Difference between revisions of "Category:203 Roadway and Drainage Excavation, Embankment and Compaction"

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'''Surcharged Embankments'''
 
'''Surcharged Embankments'''
  
As specified.  Also refer to [[Construction Inspection Guidance for Sec 204]], Embankment Monitoring
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As specified.  Also refer to [[:Category:204 Embankment Monitoring|Construction Inspection Guidance for Sec 204]], Embankment Monitoring
  
 
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'''Frozen Foundation'''

Revision as of 13:12, 25 July 2007

Contents

203.1 Construction Inspection Guidance for Sec 203

Problems can usually be held to a minimum by assignment of qualified, trained personnel to the position of compaction inspector. On larger grading projects it is well, wherever possible, to train new technicians under the supervision of the compaction inspector to perform the mechanical tests and assist in compaction inspection.

Contractor Grading Schedule

The inspector should obtain the contractor's grading plan of operation. The inspector should then immediately run enough standard compaction tests covering materials in the area where work will start to replace those furnished by the district soils and geology technologist. The inspector should also determine moisture content of the soil in its natural state throughout the area where the contractor plans to start grading.

Project Documentation

The grading inspector should record:

  • The daily record of events, including station limits where work was performed during the day, type and pieces of equipment used, manpower with an estimate of the contractor’s daily production
  • Weather conditions including the condition of material being moved with an assessment of whether the day qualifies as a working days as defined by specifications. This assessment should be recorded regardless of whether the project is a working day or a calendar day completion project
  • Notes regarding any instructions issued to, or any discussions with contractor's representatives, which affect prosecution of the work
  • A complete record of all density tests. This record should explain corrective action taken at locations where failing test results were obtained, and reasons, if required tests were not taken at other locations
  • Notes regarding damage to private property caused by contractor's equipment and/or operations
  • Notes regarding stream or lake pollution
  • Records regarding amount and disposition of salvageable materials.

The person making each diary entry must sign it.

Documentation Records

The importance of keeping accurate, up-to-date records of all work being inspected cannot be overemphasized. Documentation records are issued to authorize these items:

  • Measurements and notes to substantiate classification and quantity of the various materials encountered in the excavation.
  • Measurements and notes to document amount and reasons for undergrading and cut compaction.

Excavation Checklists

The following information outlines the areas of responsibility of the earthwork inspector. This "checklist" should be used as a reminder.

Operations to be performed before the contractor begins clearing or grading include:

  • Right-of-way is staked.
  • Limits of clearing and grubbing are marked.
  • Salvageable material marked.
  • Items to be replaced, such as survey corners, lot corners, historical markers, etc., tied out.
  • Clearing and grubbing units taken, documented in a field book, and checked and signed by contractor, or quantities furnished him.
  • Before starting an embankment, the location of the work should be clearly outlined by construction stakes.
  • Control stakes set (cut and fill) and understood by all.
  • Documentation record issued explaining how stakes were set. Stakes that are disturbed or destroyed should be immediately reset.
  • Borrow areas and estimated excavation cross-sectioned.
  • Foundation where fills are to be constructed given a thorough inspection.
  • Soil survey in field laboratory with soils identified and compaction standards run on each type and/or horizon of soil.
  • Satisfactory field laboratory with proper testing equipment and materials on site.
  • Plans and special provisions for any special equipment or construction procedures reviewed.
  • Payment diary with method of measurement for each pay item to be encountered and method of documentation (review the specifications and engineering guidance).

Responsibilities once excavation begins include:

