Factored Axial Compressive Resistance^1,7,8, kips	0.9ϕ_daF_y*A_s Maximum Nominal Driving Resistance^5,6, LRFD 10.7.8, kips	Reduced Wall Thick. for Corrosion (1/16"), LRFD 5.13.4.5.2, in.	A_st,⁹ Net Area of Steel Pipe, sq. in.	A_c Concrete Area, sq. in.	Structural Nominal Axial Compressive Resistance PNDC^5,7,10, kips	Structural Factored Axial Compressive Resistance^1,7,10, kips
14	13	0.5	0.44	18.47	923	554	831	0.375	15.76	133	1239	743
14	12.75	0.625¹¹	0.55	22.84	1142	685	1028	0.484	20.14	128	1441	865
16	15	0.5	0.44	21.22	1061	637	955	0.375	18.11	177	1506	904
16	14.75	0.625¹¹	0.55	26.28	1314	788	1183	0.484	23.18	171	1740	1044
20	19	0.5	0.44	26.72	1336	801	1202	0.375	22.83	284	2105	1263
20	18.75	0.625	0.55	33.15	1658	995	1492	0.484	29.27	276	2402	1441
24	23	0.5	0.44	32.21	1611	966	1450	0.375	27.54	415	2790	1674
	22.75	0.625	0.55	40.03	2001	1201	1801	0.484	35.36	406	3150	1890
	22.5	0.75	0.66	47.74	2387	1432	2148	0.594	43.08	398	3506	2103
¹ Values are applicable for Strength Limit States. Modify value for other Limit States. ² Use to determine preliminary number of pile and pile size. For piles predominantly embedded and tipped in cohesionless soils the maximum loads provided in EPG 751.36.5.10 will control. ³ Pipes placed in prebored holes in rock can use filled pipe capacity for axial plus flexural resistance. Therefore, number of piles should be based on this capacity assuming rock is infinitely more stiff. This recognizes that pile driving is not a concern. ⁴ Corrosion NOT considered at construction stage and for drivability analysis and static analysis. For drivability analysis and static analysis use reduced pipe nominal wall thickness, 12.5%, for fabrication (ASTM A252). ⁵ Structural Nominal Axial compressive resistance for fully embedded piles only. Value in table is a raw number and is the value used to determine the factored resistance. Structural Nominal Axial Compressive Resistance for unsupported piles shall be determined in accordance with LRFD 10.7.3.13.1. (i.e. Intermediate pile cap bent). ⁶ Minimum Nominal Axial Compressive Resistance = Required nominal driving resistance, R_ndr = Maximum factored axial loads / ϕ_dyn ≤ Structural nominal axial compressive resistance, P_n and LRFD 10.5.5.2.3 ≤ Maximum nominal driving resistance. ⁷ Axial Compressive Resistance values shown above shall be reduced when downdrag is considered ⁸ Maximum factored axial load per pile ≤ Structural factored axial compressive resistance ⁹ Net area of steel pipe, A_st, assumes a 12.5% fabrication reduction (ASTM A252) and 1/16" (LRFD 5.13.4.5.2) reduction in pipe nominal wall thickness for corrosion. ¹⁰ Use for lateral load analysis. Resistance value includes filled pipe based on net area of steel pipe, A_st (12.5% fab. reduction and 1/16” corr. reduction in nominal pipe wall thickness). ¹¹ 5/8” wall thickness is less commonly available than the smaller wall thicknesses of pipe pile. Notes: Drivability analysis shall be performed for all CIP piles (unfilled pipe) using Delmag D19-42. Do not show minimum hammer energy on plans. Check drivability for all CIP Pile in accordance with EPG 751.36.5.11. Require dynamic pile testing for field verification for all CIP piles on the plans. ϕ_dyn = 0.65 = Dynamic Testing resistance factor to be used to estimate nominal pile resistance during pile installation. This value may be increased if static load testing is specified per LRFD Table 10.5.5.2.3-1. For additional design requirements, see EPG 751.36.5.1.

751.36.5.8 Additional Provisions for Pile Cap Footings

Pile Group Layout:

P_u = Total Factored Vertical Load.

Preliminary Number of Piles Required = $\frac{T o t a l F a c t o r e d V e r t i c a l L o a d}{P F D C}$

Layout a pile group that will satisfy the preliminary number of piles required. Calculate the maximum and minimum factored load applied to the outside corner piles assuming the pile cap/footing is perfectly rigid. The general equation is as follows:

Max. Load = $\frac{P_{u}}{T o t a l N o . o f P i l e s} + \frac{M_{u x} Y_{i}}{Σ Y_{i}^{2}} + \frac{M_{u y} X_{i}}{Σ X_{i}^{2}}$

Min. Load = $\frac{P_{u}}{T o t a l N o . o f P i l e s} - \frac{M_{u x} Y_{i}}{Σ Y_{i}^{2}} - \frac{M_{u y} X_{i}}{Σ X_{i}^{2}}$

The maximum factored load per pile must be less than or equal to PFDC for the pile type and size chosen. If not, the pile size must be increased or additional piles must be added to the pile group. Reanalyze until the pile type, size and layout are satisfactory.

Pile Uplift on End Bearing Piles and Friction Piles:

Service - I Limit State:

Minimum factored load per pile shall be ≥ 0.

Tension on a pile is not allowed for conventional bridges.

Strength and Extreme Event Limit States:

Uplift on a pile is not preferred for conventional bridges.

Maximum Pile Uplift load = │Minimum factored load per pile│ - │Factored pile uplift resistance│ ≥ 0¹

Note: Compute maximum pile uplift load if value of minimum factored load is negative.

¹ The minimum factored load (maximum tensile load) per pile should preferably not result in uplift for the Strength and Extreme Event Limit States. Pile uplift for the Strength and Extreme Event limit states may be permitted by SPM or SLE based on infrequent uplift load cases and small magnitudes of uplift. This decision is based on the presumed difficulty of a pile cap footing to rotate, specifically for it to be able to rotate on piles driven to rock. When pile uplift is allowed, the necessity of top pile cap reinforcement shall be investigated and the standard anchorage detail for HP pile per EPG 751.36.4.1 Structural Steel HP Pile - Details shall be used.

Resistance of Pile Groups in Compression LRFD 10.7.3.9

If the cap is not in firm contact with the ground and if the soil at the surface is soft, the individual nominal resistance of each pile (751.36.5.5) shall be multiplied by an efficiency factor, $η$ , based on pile spacing.

751.36.5.9 Estimate Pile Length and Check Pile Capacity

751.36.5.9.1 Estimated Pile Length

Friction Piles:

Estimate the pile length required to achieve the minimum nominal axial compressive resistance, MNACR, or required driving resistance, R_ndr, for establishment of contract pile quantities. Perform a static analysis using one of the methods given in EPG 751.36.5.3 Geotechnical Resistance Factor (ϕ_stat) and Driving Resistance Factor (ϕ_dyn) to determine the nominal resistance profile of the soil. For each soil layer the appropriate resistance factor, ϕ_stat, shall be applied to account for the reliability of the static analysis method to create a factored resistance profile. The penetration depth would then occur at the location where the factored resistance profile intercepts the factored load. The relationship between the static axial compressive resistance and required driving resistance for a uniform soil profile with a constant static resistance factor is given as follows:

ϕ_dyn x R_ndr = ϕ_stat x R_nstat ≥ Factored Load

LRFD C10.7.3.3-1

Where:

ϕ_dyn = see EPG.751.36.5.3

R_ndr = Required nominal driving resistance = MNACR

ϕ_stat = Static analysis resistance factor per EPG 751.36.5.3 or as provided by the Geotechnical Engineer. Factors for side friction and end bearing may be different.

R_nstat = Required nominal static resistance

Use soil profiles from borings and mimic soil characteristics as closely as possible in computations or software to calculate the geotechnical resistance and for estimating the length of pile. For more detailed guidance see SEG 25-001 New Policy for Friction Pile.

It is not advisable to design pile deeper than available borings or to reach capacity within the bottom 3 to 5 feet of borings. If a longer pile depth is needed to meet design requirements then request Geotechnical Section to provide deeper borings or increase the number of piles which will reduce load per pile as well as the required pile length.

For friction pile the top five feet of soil friction resistance may be neglected with SPM or SLE approval for possible disturbance from MSE wall excavation prior to driving pile.

End Bearing Piles:

The estimated pile length is the distance along the pile from the cut-off elevation to the estimated tip elevation considering any penetration into rock. The estimated tip elevation shall not be shown on plans for end bearing piles.

The geotechnical material above the estimated end bearing tip elevation shall be reviewed for the presence of glacial till or similar layers. If these layers are present, then a static analysis shall be performed to verify if the required pile resistance is reached at a higher elevation due to pile friction capacity.

751.36.5.9.2 Check Pile Geotechnical Capacity (Axial Loads Only)

Use the same methodology outlined in EPG 751.36.5.9.1 Estimated Pile Length.

751.36.5.9.3 Check Pile Structural Capacity (Combined Axial and Bending)

Structural design checks which include lateral loading and bending shall be accomplished using the appropriate structural resistance factors.

751.36.5.10 Pile Nominal Axial Compressive Resistance

The minimum nominal axial compressive resistance, MNACR, or required driving resistance, R_ndr, must be calculated and shown on the final plans. The factored axial compressive resistance will be used to verify the pile group layout and loading. The minimum nominal axial compressive resistance will be used in construction field verification methods to obtain the required nominal driving resistance.

Minimum Nominal Axial Compressive Resistance, MNACR = Required Nominal Driving Resistance, R_ndr

= Maximum factored axial loads/ϕ_dyn

ϕ_dyn = Resistance factor of the dynamic method used to estimate nominal pile resistance during pile installation. LRFD 10.5.5.2.3.1

The value of R_ndr shown on the plans shall be the greater of the value required at the Strength limit state and Extreme Event limit state. This value shall not be greater than the structural nominal axial compressive resistance of the steel HP pile nor shall it exceed the maximum nominal driving resistance of the steel shell for CIP piles. See EPG 751.36.5.5. LRFD 10.7.7

For friction piles predominantly embedded and tipped in cohesionless soils the minimum nominal axial compressive resistance shall be limited to the values shown in the following table. Approval from the SPM, SLE or owner's representative is required before exceeding the limits provided in this table.

**Maximum Axial Loads for Friction Pile in Cohesionless Soils**
Pile Type	Minimum Nominal Axial Compressive Resistance (R_ndr)¹ (kips)	Maximum Factored Axial Load (kips)
		Dynamic Testing	Wave Equation Analysis	FHWA-modified Gates Dynamic Pile Formula
		ϕ_dyn= 0.65	ϕ_dyn = 0.50	ϕ_dyn = 0.40
CIP 14”	210	136	105	84
CIP 16”	240	156	120	96
CIP 20”	300	195	150	120
CIP 24”	340	221	170	136
¹ The minimum nominal axial compressive resistance values are correlated to match the maximum design tonnage values used in past ASD practice. A factor of safety of 3.5 is used to determine the equivalent R_ndr.

751.36.5.11 Check Pile Drivability

Drivability of the pile through the soil profile shall be investigated using the GRLWEAP wave equation analysis program. The static axial compressive resistance profile used in the wave equation analysis shall be determined using one of the approved static methods given in EPG 751.36.5.3.

Drivability analysis shall be performed by the designer for all pile types (bearing pile and friction pile) using the Delmag D19-42 hammer with manufacturer recommendations. The drivability analysis shall confirm that the pile can be driven to the minimum tip elevation, rock elevation or reach the minimum nominal axial compressive resistance prior to refusal and without overstressing the pile. If the drivability analysis shows overstress or refusal prior to reaching the desired depth a lighter or heavier hammer from the table below may be used to confirm constructability. The drivability analysis is not intended to confirm that a pile can be driven through rock (shales, sandstones, etc…) where the likelihood of pile damage is increased and PDA is recommended to reduce loads and monitor pile stresses in the field. The drivability analyses performed by the designer does not waive the responsibility of the contractor in selecting the appropriate pile driving system per Sec 702.3.5 (also discussed below).

Use soil profiles from borings and mimic soil characteristics as closely as possible for computations or in software to perform drivability analysis of any kind of pile.

Structural steel HP Pile:

Drivability analysis shall be performed for the box shape of the pile (i.e., not the perimeter).

Drivability shall be performed considering existing condition without considering any excavation/ disturbance (i.e., possible disturbance to top 5 feet of soil from MSE wall excavation prior to driving pile), liquefaction or future scour loss.

Hammer types:

**Pile Driving Hammer Information For GRLWEAP**
Hammer used in the field per survey response (2017)
GRLWEAP ID	Hammer name	No. of Responses
41	Delmag D19-42¹	13
40	Delmag D19-32	6
38	Delmag D12-42	4
139	ICE 32S	4
15	Delmag D30-32	2
	Delmag D25-32	2
127	ICE 30S	1
150	MKT DE-30B	1
¹ Delmag series of pile hammers is the most popular, with the D19-42 being the most widely used.

The contractor is responsible for determining the driving system required to successfully drive the pile to the minimum tip elevation and to reach the minimum nominal axial compressive resistance specified on the plans. The contractor is required to perform a drivability analysis to select an appropriate hammer size to ensure the pile can be driven without overstressing the pile and to prevent refusal of the pile prior to reaching the minimum tip elevation. The contractor shall plan pile driving activities and submit hammer energy requirements to the engineer for approval before driving. There is an exception to the contractor’s responsibility for the drivability analysis when WEAP is specified as the driving criteria for friction pile. When WEAP is specified for friction pile an inspector’s chart will be provided for the contractor in the electronic deliverables. For more detailed guidance see SEG 25-001 New Policy for Friction Pile.

Practical refusal is defined at 20 blows/inch or 240 blows per foot.

Driving should be terminated immediately once 30 blows/inch is encountered.

Nominal Driving Stress

LRFD 10.7.8

Nominal driving stress ≤ 0.9*ϕ_da*F_y

For structural steel HP pile, Maximum nominal driving stress = 45 ksi

For CIP pile, Maximum nominal driving resistance, see EPG 751.36.5.7.1.2 or EPG 751.36.5.7.2.2 (unfilled pipe for axial analysis).

If analysis indicates the piles do not have sufficient structural or geotechnical strength or drivability issues exist, then consider increasing the number of piles.

751.36.5.12 Information to be Included on the Plans

See EPG 751.50 A1 Design Specifications, Loadings & Unit Stresses for appropriate design stresses to be included in the general notes.

See EPG 751.50 E2 Foundation Data Table for appropriate data to be included in the foundation data table for HP pile and CIP pile and any additional notes required below the table. See Bridge Standard Drawings “Pile” for CIP data table.

E2. Foundation Data Table

The following table is to be placed on the design plans and filled out as indicated.

(E2.1) [MS Cell] (E2.1) (Example: Use the underlined parts in the bent headings for bridges having detached wing walls at end bents only.)

Foundation Data¹
Type	Design Data		Bent Number
Type	Design Data		1 (Detached Wing Walls Only)	1 (Except Detached Wing Walls)	2	3	4
Load Bearing Pile	CECIP/OECIP/HP Pile Type and Size		CECIP 14"	CECIP 14"	CECIP 16"	OECIP 24"	HP 12x53
	Number		6	8	15	12	6
	Approximate Length Per Each		50	50	60	40	53
	Pile Point Reinforcement		All	All	-	All	All
	Min. Galvanized Penetration (Elev.)		303	295⁴	273	Full Length	300
	Est. Max. Scour Depth 100² (Elev.)		-	-	285	-	-
	Minimum Tip Penetration (Elev.)		285	303	270	-	-
	Criteria for Min. Tip Penetration		Min. Embed.	Min. Embed.	Scour	-	-
	Pile Driving Verification Method		DT	DT	DT	DT	DF
	Resistance Factor		0.65	0.65	0.65	0.65	0.4
	Design Bearing³ Minimum Nominal Axial Compressive Resistance		175	200	300	600	250
Spread Footing	Foundation Material		-	-	Weak Rock	Rock	-
Spread Footing	Design Bearing Minimum Nominal Bearing Resistance		-	-	10.2	22.6	-
Rock Socket	Number		-	-	2	3	-
		Foundation Material	-	-	Rock	Rock	-
		Elevation Range	-	-	410-403	410-398	-
		Design Side Friction Minimum Nominal Axial Compressive Resistance (Side Resistance)	-	-	20.0	20.0	-
		Foundation Material	-	-	Weak Rock	-	-
		Elevation Range	-	-	403-385	-	-
		Design Side Friction Minimum Nominal Axial Compressive Resistance (Side Resistance)	-	-	9.0	-	-
	Design End Bearing Minimum Nominal Axial Compressive Resistance (Tip Resistance)		-	-	12	216	-
1 Show only required CECIP/OECIP/HP pile data for specific project.
2 Show maximum of total scour depths estimated for multiple return periods in years from Preliminary design which should be given on the Design Layout. Show the controlling return period (e.g. 100, 200, 500). If return periods are different for different bents, add a new line.
3 For LFD: For bridges in Seismic Performance Categories B, C and D, the design bearing values for load bearing piles given in the table should be the larger of the following two values: 1. Design bearing value for AASHTO group loads I thru VI. 2. Design bearing for seismic loads / 2.0
4 It is possible that min. tip penetration (elev.) can be higher than min. galvanized penetration (elev.).

Additional notes:
On the plans, report the following definition(s) just below the foundation data table for the specific method(s) used:

DT = Dynamic Testing
DF = FHWA-modified Gates Dynamic Pile Formula
WEAP = Wave Equation Analysis of Piles
SLT = Static Load Test

On the plans, report the following definition(s) just below the foundation data table for CIP Pile:
CECIP = Closed Ended Cast-In-Place concrete pile
OECIP = Open Ended Cast-In-Place concrete pile

On the plans, report the following equation(s) just below the foundation data table for the specific foundation(s) used:
Rock Socket (Drilled Shafts):
Minimum Nominal Axial Compressive Resistance (Side Resistance + Tip Resistance) = Maximum Factored Loads/Resistance Factors
Spread Footings:
Minimum Nominal Bearing Resistance = Maximum Factored Loads/Resistance Factor
Load Bearing Pile:
Minimum Nominal Axial Compressive Resistance = Maximum Factored Loads/Resistance Factor

Guidance for Using the Foundation Data Table:
	Pile Driving Verification Method	DF = FHWA-Modified Gates Dynamic Pile Formula
		DT = Dynamic Testing
		WEAP = Wave Equation Analysis of Piles
		SLT = Static Load Test

	Criteria for Minimum Tip Penetration	Scour
		Tension or uplift resistance
		Lateral stability
		Penetration anticipated soft geotechnical layers
		Minimize post construction settlement
		Minimum embedment into natural ground
		Other Reason

	Elevation reporting accuracy: Report to nearest foot for min. tip penetration, pile cleanout penetration, max. galvanized depth and est. max. scour depth. (Any more accuracy is acceptable but not warranted.)
	For LFD Design
	Use "Design Bearing" for load bearing pile and spread footing and use "Design Side Friction + Design End Bearing" for rock socket (drilled shaft).
	For LRFD Design
	Use "Minimum Nominal Axial Compressive Resistance" for load bearing pile, "Minimum Nominal Bearing Resistance" for spread footing and "Minimum Nominal Axial Compressive Resistance (Side Resistance + Tip Resistance)" for rock socket (drilled shaft).

Shallow Footings

(E2.10) (Use when shallow footings are specified on the Design Layout.)

In no case shall footings of Bents No. and be placed higher than elevations shown and , respectively.

Driven Piles

(E2.20) (Use when prebore is required and the natural ground line is not erratic.)

Prebore for piles at Bent(s) No. and to elevation(s) and , respectively.

(E2.21) (Use when prebore is required and the natural ground line is erratic.)

Prebore to natural ground line.

(E2.22) (Use when estimated maximum scour depth (elevation) for CIP piles is required.)

Estimated Maximum Scour Depth (Elevation) shown is for verifying Minimum Nominal Axial Compressive Resistance Design Bearing using dynamic testing only where pile resistance contribution above this elevation shall not be considered.

(E2.23) (Use when static test piles are required.) The number of piles in table should not include probe piles. If probe piles are specified, place an * beside the number of piles at the bents indicated.

*One concrete probe pile shall be driven in permanent position, one for each bent, at Bents No. and .

(E2.24)

All piles shall be galvanized down to the minimum galvanized penetration (elevation).

(E2.25) (Use for all HP pile and when pile point reinforcement is required for CIP pile.)

Pile point reinforcement need not be galvanized. Shop drawings will not be required for pile point reinforcement.

(E2.26) (Use for LFD piling design when Design Bearing is determined from service loads and shown on the plans. See guidance on [MS Cell] (E2.1) for specific pile driving verification method. Example: Considered only for widenings, repairs and rehabilitations.)