  • Observe for condition and type of soil being excavated.
  • Watch for classification changes in materials.
  • Watch for overload equipment around drainage structures. The inspector should see that the contractor has the proper permits, where necessary, for hauling over or across existing pavements or structures.
  • Ensure proper lift thicknesses are distributed uniformly over the full width of roadway.
  • Require clods to be broken up on embankment areas to minimize excessive voids or a scabbing effect produced by mashed clods.
  • Ensure the fill is continuous leveled and manipulated to insure uniform density.
  • Observe proper signing, flagging, erosion control, etc. are being performed.
  • Observe number of passes of approved compactive equipment on rock fill.
  • Ensure proper benching techniques are performed when slopes are widened or fills are tied into steep terrain to prevent future slope or grade failure.
  • Require density to meet minimum requirements of the specifications. Keep in mind that specifications may require a different density at bridge ends and for the top portion of embankments under flexible pavement, from that on remainder of the roadway.
  • When specified, require compactive effort is performed when material is at proper moisture content. If material is too wet or too dry, the contractor may correct a wet condition by aerating the material by disking or other means. If the soil is too dry, water may be added at the borrow site or cut areas before excavating. This reduces the manipulation necessary to obtain uniform distribution.
  • A stable grade is essential and it can be secured only if adequate attention is given to surface drainage. Water pockets create soft or spongy spots in the subgrade and unfit for pavement. Inspect the rolling operation. If the subgrade is pumping, cracking or is showing other signs of failure, determine the magnitude of the failure and take corrective action to address the problem. Rutting will produce areas in deficient thickness and will result in a poorly drained subgrade.
  • Perform the necessary number of field density tests daily to document the quality of the grade.
  • Obtain density tests in structure backfill.
  • Require roadway surface to be kept properly shaped and drained.
  • Document density checks, thickness lifts, roadway template checks, and any special instructions given to the contractor.

Description (Sec 203.1)

Roadway and drainage excavation is the material obtained from within the right of way, and from easements for channel revisions or from borrow. Materials include common earth, solid rock, detached boulders, or a combination of these materials (unclassified). It is used to construct embankments to required grade, line and typical section. Prior to beginning excavation and embankment operations in any area, all necessary clearing, grubbing and stripping in that area shall have been performed as specified in Sec 201.

Classification of Excavation (Sec 203.2)

Excavated material is usually classified according to its structural characteristics. Excavation classes are grouped by geologic definitions and not by excavation methods. When the contract specifies classified excavation, the ordinary classifications will be Class A, Class C, or Unclassified Excavation.

Precise records must be kept on a project with more than one class of excavation as separate pay items. Changes from one classification to another must be noted. Sufficient measurements must be taken to establish correct pay quantities for each classification. When lines of demarcation are clearly defined, the usual method of measurement is to take cross sections along these lines.

Calculation of Excavation Classification Percentages

Formations of large boulders, intermittent ledges that are not well defined, and some irregular types of pinnacle rock may be encountered which make it impractical to establish lines of demarcation. It then becomes necessary to classify material on a percentage basis. In such cases, cross sections should be taken along the upper limits of the material in question. While material under consideration is actually being removed, the resident engineer should study it jointly with the district geologist and the contractor's representative to reach agreement on the classification percentage to be used. Lateral limits of questionable classification should also be established. Divide the cut into smaller areas both longitudinally and transversely for separate consideration, if classification percentage varies appreciably through the cut. Elevations or cross sections, and longitudinal limits must be taken to establish each volume of varying percentage. After agreement is reached on the percentage of each classification, the contractor should be given a written copy of the agreement as a matter of record.

Class A Excavation (Sec 203.2.1)

The geologic definitions for determining proper classification of Class A are defined in Sec 203. One of the more difficult materials to classify is chert. Sec 203.2 should be carefully reviewed before classifying chert as either Class A or Class C.

Class C Excavation (Sec 203.2.2)

Geologic definition for determining proper classification of Class C is defined in Sec 203. Care must be taken to avoid confusing Class C excavation with shale, fire clay, or similar materials, all of which are considered Class A Excavation.

Unclassified Excavation (Sec 203.2.3)

On some projects no attempt is made to classify excavation and bids are taken on the basis of Unclassified Excavation. All material excavated will be considered Unclassified Excavation unless the contract specifies classified material. Work will consist of excavation of all materials encountered regardless of their nature or the manner in which they must be removed.

Unclassified excavation requires the same measurements for the determination of final quantities as classified material. If the roadway profile, slopes or berm elevations are changed in an unclassified cut, cross sections should be taken and a revised quantity computed.

Borrow (Sec 203.3)

An effort is made on most jobs to design for the "cut" and "fill" to balance. For many reasons there may not be enough suitable roadway excavation, together with excess channel and structure excavation, to complete the embankment to required section and grade. When this occurs, borrow excavation must be obtained to make up the difference. Borrow is of approved material classified in the same manner as roadway excavation. It is to be obtained from borrow areas shown on the plans or from other areas designated or approved by the engineer. Before the contractor moves material from a borrow area, cross sections or measurements must be taken that the volume moved can be computed.

Use of borrow from areas other than those shown on the plans or designated by the engineer should be approved only if the material is equally satisfactory, if all requirements for substitution specified in Sec 203 are met, and if the substitution is in the best interest of the Commission. Proposed alternate borrow sites will require environmental clearances if the site had not been previously approved. Reference to cost of easements includes those acquired by MoDOT as well as those the contractor may acquire.

MoDOT Borrow Easements

The Right of Way Division acquires easements required for construction of the project. However, since they are acquired to provide a construction material, they are charged as a construction cost. On federal-aid projects no federal participation can be expected, if they are not used. MoDOT could, therefore, suffer a monetary loss due to the contractor's substitution.

If the easement is used on federal aid work, MoDOT pays for a borrow easement and pays bid prices for excavation incorporated in the project. MoDOT receives federal participation in the cost of both items.

If the easement is not used, MoDOT’s payments are the same as in the previous case, but the federal participation is limited to the costs involved in the actual excavation. The Division of Construction and Materials should be contacted about the costs to be recovered before borrow substitutions are approved.

All borrow areas shall be bladed and left in such a shape as to permit taking the necessary cross sections after excavating has been completed. The finished borrow areas shall be approximately true to line and grade if so specified in the contract, and shall be finished, where practical, such that no water will collect or stand therein.

Borrow Agreement

MoDOT expects the contractor to conduct their activities in a professional manner. Property owners often look to MoDOT to correct any damages created and left by the contractor. For this reason the contractor must obtain a written release from the property owner to document that the owner suffered no damage.

Environmental Clearances

Proposed alternate borrow sites will require environmental clearances if the site had not been previously approved. At the preconstruction conference, a discussion of the project environmental issues is discussed (Category: 105 Control of Work).

MDNR Storm Water Permit

Normally it will be the inspector’s responsibility to enforce the requirements of MoDOT's Storm Water Permit obtained from MDNR. The inspector should also be alert to any developing problems, which could lead to stream polluting. If such problems are detected, they should be brought to the attention of the contractor and the resident engineer and adjustments made to correct the problem.

Erosion Control

The contractor is required to submit, at or prior to the preconstruction conference, a proposed schedule (plan) for implementing the temporary and permanent erosion control work. The proposed implementation plan should be in sufficient detail to assure the department that permanent erosion control features will be constructed at the earliest possible time and that adequate temporary controls will be used during the period of actual construction.

No work is to begin until the erosion and pollution control measures are reviewed and accepted by the resident engineer. The contractor's schedule must address borrow areas, staging areas, storage locations and handling of petroleum products and other pollutants, temporary pollution and erosion control measures for all staged and completed construction operations.

If stage construction is expected on the project, a separate erosion control plan is usually developed for each stage. The erosion control plan addresses methods to intercept the sediment before it enters crossroad drainage. Temporary erosion control measures are not to be placed in natural drainage or streams. The plan must include measures for the control of both sheet and gully erosion for the project and borrow areas. The erosion control plans should indicate the right of way limits including temporary and permanent easements and construction limits. All permanent drainage structures and temporary erosion control features are shown. Additional erosion control guidelines are available.

The wetland specialist from the Design Division and the liaison engineers in the Construction and Bridge Divisions are available for guidance to address stream crossings or to assist with marginal or questionable proposals.

It is not practical or economical to provide temporary erosion control measures through cuts when grading operations are active. In cases where the contractor operations would conflict with erosion control items, sediment containment measures must be concentrated where the soil-laden runoff from the cut area leaves the right-of-way (especially at equipment crossings and bridge projects). The main objective is to keep project sediment from leaving the project.

Authorized Open Erodible Area

The resident engineer will limit the amount of surface area of erodible earth material exposed at one time due to excavation, borrow fill within the project, contractor furnished borrow and excess material disposal site. The resident engineer may further limit the area commensurate with the contractor's capability, history of performance and progress of permanent erosion control measures.