All piling shall be driven to a minimum nominal axial compressive resistance equal to 3.5 2.75 2.25 2.00 times the Design Bearing as shown on the plans.

(E2.27) Use for galvanized piles.

The contractor shall make every effort to achieve the minimum galvanized penetration (elevation) shown on the plans for all piles. Deviations in penetration less than 5 feet of the minimum will be considered acceptable provided the contractor makes the necessary corrections to ensure the minimum penetration is achieved on subsequent piles.

(E2.28) Use when WEAP is specified as the pile driving criteria for friction pile. Place an * behind each instance of WEAP in the Foundation Data table. The pay item Pile Wave Analysis shall not be included when this note is used.

*See electronic deliverables file for pile driving inspector’s chart(s). MoDOT will provide alternate charts for different driving systems as needed per request. With the request, the contractor shall provide the hammer manufacturer make and model, and any modifications to the manufacturer’s recommended settings including hammer cushion information. The contractor shall provide the request 30 calendar days before pile driving operations begin.

REVISION REQUEST 4151

127.2.3.3.1 Missouri Unmarked Human Burials Law

If human skeletal remains are encountered during construction, their treatment will be handled in accordance with Sections 194.400 to 194.410, RSMo, as amended. When human remains are encountered, the Contractor shall first stop all work within a 330-ft. or 100-meter radius of the remains, and secondly, shall notify the MoDOT Construction Inspector and/or Resident Engineer who will contact the Historic Preservation section. Historic Preservation staff will in turn notify the local law enforcement (to ensure that it is not a crime scene) and the State Historic Preservation Office (SHPO) as per RSMo 194 or to notify SHPO what has occurred and that it is covered by Missouri’s Cemeteries Law, §§ 214. RSMo. If the contractor is unable to contact appropriate MoDOT staff, the contractor shall initiate the involvement by local law enforcement and the SHPO. A description of the contractor’s actions will be promptly made to MoDOT.

If the human remains are prehistoric, the agency must consult with Indian tribes who have with ancestral, historic, and ceded land connections to the area in which the remains are located to determine the appropriate treatment of the remains. Tribal consultation may result in the conclusion that the remains should be preserved in place and construction plans changed to facilitate their preservation.

127.2.9 Construction Inspection Guidance

Mitigation by data recovery is usually completed prior to construction if the presence of cultural resources is known. If artifacts are discovered during construction activities, the Historic Preservation section must be immediately notified. This will allow an inspection of the site by MoDOT HP staff to determine if further investigation is necessary before construction activities continue.

Sec. 107.8.2 and Sec. 203.4.8 of the Missouri Standard Specifications for Highway Construction require the contractor to take steps to preserve any such artifacts that may be encountered and to notify the MoDOT Construction Inspector or Resident Engineer of their presence. If it is necessary to discontinue operations in a particular area to preserve such objects, this section of the specifications is basis for a work suspension. In order to ensure compliance with applicable state laws, the MoDOT Construction Inspector or Resident Engineer cannot release remains or artifacts or allow the contractor to disturb the area within the 330-foot or 100-meter buffer space around these discovered items, until after consultation with MoDOT HP staff and until after all applicable requirements from FHWA or SHPO have been addressed.

127.2.9.1 Cultural Resources Encountered During Construction

If cultural resources are encountered during construction, the contractor shall immediately stop all work within a 330-foot or 100-meter buffer around the limits of the resource and shall not resume without specific authorization from a MoDOT Historic Preservation Specialist. The contractor shall notify the MoDOT Resident Engineer or Construction Inspector, who shall contact the MoDOT HP within 24 hours of the discovery. MoDOT HP shall contact FHWA and SHPO within 48 hours of learning of the discovery and provide an evaluation of the resource and reasonable efforts to see if it can be avoided. FHWA shall make an eligibility and effects determination based upon the preliminary evaluation and consul with MoDOT, and SHPO a minimize or mitigate any adverse effect. FHWA will notify the Council and any tribes that might attach religious and/or cultural significance to the property within 48 hours of this determination. FHWA shall take into account Council and Tribal recommendations regarding the eligibility of the property and proposed actions, and direct MoDOT to carry out the appropriate actions. MoDOT will provide FHWA and SHPO with a report of the actions when they are completed. FHWA shall provide this report to the council and the tribes.

127.2.9.2 Human Remains Encountered During Construction

If human remains are encountered during construction, the contractor shall immediately stop all work within a 330-foot or 100-meter radius of the remains and shall not resume without specific authorization from MoDOT HP Staff, and either the SHPO or the local law enforcement officer, whichever party has jurisdiction over and responsibility for such remains. The contractor shall notify the MoDOT Construction Inspector and/or Resident Engineer who will contact the MoDOT HP section within 24 hours of the discovery. MoDOT HP staff will immediately notify the local law enforcement (to ensure that it is not a crime scene) and the SHPO as per RSMo 194 or to notify SHPO what has occurred and that it is covered by Missouri’s Cemeteries Law, §§ 214. RSMo. MoDOT HP staff will notify FHWA that human remains have been encountered within 24 hours of being notified of the find. If, within 24 hours, the contractor is unable to contact appropriate MoDOT staff, the contractor shall initiate the involvement by local law enforcement and the SHPO. A description of the contractor’s actions will be promptly made to MoDOT. FHWA will notify any Indian tribe that might attach cultural affiliation to the identified remains as soon as possible after their identification. FHWA shall take into account Tribal recommendations regarding treatment of the remains and proposed actions, and then direct MoDOT HP to carry-out the appropriate actions in consultation with the SHPO. MoDOT shall monitor the handling of any such human remains and associated funerary objected, sacred object or objects of cultural patrimony in accordance with the Missouri Unmarked Human Burial Sites Act, §§ 194.400 – 194.410, RSMo.