Specifications limit the surface area of erodible earth material exposed at one time to 10 acres within any individual drainage area without installation of erosion controls for that drainage. The total surface area exposed at one time for the entire project shall not exceed 17 acres without the written approval of the engineer. Specifications allow the engineer to increase or decrease the amount of surface area of erodible earth material to be exposed at one time. Documentation is necessary to increase the allowable open acreage.

In order to complete projects in a timely manner and to reduce the time the project grade is susceptible to erosion, it makes sense to allow the contractor some flexibility to open additional acreage beyond the above stated square feet requirements. Depending on the resources a contractor is willing to commit to the project, additional area can be authorized for each grading spread a contractor has active. An effective grading operation must also include equipment to finish the grade. Before additional areas are increased the resident engineer must be satisfied that the contractor is installing temporary erosion controls before 435,000 square feet are opened and is finishing grade and installing permanent erosion controls before 750,000 square feet per spread are exceeded. As the contractor removes equipment from the job, the authorized acreage must also be decreased. The controls on exposure of erodible soil are intended to apply to normal operations. The use of small crews at several locations should not be allowed to serve as a means of enlarging the permissible exposed area.

In calculating the 17 acres of allowable erodible area, any area not susceptible to erosion, such as, rock fills or cuts, rock slopes, paved or rock lined ditches, base or roadway pavement, seeded or sodded surfaces could be excluded from the total. Simply removing trees do not necessarily add an area to the total allotted 750,000 square feet of erodible area. If sod is present after clearing is completed, the area need not be included. Placement of temporary erosion control measures, i.e. ditch checks, sediment basins or silt fence do not allow additional erodible area in excess of the 750,000 square feet maximum. If the authorized acreage exceeds the specified limits, written documentation is required to justify the excess.

Often the contractor will want to clear and grub the entire project. The contractor is limited to the acreage authorized by the resident engineer. Areas with ground cover do not count towards the erodible acreage allowed. The contractor may, at his expense, apply temporary seed to obtain the necessary ground cover and, once vegetation is to the specified plant density, clearing can proceed. If the area is to sit idle for an extended time frame, mulch should also be applied with the seed. Before seasonal discontinuance of project operations, erodible areas are to be seeded.

Weekly Erosion Inspections

Weekly erosion inspections are required by MoDOT's MDNR Storm Water permit. Be familiar with the permit conditions. Copies of the weekly erosion inspections, the permit and the Storm Water Pollution Prevention Plan should be maintained in a folder for easy future reference.

Permit require land disturbance sites to be inspected on a regular schedule and within a reasonable time period (not to exceed 72 hours) following heavy rains. Regularly scheduled inspections are to be at a minimum once per week. Project erosion inspections should be scheduled with the project superintendent and documented. Particular attention to the erosion control items in areas where drainage leaves the project (especially around bridge structures). For disturbed areas that have not been finally stabilized, all installed (Best Management Practices) and other pollution control measures are to be inspected for proper installation, operation and maintenance. Locations where storm water leaves the site are inspected for evidence of erosion or sediment deposition.

Any deficiencies noted during a weekly inspection shall be corrected with seven calendar days of that inspection. The results of the weekly inspections in a given month are recorded in that month's report. Notice of deficiencies is given to the contractor responsible for operation and maintenance of BMPs.

A log of each inspection is to be kept. The inspection report is to include the following minimum information;

  • Inspector's name,
  • Date of inspection,
  • Observations relative to the effectiveness of the BMPs,
  • Actions taken or necessary to correct deficiencies, and
  • A listing of areas where land disturbance operation have permanently or temporarily stopped.

The person performing the inspection signs the report.

It is recommended a diary be utilized to document erosion control inspection, inspection findings and instructions given to the contractor. The logbook should contain all relevant documentation relating to erosion control for easy reference. It would be advantageous to document payments for erosion control items on the project, documentation records and order records issued regarding erosion control. The authorization date for areas to be opened should be shown with a corresponding date the areas are permanently seeded or are no longer considered erodible. A running log of the open erodible acreage inspection records can be maintained in this diary. Documentation records at the erosion control benchmark dates for evaluating contractor performance should also be maintained in this diary.

Enforcement Inspections

MDNR or other agencies may inspect the erosion control efforts on a project. The following steps should be taken:

  • If an enforcement inspector observes a violation of our agreement with them, the inspector should notify the resident engineer describing the type and location of the violation and giving a time frame for correcting the violation.
  • The resident engineer will have the deficiency corrected within the specified time frame, usually within 7 calendar days.
  • The resident engineer will fully document the meeting with the inspector.
  • The resident engineer should videotape the location of the violation before and after corrective action is taken.
  • Notify Division of Construction immediately of any Notice of Violation (NOV) issued by the Department of Natural Resources (DNR) or of any inspection from the Environmental Protection Agency.

Water Quality Monitoring Procedure

MoDOT’s permit requires the quarterly reporting of projects with 1 acre or more of erodible area. If an enforcement agency wishes, water quality monitoring may be imposed on a project. The following procedures describe the water quality test:

  • This guidance has been developed for district personnel who may be collecting the required samples. It is intended to provide a consistent approach for choosing sample sites, collecting samples, performing the necessary tests, and reporting test results.
  • Materials needed to perform sampling and testing
  • 3 clean, wide mouthed quart mason jars
  • 3 Imhoff cones
  • 1 cone holder
  • Procedure.
a. Choose 3 representative sample collection locations. Identify three different locations on your selected project site where you will be able to collect a sample of runoff water during a rainfall event. Since the primary purpose of our water sampling is to verify the effectiveness of our erosion control practices or structures, it is important to locate your sample collection stations downgrade from a series of silt fences, straw bale dams, detention ponds or combination of these. Remember, it will be muddy when you are sampling, so keep convenience in mind when you consider your sample collection points.
b. Construct sample collection point. Before you collect any runoff samples, you will need to identify or create a situation whereby you can grab a representative sample of water flowing away from the erosion controls with a wide-mouthed sample jar. It will be best to locate your sample collection point at a box culvert, drop inlet, or ditch check. The critical element is to insure that you are grabbing a sample that is representative of that water which is leaving the site.
c. Diagram your three sample locations. Develop a simple sketch that describes the basics of your sample location. Show the direction of flow, the locations of check dams, silt fences, etc, and the sample collection point. This may need to be modified as construction proceeds, and will ultimately be included with your sample results. This sketch will be of value in the eventual interpretation of the test results and may help to identify the most effective erosion controls.
d. Wait for rain.
e. Collect samples. During a rainfall event that is of sufficient duration or intensity to cause runoff, use the wide mouth mason jars to grab a sample from each of your three sampling points. Again, you are attempting to collect a representative sample of the runoff water. Make sure you completely fill your quart sample collection jar because the test that you will perform back at your project office requires one liter of water. Make certain that you identify each jar according to its specific sample location. This can be done with a magic marker on the lid, a prepared label taped to the jar or any other means by which you can keep your samples straight. This is important because some erosion controls may be more effective than others and we will want to carefully document these differences.
f. Record appropriate rainfall intensity information. Note as much information about the intensity, duration, and accumulation of the specific rainfall event. This information is necessary to correctly evaluate our sample results. Installation of rain gauges is not necessary as the type of information that we seek should be readily available from local radio stations, newspapers, local ASCS office or other sources.
g. Perform the test for settleable solids. The attached methodology is taken from "Standard Methods for the Examination of Waters and Wastewaters". Note that there are two different methods. Use procedure 209 E. 3a, the volumetric method. You will use the three Imhoff cones and the cone rack that were provided to you.
h. Record your results. Use the attached form to record your results. If you collected samples on different days use a different page for each day (See Figure 200.19).
i. Mail in your results. Attach a copy of your site sketch(s) to your sample results and send them to the Construction and Materials Division. Keep a copy in your project file.