User talk:Hoskir: Difference between revisions

Latest revision as of 16:04, 3 February 2026

Contents

REVISION REQUEST 4036

106.3.2.93.1 Means of Evaluating Aggregate Alkali Carbonate Reactivity

REVISION REQUEST 4143

751.36.5 Design Procedure

751.36.5.1 Design Procedure Outline

751.36.5.2 Structural Resistance Factor (ϕ_c and ϕ_f) for Strength Limit State

751.36.5.3 Geotechnical Resistance Factor (ϕ_stat) and Driving Resistance Factor (ϕ_dyn)

751.36.5.4 Downdrag and Losses to Geotechnical Resistance due to Scour and Liquefaction

751.36.5.5 Preliminary Structural Nominal Axial Design Capacity (PNDC) of an individual pile

751.36.5.6 Preliminary Factored Axial Design Capacity (PFDC) of an Individual Pile

751.36.5.7 Design Values for Steel Pile

751.36.5.7.1 Integral End Bent Simple Pile Design

751.36.5.7.1.1 Design Values for Individual HP Pile

751.36.5.7.1.2 Design Values for Individual Cast-In-Place (CIP) Pile

751.36.5.7.2 General Pile Design

751.36.5.7.2.1 Design Values for Individual HP Pile

751.36.5.7.2.2 Design Values for Individual Cast-In-Place (CIP) Pile

751.36.5.8 Additional Provisions for Pile Cap Footings

751.36.5.9 Estimate Pile Length and Check Pile Capacity

751.36.5.9.1 Estimated Pile Length

751.36.5.9.2 Check Pile Geotechnical Capacity (Axial Loads Only)

751.36.5.9.3 Check Pile Structural Capacity (Combined Axial and Bending)

751.36.5.10 Pile Nominal Axial Compressive Resistance

751.36.5.11 Check Pile Drivability

751.36.5.12 Information to be Included on the Plans

E2. Foundation Data Table

REVISION REQUEST 4151

127.2.3.3.1 Missouri Unmarked Human Burials Law

127.2.9 Construction Inspection Guidance

127.2.9.1 Cultural Resources Encountered During Construction

127.2.9.2 Human Remains Encountered During Construction

Navigation menu

@@ Line 1: / Line 1: @@
 ='''REVISION REQUEST 4036'''=
 ==106.3.2.93.1 Means of Evaluating Aggregate Alkali Carbonate Reactivity==
@@ Line 17: / Line 15: @@
 A petrographic examination is another means of determining alkali carbonate reactivity.  The sample aggregate for petrographic analysis will be obtained at the same time as the source sample.  MoDOT personnel shall be present at the time of sample.  The petrographic sample shall be placed in an approved tamper-evident container (provided by the quarry) for shipment to petrographer.  Per ASTM C 295, a petrographic examination is to be performed by a petrographer with at least 5 years of experience in petrographic examinations of concrete aggregate including, but not limited to, identification of minerals in aggregate, classification of rock types, and categorizing physical and chemical properties of rocks and minerals.  The petrographer will have completed college level course work in mineralogy, petrography, or optical mineralogy.  MoDOT does not accept on-the-job training by a non-degreed petrographer as qualified to perform petrographical examinations.  MoDOT may request petrographer’s qualifications in addition to the petrographic report.  The procedures in C 295 shall be used to perform the petrographic examination.  The petrographic examination report to MoDOT shall include at a minimum:
-:* Quarry name and ledge name; all ledges if used in combination
+* Quarry name and ledge name; all ledges if used in combination
-:* MoDOT District quarry resides
+* MoDOT District quarry resides
-:* Date sample was obtained; date petrographic analysis was completed
+* Date sample was obtained; date petrographic analysis was completed
-:* Name of petrographer and company/organization affiliated
+* Name of petrographer and company/organization affiliated
-:* Lithographic descriptions with photographs of the sample(s) examined
+* Lithographic descriptions with photographs of the sample(s) examined
-:* Microphotographs of aggregate indicating carbonate particles and/or other reactive materials
+* Microphotographs of aggregate indicating carbonate particles and/or other reactive materials
-:* Results of the examination
+* Results of the examination
-:* All conclusions related to the examination
+* All conclusions related to the examination
 See flow charts in EPG 106.3.2.93.2 for the approval hierarchy.  See EPG 106.3.2.93.3 for petrographic examination submittals.  No direct payment will be made by the Commission for shipping the petrographic analysis sample to petrographer, or for the petrographic analysis performed by the petrographer.
@@ Line 32: / Line 30: @@
 ASTM C 1105 is yet another means for determining the potential expansion of alkali carbonate reactivity in concrete aggregate.  MoDOT will perform this test per C 1105 at its Central Laboratory.  Concrete specimen expansion will be measured at 3, 6, 9, and 12 months.  The test specimens will be considered alkali carbonate reactive (expansive) if the specimens expand greater than 0.015% at 3 months, 0.025% at 6 months, or 0.030% at 12 months.  See flow chart in EPG 106.3.2.93.2 for the approval hierarchy.
-----
-='''REVISION REQUEST 4060'''=
+='''REVISION REQUEST 4143'''=
+==751.36.5 Design Procedure==
+*Structural Analysis
+*Geotechnical Analysis
+*Drivability Analysis
-==902.5.43 Power Outages at Signalized Intersections==
+===751.36.5.1 Design Procedure Outline===
+*Determine foundation load effects from the superstructure and substructure for Service, Strength and Extreme Event Limit States.
+*If applicable, determine scour depths, liquefaction information and pile design unbraced length information.
+*Determine if downdrag loadings should be considered.
+*Select preliminary pile size and pile layout.
+*Perform a Static Pile Soil Interaction Analysis.  Estimate Pile Length and pile capacity.
+*Based on pile type and material, determine Resistance Factors for Structural Strength (<math>\, \phi_c</math> and <math>\, \phi_f</math>).
+*Determine:
+**Maximum axial load effects at toe of a single pile
+**Maximum combined axial & flexural load effects of a single pile
+**Maximum shear load effect for a single pile
+**Uplift pile reactions
+*Determine Nominal and Factored Structural Resistance for single pile
+**Determine Structural Axial Compression Resistance
+**Determine Structural Flexural Resistance
+**Determine Structural Combined Axial & Flexural Resistance
+**Determine Structural Shear Resistance
+*Determine method for pile driving acceptance criteria
+*Determine Resistance Factor for Geotechnical Resistance (<math>\, \phi_{stat}</math>) and Driving Resistance (<math>\, \phi_{dyn}</math>).
+*If other than end bearing pile on rock or shale, determine Nominal Axial Geotechnical Resistance for pile.
+*Determine Factored Axial Geotechnical Resistance for single pile.
+*Determine Nominal pullout resistance if pile uplift reactions exist.
+*Check for pile group effects.
+*Resistance of Pile Groups in Compression
+*Check Drivability of all pile (bearing and friction pile) using the Wave equation analysis.
+*Review Static Pile Soil Interaction Analysis and pile lengths for friction pile.
+*Show proper Pile Data on Plan Sheets ([https://epg.modot.org/index.php/751.50_Standard_Detailing_Notes#E2._Foundation_Data_Table Foundation Data Table]).
-===902.5.43.1 Temporary Stop Signs at Signalized Intersections===
+===751.36.5.2 Structural Resistance Factor (ϕ<sub>c</sub> and ϕ<sub>f</sub>) for Strength Limit State===
-'''Support.''' Temporary Stop Signs (TSS) refer to stop signs that meet the MUTCD stop sign design requirements for regulatory signs and are temporarily installed at signalized intersections where the traffic signals cannot function due to damage and/or power outage. These temporary placements include but are not limited to roll-up stop signs, temporary mounts on the signal vertical upright, or stop signs mounted on other crash worthy devices.
+{| style="margin: 1em auto 1em auto"
+|-
+|align="right" width="850"|'''LRFD 6.5.4.2'''
+|}
-'''Standard.''' If used, such signs shall remain at the intersection until power at the non-functioning signalized intersection has been restored (see [[#902.5.43.1.4 Recovery|EPG 902.5.43.1.4 Recovery]]).
+'''For integral end bent simple pile design,''' use Φ<sub>c</sub>  = 0.35 for CIP steel pipe piles and HP piles.  See [[751.35 Concrete Pile Cap Integral End Bents#751.35.2.4.2 Pile Design|Figure 751.35.2.4.2]].
-====902.5.43.1.1 Conditions For Use====
+'''For pile at all locations where integral end bent simple pile design is not applicable,''' use the following:
-'''Guidance.''' TSS may be erected at locations where a signalized intersection is non-functioning. A non-functioning signalized intersection is defined as an intersection that is equipped with a traffic signal that is damaged and/or without power which cannot display proper indications to control traffic.
-After verifying that the signal is non-functioning, Districts should contact the appropriate utility company to notify them of the power outage, if applicable, and to determine if power will be restored in a reasonable amount of time (at the District’s discretion). If used, the TSS should be deployed as soon as practical depending on location of the signalized intersection and the stored TSS. Districts should also request police assistance for traffic control if they are not already present at the site or aware of the power outage. Outside of normal business hours, it might be necessary for the electrician or maintenance personnel to directly contact the highway patrol or local police and the power company. When a signalized intersection is non-functioning, then TSS may be installed when one of the following conditions is met:
+:The structural resistance factor for axial resistance in compression is dependent upon the expected driving conditions. When the pile is subject to damage due to severe driving conditions where use of pile point reinforcement is necessary:
-* When the traffic signal is both damaged and without power, or
+::Steel Shells (Pipe): <math> \phi_c </math>= 0.60
-* When the traffic signal is without power and restoration of power using an alternate power source is not possible.
+::HP Piles: <math> \phi_c </math>= 0.50
+:When the pile is subject to good driving conditions where use of pile point reinforcement is not necessary:
+::Steel Shells (Pipe) Piles: <math> \phi_c </math>= 0.70
+::HP Piles: <math> \phi_c </math>= 0.60
+:For HP piles, pile point reinforcement is always required when HP piles are anticipated to be driven to rock and proofed. Driving HP piles to rock is considered severe driving conditions for determination of structural resistance factor. However, driving HP piles through overburden not likely to impede driving to deep rock or preboring to rock for setting piles are two situations that could be considered as less than severe. Further, driving any steel pile through soil without rubble, boulders, cobbles or very dense gravel could be considered good driving conditions for determination of structural resistance factor. Consult the Structural Project Manager or Structural Liaison Engineer.
+:The structural resistance factor for combined axial and flexural resistance of undamaged piles:
+::Axial resistance factor for HP Piles: <math> \phi_c </math>= 0.70
+::Axial resistance for Steel Shells (Pipe): <math> \phi_c </math>= 0.80
+::Flexural resistance factor for HP Piles or Steel Shells: <math> \phi_f </math>= 1.00
+:For Extreme Event Limit States, see LRFD 10.5.5.3.
+<div id="751.36.5.3 Geotechnical Resistance"></div>
-'''Standard.''' When TSS are utilized at a signalized intersection that is non-functioning, the District shall decide whether the power shall be disconnected or whether the signal should be switched to flash to avoid conflicts when power is restored.  If switched to flash, the flash shall be red-red since TSS will be installed on all approaches, if used, at a signalized intersection without power (dark signals are to be treated like a 4-way stop according to the Missouri Driver’s Guide).  The TSS shall not be displayed at the same time as any signal indication is displayed other than a flashing red.
+===751.36.5.3 Geotechnical Resistance Factor (ϕ<sub>stat</sub>) and Driving Resistance Factor (ϕ<sub>dyn</sub>)===
+The factors for Geotechnical Resistance (<math> \phi_{stat}</math>) and Driving Resistance (<math> \phi_{dyn}</math>) may be different because of the reliability of the different methods used to determine the nominal bearing resistance. Caution should be used if the difference in factors for Geotechnical Resistance and Driving Resistance are great as it can lead to issues with pile overruns. Also see [[#751.36.5.9 Estimate Pile Length and Check Pile Capacity|EPG 751.36.5.9]].
-A request shall be made of the nearest maintenance building, emergency responder, or external emergency responder (whomever stores the TSS) to bring stop signs to the intersection.  Personnel or emergency responders instructed in signal operation shall disconnect the power or switch the signal to flash operation (external emergency responders will do this in the signal cabinet police door) before placing the TSS.  Without this change in operation, the traffic signal could return to steady (stop-and-go) mode within seconds after the signal is repaired or power is restored, which would cause conflicts between the signal and the TSS (conflicting green or yellow indications with a stop sign for the same approach).  The signal shall be visible to traffic on all approaches and all these approaches will flash upon restoration of power (see EPG 902.5.43.2 for more information regarding Startup from Dark).
+'''Geotechnical Resistance Factor, ϕ<sub>stat</sub>:'''
-'''Guidance.''' When law enforcement is present at a non-functioning signalized intersection to direct traffic, then the TSS that have been placed should be covered or removed to avoid conflicts (the law enforcements authority supersedes the TSS).
+The Geotechnical Resistance factor is based on the static method used by the designer in determining the nominal bearing resistance. Unlike the Driving Resistance factor the Geotechnical Resistance factor can vary with the soil layers. If Geotechnical Resistance factors are not provided by the Geotechnical Engineer, the static method and resistance factors shall be selected from the table below. The values provided in LRFD Table 10.5.5.2.3-1 are only applicable if the end of drive criteria is based off the total pile penetration which is not recommended. For Extreme Event Limit States see LRFD 10.5.5.3.
-'''Option.''' If it has been determined that the power outage will last for an extended amount of time (at the district’s discretion) the signal heads may be covered to reduce the confusion of approaching motorists.
+{|border="1" style="text-align:center; width: 750px" cellpadding="5" align="center"  cellspacing="0"
+|+ '''Table - Static Analysis Resistance Factors used for Pile Length Estimates'''
+! Pile Type !! Soil Type !! Static Analysis Method !! Side Friction<sup>1</sup><br><math> \phi_{stat}</math> !! End Bearing<br><math> \phi_{stat}</math>
+|-
+| rowspan="4" | '''CIP Piles - Steel Pipe Shells''' || Clay || Alpha - Tomlinson || <math> \phi_{dyn}</math><sup>2</sup> || <math> \phi_{dyn}</math><sup>2</sup>
+|-
+| rowspan="3" | Sand || Nordlund<sup>3</sup> || 0.45 - Gates<br>0.45 - WEAP<br>0.55 - PDA || 0.45 - Gates<br>0.45 - WEAP<br>0.55 - PDA
+|-
+| LCPC<sup>4</sup> || 0.70 || 0.45
+|-
+| Schmertmann<sup>5</sup> || 0.50 || 0.50
+|}
-'''Guidance.''' If signal heads are covered, the appropriate enforcement agency should be advised and asked to occasionally monitor the intersection.  Also, the power company should be advised and asked to notify proper personnel when the power is restored.
+{|border="0" style="text-align:left; width: 750px" align="center"  cellspacing="0"
+|-
+| <sup>1</sup> For mixed soil profiles the lowest applicable resistance factor for clay or sand may be used to simplify the analysis.
+|-
+| <sup>2</sup>  ϕ<sub>dyn</sub> = see following section.
+|-
+| <sup>3</sup>The Nordlund method is recommended for sand layers in mixed soil profiles where CPT data is not available.
+|-
+| <sup>4</sup>The resistance factors associated with the LCPC method are not statistically calibrated for reliability, but studies have shown this method to be one of the most reliable methods for predicting soil behavior from CPT data.
+|-
+| <sup>5</sup>Per LRFD 10.7.3.8.6g the Schmertmann method shall only be used for sands and nonplastic silts with CPT data.
+|-
+| For more detailed guidance see [https://www.modot.org/media/54989 SEG 25-001 New Policy for Friction Pile].
+|}
-====902.5.43.1.2 Location and Placement====
+'''Driving Resistance Factor, ϕ<sub>dyn</sub>:'''
-'''Standard.''' The signalized intersection locations for installation of TSS shall meet the conditions of use in EPG 902.5.43.1.1 and shall be at the discretion of the district.
-'''Guidance.''' The installation of TSS should be prioritized as follows (as applicable to each district):
+The Driving Resistance factor shall be selected from LRFD Table 10.5.5.2.3-1 based on the method to be used in the field during construction to verify nominal axial compressive resistance.
-# Signals with railroad preemption
-# Signals with a speed limit greater than 50 mph
-# Signals with a high accident rate
-# Intersections difficult to flag or require multiple flaggers (non-routine roadway configurations/geometry, SPUIs, multi-lane approaches, etc.)
-# Signals with high volumes (freeway type off-ramps, major roadways, etc.)
-# Signals with frequent power outages
-# Signals located at schools.
-'''Standard.''' When used, TSS shall be placed in a location where they are visible to all lanes on all roadways. On two-way roadways, stop signs shall be erected on the right-hand side of all approaches. On divided highways, stop signs shall be erected on both the right and, if possible, on the left-hand side or at location for best visibility of all approaches.
+{|border="1" style="text-align:center;" cellpadding="5" align="center"  cellspacing="0"
+! Pile Driving Verification Method !! Resistance Factor,<br/><math> \phi_{dyn}</math>
-'''Guidance.''' If the power outage is widespread, additional personnel should be requested to help with the placement of the signs.
+|-
+| FHWA-modified Gates Dynamic Pile Formula<br/>(End of Drive condition only) || 0.40
-====902.5.43.1.3 Storage and Distribution====
+|-
-'''Standard.''' TSS shall be distributed by the district to the district’s maintenance personnel or emergency responders or external emergency responders on an as-needed basis.  It shall be the responsibility of the district to develop a means of distribution.
+| Wave Equation Analysis (WEAP) || 0.50
+|-
-====902.5.43.1.4 Recovery====
+| Dynamic Testing (PDA) on 1 to 10% piles || 0.65
-'''Standard.''' TSS shall remain at the intersection until power at the non-functioning signalized intersection has been restored.  Power will remain disconnected or the signal will flash until TSS are removed.  Immediately following TSS removal, personnel or emergency responders instructed in signal operation shall restore signal operation in accordance with the procedures set forth in EPG 902.5.43.2 Steady (stop-and-go) Mode for transition to steady (stop-and-go) mode.
+|-
+| Other methods || Refer to LRFD Table 10.5.5.2.3-1
-The recovery of the TSS shall be accomplished by using the district’s maintenance personnel or emergency responders or external emergency responders by either of the following:
+|}
-* Complete removal from each intersection.
-* Stockpiling outside of the intersection to avoid conflicts with the signalized intersection (stockpiled signs shall not be faced towards the traveling public and stored not to damage sheeting) and stored in a location to not become a roadside hazard.
-===902.5.43.2 Start up from Dark at Signalized Intersections===
-'''Standard.''' When a signalized intersection has been damaged and/or is without power the district shall have either disconnected the power or switched the signal to flash to avoid conflicts when power is restored.  If switched to flash, the flash shall be red-red since TSS will be installed on all approaches, if used, at a signalized intersection without power (dark signals are to be treated like a 4-way stop according to the Missouri Drive’s Guide).  If TSS are in place, the power shall remain disconnected or the signal shall operate in flash mode until TSS are removed and personnel or emergency responders instructed in signal operation restore signal operation.
-'''Steady (stop-and-go) Mode'''
+Use [https://epg.modot.org/index.php/751.50_Standard_Detailing_Notes#G7._Steel_HP_Pile EPG 751.50 Standard Detailing Note G7.3] on plans as required for end bearing piles driven to rock. This requirement shall apply to any type of rock meaning weak to strong rock including stronger shales where HP piling is anticipated to meet refusal. The verification method shown on the plans is only used to verify the nominal axial compressive resistance prior to reaching practical refusal. If the practical refusal criterion is met the field verification method shown on the plans is no longer considered valid.
-'''Standard.''' When power is reconnected or when the signal is switched from flash to steady (stop-and-go) mode, the controllers shall be programmed for startup from flash.  The signal shall flash red-red for 7 seconds and then change to steady red clearance for 6 seconds followed by beginning of major-street green interval or if there is no common major-street green interval, at the beginning of the green interval for the major traffic movement on the major street.
+For end bearing piles tipped in shale, sandstone, or rock of uncertain strength at any loading where the likelihood of pile damage is increased, the Foundation Investigation Geotechnical Report (FIGR) should give a recommendation for dynamic pile testing (PDA) or no PDA. For most end bearing piles, where a recommendation for field verification is not given in the FIGR, the designer will need to determine whether gates or WEAP is required for the pile driving verification method based on the loading demands on the pile or other factors.
-===902.5.43.3 Battery Backup Systems at Signalized Intersections===
+For piles bearing on hard rock with MNACR less than 600 kips, FHWA-modified Gates Dynamic Pile Formula should be listed as verification method, and practical refusal criterion should control end of driving criteria. FHWA-modified Gates Dynamic Pile Formula is not considered accurate for pile loading (Minimum Nominal Axial Compressive Resistance) exceeding 600 kips. When pile loading exceeds 600 kips, use wave equation analysis, dynamic testing, or other method. Consideration should be given to using additional piles to reduce the MNACR below 600 kips.
-====902.5.43.3.1 Installation/Placement====
+Under special circumstances when rock limits or conditions are nonuniform, WEAP should be considered in order to limit pile damage since it requires further scrutiny of the site conditions with the proposed pile driving system.
-'''Guidance.''' The installation of Battery Backup Systems(BBS) should be prioritized as follows (as applicable to each district):
-# Signals with railroad preemption
-# Signals with a speed limit greater than 50 mph
-# Signals with a high accident rate
-# Intersections difficult to flag or require multiple flaggers (non-routine roadway configurations/geometry, SPUIs, multi-lane approaches, etc.)
-# Signals with high volumes (freeway type off-ramps, major roadways, etc.)
-# Signals with frequent power outages
-# Signals located at schools.
-====902.5.43.3.2 Duration====
-'''Standard.''' BBS shall be capable of operating at a minimum of 2 hours in steady (stop-and-go) mode and a minimum of 2 hours in flash operation.
-'''Guidance.''' Any signalized intersection with BBS should have a generator socket for extended operation.
-----
-='''REVISION REQUEST 4066'''=
-==751.50 Standard Detailing Notes==
-<big>'''Delete Notes B3.5 and B3.6'''</big>
- '''(B3.5) Use for CIP pile in all bridges except for continuous concrete slab bridges.'''
- All reinforcement in cast-in-place pile at non-integral end bents and intermediate bents is included in the substructure quantities.
- '''(B3.6) Use for CIP pile in continuous concrete slab bridges.'''
- All reinforcement in cast-in-place pile at end bents and pile cap intermediate bents is included in the superstructure quantities and all reinforcement in cast-in-place pile at open concrete intermediates bents is included in the substructure quantities.
-=== G5. CIP Concrete Piles (Notes for Bridge Standard Drawings)===
-====G5a Closed Ended Cast-in Place (CECIP) Concrete Pile====
-'''(G5a1)'''
-:Welded or seamless steel shell (pipe) shall be ASTM A252 Modified Grade 3 (fy = 50,000 psi) with physical and chemical requirements that meet ASTM A572 Grade 50. Pipe certification and source material certification shall be required.
-'''(G5a2)'''
-:Concrete for cast-in-place pile shall be Class B-1.
-'''(G5a3)'''
-:Steel for closure plate shall be ASTM A709 Grade 50.
-'''(G5a4)'''
-:Steel for cruciform pile point reinforcement shall be ASTM A709 Grade 50.
-'''(G5a5)'''
-:Steel casting for conical pile point reinforcement shall be ASTM A148 Grade 90-60.
-'''(G5a6)'''
-:The minimum wall thickness of any spot or local area of any type shall not be more than 12.5% under the specified nominal wall thickness.
-'''(G5a7)'''
-:Closure plate shall not project beyond the outside diameter of the pipe pile. Satisfactory weldments may be made by beveling tip end of pipe or by use of inside backing rings. In either case, proper gaps shall be used to obtain weld penetration full thickness of pipe. Payment for furnishing and installing closure plate will be considered completely covered by the contract unit price for Galvanized Cast-In-Place Concrete Piles.
-'''(G5a8)'''
-:Splices of pipe for cast-in-place concrete pile shall be made watertight and to the full strength of the pipe above and below the splice to permit hard driving without damage. Pipe damaged during driving shall be replaced without cost to the state. Pipe sections used for splicing shall be at least 5 feet in length.
-'''(G5a9a) Use the following note for seismic category A'''
-:At the contractor's option, the hooks of vertical bars embedded in the beam cap may be oriented inward or outward.
-'''(G5a9b) Use the following note for seismic category B, C or D '''
-:The hooks of vertical bars embedded in the beam cap should not be turned outward, away from the pile core.
-'''(G5a10)'''
-:The hooks of vertical bars embedded in the pile cap footing should be oriented outward for all seismic categories.
-'''(G5a11)'''
-:Closure plate need not be galvanized.
-'''(G5a12) '''
-:Reinforcing steel for cast-in-place pile is included in the Bill of Reinforcing Steel.
-'''(G5a13) Use for CIP pile on all bridges except for continuous concrete slab bridges. Remove underlined portion for non-integral end bents.'''
-:All reinforcement for cast-in-place pile <u>at end bents is included in the Estimated Quantities for Slab on _____. Reinforcement for cast-in-place pile at intermediate bents</u> is included in the substructure quantity tables.
-'''(G5a14) Use for CIP pile on continuous concrete slab bridges. The first underlined portion is included for pile cap intermediate bents. The second underlined portion is included for intermediate bents with pile footings.'''
-:All reinforcement in cast-in-place pile at end bents <u>and intermediate bents</u> is included in the superstructure quantities <u>and all reinforcement in cast-in-place pile at intermediates bents is included in the substructure quantity tables</u>.
-'''(G5a15)'''
-:The contractor shall determine the pile wall thickness required to avoid damage from all driving activities, but wall thickness shall not be less than the minimum specified.  No additional payment will be made for furnishing a thicker pile wall than specified on the plans.
-====G5b Open Ended Cast-in Place (OECIP) Concrete Pile====
-'''(G5b1)'''
-:Welded or seamless steel shell (pipe) shall be ASTM A252 Modified Grade 3 (fy = 50,000 psi) with physical and chemical requirements that meet ASTM A572 Grade 50. Pipe certification and source material certification shall be required.