Contractor Performance Erosion Control Benchmark Inspections

The entire effort to achieve compliance with our permits should not fall on the project inspector. The contractor is required to submit an erosion control plan at the preconstruction conference. Compliance with contract requirements is the contractor's responsibility. Currently the contractor performance rating evaluates the contractor's erosion control efforts at quarterly benchmark dates of January 1st, April 1st, June 1st, and September 1st. At the preconstruction conference, a contractor contact should be provided as a point of contact for erosion control matters. The individual should be included in the DNR inspections and erosion control benchmark date inspections. If deficiencies is noted from a weekly inspection or if a DNR letter of warning is received, written notice would be given to the prime to correct the deficiencies within a specified time frame, usually a calendar week. The failure to comply with the written instructions would result in an order record with a second deadline date for compliance. If an order record is necessary, it is recommended 10% of all grading quantities for unfinished grades and 5% for any non-seeded finished areas be withheld from the pay estimate and not paid until the seeded areas are accepted. Failure to meet that date would result in a second order record with a notice to cease and desist all operations other than operations to bring the contract into compliance with our erosion control permit. Failure to meet the second deadline would also be grounds for the resident engineer to hire a contractor to correct the deficiencies. The cost to correct the deficiencies would be subtracted from the project's pay estimate.

Documentation Record

Documentation for evaluating contractor performance must include the open and authorized acreage and the proper maintenance of temporary erosion control items. The documentation should reflect the number of items currently required on the project compared to the number of items properly installed and maintained. For example; if the project currently requires 24 Type II ditch checks and the contractor has only 12 installed and of the 12 in place only 50% are properly maintained, the contractor would have 25% of the contract value for 24 Type II ditch checks applicable to his performance rating. If sediment buildup is more than 50% of the height of the check, then the ditch check isn't being properly maintained. The same reasoning would be applied to Type I ditch checks, slope drains, silt fence, sediment basins, etc.

Construction Directory

Once the erosion status for the project is given to the contractor, the project's erodible acreage information in the Construction Directory must be updated. If a project has zero acreage erodible, please enter a zero "0" in the field. This information is important as it is used to generate the DNR erodible acreage quarterly report. A blank field will result with the project being listed in the report.

Construction Requirements (Sec 203.4)

General

Constructing earthwork to reasonably neat and uniform lines is desirable for all phases of earthwork construction including channels, roadway ditches, and other such features. The task of finishing earthwork can be held to a minimum, better construction will result and erosion is minimized if every reasonable effort is made during excavation of cuts and construction of embankments to finish slopes, shoulders and ditches as work progresses. It is impractical to trim rock slopes to exact cross section; however, any dangerous or objectionable appearing projections or loosened boulders should be removed and the slope made as uniform as possible.

Finished earthwork should have a pleasing contour and be reasonably smooth in all respects. Tops and bottoms of slopes should be rounded where shown on typical sections. Rounding improves appearance and helps reduce erosion. Transitions in slope and warping to fit special or unusual features within the roadway should be gradual. Abrupt changes of slope at the intersection of cuts and fills should be avoided.

Grading Tolerances

The tolerances for finish grading on stage construction projects will be administered as follows:

  • Class A subgrade has a tolerance of + / - ½” as required by Sec 209.2.1. 2.
  • Class C subgrade is to be 2 inches low with the top 2 inches backfilled with material meeting the requirements of Sec 203.4.4.2.1 to the established template with a tolerance of 0.1 feet.

Field Stone (Sec 203.4.1.1)

As specified.

Shoulders (Sec 203.4.1.2)

The construction of shoulders shall start when sufficient surfacing has been completed and the surfacing has attained satisfactory strength to permit continuous shouldering operations. Equipment that will damage the surfacing will be prohibited from operating on the surfacing during shouldering operations. Surfacing and curbs shall be protected where equipment is crossing or turning.

Grading for Aggregate Type Surface Roadway (Sec 203.4.1.3)

As specified.

Maintenance (Sec 203.4.2)

As specified.

Removal of Oversize Material in Subgrade (Sec 203.4.3)

The engineer may order the contractor to remove oversize material if the upper 4 inches (100 mm) of the subgrade, as tentatively completed, contains loose rock over 2 inches (50 mm) in size to make the subgrade unacceptable as a roadbed for the proposed type of surfacing in the judgment of the engineer.