-'''(G5b2)'''
+Dynamic Testing is recommended for projects with friction piles where the soil profile is comprised primarily of sand. For bridges where the soil profile is comprised primarily of clays or evenly mixed clays and sands the recommended verification method is WEAP. When WEAP is specified as the pile driving criteria for friction pile, provide standard note E2.28 below the foundation table. For more detailed guidance see [https://www.modot.org/media/54989 SEG 25-001 New Policy for Friction Pile].
-:Open ended pile shall be augered out to the minimum pile cleanout penetration elevation and filled with Class B-1 concrete.
-'''(G5b3)'''
+===751.36.5.4 Downdrag and Losses to Geotechnical Resistance due to Scour and Liquefaction===
-:Concrete for cast-in-place pile shall be Class B-1.
-'''(G5b4)'''
+Downdrag and Losses to Geotechnical Resistance due to Scour and Liquefaction (kips), '''LRFD 10.7.3.6, 10.7.3.7, and AASHTO Guide Specifications for LRFD Seismic Bridge Design (SGS) 6.8.'''
-:Steel casting for open ended cutting shoe pile point reinforcement shall be ASTM A148 Grade 90-60.
-'''(G5b5)'''
+Downdrag, liquefaction and scour all reduce the available skin friction capacity of piles.  Downdrag <math>\, (DD)</math> is unique because it not only causes a loss of capacity, but also applies a downward force to the piles.  This is usually attributed to embankment settlement.  However, downdrag can also be caused by a non-liquefied layer overlying a liquefied layer.  Review geotechnical report for downdrag and liquefaction information.
-:The minimum wall thickness of any spot or local area of any type shall not be more than 12.5% under the specified nominal wall thickness.
-'''(G5b6)'''
+===751.36.5.5 Preliminary Structural Nominal Axial Design Capacity (PNDC) of an individual pile ===
-:Splices of pipe for cast-in-place pipe pile shall be made watertight and to the full strength of the pipe above and below the splice to permit hard driving without damage. Pipe damaged during driving shall be replaced without cost to the state. Pipe sections used for splicing shall be at least 5 feet in length.
-'''(G5b7a) Use the following note for seismic category A'''
+The PNDC equations provided herein assume the piles are continually braced. This assumption is applicable for the portion of piling below ground or confined by solid wall encasement. If designing a pile bent structure, scour exists or liquefaction exists, then the pile shall be checked considering the appropriate unbraced length.
-:At the contractor's option, the hooks of vertical bars embedded in the beam cap may be oriented inward or outward.
-'''(G5b7b) Use the following note for seismic category B, C or D'''
+'''Structural Steel HP Piles'''
-:The hooks of vertical bars embedded in the beam cap should not be turned outward, away from the pile core.
-'''(G5b8)'''
+:<math>\, PNDC = 0.66^\lambda F_y A_S</math>
-:The hooks of vertical bars embedded in the pile cap footing should be oriented outward for all seismic categories.
-'''(G5b9)'''
+:Since we are assuming the piles are continuously braced, then <math>\,\lambda</math>= 0.
-:Reinforcing steel for cast-in-place pile is included in the Bill of Reinforcing Steel.
-'''(G5b10) Use for CIP pile on all bridges except for continuous concrete slab bridges. Remove underlined portion for non-integral end bents.'''
+:{|
-:All reinforcement for cast-in-place pile <u>at end bents is included in the Estimated Quantities for Slab on _____. Reinforcement for cast-in-place pile at intermediate bents</u> is included in the substructure quantity tables.
+|<math>\, F_y</math>||is the yield strength of the pile
+|-
+|<math>\, A_S</math>||is the area of the steel pile
+|}
-'''(G5b11) Use for CIP pile on continuous concrete slab bridges. The first underlined portion is included for pile cap intermediate bents. The second underlined portion is included for intermediate bents with pile footings.'''
+'''Welded or Seamless Steel Shell (Pipe) Cast-In-Place Piles (CIP Piles)'''
-:All reinforcement in cast-in-place pile at end bents <u>and intermediate bents</u> is included in the superstructure quantities <u>and all reinforcement in cast-in-place pile at intermediates bents is included in the substructure quantity tables</u>.
-'''(G5b12)'''
+:<math>\, PNDC = 0.85 f'_c Ac+F_y A_{st}</math>
-:The contractor shall determine the pile wall thickness required to avoid damage from all driving activities, but wall thickness shall not be less than the minimum specified.  No additional payment will be made for furnishing a thicker pile wall than specified on the plans.
+:{|
+|<math>\, F_y</math>||is the yield strength of the pipe pile
+|-
+|valign="top"|<math>\, A_{st}</math>||is the area of the steel pipe (deducting 12.5 % ASTM tolerance and 1/16 inch corrosion where appropriate.)
+|-
+|<math>\, f'_c</math>||is the concrete compressive strength at 28 days
+|-
+|<math>\, Ac</math>|| is the area of the concrete inside the pipe pile
+|}
+:Maximum Load during pile driving = <math>\, 0.90 (f_y A_{st})</math>
-----
+Welded or Seamless Steel Shell shall be ASTM A252 Modified Grade 3 (50 ksi). ASTM A252 states “the wall thickness at any point shall not be more than 12.5% under the specified nominal wall thickness.” AASHTO recommends deducting 1/16” of the wall thickness due to corrosion (LRFD 5.13.4.5.2). Corrosion need not be considered at construction stage and for drivability analysis and static analysis. For drivability analysis and static analysis deduct 12.5% of specified nominal wall thickness (ASTM A252). For structural design deduct 12.5 % (ASTM A252) and 1/16” for corrosion (LRFD 5.13.4.5.2) from specified nominal wall thickness.
-='''REVISION REQUEST 4071'''=
+===751.36.5.6 Preliminary Factored Axial Design Capacity (PFDC) of an Individual Pile ===
+:PFDC = Structural Factored Axial Compressive Resistance – Factored Downdrag Load
-====751.1.2.9.2 Steel Girder Options====
+===751.36.5.7 Design Values for Steel Pile===
-When considering steel structures, the preliminary designer must decide if the girders should be painted or fabricated from weathering steel.  If site-specific conditions allow, the use of unpainted weathering steel (ASTM A709 Grades 50W and HPS70W) should be considered and is MoDOT’s preferred system for routine steel I-girder type bridges due to its performance, economic and environmental benefits.  Cost savings are realized because of the elimination of the initial paint system as well as the need for periodic renewal of the paint system over the life of the structure.
+====751.36.5.7.1 Integral End Bent Simple Pile Design ====
+The following design values may be used for integral end bents where the simple pile design method is applicable per [[751.35 Concrete Pile Cap Integral End Bents#751.35.2.4.2 Pile Design|EPG 751.35.2.4.2 Pile Design]].  These values are not applicable for soils subject to liquefaction or scour where  unbraced lengths may alter the design.
-Weathering steels provide significant environmental and worker safety benefits as well.  Since they do not require initial and periodic repainting of the whole bridge, emissions of volatile organic compounds (VOC) are reduced.  Also, they generally do not require coating removal or disposal of contaminated blast debris over the service life of the structure.  By eliminating the need for periodic repainting, the closing of traffic lanes can be prevented as well as the associated hazards to painters, maintenance workers, and the travelling public.
+=====751.36.5.7.1.1 Design Values for Individual HP Pile=====
-Partial coating of weathering steel is required near expansion joints.  See [[751.14 Steel Superstructure#751.14.5.8 Protective Coating Requirements|EPG 751.14.5.8]].  Periodic recoating or overcoating will be required, however, on a much smaller scale than the whole bridge with the effect that lane closures and associated hazards are greatly reduced compared to painted steel.
+<center>
+F<sub>y</sub> = 50 ksi. End Bearing Piles (HP piles) anticipated to be driven to rock.
-Although weathering steel is MoDOT’s preferred system for routine I-girder bridges with proper detailing, it should not be used for box girders, trusses or other structure types where details may tend to trap moisture or debris.  There are also some situations where the use of weathering steel may not be advisable due to unique environmental circumstances of the site.  Generally, these types of structures would receive high deposits of salt along with humidity, or long-term wet conditions and individually each circumstance could be considered critical.
+{|border="1" style="text-align:center;" cellpadding="5" align="center"  cellspacing="0"
+!Pile Size!!A<sub>s</sub><br/>Area,<br/>sq. in.!!Structural<br/>Nominal<br/>Axial<br/>Compressive<br/>Resistance<br/>PNDC<sup>1,2</sup>,<br/>kips!!Φ<sub>c</sub><br/>Structural<br/>Resistance<br/>Factor<sup>4,5</sup>,<br/>LRFD 6.5.4.2!!Structural<br/>Factored<br/>Axial<br/>Compressive<br/>Resistance<sup>2,3,4</sup>,<br/>kips!!0.9*ϕ<sub>da</sub>*F<sub>y</sub><br/>Maximum<br/>Nominal<br/>Driving<br/>Stress,<br/>LRFD 10.7.8,<br/>ksi
-The FHWA Technical Advisory T5140.22 October 1989 should be used as guidance when determining the acceptability of weathering steel. Due to the large amounts of deicing salts used on our highways which ultimately causes salt spray on bridge girders, the flowchart below should be used as guidance for grade separations. The flowchart, Fig. 751.1.2.9, below, is general guidance but is not all inclusive. There may be cases based on the circumstances of the bridge site where the use of weathering steel is acceptable even though the flowchart may indicate otherwise. In these cases, follow MoDOT’s [[131.1 Design Exception Process|design exception process]].
-[[image:751.1.2.7 weathering steel Nov 2010.jpg|center|650px|thumb|<center>'''Fig. 751.1.2.9 Guidance on the Use of Weathering Steel for Grade Separations'''</center>
-'''*''' For multi-lane divided or undivided highways, consider the AADT and AADTT in one direction only.]]
-<div id="Weathering steel may be used"></div>
-Weathering steel may be used for stream crossings where 1) the base flood elevation is lower than the bottom of girder elevation and 2) the difference between the ordinary high water and bottom of girder elevations is greater than 10 ft. for stagnant and 8 ft. for moving bodies of water.  Where the difference in elevations is less than noted, weathering steel may be used upon approval of the Assistant State Bridge Engineer.
-Additional documents that can be referenced to aid in identifying the site-specific locations and details that should be avoided when the use of weathering steel is being considered include:
-:1. Transportation Research Board. (1989).  ''Guidelines for the use of Weathering Steel in Bridges'', (NCHRP Report 314). Washington, DC: Albrecht, et al.
-:2. American Iron and Steel Institute. (1995).  ''Performance of Weathering Steel in Highway Bridges, Third Phase Report''. Nickerson, R.L.
-:3. American Institute of Steel Construction. (2022). Uncoated Weathering Steel Reference Guide. NSBA
-:4. MoDOT. (1996). ''Missouri Highway and Transportation Department Task Force Report on Weathering Steel for Bridges''. Jefferson City, MO: Porter, P., et al.
-The final brown rust appearance could be an aesthetic concern.  When determining the use of weathering steel, aesthetics and other concerns should be discussed by the Core Team members, with input from [https://modotgov.sharepoint.com/sites/br Bridge Division] and [https://modotgov.sharepoint.com/sites/mt Maintenance Division].
-If weathering steel cannot be used, the girders should be painted gray (Federal Standard #26373).  If the district doesn’t want gray, they can choose brown (Federal Standard #30045).  If the district or the local municipality wants a color other than gray or brown, they must meet the requirements of [[1045.5_Policy_on_Color_of_Structural_Steel_Paint|EPG 1045.5 Policy on Color of Structural Steel Paint]]. See [[751.6_General_Quantities#751.6.2.11_Structural_Steel_Protective_Coatings_.28Non-weathering Steel.29|EPG 751.6.2.11]], [[751.6 General Quantities#751.6.2.12 Structural Steel Protective Coatings (Weathering Steel)|EPG 751.6.2.12]] and [[751.14 Steel Superstructure#751.14.5.8 Protective Coating Requirements|EPG 751.14.5.8]] for further guidance on paint systems.
-===751.6.1 Index of Quantities===
-{| class="wikitable" style="text-align:center"
 |-
-| colspan="4" align="left" | '''Sec 712 – Structural Steel Construction'''
+|HP 12x53||				15.5||	775||	0.35||	271||	45.00
 |-
-| 712-09.00 || 1 || linear foot || align="left" | Expansion Device (Finger Plate)
+|HP 14x73||				21.4||	1070||	0.35||	375||	45.00
 |-
-| 712-09.15 || 1 || linear foot || align="left" | Expansion Device (Flat Plate)
+|colspan="6" align="left"|'''<sup>1</sup>''' Structural Nominal Axial Compressive Resistance for fully embedded piles only. <br/><br/>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;Minimum Nominal Axial Compressive Resistance  =  Required nominal driving resistance, R<sub>ndr</sub><br/>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; = (Maximum factored axial loads / ϕ<sub>dyn</sub>) ≤ Structural nominal axial compressive resistance, PNDC &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;LRFD 10.5.5.2.3<br/><br/>
+'''<sup>2</sup>''' Axial Compressive Resistance values shown above shall be reduced when downdrag is considered.
+<br/><br/>'''<sup>3</sup>''' Maximum factored axial load per pile  ≤  Structural factored axial compressive resistance.
+<br/><br/>'''<sup>4</sup>''' Values are applicable for Strength Limit States.
+<br/><br/>'''<sup>5</sup>''' Use (Φ<sub>c</sub>) = 0.35 instead of 0.5 for structural resistance factor (LRFD 6.5.4.2)
+<br/><br/><br/>'''Notes:
+<br/><br/>ϕ<sub>dyn</sub> = Resistance factor of the dynamic method to be used to estimate nominal pile resistance during pile installation.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;	LRFD Table 10.5.5.2.3-1
+<br/><br/>For more information about selecting pile driving verification methods refer to [[751.36_Driven_Piles#751.36.5.3_Geotechnical_Resistance_Factor_.28.CF.95stat.29_and_Driving_Resistance_Factor_.28.CF.95dyn.29|EPG 751.36.5.3 Geotechnical Resistance Factor (ϕ<sub>stat</sub>) and Driving Resistance Factor (ϕ<sub>dyn</sub>)]].
+<br/><br/>Drivability analysis shall be performed for all HP piles using Delmag D19-42.  Do not show minimum hammer energy on plans.
+<br/><br/>Check drivability for all HP Pile in accordance with [[#751.36.5.11 Check Pile Drivability|EPG 751.36.5.11]]
+<br/><br/>For additional design requirements, see [[#751.36.5.1 Design Procedure Outline|EPG 751.36.5.1]].
+|}
+</center>
+=====751.36.5.7.1.2 Design Values for Individual Cast-In-Place (CIP) Pile=====
+<center>
+Modified Grade 3 F<sub>y</sub> = 50 ksi; F'<sub>c</sub> = 4 ksi; Structural Axial Compressive Resistance Factor, (Φ<sub>c</sub>)<sup>1,3</sup> = 0.35
+{|border="1" style="text-align:center;" cellpadding="5" align="center" cellspacing="0"
 |-
-| 712-10.00 || 10 || pound || align="left" | Fabricated Structural Carbon Steel (Misc.)
+! colspan="8" | Unfilled Pipe For Axial Analysis<sup>2</sup>
 |-
-| 712-10.10 || 10 || pound || align="left" | Fabricated Structural Carbon Steel (I-Beam)
+! Pile Outside Diameter O.D., in. !! Pile Inside Diameter I.D., in. !! Minimum Wall Thickness, in. !! Reduced Wall thick. for Fabrication (ASTM A252), in. !! A<sub>s</sub>,<sup>4</sup><br/>Area<br/>of<br/>Steel<br/>Pipe,<br/>sq. in. !! Structural<br/>Nominal<br/>Axial<br/>Compressive<br/>Resistance<br/>P<sub>n</sub><sup>5,6,7</sup>,<br/>kips !! Structural<br/>Factored Axial<br/>Compressive<br/>Resistance<sup>1,7,8</sup>,<br/>kips !! 0.9*ϕ<sub>da</sub>*F<sub>y</sub>*A<sub>s</sub><br/>Maximum<br/>Nominal<br/>Driving<br/>Resistance<sup>6</sup>,<br/>LRFD 10.7.8,<br/>kips
 |-
-| 712-10.20 || 10 || pound || align="left" | Fabricated Structural Carbon Steel (Plate Girder)
+| rowspan="2" | 14 || 13 || 0.5 || 0.44 || 18.47 || 923 || 323 || 831
 |-
-| 712-10.30 || 10 || pound || align="left" | Fabricated Structural Carbon Steel (Trusses)
+| 12.75 || 0.625<sup>9</sup> || 0.55 || 22.84 || 1142 || 400 || 1028
 |-
-| 712-10.40 || 10 || pound || align="left" | Fabricated Structural Carbon Steel (Concrete)
+| rowspan="2" | 16 || 15 || 0.5 || 0.44 || 21.22 || 1061 || 371 || 955
 |-
-| 712-10.50 || 10 || pound || align="left" | Fabricated Structural Carbon Steel (Box Girder)
+| 14.75 || 0.625<sup>9</sup> || 0.55 || 26.28 || 1314 || 460 || 1183
 |-
-| 712-10.60 || 1 || lump sum || align="left" | Fabricated Sign Support Brackets
+| rowspan="2" | 20 || 19 || 0.5 || 0.44 || 26.72 || 1336 || 468 || 1202
 |-
-| 712-11.00 || 10 ||pound || align="left" | Fabricated Structural Low Alloy Steel (Misc.)
+| 18.75 || 0.625 || 0.55 || 33.15 || 1658 || 580 || 1492
 |-
-| 712-11.11 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (I-Beam) A709, Grade 50
+| rowspan="3" | 24 || 23 || 0.5 || 0.44 || 32.21 || 1611 || 564 || 1450
 |-
-| 712-11.13 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (I-Beam) A709, Grade 50W
+| 22.75 || 0.625 || 0.55 || 40.03 || 2001 || 700 || 1801
 |-
-| 712-11.21 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (Plate Girder) A709, Grade 50
+| 22.5 || 0.75 || 0.66 || 47.74 || 2387 || 835 || 2148
 |-
-| 712-11.22 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (Plate Girder) A709, Grade 50W
+| colspan="8" align="left" |
-|-
+'''<sup>1</sup>'''Values are applicable for Strength Limit States.
-| 712-11.23 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (Plate Girder) A709 Grade HPS70W
-|-
+'''<sup>2</sup>''' Use to determine preliminary number of pile and pile size. For piles predominantly embedded and tipped in cohesionless soils the maximum loads provided in [[#751.36.5.10 Pile Nominal Axial Compressive Resistance|EPG 751.36.5.10]] will control.
-| 712-11.24 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (Plate Girder) A709 Grade HPS50W
-|-
+'''<sup>3</sup>''' Use (Φ<sub>c</sub>) = 0.35 instead of 0.6 for structural axial compressive resistance factor (LRFD 6.5.4.2). Since ϕ<sub>dyn</sub> >> Φ<sub>c</sub> the maximum nominal driving resistance may not control.
-| 712-11.30 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (Trusses)
-|-
-| 712-11.40 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (Concrete)
-|-
-| 712-11.51 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (Box Girder) A709, Grade 50
-|-
-| 712-11.52 || 10 || pound || align="left" | Fabricated Structural Low Alloy Steel (Box Girder) A709, Grade 50W
-|-
-| 712-11.59 || 1 || each || align="left" | Shear Connectors
-|-
-| 712-11.60 || 1 || sq. foot || align="left" | Steel Grid Floor (Half Concrete Filled)
-|-
-| 712-11.61 || 1 || sq. foot || align="left" | Steel Grid Floor (Concrete Filled)
-|-
-| 712-12.50 || 1 || lump sum || align="left" | Strengthening Existing Beams
-|-
-| 712-12.51 || 1 || each || align="left" | Hinge Modification
-|-
-| 712-13.00 || 10 || pound || align="left" | Fabricated Structural Steel Bearings
-|-
-| 712-20.00 || 10 || pound || align="left" | Carbon Steel Castings
-|-
-| 712-22.00 || 10 || pound || align="left" | Gray Iron Castings
-|-
-| 712-23.00 || 1 || linear foot || align="left" | Bridge Rail (Two Tube Structural Steel)
-|-
-| 712-30.00 || 1 || each || align="left" | Steel Bar Dam
-|-
-| 712-31.00 || 1 || each || align="left" | Cleaning and Coating Existing Bearings
-|-
-| 712-31.10 || 1 || each || align="left" | Bearing Removal for Inspection
-|-
-| 712-31.15 || 1 || each || align="left" | Surface Finishing Bearing Rocker
-|-
-| 712-31.20 || 1 || each || align="left" | Cleaning, Lubricating and Coating Bearing
-|-
-| 712-31.30 || 1 || each || align="left" | Rehabilitate Bearing
-|-
-| 712-31.40 || 10 || pound || align="left" | New Bearing Materials
-|-
-| 712-31.50 || 1 || each || align="left" | Anchor Bolt Replacement
-|-
-| 712-32.00 || 1 || each || align="left" | Removing, Coating and Reinstalling Light Standards (Bridges)
-|-
-| 712-32.10 || 1 || each || align="left" | Earthquake Restrainer Assemblies
-|-
-| 712-32.50 || 1 || each || align="left" | Rivet Removal and Replacement
-|-
-| 712-33.00 || 1 || lump sum || align="left" | Existing Diaphragm Connections to Flange
-|-
-| 712-33.01 || 1 || each || align="left" | Steel Intermediate Diaphragm for P/S Concrete Girders
-|-
-| 712-35.00 || 1 || linear foot || align="left" | Railing for Steps
-|-
-| 712-36.10 || 1 || each || align="left" | Slab Drain
-|-
-| 712-36.11 || 1 || each || align="left" | Slab Drain with Grate
-|-
-| 712-36.20 || 1 || lump sum || align="left" | Drainage System (On Structure)
-|-
-| 712-51.00 || 1 || lump sum || align="left" | Surface Preparation for Recoating Structural Steel
-|-
-| 712-51.01 || 1 || lump sum || align="left" | Surface Preparation for Overcoating Structural Steel (System G)
-|-
-| 712-51.02 || 1 || lump sum || align="left" | Surface Preparation for Applying Epoxy-Mastic Primer
-|-
-| 712-51.09 || 1 || lump sum || align="left" | Field Application of Organic Zinc Primer
-|-
-| 712-51.10 || 1 || lump sum || align="left" | Field Application of Inorganic Zinc Primer
-|-
-| 712-51.11 || 1 || lump sum || align="left" | Intermediate Field Coat (System G)
-|-
-| 712-51.12 || 1 || lump sum || align="left" | Finish Field Coat (System G)
-|-
-| 712-51.13 || 1 || lump sum || align="left" | Intermediate Field Coat (System H)
-|-
-| 712-51.14 || 1 || lump sum || align="left" | Finish Field Coat (System H)
-|-
-| 712-51.15 || 1 || lump sum || align="left" | Finish Field Coat (System I)
-|-
-| 712-51.16 || 1 || lump sum || align="left" | Finish Field Coat (System L)
-|-
-| 712-52.00 || 100 || sq. foot || align="left" | Surface Preparation for Recoating Structural Steel
-|-
-| 712-52.01 || 100 || sq. foot ||align="left" | Surface Preparation for Overcoating Structural Steel (System G)
-|-
-| 712-52.09 || 100 || sq. foot || align="left" | Field Application of Organic Zinc Primer
-|-
-| 712-52.10 || 100 || sq. foot || align="left" | Field Application of Inorganic Zinc Primer
-|-
-| 712-53.15A || 0.1 || ton || align="left" | Intermediate Field Coat (System G)
-|-
-| 712-53.20A || 0.1 || ton || align="left" | Finish Field Coat (System G)
-|-
-| 712-53.35A || 0.1 || ton || align="left" | Intermediate Field Coat (System H)
-|-
-|| 712-53.40A || 0.1 || ton || align="left" | Finish Field Coat (System H)
-|-
-| 712-53.46 || 0.1 || ton || align="left" | Finish Field Coat (System I)
-|-
-| 712-53.47 || 0.1 || ton || align="left" | Finish Field Coat (System L)
-|-
-| 712-53.65A || 100 || sq. foot || align="left" | Intermediate Field Coat (System G)
-|-
-| 712-53.70A || 100 || sq. foot || align="left" | Finish Field Coat (System G)
-|-
-| 712-53.85A || 100 || sq. foot || align="left" | Intermediate Field Coat (System H)
-|-
-| 712-53.90A || 100 ||sq. foot || align="left" | Finish Field Coat (System H)
-|-
-| 712-53.96 || 100 || sq. foot || align="left" | Finish Field Coat (System I)
-|-
-| 712-53.97 || 100 || sq. foot || align="left" | Finish Field Coat (System L)
-|-
-| 712-59.60 || 1 || lump sum || align="left" | Aluminum Epoxy-Mastic Primer
-|-
-| 712-59.61 || 1 || lump sum || align="left" | Gray Epoxy-Mastic Primer
-|-
-| 712-60.00 || 1 || linear foot || align="left" | Non-Destructive Testing
-|-
-| 712-99.01 || 1 || lump sum || align="left" | Galvanizing Structural Steel
-|-
-| 712-99.02 || 1 || each || align="left" | Misc.
-|-
-| 712-99.03 || 1 || linear foot || align="left" | Misc.
-|-
-| 712-99.04 || 1 || sq. foot || align="left" | Misc.
-|-
-| 712-99.05 || 1 || sq. yard || align="left" | Misc.
-|-
-| 712-99.10 || 0.1 || ton || align="left" | Misc.
-|-
-| 712-99.11 || 10 || pound || align="left" | Misc.
-|-
-|}
+'''<sup>4</sup>''' Corrosion NOT considered at construction stage and for drivability analysis and static analysis. For drivability analysis and static analysis use reduced pipe nominal wall thickness, 12.5%, for fabrication (ASTM A252).
+'''<sup>5</sup>''' Structural Nominal Axial compressive resistance for fully embedded piles only.
-====751.6.2.11 Structural Steel Protective Coatings (Non-weathering Steel)====
+'''<sup>6</sup>''' Minimum Nominal Axial Compressive Resistance = Required nominal driving resistance, R<sub>ndr</sub>
-The protective coating, as specified on the Design Layout, shall be System G, H, I or L with the color being gray or brown. The coating color shall be specified on the Design Layout. The following gives pay item guidelines for most bridges.
+&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; = Maximum factored axial loads / ϕ<sub>dyn</sub> ≤ Structural nominal axial compressive resistance, P<sub>n</sub> and &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; LRFD 10.5.5.2.3
-Note: The figures in this section are provided to aid in interpretation of the specifications and do not intend to represent a preference for any particular system.
+&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; ≤ Maximum nominal driving resistance.
-'''<u>Coating New Multi-Girder/Beam Bridges</u> '''
+'''<sup>7</sup>''' Axial Compressive Resistance values shown above shall be reduced when downdrag is considered.
-Intermediate Field Coat and Finish Field Coat (System G, H, I or L) (Gray or Brown) - The quantity shall be computed to the nearest one hundred square foot of structural steel to be field coated. The area computations do not include bearings, diaphragms, stiffeners and all other miscellaneous steel within the limits of the field coatings.
+'''<sup>8</sup>''' Maximum factored axial load per pile ≤ Structural factored axial compressive resistance.
-'''1. Bridges over Roadways''' (does not include over Railroads)
+'''<sup>9</sup>''' 5/8” wall thickness is less commonly available than the smaller wall thicknesses of pipe pile.
-The intermediate field coat for System G and H and the finish field coat for System L for beam and girder spans shall be applied to the surfaces of all structural steel except those surfaces to be in contact with concrete. The field coat shall also be applied to the bearings, except where bearings will be encased in concrete.
+'''Notes: '''
-The finish field coat for System G or H for beam and girder spans shall include the facia girders or beams. The limits of the facia girders or beams shall include the bottom of the top exterior flanges, the top of the bottom exterior flanges, the exterior web area, the exterior face of the top and bottom flanges, and the bottom of the bottom flange. Areas of steel to be in contact with concrete shall not receive the finish coat. The finish coat shall also be applied to the exterior bearings, except where bearings will be encased in concrete.
+Drivability analysis shall be performed for all CIP piles (unfilled pipe) using Delmag D19-42. Do not show minimum hammer energy on plans.
-The surfaces of all structural steel located under expansion joints of beam and girder spans shall be field coated with intermediate and finish coats for a distance of one and a half times the girder depth, but not less than 10 feet from the center line of the joint. Within this limit, the items to be field coated shall include all surfaces of beams, girders, bearings, diaphragms, stiffeners and miscellaneous structural steel items. Areas of steel to be in contact with concrete shall not receive the field coats.
+Check drivability for all CIP Pile in accordance with [[#751.36.5.11 Check Pile Drivability|EPG 751.36.5.11]].
-<div id="When System I finish field coat"></div>
+Require dynamic pile testing for field verification for all CIP piles on the plans. <br/>ϕ<sub>dyn</sub> = 0.65 = Dynamic Testing resistance factor to be used to estimate nominal pile resistance during pile installation. This value may be increased if static load testing is specified per LRFD Table 10.5.5.2.3-1.
-When System I finish field coat is specified on the plans with System G intermediate coat, System I finish field coat quantity will be figured the same as above for the finish field coat for System G or H. System G intermediate coat with System I finish field coat will be as above for the intermediate field coat except that the area of the System I finish field coat will not be included in the System G intermediate field coat area. When the plans state System I finish field coat shall be substituted for System G intermediate coat, System I finish field coat quantity will be figured for all girder surfaces as discussed above for finish field coat area for System L.
-{| style="text-align: center; font-size:1.6em", align="center"
+For additional design requirements, see [[#751.36.5.1 Design Procedure Outline|EPG 751.36.5.1]].
-|-
-| COLSPAN="3" | <u>'''New Non-Weathering Bridge Over Roadway'''</u>
-|-
-| [[image:751.6.2.11-Typical Roadway.jpg|center|x300px]] || style="width: 50px" | || [[image:751.6.2.11-Deck Joints Roadway.jpg|center|x300px]]
-|-
-| '''Typical Coating for System G''' || ||'''Coating Near Deck Joints (System G)'''
-|-
 |}
+</center>
-'''2. Bridges over Streams and Bridges over Railroads '''
+====751.36.5.7.2 General Pile Design====
-The field coatings (including intermediate and finish coats) for beam and girder spans shall include the facia girders or beams. The limits of the facia girders or beams shall include the bottom of the top exterior flanges, the top of the bottom exterior flanges, the exterior web area, the exterior face of the top and bottom flanges, and the bottom of the bottom flange. Areas of steel to be in contact with concrete shall not receive the field coats. The field coatings shall also be applied to the exterior bearings, except where bearings will be encased in concrete. The interior beams or girders shall only have the prime coat applied with no other field coatings required.
+The following design values are recommended for general use where the simple pile design method is not applicable per [[751.35 Concrete Pile Cap Integral End Bents#751.35.2.4.2 Pile Design|EPG 751.35.2.4.2 Pile Design]].  These values are not applicable for soils subject to liquefaction or scour where unbraced lengths may alter the design.
-The surfaces of all structural steel located under expansion joints of beam and girder spans shall be field coated with intermediate and finish coats for a distance of one and a half times the girder depth, but not less than 10 feet from the center line of the joint. Within the limit, the items to be field coated shall include all surfaces of beams, girders, bearings, diaphragms, stiffeners and miscellaneous structural steel items. Areas of steel to be in contact with concrete shall not receive the field coats.
+=====751.36.5.7.2.1 Design Values for Individual HP Pile=====
-When System I or L is specified, the intermediate field coat will not be required.
+<center>
+F<sub>y</sub> = 50 ksi. End Bearing Piles (HP piles) anticipated to be driven to rock.
-{| style="text-align: center; font-size:1.6em", align="center"
+{|border="1" style="text-align:center;" cellpadding="5" align="center"  cellspacing="0"
+!Pile Size!!A<sub>s</sub><br/>Area,<br/>sq. in.!!Structural<br/>Nominal<br/>Axial<br/>Compressive<br/>Resistance<br/>PNDC<sup>1,2</sup>,<br/>kips!!Φ<sub>c</sub><br/>Structural<br/>Resistance<br/>Factor<sup>4</sup>,<br/>LRFD 6.5.4.2!!Structural<br/>Factored<br/>Axial<br/>Compressive<br/>Resistance<sup>2,3,4</sup>,<br/>kips!!0.9*ϕ<sub>da</sub>*F<sub>y</sub><br/>Maximum<br/>Nominal<br/>Driving<br/>Stress,<br/>LRFD 10.7.8,<br/>ksi
 |-
-| COLSPAN="3"| <u>'''New Non-Weathering Bridge Over Stream or Railroad'''</u>
+|HP 12x53||				15.5||	775||	0.5||	388||	45.00
 |-
-| [[image:751.6.2.11-Typical_Stream_RR.jpg|center|x300px]] || style="width: 50px" | || [[image:751.6.2.11-Deck_Joints_Stream_RR.jpg|center|x300px]]
+|HP 14x73||				21.4||	1070||	0.5||	535||	45.00
-|-
-| '''Typical Coating for System G''' || || '''Coating Near Deck Joints (System G)'''
 |-
+|colspan="6" align="left"|'''<sup>1</sup>''' Structural Nominal Axial Compressive Resistance for fully embedded piles only. Structural Nominal Axial Compressive Resistance for unsupported piles shall be determined in accordance with LRFD 10.7.3.13.1. (i.e., intermediate pile cap bent).<br/><br/>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;Minimum Nominal Axial Compressive Resistance  =  Required nominal driving resistance, R<sub>ndr</sub><br/>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; = (Maximum factored axial loads / ϕ<sub>dyn</sub>) ≤ Structural nominal axial compressive resistance, PNDC &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;LRFD 10.5.5.2.3<br/><br/>
+'''<sup>2</sup>''' Axial Compressive Resistance values shown above shall be reduced when downdrag is considered.
+<br/><br/>'''<sup>3</sup>''' Maximum factored axial load per pile  ≤  Structural factored axial compressive resistance.
+<br/><br/>'''<sup>4</sup>''' Values are applicable for Strength Limit States.  Modify value for other Limit States.
+<br/><br/><br/>'''Notes:
+<br/><br/>ϕ<sub>dyn</sub> = Resistance factor of the dynamic method to be used to estimate nominal pile resistance during pile installation.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;	LRFD Table 10.5.5.2.3-1
+<br/><br/>For more information about selecting pile driving verification methods refer to [[751.36_Driven_Piles#751.36.5.3_Geotechnical_Resistance_Factor_.28.CF.95stat.29_and_Driving_Resistance_Factor_.28.CF.95dyn.29|EPG 751.36.5.3 Geotechnical Resistance Factor (ϕ<sub>stat</sub>) and Driving Resistance Factor (ϕ<sub>dyn</sub>)]].
+<br/><br/>Drivability analysis shall be performed for all HP piles using Delmag D19-42. Do not show minimum hammer energy on plans.
+<br/><br/>Check drivability for all HP Pile in accordance with [[#751.36.5.11 Check Pile Drivability|EPG 751.36.5.11]]
+<br/><br/>For additional design requirements, see [[#751.36.5.1 Design Procedure Outline|EPG 751.36.5.1]].
 |}
+</center>
-'''<u>Coating New Truss Bridges or Other Unusual Structures</u> '''
+=====751.36.5.7.2.2 Design Values for Individual Cast-In-Place (CIP) Pile=====
-Intermediate Field Coat and Finish Field Coat (System G, H, I or L) (Gray or Brown) - The quantity shall be computed as a lump sum quantity.
+<center>
+Modified Grade 3 F<sub>y</sub> = 50 ksi; F'<sub>c</sub> = 4 ksi; Structural Resistance Factor, (Φ<sub>c</sub>)<sup>'''1'''</sup> = 0.6
-All structural steel for truss or steel box girder spans shall be field coated with intermediate and finish coats, except the area of steel to be in contact with concrete. Intermediate field coat is not required when System I or L is specified.
+{|border="1" style="text-align:center;" cellpadding="5" align="center" cellspacing="0"
+! colspan="8" | Unfilled Pipe For Axial Analysis<sup>2</sup> !! colspan="5" | Concrete Filled Pipe For Flexural Analysis<sup>3</sup>
-<u>'''Recoating Existing Multi-Girder/Beam Bridges '''</u>
+|-
+! Pile Outside Diameter O.D., in. !! Pile Inside Diameter I.D., in. !! Minimum Wall Thickness, in. !! Reduced Wall thick. for Fabrication (ASTM A252), in. !! A<sub>s</sub>,<sup>4</sup> Area of Steel Pipe, sq. in. !! Structural Nominal Axial Compressive Resistance, P<sub>n</sub><sup>5,6,7</sup>, kips !! Structural Factored Axial Compressive Resistance<sup>1,7,8</sup>, kips !! 0.9*ϕ<sub>da</sub>*F<sub>y</sub>*A<sub>s</sub> Maximum<br/>Nominal<br/>Driving<br/>Resistance<sup>5,6</sup>, LRFD 10.7.8, kips !! Reduced Wall Thick. for Corrosion (1/16"), LRFD 5.13.4.5.2, in. !! A<sub>st</sub>,<sup>9</sup> Net Area of Steel Pipe, sq. in. !! A<sub>c</sub> Concrete Area, sq. in. !! Structural Nominal Axial Compressive Resistance PNDC<sup>5,7,10</sup>, kips !! Structural Factored Axial Compressive Resistance<sup>1,7,10</sup>, kips
-Quantities shall be computed to the nearest one hundred square feet of structural steel to be prepared or coated. The area computations do not include bearings, diaphragms, stiffeners and all other misc. steel within the limits of surface preparation or field coatings.
+|-
+| rowspan="2" | 14 || 13 || 0.5 || 0.44 || 18.47 || 923 || 554 || 831 || 0.375 || 15.76 || 133 || 1239 || 743
-'''1. Surface Preparation for Recoating Structural Steel '''- Preparation shall include the surfaces of all structural steel except areas to be in contact with concrete.
+|-
+| 12.75 || 0.625<sup>'''11'''</sup> || 0.55 || 22.84 || 1142 || 685 || 1028 || 0.484 || 20.14 || 128 || 1441 || 865
-'''2. Field Application of Inorganic or Organic Zinc Primer''' - Coverage shall meet the same requirements of Surface Preparation for Recoating Structural Steel.
+|-
+| rowspan="2" | 16 || 15 || 0.5 || 0.44 || 21.22 || 1061 || 637 || 955 || 0.375 || 18.11 || 177 || 1506 || 904
-'''3. Intermediate Field Coat (System G or H) (Gray or Brown)''' - Coverage shall meet the same requirements as new multi-girder/beam bridges.
+|-
+| 14.75 || 0.625<sup>'''11'''</sup> || 0.55 || 26.28 || 1314 || 788 || 1183 || 0.484 || 23.18 || 171 || 1740 || 1044
-'''4. Finish Field Coat (System G, H, I or L) (Gray or Brown)''' - Coverage shall meet the same requirements as new multi-girder/beam bridges.
-{| style="text-align: center; font-size:1.6em", align="center"
 |-
-| COLSPAN="3" | <u>'''Existing Non-Weathering Bridge'''</u>
+| rowspan="2" | 20 || 19 || 0.5 || 0.44 || 26.72 || 1336 || 801 || 1202 || 0.375 || 22.83 || 284 || 2105 || 1263
 |-
-| [[image:751.6.2.11-Recoating_Roadway.jpg|center|x300px]] || style="width: 50px"| || [[image:751.6.2.11-Recoating_Stream_RR.jpg|center|x300px]]
+| 18.75 || 0.625 || 0.55 || 33.15 || 1658 || 995 || 1492 || 0.484 || 29.27 || 276 || 2402 || 1441
 |-
-| '''Typical Recoating Over Roadway for System G or H''' || || '''Typical Recoating Over Stream or Railroad for System G or H'''
+| rowspan="3" | 24 || 23 || 0.5 || 0.44 || 32.21 || 1611 || 966 || 1450 || 0.375 || 27.54 || 415 || 2790 || 1674
 |-
-| COLSPAN="3" | [[image:751.6.2.11-Recoating_Deck_Joints.jpg|center|x300px]]
+| 22.75 || 0.625 || 0.55 || 40.03 || 2001 || 1201 || 1801 || 0.484 || 35.36 || 406 || 3150 || 1890
 |-
-| COLSPAN="3" | '''Recoating Near Deck Joints (System G or H)'''
+| 22.5 || 0.75 || 0.66 || 47.74 || 2387 || 1432 || 2148 || 0.594 || 43.08 || 398 || 3506 || 2103
 |-
-|}
+| colspan="13" align="left" |
+'''<sup>1</sup>''' Values are applicable for Strength Limit States. Modify value for other Limit States.
-<u>'''Recoating Existing Truss Bridges or other Unusual Structures '''</u>
+'''<sup>2</sup>''' Use to determine preliminary number of pile and pile size. For piles predominantly embedded and tipped in cohesionless soils the maximum loads provided in [[#751.36.5.10 Pile Nominal Axial Compressive Resistance|EPG 751.36.5.10]] will control.
-Quantities shall be computed as lump sum quantities. The approximate weight of steel shall be shown to the nearest ton in the contract documents.
+'''<sup>3</sup>''' Pipes placed in prebored holes in rock can use filled pipe capacity for axial plus flexural resistance. Therefore, number of piles should be based on this capacity assuming rock is infinitely more stiff. This recognizes that pile driving is not a concern.
-'''1. Surface Preparation for Recoating Structural Steel''' - Preparation shall include the surfaces of all structural steel except areas to be in contact with concrete.
+'''<sup>4</sup>''' Corrosion NOT considered at construction stage and for drivability analysis and static analysis. For drivability analysis and static analysis use reduced pipe nominal wall thickness, 12.5%, for fabrication (ASTM A252).
-'''2. Field Application of Inorganic or Organic Zinc Primer''' – Coverage shall meet the same requirements of Surface Preparation for Recoating Structural Steel.
+'''<sup>5</sup>''' Structural Nominal Axial compressive resistance for fully embedded piles only. Value in table is a raw number and is the value used to determine the factored resistance. Structural Nominal Axial Compressive Resistance for unsupported piles shall be determined in accordance with LRFD 10.7.3.13.1. (i.e. Intermediate pile cap bent).
-'''3. Intermediate Field Coat (System G or H) (Gray or Brown)''' – Coverage shall meet the same requirements as new truss bridges.
+'''<sup>6</sup>''' Minimum Nominal Axial Compressive Resistance = Required nominal driving resistance, R<sub>ndr</sub>
-'''4. Finish Field Coat (System G, H, I or L) (Gray or Brown)''' – Coverage shall meet the same requirements as new truss bridges.
+&nbsp; &nbsp; &nbsp; = Maximum factored axial loads / ϕ<sub>dyn</sub> ≤ Structural nominal axial compressive resistance, P<sub>n</sub> and &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; LRFD 10.5.5.2.3
-<u>'''Overcoating Existing Multi-Girder/Beam Bridges '''</u>
+&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; ≤ Maximum nominal driving resistance.
-Quantities shall be computed to the nearest one hundred square feet of structural steel to be prepared or overcoated except as noted below. The area computations do not include bearings, diaphragms, stiffeners and all other misc. steel within the limits of surface preparation or field coatings.  Partial overcoating of steel structures is allowed and the areas of partial overcoating should be clearly indicated on the plans.
+'''<sup>7</sup>''' Axial Compressive Resistance values shown above shall be reduced when downdrag is considered
-'''1. Surface Preparation for Overcoating Structural Steel (System G)''' - Preparation shall include the surfaces of all structural steel except areas to be in contact with concrete.
+'''<sup>8</sup>''' Maximum factored axial load per pile ≤ Structural factored axial compressive resistance
-'''2. Intermediate Field Coat (System G)''' - Coverage shall meet the same requirements as Surface Preparation for Overcoating Structural Steel (System G).
+'''<sup>9</sup>''' Net area of steel pipe, A<sub>st</sub>, assumes a 12.5% fabrication reduction (ASTM A252) and 1/16" (LRFD 5.13.4.5.2) reduction in pipe nominal wall thickness for corrosion.
-'''3. Finish Field Coat (System G)''' - Coverage shall meet the same requirements as new bridges.
+'''<sup>10</sup>''' Use for lateral load analysis. Resistance value includes filled pipe based on net area of steel pipe, A<sub>st</sub> (12.5% fab. reduction and 1/16” corr. reduction in nominal pipe wall thickness).
-{| style="text-align: center; font-size:1.6em", align="center"
+'''<sup>11</sup>''' 5/8” wall thickness is less commonly available than the smaller wall thicknesses of pipe pile.
-|-
-|COLSPAN="3"|[[image:751.6.2.11-Overcoating_Existing_Bridge.jpg|center|x300px]]
-|-
-|COLSPAN="3" style="font-size:0.75em"|'''Overcoating Existing Non-Weathering Bridge (System G)'''
-|-
-|}
-<u>'''Limits of Paint Overlap '''</u>
+'''Notes:
-Refer to [[751.50_Standard_Detailing_Notes#A4a1._Steel_Structures-_Nonweathering_Steel|EPG 751.50 Note A4a1.24]]. The figure below with note is available in a CADD cell. Detail should be modified as necessary for paint systems other than System G.
+Drivability analysis shall be performed for all CIP piles (unfilled pipe) using Delmag D19-42. Do not show minimum hammer energy on plans.
-[[image:Part_Elev_Paint_Overlap_11-3-23.png|800px]]
+Check drivability for all CIP Pile in accordance with [[#751.36.5.11 Check Pile Drivability|EPG 751.36.5.11]].
+Require dynamic pile testing for field verification for all CIP piles on the plans.
+ϕ<sub>dyn</sub> = 0.65 = Dynamic Testing resistance factor to be used to estimate nominal pile resistance during pile installation. This value may be increased if static load testing is specified per LRFD Table 10.5.5.2.3-1.
-====751.6.2.12 Structural Steel Protective Coatings (Weathering Steel)====
+For additional design requirements, see [[#751.36.5.1 Design Procedure Outline|EPG 751.36.5.1]].
+|}
+</center>
-'''<u>Coating New Multi-Girder/Beam Bridges, Truss Bridges or other Unusual Structures</u>'''
+===751.36.5.8 Additional Provisions for Pile Cap Footings===
+'''Pile Group Layout:'''
-There will not be a quantity item for coating weathering steel. The cost of coating weathering steel structures will be considered completely covered by the contract unit price for the Fabricated Structural Steel.
+P<sub>u</sub> = Total Factored Vertical Load.
-'''<u>Recoating Existing Multi-Girder/Beam Bridges, Truss Bridges or other Unusual Structures </u>'''
+Preliminary Number of Piles Required = <math>\, \frac{Total\ Factored\ Vertical\ Load}{PFDC}</math>
-Recoating weathering steel when performing joint repair/replacement may be included on the contract plans. Other areas may be recoated depending upon inspection of the condition of weathering steel and the future deterioration expectations of same by Bridge Maintenance. See Structural Project Manager or Structural Liaison Engineer.
+Layout a pile group that will satisfy the preliminary number of piles required.  Calculate the maximum and minimum factored load applied to the outside corner piles assuming the pile cap/footing is perfectly rigid.  The general equation is as follows:
-For existing multi-girder/beam bridges, quantities shall be computed to the nearest one hundred square feet of structural steel to be prepared or recoated. The area computations do not include bearings, diaphragms, stiffeners and all other misc. steel within the limits of surface preparation or field coatings. For truss bridges or other unusual structures, quantities shall be computed as lump sum quantities.
+Max. Load = &nbsp; <math>\, \frac {P_u}{Total\ No.\ of\ Piles} + \frac {M_{ux} Y_i}{\Sigma Y_i^2} + \frac {M_{uy} X_i}{\Sigma X_i^2}</math>
-'''1. Surface Preparation for Recoating Structural Steel''' - Preparation shall be on a case-by-case basis except areas to be in contact with concrete.
+Min. Load = &nbsp; <math>\, \frac {P_u}{Total\ No.\ of\ Piles} - \frac {M_{ux} Y_i}{\Sigma Y_i^2} - \frac {M_{uy} X_i}{\Sigma X_i^2}</math>
-'''2. Field Application of Inorganic or Organic Zinc Primer''' - Coverage shall meet the same requirements of Surface Preparation for Recoating Structural Steel.
+The maximum factored load per pile must be less than or equal to PFDC for the pile type and size chosen.  If not, the pile size must be increased or additional piles must be added to the pile group.  Reanalyze until the pile type, size and layout are satisfactory.
-'''3. Intermediate Field Coat (System G) (Brown)''' - Coverage shall be on a case-by-case basis.
-'''4. Finish Field Coat (System G, I or L) (Brown)''' - Coverage shall be on a case-by-case basis.
+'''Pile Uplift on End Bearing Piles and Friction Piles:'''
+:'''Service - I Limit State:'''
+::Minimum factored load per pile shall be ≥ 0.
+::Tension on a pile is not allowed for conventional bridges.
-===751.14.5.8 Protective Coating Requirements===
+:'''Strength and Extreme Event Limit States:'''
-Coating requirements for new steel girder bridge shall be in accordance with [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1080] and [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1081]. See [[751.1 Preliminary Design#751.1.2.9.2 Steel Girder Options|EPG 751.1.2.9.2]], [[751.6_General_Quantities#751.6.2.11_Structural_Steel_Protective_Coatings_.28Non-weathering_Steel.29|EPG 751.6.2.11]] and [[751.6 General Quantities#751.6.2.12 Structural Steel Protective Coatings (Weathering Steel)|EPG 751.6.2.12]] for additional guidance.
-System G (three-coat system) may be used for non-weathering steel and weathering steel structures ([https://www.modot.org/missouri-standard-specifications-highway-construction Sec 1081]). System G typically is not preferred when overlapping an existing vinyl coating but may be allowed if the existing coating is determined to be in good condition. System G uses a solvent based finish coat which may cause issues when overlapping an existing solvent-based vinyl coating system (System C) because it may re-wet the existing coating and cause delamination of the base coat. If the existing coating is in good condition as determined by paint pull-off tests the intermediate epoxy coating will provide a reliable barrier between the solvent-based coatings. Consult the structural project manager or structural liaison engineer before using System G near existing vinyl coatings.
+::Uplift on a pile is not preferred for conventional bridges.
+::Maximum Pile Uplift load = │Minimum factored load per pile│ - │Factored pile uplift resistance│ ≥ 0<sup>'''1'''</sup>
-System G has replaced calcium sulfonate as the preferred overcoating system. To ensure sufficient bond of the existing coating, adhesion pull-off tests shall be performed in accordance with ASTM D4541. If the adhesion test fails, as determined by the engineer of record, then overcoating shall not be allowed and recoating should be considered.
+:::'''Note:''' Compute maximum pile uplift load if value of minimum factored load is negative.
-System H (three-coat system) is typically used when the bond for System G is considered questionable where recoating operations will take place near an existing vinyl coating system (System C). System H uses a waterborne acrylic for the intermediate and finish field coats that does not tend to interfere with the solvent-based vinyl coating.
+::::<sup>'''1'''</sup> The minimum factored load (maximum tensile load) per pile should preferably not result in uplift for the Strength and Extreme Event Limit States. Pile uplift for the Strength and Extreme Event limit states may be permitted by SPM or SLE based on infrequent uplift load cases and small magnitudes of uplift. This decision is based on the presumed difficulty of a pile cap footing to rotate, specifically for it to be able to rotate on piles driven to rock. When pile uplift is allowed, the necessity of top pile cap reinforcement shall be investigated and the standard  anchorage detail for HP pile per [[#751.36.4.1 Structural Steel HP Pile - Details|EPG 751.36.4.1 Structural Steel HP Pile - Details]] shall be used.
-System I (two-coat system) may be used for non-weathering and weathering steel and should be based on the following guidance:
-:(a) System I should be considered in areas where the aesthetics of a coating system over the long term is critical. While System G, L and I provide long term protection, System I has excellent gloss retention and UV resistance. System I is a context sensitive design (CSD) solution. CSD follows from project scoping and is subject to the project core team protocols.
+'''Resistance of Pile Groups in Compression'''&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;'''LRFD 10.7.3.9'''
-::(1) Consider for locations where the structure is more visible or the public has leisurely time for more than just a casual glance, for example structures near a ballpark or a pedestrian bridge. Using same rationale, bridges that are tall or have wide girder spacing or a low number of girders where more of the superstructure is visible could also be candidates.
+If the cap is not in firm contact with the ground and if the soil at the surface is soft, the individual nominal resistance of each pile (751.36.5.5) shall be multiplied by an efficiency factor, <math>\eta</math>, based on pile spacing.
-::(2) Consider the image consciousness of the surroundings in conjunction with rather than solely the protection of the structure which is equally provided by systems G and I. Maintenance of either System G or I should be considered the same. Reduced maintenance is an expectation for System L.
+===751.36.5.9 Estimate Pile Length and Check Pile Capacity===
-:(b) System I is a polysiloxane finish coat that is normally applied directly over an inorganic or organic zinc primer with no intermediate coating. Since the system is a two-coat system, it may be applied in less time which can influence critical path scheduling and impacts to the driving public. For example, it may be possible for a contractor to get in and out quicker than if they were to use a three-coat system.  MoDOT coating policy as described in Standard Specification Section 1081 requires different field coating requirements based on the type of bridge crossing. For roadway grade separations, it is required that interior girders have only a single field coat in order to satisfy that all girders on a roadway grade separation bridge have at least two coatings for protection. In the case of System I, the Standard Specifications require that a System G epoxy intermediate field coat be applied to all interior girders and the interior of fascia girders and that the System I  polysiloxane finish coating be applied to the exterior of the facia girders only. This is based on a system I polysiloxane coating cost being greater than a system G epoxy coating on a per-gallon cost basis. It also requires that the contractor be given the option to substitute the System I finish coat in place of a System G intermediate coat.  If CSD determines that the polysiloxane should be applied to all girders, then the general notes for coatings and the quantities on the contract plans will need to reflect the revised coating requirements.
+====751.36.5.9.1 Estimated Pile Length====
-:(c) System I is approved for use on state highway projects beginning February 2011. Alternate bidding is encouraged if guideline (a) is not required to be met and with approval of the Structural Project Manager or Structural Liaison Engineer and the project core team.
+'''Friction Piles:'''
-System L (two-coat system) may be used for non-weathering steel and weathering steel structures. System L requires an inorganic zinc primer so organic zinc shall not be substituted. Testing indicates that System L is expected to outlast System G, H or I coatings when properly applied. Since the system is a two-coat system, it may be applied in less time which can influence critical path scheduling and impacts to the driving public. Similarly, the expectation for reduced maintenance should be considered for areas where access is limited or impactful (e.g., over railroads and interstates).
+Estimate the pile length required to achieve the minimum nominal axial compressive resistance, MNACR, or required driving resistance, R<sub>ndr</sub>, for establishment of contract pile quantities. Perform a static analysis using one of the methods given in EPG [[751.36_Driven_Piles#751.36.5.3_Geotechnical_Resistance_Factor_(ϕstat)_and_Driving_Resistance_Factor_(ϕdyn)|751.36.5.3 Geotechnical Resistance Factor (ϕ<sub>stat</sub>) and Driving Resistance Factor (ϕ<sub>dyn</sub>)]] to determine the nominal resistance profile of the soil.  For each soil layer the appropriate resistance factor, ϕ<sub>stat</sub>, shall be applied to account for the reliability of the static analysis method to create a factored resistance profile. The penetration depth would then occur at the location where the factored resistance profile intercepts the factored load. The relationship between the static axial compressive resistance and required driving resistance for a uniform soil profile with a constant static resistance factor is given as follows:
+:{| style="margin: 1em auto 1em auto"
+|-
+|ϕ<sub>dyn</sub> x R<sub>ndr</sub> = ϕ<sub>stat</sub> x R<sub>nstat</sub> ≥ Factored Load||width="450"| ||LRFD C10.7.3.3-1
+|}
-Inorganic zinc primer shall be used for new steel fabrication with System G, I or L coatings. For recoating operations with System G, H or I, where closure time has severe impacts on cost or safety, organic zinc primer should be considered as a direct replacement for the inorganic zinc required in the specifications. Organic zinc primers require a lower level of surface preparation (SSPC-SP6: commercial blast cleaning vs SSPC-SP10: near white blast cleaning) and are generally easier to apply in the field than inorganic zinc primers. Only organic zinc primers that can provide a Class B slip coefficient are allowed for use in recoating operations.
+Where:
+:ϕ<sub>dyn</sub> = see [[#751.36.5.3 Geotechnical Resistance|EPG.751.36.5.3]]
+:R<sub>ndr</sub> = Required nominal driving resistance = MNACR
+:ϕ<sub>stat</sub> = Static analysis resistance factor per [[751.36_Driven_Piles#751.36.5.3_Geotechnical_Resistance_Factor_(ϕstat)_and_Driving_Resistance_Factor_(ϕdyn)|EPG 751.36.5.3]] or as provided by the Geotechnical Engineer. Factors for side friction and end bearing may be different.