Excavating in Rock (Sec 203.4.4)

Rock excavation must be broken down to satisfactory sizes for removal from the excavation and incorporation into embankments. Blasting should always be done under competent, careful supervision to prevent injury to persons or damage to adjacent property.

Blasting Requirements (Sec 203.4.4.1)

The resident engineer must ensure the contractor complies with the requirements of Sec 107.7 regarding the use of explosives and blaster certification requirements.

Blasting Plan

The contractor must submit a blasting plan to address the requirements of Sec 203.4.4.1.1. Spacing and depth of drill holes, type of explosive, loading sequence, methods of firing, and related matters are items to be determined by blasting experts. Each of these items depends on local rock conditions and production equipment to be used. Spacing and strength of blasting charges should be such that the actual blast is as light as possible consistent with thorough rock breakage and reduction in size. Overshooting is very undesirable. It can produce rock fractures beyond the intended line and grade that result in jagged slopes, uneven ditch grades, and possible future slides in the slope area.

Blasting should produce specification material while leaving the "cut" area at the correct line and grade. Good blasting technique can materially lower the contractor's cost by producing specification material under relatively safe conditions. Poor blasting technique is not only dangerous, but it can cause excess over-breakage, or it can fail to shatter the material enough for economical handling and placement, thereby requiring additional drilling and shooting.

Presplitting

In deep cuts through difficult material where slope smoothness is hard to obtain it can be advantageous to drill holes parallel to the proposed roadway slope. In these holes the charge is distributed along the length of the hole instead of placing it all at the bottom. The portions of the charge are then exploded simultaneously. This method, known as "presplitting", is not intended to loosen and break up an appreciable quantity of rock. It is intended instead to shear the rock in a reasonably smooth plane along the proposed slope face. The rest of the rock in the cut is then shot and removed in the manner best suited to the material involved.

Undergrading (Sec 203.4.4.2)

The contractor must backfill undergraded the area areas with rock spalls or other acceptable granular material.

Final Surface

The approximately top 2" of the rock grade is to be finished with rock fragments, spalls, or granular base to provide a surface that can be autograded. This issue is important if a subsequent project provides for the paving. Large material left in the subgrade can create additional work and expense for the department if this requirement is not properly performed.

Overbreak (Sec 203.4.4.3)

Excess overbreakage is not only undesirable from an appearance standpoint but is very costly to the contractor, since he receives no pay for material excavated beyond design slope limits. All additional excavation, hauling, and disposal expense caused by overbreakage must be borne by the contractor.

Special care should be taken in blasting immediately adjacent to proposed slopes or ditch lines.

Unsuitable Material (Sec 203.4.5)

Unsuitable material is defined as material that will adversely affect stability of the completed roadbed. It may be material with high organic content, exceedingly high moisture content, excessive P.I., etc., or it may be unsuitable only for a particular location in the roadbed template. Normal construction processes can correct some conditions that render material unsuitable. For example, high moisture content can, in many soils, be reduced by aeration and manipulation. Materials that cannot be rendered satisfactory by manipulation create problems for inspecting personnel. When such material is encountered above grade in cuts, disposition should be as directed by the resident engineer, unless a reasonable method of treatment is available to make it satisfactory. In some cases, material may be of a type that can be used in the bottom of high fills without affecting the ultimate stability of the roadbed, in other cases disposition of the material should be outside roadbed limits as discussed in Sec 203.6.

Borrow (Sec 203.4.6)

When the contract provides for borrow from both a future roadway and a borrow area, roadway excavation must be completed first before excavating from borrow areas. Project borrow sites must be utilized prior to excavating contractor provided borrow areas. Should the contractor proceed to excavate in designated or provided area before completing excavation from the roadway, the contractor should be advised by order record that such action is being done at his own risk and expense. If excess material must be restored to the borrow area, it shall be returned at the contractor's expense.

The contractor shall not excavate beyond the dimensions and elevations established, and no material shall be removed prior to staking and cross sectioning the site. Borrow quantities are not to be finaled until all grading is completed. If the contractor places more borrow than required, thereby causing a waste of excavation, such waste will be deducted from the borrow volume.