+:R<sub>nstat</sub> = Required nominal static resistance
-See [https://epg.modot.org/index.php?title=751.50_Standard_Detailing_Notes#A4._Protective_Coatings EPG 751.50 A4. Protective Coatings] for standard detailing notes and guidance on how they are used.
+Use soil profiles from borings and mimic soil characteristics as closely as possible in computations or software to calculate the geotechnical resistance and for estimating the length of pile. For more detailed guidance see [https://www.modot.org/media/54989 SEG 25-001 New Policy for Friction Pile].
-Epoxy-mastic primers may be used for overcoating lead-based coatings if the existing coating is determined to be in good condition, but this is considered a short-term solution in comparison to System G overcoating. Consult the structural project manager or structural liaison engineer before using epoxy-mastics near existing lead-based coatings.
+It is not advisable to design pile deeper than available borings or to reach capacity within the bottom 3 to 5 feet of borings. If a longer pile depth is needed to meet design requirements then request Geotechnical Section to provide deeper borings or increase the number of piles which will reduce load per pile as well as the required pile length.
-Galvanized non-weathering structural steel beams, girders, bracing and diaphragms may be used as required or allowed by alternate, on a case-by-case basis, with approval of the Structural Project Manager or Structural Liaison Engineer and the project core team.
+For friction pile the top five feet of soil friction resistance may be neglected with SPM or SLE approval for possible disturbance from MSE wall excavation prior to driving pile.
-When galvanized structural steel is required, place note EPG 751.50 (A4a1.8.2a) on the plans. Do not use notes EPG 751.50 (A4a1.1 – A4a1.7). When galvanized structural steel is bid as an alternate, place notes EPG 751.50 (A4a1.8.1a, A4a1.8.1b, and A4a1.8.1c) on the plans under the applicable coating new steel notes EPG 751.50 (A4a1.1-A4a1.7).
+'''End Bearing Piles:'''
+The estimated pile length is the distance along the pile from the cut-off elevation to the estimated tip elevation considering any penetration into rock. The estimated tip elevation shall not be shown on plans for end bearing piles.
+The geotechnical material above the estimated end bearing tip elevation shall be reviewed for the presence of glacial till or similar layers. If these layers are present, then a static analysis shall be performed to verify if the required pile resistance is reached at a higher elevation due to pile friction capacity.
-=== A4. Protective Coatings ===
+====751.36.5.9.2 Check Pile Geotechnical Capacity (Axial Loads Only)====
-====A4a. Structural Steel Protective Coatings====
+Use the same methodology outlined in [[#751.36.5.9.1 Estimated Pile Length|EPG 751.36.5.9.1 Estimated Pile Length]].
-In "'''General Notes:'''" section of plans, place the following notes under the heading "Structural Steel Protective Coatings:".
+====751.36.5.9.3 Check Pile Structural Capacity (Combined Axial and Bending)====
-=====A4a1. <u>Steel Structures-Nonweathering Steel</u>=====
+Structural design checks which include lateral loading and bending shall be accomplished using the appropriate structural resistance factors.
-'''<u>Coating New Steel (Notes A4a1.1 – A4a1.7)</u>'''
+===751.36.5.10 Pile Nominal Axial Compressive Resistance ===
+The minimum nominal axial compressive resistance, MNACR, or required driving resistance, R<sub>ndr</sub>, must be calculated and shown on the final plans. The factored axial compressive resistance will be used to verify the pile group layout and loading. The minimum nominal axial compressive resistance will be used in construction field verification methods to obtain the required nominal driving resistance.
-'''(A4a1.1) Use the 2<sup>nd</sup> underlined option for grade separations where System I finish field coat is only required on the fascia surfaces per Sec 1081.  “System I” may be used for water crossings or where note A4a1.3 is used. '''
+: Minimum Nominal Axial Compressive Resistance, MNACR = Required Nominal Driving Resistance, R<sub>ndr</sub>
+: = Maximum factored axial loads/ϕ<sub>dyn</sub>
+:ϕ<sub>dyn</sub> = Resistance factor of the dynamic method used to estimate nominal pile resistance during pile installation. LRFD 10.5.5.2.3.1
-:Protective Coating: <u>System G</u> <u>System I Prime Coat with System I Finish Field Coat and System G Intermediate Field Coat</u> <u>System I</u> <u>System L</u> in accordance with Sec 1081.
+The value of R<sub>ndr</sub> shown on the plans shall be the greater of the value required at the '''Strength limit state and Extreme Event limit state'''.  This value shall not be greater than the structural nominal axial compressive resistance of the steel HP pile nor shall it exceed the maximum nominal driving resistance of the steel shell for CIP piles.  See [[#751.36.5.5 Preliminary Structural Nominal Axial Design Capacity (PNDC) of an individual pile |EPG 751.36.5.5]]. &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;	LRFD 10.7.7
-'''(A4a1.2)  '''
+For friction piles predominantly embedded and tipped in cohesionless soils the minimum nominal axial compressive resistance shall be limited to the values shown in the following table. Approval from the SPM, SLE or owner's representative is required before exceeding the limits provided in this table.
-:Prime Coat: The cost of the inorganic zinc prime coat will be considered completely covered by the contract unit price for the fabricated structural steel.
+{| border="1" style="text-align:center;" cellpadding="5" align="center"  cellspacing="0"
+|+ '''Maximum Axial Loads for Friction Pile in Cohesionless Soils'''
+! rowspan="3" | Pile Type !! rowspan="3" | Minimum Nominal<br/>Axial Compressive<br/>Resistance (R<sub>ndr</sub>)<sup>'''1'''</sup><br/>(kips)<br/> !! colspan="3" | Maximum Factored Axial Load (kips)
+|-
+! Dynamic Testing !! Wave Equation<br/>Analysis !! FHWA-modified<br/>Gates Dynamic<br/>Pile Formula
+|-
+! ϕ<sub>dyn</sub>= 0.65 !! ϕ<sub>dyn</sub> = 0.50 !! ϕ<sub>dyn</sub> = 0.40
+|-
+| CIP 14” || 210 || 136 || 105 || 84
+|-
+| CIP 16” || 240 || 156 || 120 || 96
+|-
+| CIP 20” || 300 || 195 || 150 || 120
+|-
+| CIP 24” || 340 || 221 || 170 || 136
+|-
+| colspan="5" align="left" | <sup>'''1'''</sup> The minimum nominal axial compressive resistance values are correlated to match the maximum design tonnage values used in past ASD practice.  A factor of safety of 3.5 is used to determine the equivalent R<sub>ndr</sub>.
+|}
-'''(A4a1.3) For grade separations where System I is preferred for all girder surfaces and not just the fascia surfaces.'''
+===751.36.5.11 Check Pile Drivability===
+Drivability of the pile through the soil profile shall be investigated using the GRLWEAP wave equation analysis program. The static axial compressive resistance profile used in the wave equation analysis shall be determined using one of the approved static methods given in [[751.36_Driven_Piles#751.36.5.3_Geotechnical_Resistance_Factor_(ϕstat)_and_Driving_Resistance_Factor_(ϕdyn)|EPG 751.36.5.3]].
-:System I finish coat shall be substituted for System G intermediate coat in Sec 1081.10.3.4.1.5.
+Drivability analysis shall be performed by the designer for all pile types (bearing pile and friction pile) using the Delmag D19-42 hammer with manufacturer recommendations. The drivability analysis shall confirm that the pile can be driven to the minimum tip elevation, rock elevation or reach the minimum nominal axial compressive resistance prior to refusal and without overstressing the pile. If the drivability analysis shows overstress or refusal prior to reaching the desired depth a lighter or heavier hammer from the table below may be used to confirm constructability. The drivability analysis is not intended to confirm that a pile can be driven through rock (shales, sandstones, etc…) where the likelihood of pile damage is increased and PDA is recommended to reduce loads and monitor pile stresses in the field. The drivability analyses performed by the designer does not waive the responsibility of the contractor in selecting the appropriate pile driving system per Sec 702.3.5 (also discussed below).
-'''(A4a1.4) 	The coating color shall be as specified on the Design Layout. When System L or note (A4a1.3) is used, omit the 2<sup>nd</sup> sentence'''.
-:Field Coat(s): The color of the field coat(s) shall be <u>Gray (Federal Standard #26373)</u> <u>Brown (Federal Standard #30045)</u> <u>Black (Federal Standard #17038)</u> <u>Dark Blue (Federal Standard #25052)</u> <u>Bright Blue (Federal Standard #25095)</u>. The cost of the intermediate field coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Intermediate Field Coat (System G). The cost of the finish field coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Finish Field Coat <u>(System G</u> <u>I</u> <u>L)</u> .
-'''(A4a1.5) 	When System L is specified, System I is specified for water crossings or when note (A4a1.3) is used, omit the underlined part.'''
-:At the option of the contractor, the <u>intermediate field coat and</u> finish field coat may be applied in the shop. The contractor shall exercise extreme care during all phases of loading, hauling, handling, erection and pouring of the slab to minimize damage and shall be fully responsible for all repairs and cleaning of the coating systems as required by the engineer.
-'''(A4a1.6) 	Use for structures with Access Doors'''
+Use soil profiles from borings and mimic soil characteristics as closely as possible for computations or in software to perform drivability analysis of any kind of pile.
-:Structural steel access doors shall be cleaned and coated in the shop or field with a minimum of two coats of inorganic zinc primer to provide a total dry film thickness of 4 mils minimum, 6 mils maximum. In lieu of coating, the access doors may be galvanized in accordance with ASTM A123 and AASHTO M 232 (ASTM A153), Class C. The cost of coating or galvanizing doors will be considered completely covered by the contract unit price for other items.
+'''Structural steel HP Pile:'''
-'''(A4a1.7) Use for structures with Access Doors and when a fabricated structural steel pay item is not included.'''
+Drivability analysis shall be performed for the box shape of the pile (i.e., not the perimeter).
-:Payment for furnishing, coating or galvanizing and installing access doors and frames will be considered completely covered by the contract unit price for other items.
-<div id="(A4a1.8.1) Place"></div>
+Drivability shall be performed considering existing condition without considering any excavation/ disturbance (i.e., possible disturbance to top 5 feet of soil from MSE wall excavation prior to driving pile), liquefaction or future scour loss.
-'''(A4a1.8.1) Place the following notes on the plans when alternate galvanized structural steel protective coating is approved by SPM.'''
-:'''(A4a1.8.1a) Place the following note under the notes for “Structural Steel Protective Coatings”.'''
+'''Hammer types:'''
-::Alternate A Structural Steel Protective Coating:
-::Structural steel shall be galvanized in accordance with ASTM A123 and Sec 1081.
-:'''(A4a1.8.1b) In "General Notes:" section place the following note under the heading "Miscellaneous:”'''
+{| border="1" style="text-align:center;" cellpadding="5" align="center"  cellspacing="0"
-::Alternate bids for structural steel coating shall be completed.
+|+ '''Pile Driving Hammer Information For GRLWEAP'''
+! colspan="3" | Hammer used in the field per survey response (2017)
-:'''(A4a1.8.1c) Place following information at bottom part of “Estimated Quantities” table. (At least four (4) blank rows should be left at bottom of table to allow for additional entries in the field.)'''
-<center>
-{|border="1" style="text-align:center;" cellpadding="5" cellspacing="0"
 |-
-!colspan="4"|Estimated Quantities
+! GRLWEAP ID !! Hammer name !! No. of Responses
 |-
-!Item||Substr.||Superstr.||Total
+| 41 || Delmag D19-42<sup>1</sup> || 13
 |-
-|Last Pay Item|| || ||
+| 40 || Delmag D19-32 || 6
 |-
-|Blank|| || ||
+| 38 || Delmag D12-42 || 4
 |-
-|ADD ALTERNATE A:|| || ||
+| 139 || ICE 32S || 4
 |-
-|Galvanizing Structural Steel&nbsp;&nbsp;&nbsp;&nbsp; lump sum|| || ||1
+| 15 || Delmag D30-32 || 2
 |-
-|Blank|| || ||
+| || Delmag D25-32 || 2
 |-
-|Blank|| || ||
+| 127 || ICE 30S || 1
 |-
-|Blank|| || ||
+| 150 || MKT DE-30B || 1
 |-
-|Blank|| || ||
+| colspan="3" | <sup>'''1</sup>''' Delmag series of pile hammers is the most popular, with the D19-42 being the most widely used.
 |}
-</center>
-'''(A4a1.8.2) Place the following note instead of notes A4a1.1 – A4a1.7 on the plans when galvanized structural steel protective coating is approved by SPM.'''
-:'''(A4a1.8.2a) '''
-::Structural steel shall be galvanized in accordance with ASTM A123 and Sec 1081.
-'''<u>Recoating Existing Steel (Notes A4a1.9 - A4a1.13)</u>'''
+The contractor is responsible for determining the driving system required to successfully drive the pile to the minimum tip elevation and to reach the minimum nominal axial compressive resistance specified on the plans. The contractor is required to perform a drivability analysis to select an appropriate hammer size to ensure the pile can be driven without overstressing the pile and to prevent refusal of the pile prior to reaching the minimum tip elevation. The contractor shall plan pile driving activities and submit hammer energy requirements to the engineer for approval before driving. There is an exception to the contractor’s responsibility for the drivability analysis when WEAP is specified as the driving criteria for friction pile. When WEAP is specified for friction pile an inspector’s chart will be provided for the contractor in the electronic deliverables. For more detailed guidance see [https://www.modot.org/media/54989 SEG 25-001 New Policy for Friction Pile].
-'''(A4a1.9) Use the 2<sup>nd</sup> underlined option for grade separations where System I finish field coat is only required on the fascia surfaces per Sec 1081. “System I” may be used for water crossings or where note A4a1.13 is used.'''
+Practical refusal is defined at 20 blows/inch or 240 blows per foot.
-:Protective Coating: <u>System G</u> <u>System I Prime Coat with System I Finished Field Coat and System G Intermediate Field Coat</u> <u>System I</u> <u>System L</u> in accordance with Sec 1081.
+Driving should be terminated immediately once 30 blows/inch is encountered.
-'''(A4a1.10) Use primer specified on the Design Memorandum. System L must be used with inorganic zinc primer only.'''
+:{| style="margin: 1em auto 1em auto"
+|-
+|'''Nominal Driving Stress'''||width="840"| ||'''LRFD 10.7.8'''
+|}
+:Nominal driving stress ≤ 0.9*ϕ<sub>da</sub>*F<sub>y</sub>
+::For structural steel HP pile, Maximum nominal driving stress = 45 ksi
+::For CIP pile, Maximum nominal driving resistance, see [[#751.36.5.7.2.1 Design Values for Individual HP Pile|EPG 751.36.5.7.1.2]] or [[#751.36.5.7.2.2 Design Values for Individual Cast-In-Place (CIP) Pile|EPG 751.36.5.7.2.2]] (unfilled pipe for axial analysis).
+If analysis indicates the piles do not have sufficient structural or geotechnical strength or drivability issues exist, then consider increasing the number of piles.
-:Surface Preparation: Surface preparation of the existing steel shall be in accordance with Sec 1081 for <u>Recoating of Structural Steel (System G, H, I or L)</u> with <u>organic</u> <u>inorganic</u> zinc primer. The cost of surface preparation will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Surface Preparation for Recoating Structural Steel.
+===751.36.5.12 Information to be Included on the Plans===
+See [https://epg.modot.org/index.php?title=751.50_Standard_Detailing_Notes#A1._Design_Specifications.2C_Loadings_.26_Unit_Stresses EPG 751.50 A1 Design Specifications, Loadings & Unit Stresses] for appropriate design stresses to be included in the general notes.
-'''(A4a1.11) 	'''
+See [https://epg.modot.org/index.php?title=751.50_Standard_Detailing_Notes#E2._Foundation_Data_Table EPG 751.50 E2 Foundation Data Table] for appropriate data to be included in the foundation data table for HP pile and CIP pile and any additional notes required below the table. See [https://www.modot.org/pile-pile  Bridge Standard Drawings “Pile”] for CIP data table.
-:Prime Coat: The cost of the prime coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Field Application of <u>Inorganic</u> <u>Organic</u> Zinc Primer.
-'''(A4a1.12) The coating color shall be as specified on the Design Layout. When System L or note (A4a1.13) is used, omit the 2<sup>nd</sup> sentence.'''
+<br><br>
+<hr style="border:none; height:2px; background-color:red;" />
+<br><br>
-:Field Coat(s): The color of the field coat(s) shall be <u>Gray (Federal Standard #26373)</u> <u>Brown (Federal Standard #30045)</u> <u>Black (Federal Standard #17038)</u> <u>Dark Blue (Federal Standard #25052)</u> <u>Bright Blue (Federal Standard #25095)</u>. The cost of the intermediate field coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Intermediate Field Coat (System G). The cost of the finish field coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Finish Field Coat <u>(System G</u> <u>I</u> <u>L)</u>.
-'''(A4a1.13) For grade separations where System I is preferred for all girder surfaces and not just the fascia surfaces.'''
+=== E2. Foundation Data Table ===
-:System I finish coat shall be substituted for System G intermediate coat in Sec 1081.10.3.4.1.5.
+The following table is to be placed on the design plans and filled out as indicated.
-'''(A4a1.14) Use for recoating truss bridges.  '''
+'''(E2.1) <font color="purple">[MS Cell] (E2.1)</font color="purple"> (Example: Use the underlined parts in the bent headings for bridges having detached wing walls at end bents only.) '''
-{|style="padding: 0.3em; margin-left:10px; border:1px solid #a9a9a9; text-align:left; font-size: 95%; background:#f5f5f5" width="780px" align="center"
+<center>
+{|border="1" style="text-align:center;" cellpadding="5" cellspacing="0"
+|-
+!colspan="8" style="background:#BEBEBE"| Foundation Data<sup>1</sup>
+|-
+!rowspan="2" style="background:#BEBEBE"|Type!!rowspan="2" style="background:#BEBEBE" colspan="2"|Design Data!!colspan="5" style="background:#BEBEBE"| Bent Number
+|-
+!style="background:#BEBEBE"|1 <u>(Detached<br/>Wing Walls<br/>Only)</u> !!style="background:#BEBEBE"|1 <u>(Except<br/>Detached<br/>Wing Walls)</u> !!style="background:#BEBEBE"|2 !!style="background:#BEBEBE"| 3 !!style="background:#BEBEBE"|4
+|-
+|rowspan="11"|'''Load<br/>Bearing<br/>Pile'''|| colspan="2" align="left" width="300"|CECIP/OECIP/HP Pile Type and Size||CECIP 14"||CECIP 14"||CECIP 16"|| OECIP 24"||HP 12x53
+|-
+|colspan="2" align="left" width="300"|Number [[image:751.50 ea.jpg|34px|right]]||6||8||15||12||6
+|-
+|colspan="2" align="left" width="300"|Approximate Length Per Each [[image:751.50 ft.jpg|20px|right]]||50||50||60||40||53
+|-
+|colspan="2" align="left" width="300"|Pile Point Reinforcement[[image:751.50 ea.jpg|34px|right]]||All||All|| - ||All||All
+|-
+|colspan="2" align="left" width="300"|Min. Galvanized Penetration (Elev.) [[image:751.50 ft.jpg|20px|right]]||303||295<sup>'''4'''</sup>||273||Full Length||300
 |-
-|The length of span that is permissible to drape is to be determined by the designer and given in the note. Typically, ¼ span length is used but greater lengths have been used in the past based on calculations. See Structural Project Manager or Structural Liaison Engineer.
+|colspan="2" align="left" width="300"|Est. Max. Scour Depth 100<sup>'''2'''</sup> (Elev.) [[image:751.50 ft.jpg|20px|right]]|| - || - ||285 || - || -
+|-
+|colspan="2" align="left" width="300"|Minimum Tip Penetration (Elev.) [[image:751.50 ft.jpg|20px|right]]||285||303||270|| - || -
+|-
+|colspan="2" align="left" width="300"|Criteria for Min. Tip Penetration ||Min. Embed.||Min. Embed.|| Scour || - || -
+|-
+|colspan="2" align="left" width="300"|Pile Driving Verification Method || DT ||DT ||DT||DT||DF
+|-
+|colspan="2" align="left" width="300"|Resistance Factor||0.65||	0.65||	0.65||	0.65||	0.4
+|-
+|colspan="2" align="left" width="300"|<u>Design Bearing</u><sup>'''3'''</sup> <u>Minimum Nominal Axial</u><br/><u>Compressive Resistance</u> [[image:751.50 kip.jpg|27px|right]]||175||200||300||600||250
+|-
+|rowspan="2"|'''Spread<br/>Footing||colspan="2" align="left"|Foundation Material || - || - ||Weak Rock||Rock|| -
+|-
+|colspan="2" align="left"|<u>Design Bearing</u> <u>Minimum Nominal</u><br/><u>Bearing Resistance</u> [[image:751.50 ksf.jpg|30px|right]]|| - || - ||10.2||22.6|| -
+|-
+|rowspan="8"|'''Rock<br/>Socket'''||colspan="2" align="left"|Number [[image:751.50 ea.jpg|34px|right]]|| - || - || 2 ||3|| -
+|-
+|rowspan="3" width="35"|[[image:751.50 Layer 1.jpg|center|24px]]||align="left" width="265"|Foundation Material|| - || - || Rock||Rock|| -
+|-
+| align="left"|Elevation Range [[image:751.50 ft.jpg|20px|right]]|| - || - ||410-403||410-398|| -
+|-
+| align="left"|<u>Design Side Friction</u><br/><u>Minimum Nominal Axial</u><br/><u>Compressive Resistance</u><br/><u>(Side Resistance)</u> [[image:751.50 ksf.jpg|30px|right]]|| - || - ||20.0||20.0|| -
+|-
+|rowspan="3"|[[image:751.50 Layer 2.jpg|center|21px]]|| align="left" |Foundation Material|| - || - ||Weak Rock|| - || -
+|-
+| align="left"|Elevation Range [[image:751.50 ft.jpg|20px|right]]|| - || - ||403-385|| - || -
+|-
+| align="left"|<u>Design Side Friction</u><br/><u>Minimum Nominal Axial</u><br/><u>Compressive Resistance</u><br/><u>(Side Resistance)</u> [[image:751.50 ksf.jpg|30px|right]]|| - || - ||9.0|| - || -
+|-
+|colspan="2" align="left"|<u>Design End Bearing</u><br/><u>Minimum Nominal Axial</u><br/><u>Compressive Resistance</u><br/><u>(Tip Resistance)</u> [[image:751.50 ksf.jpg|30px|right]]|| - || - ||12||216|| -
+|-
+|colspan="8" align="left"|'''1'''   Show only required CECIP/OECIP/HP pile data for specific project.
+|-
+|colspan="8" align="left"|'''2''' Show maximum of total scour depths estimated for multiple return periods in years from Preliminary design which should be given on the Design Layout. Show the controlling return period (e.g. 100, 200, 500). If return periods are different for different bents, add a new line.
+|-
+|colspan="8" align="left"|'''3''' For LFD: For bridges in Seismic Performance Categories B, C and D, the design bearing values for load bearing piles given in the table should be the larger of the following two values: <br/> &nbsp; 1. Design bearing value for AASHTO group loads I thru VI. <br/> &nbsp; 2. Design bearing for seismic loads / 2.0
+|-
+|colspan="8" align="left"|'''4''' It is possible that min. tip penetration (elev.) can be higher than min. galvanized penetration (elev.).
 |}
-:For the duration of cleaning and recoating the truss spans, the truss span superstructure in any span shall not be draped with an impermeable surface subject to wind loads for a length any longer than <u>1/4</u> the span length at any one time regardless of height of coverage. Simultaneous work in adjacent spans is permissible using the specified limits in each span.
+{|border="2" style="text-align:center;" cellpadding="5" cellspacing="0"
+|-
+| align="left"|'''Additional notes:'''<br/> On the plans, report the following definition(s) just below the foundation data table for the specific method(s) used:<br/>
+DT = Dynamic Testing<br/>
+DF = FHWA-modified Gates Dynamic Pile Formula<br/>
+WEAP = Wave Equation Analysis of Piles<br/>
+SLT = Static Load Test<br/><br/>On the plans, report the following definition(s) just below the foundation data table for CIP Pile:<br/>CECIP = Closed Ended Cast-In-Place concrete pile<br/>OECIP = Open Ended Cast-In-Place concrete pile<br/><br/>On the plans, report the following equation(s) just below the foundation data table for the specific foundation(s) used:<br/>'''Rock Socket (Drilled Shafts):'''<br/>Minimum Nominal Axial Compressive Resistance (Side Resistance + Tip Resistance) = Maximum Factored Loads/Resistance Factors<br/>'''Spread Footings:'''<br/>Minimum Nominal Bearing Resistance = Maximum Factored Loads/Resistance Factor <br/>'''Load Bearing Pile:'''<br/>Minimum Nominal Axial Compressive Resistance = Maximum Factored Loads/Resistance Factor
+|}
-<div id="Overcoating Existing Steel (Notes A4a.10 – A4a.14)"></div>
-'''<u>Overcoating Existing Steel (Notes A4a1.21 – A4a1.27)</u> '''
-'''(A4a1.21) Include underlined portion when overcoating an existing vinyl coating (System C).'''
+</center>
-:Protective Coating: System G in accordance with Sec 1081 <u>except thinners are not permitted</u>.
+{|style="padding: 0.3em; margin-left:10px; border:1px solid #a9a9a9; text-align:left; font-size: 95%; background:#f5f5f5" width="700px" align="center"
+|-
-'''(A4a1.22) '''
+|colspan="3" align="left"|<b>Guidance for Using the Foundation Data Table:</b>
+|-
-:Surface Preparation: Surface preparation of the existing steel shall be in accordance with Sec 1081 for Overcoating of Structural Steel. The cost of surface preparation will be considered completely covered by the contract <u>lump sum unit</u> price <u>per sq. foot</u> for Surface Preparation for Overcoating Structural Steel (System G).
+|rowspan="18"| || rowspan="4"|Pile Driving Verification Method ||width="350px"|DF = FHWA-Modified Gates Dynamic Pile Formula
+|-
-'''(A4a1.23) The 2nd underlined portion in the first sentence is applicable only for bridges over streams and railroads. '''
+|DT = Dynamic Testing
+|-
-:Field Coat(s): The color of the field overcoat shall be <u>Gray (Federal Standard #26373)</u> <u>Brown (Federal Standard #30045)</u> <u>Black (Federal Standard #17038)</u> <u>Dark Blue (Federal Standard #25052)</u> <u>Bright Blue (Federal Standard #25095)</u> and shall be applied in accordance with Sec 1081.10.3.4<u>, except that all structural steel shall have the intermediate field coat applied in accordance with Sec 1081.10.3.4.1.1</u>. The cost of the intermediate field coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Intermediate Field Coat (System G). The cost of the finish field coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Finish Field Coat (System G).
+|WEAP = Wave Equation Analysis of Piles
+|-
-'''(A4a1.24) Use when new coating system overlaps existing coating system. Show detail on plans.'''
+|SLT = Static Load Test
+|-
-:Limits of Paint Overlap: System G shall overlap the existing coating between 6 inches and 12 inches in order to achieve maximum coverage at the paint limit of each complete system near the expansion and contraction areas. The final field coating shall be masked to provide crisp, straight lines and to prevent overspray beyond the overlap required.
+|colspan="7"  style="background:#BEBEBE"|
+|-
-=====A4a2. <u>Steel Structures- Weathering Steel</u>=====
+|rowspan="7"|Criteria for Minimum Tip Penetration ||Scour
+|-
-'''<u>Coating New Steel (Notes A4a2.1 - A4a2.3) </u>'''
+|Tension or uplift resistance
-'''(A4a2.1) '''
-:Protective Coating: System <u>G</u> <u>I</u> <u>L</u> in accordance with Sec 1080.
-:Prime Coat: The cost of the inorganic zinc prime coat will be considered completely covered by the contract unit price for the fabricated structural steel.
-'''(A4a2.2) '''
-:Field Coats: The color of the field coats shall be Brown (Federal Standard #30045). The cost of the <u>intermediate and</u> finish field coats will be considered completely covered by the contract unit price for the fabricated structural steel.
-'''(A4a2.3) 	'''
-:At the option of the contractor, the intermediate and finish field coats may be applied in the shop. The contractor shall exercise extreme care during all phases of loading, hauling, handling, erection and pouring of the slab to minimize damage and shall be fully responsible for all repairs and cleaning of the coating systems as required by the engineer.
-'''<u>Recoating Existing Steel (A4a2.10 – A4a2.13) </u>'''
-'''(A4a2.10)'''
-:Protective Coating: System <u>G</u> <u>I</u> <u>L</u> in accordance with Sec 1080.
-'''(A4a2.11) Use primer specified on Design Memorandum. System L must be used with inorganic zinc primer only.'''
-:Surface Preparation: Surface preparation of the existing steel shall be in accordance with Sec 1080 and Sec 1081 for <u>Recoating of Structural Steel (System G, H or I)</u> with <u>inorganic</u> <u>organic</u> zinc primer. The cost of surface preparation will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Surface Preparation for Recoating Structural Steel.
-'''(A4a2.12)'''
-:Prime Coat: The cost of the prime coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Field Application of <u>Inorganic</u> <u>Organic</u> Zinc Primer.
-'''(A4a2.13) The coating color shall be as specified on the Design Layout. When System L or I is specified, omit the 2nd sentence.'''
-:Field Coats: The color of the field coats shall be Brown (Federal Standard #30045). The cost of the intermediate field coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Intermediate Field Coat (System G). The cost of the finish field coat will be considered completely covered by the contract <u>lump sum</u> <u>unit</u> price <u>per sq. foot</u> for Finish Field Coat (System <u>G</u> <u>I</u>).
-=====A4a3. <u>Miscellaneous</u>=====
-'''(A4a3.1) 	Use for weathering steel or concrete structures with girder chairs and when a coating pay item is not included. '''
-:Structural steel for the <u>girder</u> <u>beam</u> chairs shall be coated with not less than 2 mils of inorganic zinc primer. Scratched or damaged surfaces are to be touched up in the field before concrete is poured. In lieu of coating, the <u>girder</u> <u>beam</u> chairs may be galvanized in accordance with ASTM A123. The cost of coating or galvanizing the <u>girder</u> <u>beam</u> chairs will be considered completely covered by the contract unit price for other items.
-'''(A4a3.2) Use when recoating existing exposed piles. (Guidance: "Aluminum" is preferred because it acts as both a barrier and corrosion protection where "Gray" only acts as a barrier. If for any reason coated pile is embedded in fresh concrete, "Aluminum" shall not be used.)'''
-:All exposed surfaces of the existing structural steel piles <u>and sway bracing</u> shall be recoated with one 6-mil thickness of <u>aluminum</u> <u>gray</u> epoxy-mastic primer applied over an SSPC-SP3 surface preparation in accordance with Sec 1081. The bituminous coating shall be applied one foot above and below the existing ground line and in accordance with Sec 702. These protective coatings will not be required below the normal low water line. The cost of surface preparation will be considered completely covered by the contract lump sum price for Surface Preparation for Applying Epoxy-Mastic Primer. The cost of the <u>aluminum</u> <u>gray</u> epoxy-mastic primer and bituminous coating will be considered completely covered by the contract lump sum price for <u>Aluminum</u> <u>Gray</u> Epoxy-Mastic Primer.
-====A4b. Concrete Protective Coatings====
-=====A4b1. Concrete Protective Coatings=====
-In "'''General Notes:'''" section of plans, place the following notes under the heading "'''Concrete Protective Coatings:'''".
-'''(A4b1.1) Use note with weathering steel structures. '''
-:Temporary coating for concrete bents and piers (weathering steel) shall be applied on all concrete surfaces above the ground line or low water elevation on all abutments and intermediate bents in accordance with Sec 711.
-'''(A4b1.2) Use note with coating for concrete bents and piers either urethane or epoxy. '''
-:Protective coating for concrete bents and piers <u>(Urethane)</u> <u>(Epoxy)</u> shall be applied as shown on the bridge plans and in accordance with Sec 711.
-'''(A4b1.3) Use note when specified on Design Layout.'''
-:Concrete and masonry protective coating shall be applied on all exposed concrete and stone areas in accordance with Sec 711.
-'''(A4b1.4) Use note when specified on Design Layout. '''
-:Sacrificial graffiti protective coating shall be applied on all exposed concrete and stone areas in accordance with Sec 711.
-=<big><big>'''1045 Paint for Structural Steel'''</big></big>=
-<br> <br> <br> <br>
-[[image:1045.jpg|right|275px]]
-This article establishes procedures for inspecting, [[106.3 Samples, Tests and Cited Specifications#106.3.1 Sampling|sampling]] and reporting paint and paint constituents.  Refer to [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045] for MoDOT’s specifications.
-Discussions on [[1045.4 Non-Standard Colors of Structural Steel Paint|non-standard colors of structural steel paint]] and [[1045.5 Policy on Color of Structural Steel Paint|color of structural steel paint]] policies are available.
-For Laboratory testing and sample reporting procedures, refer to [[1045.6 Laboratory Testing Guidelines for Sec 1045|EPG 1045.6 Laboratory Testing Guidelines for Sec 1045]].
-==1045.1 Apparatus==
-{|style="padding: 0.3em; margin-left:15px; border:1px solid #a9a9a9; text-align:center; font-size: 95%; background:#f5f5f5" width="210px" align="right"
 |-
-|'''Approved and Pre-Qualified List'''
+|Lateral stability
 |-
-|[https://www.modot.org/media/505 Qualified Aluminum Epoxy Mastic Paint]
+|Penetration anticipated soft geotechnical layers
 |-
-|[https://www.modot.org/media/506 Qualified High Solids Inorganic Zinc Silicate Paints]
+|Minimize post construction settlement
 |-
-|[https://www.modot.org/media/507 Qualified Epoxy\Polyurethane Paints]
+|Minimum embedment into natural ground
 |-
-|[https://www.modot.org/media/508 Qualified Waterborne Acrylic Paints]
+|Other Reason
 |-
-|[https://www.modot.org/media/509 Qualified Gray Epoxy-Mastic Primer]
+|colspan="7"  style="background:#BEBEBE"|
 |-
-|[https://www.modot.org/media/510 Qualified Organic Zinc Paints]
+|colspan="7"|'''Elevation reporting accuracy: Report to nearest foot for min. tip penetration, pile cleanout penetration, max. galvanized depth and est. max. scour depth.  (Any more accuracy is acceptable but not warranted.)'''
 |-
-|[https://www.modot.org/media/511 Qualified Polysiloxane Paints]
+|colspan="3"|'''For LFD Design'''
 |-
-|[https://www.modot.org/media/511 Qualified High Solids Inorganic Ethyl Silicate Paints]
+|colspan="3"|Use "Design Bearing" for load bearing pile and spread footing and use "Design Side Friction + Design End Bearing" for rock socket (drilled shaft).
 |-
-|'''MGS Information'''
+|colspan="3"|'''For LRFD Design'''
 |-
-|[https://www.modot.org/general-services-specifications-mgs-subject Current General Services Specifications (MGS) By Subject]
+|colspan="3"|Use "Minimum Nominal Axial Compressive Resistance" for load bearing pile, "Minimum Nominal Bearing Resistance" for spread footing and "Minimum Nominal Axial Compressive Resistance (Side Resistance + Tip Resistance)" for rock socket (drilled shaft).
 |}
-All sample containers and equipment used in sampling paint and paint constituents shall be clean and free of all contaminants. The apparatus required shall consist of:
+'''Shallow Footings '''
-(a) Appropriate size and type of sample container as given in the following subsections for the type of paint to be sampled.
+'''(E2.10) (Use when shallow footings are specified on the Design Layout.)'''
-(b) Appropriate thief or sampling device to obtain a representative sample.
+:In no case shall footings of Bents No. <u> &nbsp;  &nbsp;  &nbsp;  </u> and <u> &nbsp;  &nbsp;  &nbsp;  </u> be placed higher than elevations shown <u> &nbsp;  &nbsp;  &nbsp;  </u> and  <u> &nbsp;  &nbsp;  &nbsp;  </u>, respectively.
-(c) Packaging and labeling materials as described in [[106.3 Samples, Tests and Cited Specifications#106.3.1.2.2 Transportation of Samples|EPG 106.3.1.2.2 Transportation of Samples]] and [[106.3 Samples, Tests and Cited Specifications#106.3.1.3 Sampling Supplies|EPG 106.3.1.3 Sampling Supplies]].
+'''Driven Piles'''
-==1045.2 Procedure==
+'''(E2.20) (Use when prebore is required and the natural ground line is not erratic.)'''
+:Prebore for piles at Bent(s) No.<u> &nbsp;  &nbsp;  &nbsp;  </u> and <u> &nbsp;  &nbsp;  &nbsp;  </u> to elevation(s) <u> &nbsp;  &nbsp;  &nbsp;  </u> and <u> &nbsp;  &nbsp;  &nbsp;  </u>, respectively.
-Samples shall be taken by, or under the direct supervision of, the inspector, using all possible caution, skill and judgment to ensure that a representative sample is obtained.
+'''(E2.21) (Use when prebore is required and the natural ground line is erratic.)'''
+:Prebore to natural ground line.
+<div id="(E2.22) (Use the following note"></div>
-When sampling paint and paint constituents, take precautions to ensure that the samples are not contaminated or altered by any material not representative of the lot being sampled. Some paints or liquid constituents exhibit a tendency to settle or separate upon standing. Because of this, it is important to ensure that containers to be sampled, no matter the size container, is uniform prior to obtaining a sample. Mark all sample containers with the type of material, lot number, and the inspector's identification number. It is essential that samples of constituents be marked with the chemical names as called for in the given specification. Unless specifically requested, obtain only one random sample from each lot, batch, day's pack or other unit of production. In cases where several small lots are uniformly mixed in a larger mixer or tank, the mixed material shall be considered as one lot.
+'''(E2.22)  (Use when estimated maximum scour depth (elevation) for CIP piles is required.)   '''
+:Estimated Maximum Scour Depth (Elevation) shown is for verifying <u>Minimum Nominal Axial Compressive Resistance</u> <u>Design Bearing</u> using dynamic testing only where pile resistance contribution above this elevation shall not be considered.
-Whenever possible, obtain samples from original, unopened containers for all types of materials. When constituent containers have no markings distinguishing between units of production, take samples from different containers or storage units in the ratio of two samples for each 10,000 pounds (4500 kg) or portion thereof and blended in equal quantities to form a composite sample. Submit constituent samples only when requested by the Laboratory.
+'''(E2.23) (Use when static test piles are required.) The number of piles in table should not include probe piles. If probe piles are specified, place an * beside the number of piles at the bents indicated.'''
+:&nbsp;*One concrete probe pile shall be driven in permanent position, one for each bent, at Bents No. <u> &nbsp;  &nbsp;  &nbsp;  </u> and <u> &nbsp;  &nbsp;  &nbsp;  </u>.
-Packaging must comply with the applicable requirements of [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045].
+'''(E2.24) '''
-===1045.2.1 Vehicle Constituents===
+:All piles shall be galvanized down to the minimum galvanized penetration (elevation).
-When samples are requested by the Laboratory, ensure that the contents of the container or tank to be sampled has been thoroughly mixed. Fill the sample container, leaving approximately one inch (25 mm) space for expansion. Secure friction top lids with clips or other fastening devices before shipment. Observe shipping regulations when preparing samples for shipment.
-===1045.2.2 Pigments===
-When the Laboratory requests samples, open the package or storage container and take a sample at random from the contents.
-===1045.2.3 Mixed Paints===
-Sample containers are one quart (1 L), friction top cans and should be filled, leaving approximately one inch (25 mm) space for expansion. The inspector may mark and submit an original, unopened container of paint to the Laboratory in cases where the containers are small, such as quarts (L) or gallons (L). When an original container of paint cannot be sent to the Laboratory and there are no facilities for mixing or shaking the material mechanically, the inspector must ensure a representative sample by the following steps:
-(a) Pour off the top liquid into a clean, suitable container having a volume equal to or larger than the one being sampled.
-(b) Stir the settled portion of the paint with a paddle, gradually reincorporating the poured off liquid in small quantities until all has been returned.
-(c) Mix the paint by pouring it back and forth between the two containers several times.
-(d) Obtain a sample promptly so that settling does not occur before the sample is obtained.
-NOTE: This process is referred to as “boxing” the material.
-When samples are taken during the filling of containers, obtain a composite sample by combining samples taken at the beginning, middle, and near the end of the operation.
+'''(E2.25) (Use for all HP pile and when pile point reinforcement is required for CIP pile.)'''
+:Pile point reinforcement need not be galvanized. Shop drawings will not be   required for pile point reinforcement.
+<div id="(E2.26)"></div>
+'''(E2.26) (Use for LFD piling design when Design Bearing is determined from service loads and shown on the plans. See guidance on <font color="purple">[MS Cell] (E2.1)</font color="purple"> for specific pile driving verification method. Example: Considered only for widenings, repairs and rehabilitations.) '''
-Mechanically mix paint in holding tanks or 55 gallon (208 L) drums to ensure uniformity and sample promptly after mixing.
+:All  piling shall be driven to a minimum nominal axial compressive resistance equal to <u>3.5</u> <u>2.75</u> <u>2.25</u> <u>2.00</u> times the Design Bearing as shown on the plans.
+<div id="(E2.27)"></div>
+'''(E2.27) Use for galvanized piles.'''
-===1045.2.4 Submission of Samples===
+:The contractor shall make every effort to achieve the minimum galvanized penetration (elevation) shown on the plans for all piles.  Deviations in penetration less than 5 feet of the minimum will be considered acceptable provided the contractor makes the necessary corrections to ensure the minimum penetration is achieved on subsequent piles.
-Paint and some paint constituents require special handling. See [[106.3 Samples, Tests and Cited Specifications#106.3.1.2.2 Transportation of Samples|EPG 106.3.1.2.2 Transportation of Samples]] and [[106.3 Samples, Tests and Cited Specifications#106.3.1.3 Sampling Supplies|EPG 106.3.1.3 Sampling Supplies]] for packaging, labeling and marking instructions. Enter a Basic Sample Data report into AASHTOWARE Project (AWP) (see [https://epg.modot.org/forms/CM/AWP_MA_Sample_Record_General.docx AWP MA Sample Record, General]) for each sample of material submitted to the Laboratory. Include all pertinent information necessary to the sample, such as: kind of paint or constituent, batch or lot number, project number, purchase order or "general construction" for warehouse stock, inspector, source, quantity, intended use, contractor, destination, manufacturer's name and address.
-===1045.2.5 High Solids Inorganic Zinc Silicate Coating===
+'''(E2.28) Use when WEAP is specified as the pile driving criteria for friction pile. Place an * behind each instance of WEAP in the Foundation Data table. The pay item Pile Wave Analysis shall not be included when this note is used.'''
-[[image:1045.2.5.jpg|right|325px|thumb|<center>'''Field inspection of existing bridge coatings'''</center>]]
-Refer to the applicable requirements of [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045] for requirements pertaining to prequalification. The list of paints that are qualified by manufacturer and brand name appears as [https://www.modot.org/media/506 Qualified High Solids Inorganic Zinc Silicate Paints]. Sample each batch or lot of each component. A sample consists of one pint (500 mL) of inorganic silicate vehicle, one pint (500 mL) of metallic zinc powder and four ounces (120 mL) of activator component. Note that the activator is not to be sampled in metal containers and will be required only when sampling 3-component, high-solids primer. Submit the samples to the Laboratory through AWP, including the brand name, the batch or lot number of each component and the net weight (mass) shown on the container of each component.
-===1045.2.6 Polyurethane System G Final Coating===
+:<nowiki>*</nowiki>See electronic deliverables file for pile driving inspector’s chart(s). MoDOT will provide alternate charts for different driving systems as needed per request. With the request, the contractor shall provide the hammer manufacturer make and model, and any modifications to the manufacturer’s recommended settings including hammer cushion information. The contractor shall provide the request 30 calendar days before pile driving operations begin.
-Refer to the applicable requirements of [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045] for requirements pertaining to prequalification. The list of paints that are qualified by manufacturer and brand name appears as [https://www.modot.org/media/507 Qualified Epoxy\Polyurethane Paints]. Sample each batch or lot of each component. A sample consists of each component in the approximate volume proportions recommended by the manufacturer so that the mixed sample will consist of at least one quart (1 L). Submit the samples to the Laboratory through an AWP record, including the brand name, the batch or lot number of each component, and the net weight (mass) shown on the container of each component.
-===1045.2.7 High Solids Epoxy Intermediate Coat===
+='''REVISION REQUEST 4151'''=
-Refer to the applicable requirements of [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045] for requirements pertaining to prequalification. The list of paints that are qualified by manufacturer and brand name appears as [https://www.modot.org/media/507 Qualified Epoxy\Polyurethane Paints]. Sample each batch or lot of each component. A sample consists of one pint (500 mL) of each component. Submit the samples to the Laboratory using an AWP record, including the brand name, batch or lot number of each component, and the net weight (mass) as shown on the container of each component.
-===1045.2.8 Waterborne Acrylic System H Intermediate and Finish Coating===
+====127.2.3.3.1 Missouri Unmarked Human Burials Law====
-Refer to the applicable requirements of [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045] for requirements pertaining to prequalification. The list of paints that are qualified by manufacturer and brand name appears as
+If human skeletal remains are encountered during construction, their treatment will be handled in accordance with [https://revisor.mo.gov/main/OneChapter.aspx?chapter=194 Sections 194.400 to 194.410, RSMo], as amended. When human remains are encountered, the Contractor shall first stop all work within a 330-ft. or 100-meter radius of the remains, and secondly, shall notify the MoDOT Construction Inspector and/or Resident Engineer who will contact the Historic Preservation section. Historic Preservation staff will in turn notify the local law enforcement (to ensure that it is not a crime scene) and the State Historic Preservation Office (SHPO) as per RSMo 194 or to notify SHPO what has occurred and that it is covered by Missouri’s Cemeteries Law, §§ 214. RSMo. If the contractor is unable to contact appropriate MoDOT staff, the contractor shall initiate the involvement by local law enforcement and the SHPO. A description of the contractor’s actions will be promptly made to MoDOT.
-[https://www.modot.org/media/508 Qualified Waterborne Acrylic Paints]. Sample each batch or lot of each intermediate or finish coat.
-A sample consists of one quart (1 L) in a friction top can. Submit the sample to the Laboratory through an AWP record, including the brand name, the batch or lot number of each component, and the net weight (mass) shown on the container.
-===1045.2.9 Aluminum Epoxy Mastic Primer===
+If the human remains are prehistoric, the agency must consult with Indian tribes who have with ancestral, historic, and ceded land connections to the area in which the remains are located to determine the appropriate treatment of the remains. [http://www.modot.org/ehp/TribalMap.htm Tribal consultation] may result in the conclusion that the remains should be preserved in place and construction plans changed to facilitate their preservation.
-Refer to [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045] for requirements pertaining to prequalification. Aluminum epoxy mastic primer is not suitable for use in contact with freshly poured concrete. Brands that have been qualified are listed in [https://www.modot.org/media/505 Qualified Aluminum Epoxy Mastic Paint]. Sample each batch or lot submitted for use. A sample consists of one pint (500 mL) of each component in friction top cans. Submit the sample to the Laboratory through an AWP record, including the brand name, batch or lot number(s) of each component, and the weight (mass) shown on each container.
-===1045.2.10 Gray Epoxy Mastic Primer===
+<br><br>
-Refer to [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045] for requirements pertaining to prequalification. Gray epoxy mastic primer may be used in lieu of aluminum epoxy mastic. The list of paints that have been qualified by manufacturer and brand name are listed in Sec 1045. Each batch or lot submitted for use shall be sampled. A sample consists of one pint (500 mL) of each component in friction top cans. Submit the sample to the Laboratory through an AWP record, including the brand name, batch or lot number(s) of each component, and the weight (mass) shown on each container.
+<hr style="border:none; height:2px; background-color:red;" />
+<br><br>
-===1045.2.11 Organic Zinc-Rich Coating===
+==127.2.9 Construction Inspection Guidance==
-Refer to the applicable requirements of [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=14 Sec 1045] for requirements pertaining to prequalification. The list of paints that are qualified by manufacturer and brand name appears as Qualified Organic Zinc Paints. Sample each batch or lot of each component. A sample consists of one pint (500 mL) of organic vehicle, one pint (500 mL) of metallic zinc powder and four ounces (120 mL) of activator component. Note that the activator is not to be sampled in metal containers and will be required only when sampling 3-component, high-solids primer. Submit the samples to the Laboratory through AWP, including the brand name, the batch or lot number of each component and the net weight (mass) shown on the container of each component.
+Mitigation by data recovery is usually completed prior to construction if the presence of cultural resources is known. If [http://epg.modot.org/index.php/127.2_Historic_Preservation_and_Cultural_Resources#127.2.8_Artifacts_and_Features artifacts] are discovered during construction activities, the Historic Preservation section must be immediately notified. This will allow an inspection of the site by MoDOT HP staff to determine if further investigation is necessary before construction activities continue.
-===1045.2.12 High Solids Inorganic Ethyl Silicate Coating===
+[http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=4 Sec. 107.8.2] and [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=5 Sec. 203.4.8] of the ''Missouri Standard Specifications for Highway Construction'' require the contractor to take steps to preserve any such artifacts that may be encountered and to notify the MoDOT Construction Inspector or Resident Engineer of their presence. If it is necessary to discontinue operations in a particular area to preserve such objects, this section of the specifications is basis for a work suspension. In order to ensure compliance with applicable state laws, the MoDOT Construction Inspector or Resident Engineer cannot release remains or artifacts or allow the contractor to disturb the area within the 330-foot or 100-meter buffer space around these discovered items, until after consultation with MoDOT HP staff and until after all applicable requirements from FHWA or SHPO have been addressed.
-Refer to the applicable requirements of Sec 1045 for requirements pertaining to prequalification. The list of paints that are qualified by manufacturer and brand name appears as Qualified High Solids Inorganic Ethyl Silicate Paints. Sample each batch or lot submitted for use. A sample consists of one pint (500 mL) in a friction top can. Submit the sample to the Laboratory through an AWP record, including the brand name, the batch or lot number of each component, and the net weight (mass) shown on the container of each component.
-==1045.3 Acceptance==
+===127.2.9.1 Cultural Resources Encountered During Construction===
-Confirm that the paint is on the current approved list and that the paint is within its shelf life.  Obtain a certification specific to the batch of paint, with lot or batch numbers, date of manufacture and quantity represented by the certification.  Confirm that the lot or batch of paint has been sampled and approved by the Laboratory.  If not, sample the paint and submit it for approval prior to use.
+If cultural resources are encountered during construction, the contractor shall immediately stop all work within a 330-foot or 100-meter buffer around the limits of the resource and shall not resume without specific authorization from a MoDOT Historic Preservation Specialist. The contractor shall notify the MoDOT Resident Engineer or Construction Inspector, who shall contact the MoDOT HP within 24 hours of the discovery. MoDOT HP shall contact FHWA and SHPO within 48 hours of learning of the discovery and provide an evaluation of the resource and reasonable efforts to see if it can be avoided. FHWA shall make an eligibility and effects determination based upon the preliminary evaluation and consul with MoDOT, and SHPO a minimize or mitigate any adverse effect. FHWA will notify the Council and any tribes that might attach religious and/or cultural significance to the property within 48 hours of this determination. FHWA shall take into account Council and Tribal recommendations regarding the eligibility of the property and proposed actions, and direct MoDOT to carry out the appropriate actions. MoDOT will provide FHWA and SHPO with a report of the actions when they are completed. FHWA shall provide this report to the council and the tribes.
-==1045.4 Sample Record==
+===127.2.9.2 Human Remains Encountered During Construction===
-The Laboratory will issue the reports for samples submitted to the Laboratory.  Sample records indicating acceptance for project use will typically state “Prior Approval or Acceptance”, and will include the information provided in the certification, and where the certification is filed.
+If human remains are encountered during construction, the contractor shall immediately stop all work within a 330-foot or 100-meter radius of the remains and shall not resume without specific authorization from MoDOT HP Staff, and either the SHPO or the local law enforcement officer, whichever party has jurisdiction over and responsibility for such remains. The contractor shall notify the MoDOT Construction Inspector and/or Resident Engineer who will contact the MoDOT HP section within 24 hours of the discovery. MoDOT HP staff will immediately notify the local law enforcement (to ensure that it is not a crime scene) and the SHPO as per RSMo 194 or to notify SHPO what has occurred and that it is covered by Missouri’s Cemeteries Law, §§ 214. RSMo. MoDOT HP staff will notify FHWA that human remains have been encountered within 24 hours of being notified of the find. If, within 24 hours, the contractor is unable to contact appropriate MoDOT staff, the contractor shall initiate the involvement by local law enforcement and the SHPO. A description of the contractor’s actions will be promptly made to MoDOT. FHWA will notify any Indian tribe that might attach cultural affiliation to the identified remains as soon as possible after their identification. FHWA shall take into account Tribal recommendations regarding treatment of the remains and proposed actions, and then direct MoDOT HP to carry-out the appropriate actions in consultation with the SHPO. MoDOT shall monitor the handling of any such human remains and associated funerary objected, sacred object or objects of cultural patrimony in accordance with the Missouri Unmarked Human Burial Sites Act, §§ 194.400 – 194.410, RSMo.

User talk:Hoskir: Difference between revisions

Latest revision as of 16:04, 3 February 2026

REVISION REQUEST 4036

106.3.2.93.1 Means of Evaluating Aggregate Alkali Carbonate Reactivity

REVISION REQUEST 4143

751.36.5 Design Procedure

751.36.5.1 Design Procedure Outline

751.36.5.2 Structural Resistance Factor (ϕc and ϕf) for Strength Limit State

751.36.5.3 Geotechnical Resistance Factor (ϕstat) and Driving Resistance Factor (ϕdyn)

751.36.5.4 Downdrag and Losses to Geotechnical Resistance due to Scour and Liquefaction

751.36.5.5 Preliminary Structural Nominal Axial Design Capacity (PNDC) of an individual pile

751.36.5.6 Preliminary Factored Axial Design Capacity (PFDC) of an Individual Pile

751.36.5.7 Design Values for Steel Pile

751.36.5.7.1 Integral End Bent Simple Pile Design

751.36.5.7.1.1 Design Values for Individual HP Pile

751.36.5.7.1.2 Design Values for Individual Cast-In-Place (CIP) Pile

751.36.5.7.2 General Pile Design

751.36.5.7.2.1 Design Values for Individual HP Pile

751.36.5.7.2.2 Design Values for Individual Cast-In-Place (CIP) Pile

751.36.5.8 Additional Provisions for Pile Cap Footings

751.36.5.9 Estimate Pile Length and Check Pile Capacity

751.36.5.9.1 Estimated Pile Length

751.36.5.9.2 Check Pile Geotechnical Capacity (Axial Loads Only)

751.36.5.9.3 Check Pile Structural Capacity (Combined Axial and Bending)

751.36.5.10 Pile Nominal Axial Compressive Resistance

751.36.5.11 Check Pile Drivability

751.36.5.12 Information to be Included on the Plans

E2. Foundation Data Table

REVISION REQUEST 4151

127.2.3.3.1 Missouri Unmarked Human Burials Law

127.2.9 Construction Inspection Guidance

127.2.9.1 Cultural Resources Encountered During Construction

127.2.9.2 Human Remains Encountered During Construction

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751.36.5.2 Structural Resistance Factor (ϕ_c and ϕ_f) for Strength Limit State

751.36.5.3 Geotechnical Resistance Factor (ϕ_stat) and Driving Resistance Factor (ϕ_dyn)