If it is necessary to remove fencing in order to obtain borrow material, the fencing shall be replaced in as good condition as the fencing was at the time of removal. The contractor shall be responsible for confining livestock when a portion of the fence is removed. Removing and replacing such a fence or the confining of livestock shall be at the contractor’s expense.

Roadway Obliteration (Sec 203.4.7)

As specified.

Human, Criminal, Historical, Archaeological or Geological Remains (Sec 203.4.8)

As specified.

Excavated Material Stockpile (Sec 203.4.9)

In some areas where a scarcity of suitable material is anticipated for constructing top portions of embankments and backfilling undergraded areas, the plans may show certain material available from roadway excavation to be stockpiled for future use. If there is any doubt about suitability of material proposed for such purposes, the resident engineer should contact the district operations engineer for advice. The district soils and geology technologist may also be consulted and may wish to test the proposed material. Stockpile sites should be selected which will minimize the haul involved without interference or delay to other construction operations.

Embankment Construction (Sec 203.4.10)

Uneven riding surfaces may result from non-uniform soil types or from variations in moisture and density during construction. These conditions cause variable initial strength. They also cause uneven responses to moisture change in the form of swell or shrink. They may lead to changes in strength as a result of the non-uniform responses, all because of climatic effects such as periods of excessive rainfall or drought, and of freezing and thawing. To guard against these undesirable effects, proper blending of materials is essential. The use of discs, plows, blade graders, or similar equipment will usually accomplish the desired result. The less desirable materials should, whenever feasible, be used in the lower portion of the higher embankments.

Selection of equipment used to haul and spread embankment material is the contractor's option. However, he should not be permitted to operate equipment of such weight or in such manner that it will damage any completed work.

All ditches, including inlet and outlet ditches, shall be cut to grades that will properly drain. The required cross section for inlet and outlet ditches leading to or from structures shall be of a width no less than the width of the structure.

Broken up portland cement concrete, asphaltic concrete, bituminous pavement, rock, gravel, sand, uncontaminated soil, cinder blocks and brick are considered to be clean fill. Asphaltic concrete and bituminous pavement is considered clean fill only when used above the ordinary high water mark of a stream. Disposal of these materials will be in accordance with Construction Inspection Guidance for Sec 202. The inspector should ensure the contractor spreads his hauling units over the full width of the grade while hauling to and returning from the embankment area. By distributing movement of units, compactive effort is applied by hauling units, deep rutting is minimized, and compacting time of tampers and rollers is reduced. The inspector should acquaint himself with the compaction equipment to be certain adequate compactive effort is being exerted since it will be physically impossible in some cases to obtain a density test on each lift. This also applies to compactive effort around structures and on the edges of embankments.

Surcharged Embankments

As specified. Also refer to Construction Inspection Guidance for Sec 204, Embankment Monitoring

Frozen Foundation

Layers of embankment may not be built of frozen material. Neither may layers of embankment be placed on foundation soil that has frost penetration in excess of 0.2 foot except under specific conditions defined in Sec 203.

Embankment on Hillsides or Against Existing Embankment (Sec 203.4.11)

When constructing embankments on steep slopes, particular attention must be given to obtaining a good interlock between the sloping foundation and new embankment. Every effort must be made to prevent formation of slippage planes. This usually requires removal of all vegetation, plowing of hard surface areas, and benching, in accordance with Sec 203. This "benching" is required when constructing a new embankment against existing ground which has a slope steeper than 6:1. Each horizontal cut for the bench must begin at the intersection of the ground line and the vertical side of the previous bench. The bench must be wide enough to permit placing and compacting operations. Benches are required to have a minimum rise of 12 inches. This method of keying new embankment to the surface of foundation material should also be used when widening and/or raising the grade of old embankments.

Scalping (Sec 203.4.12)

Stumps, roots, rubbish or any other deleterious material shall not be placed in embankments. Where an embankment less than 2 feet (600 mm) high is to be constructed, all vegetative matter shall be cut and removed from the surface upon which the embankment is to be placed. The cutover surface shall be thoroughly broken.

Embankment Against Existing Structures (Sec 203.4.13)

As specified.

Excess or Unsuitable Material (Sec 203.4.15)

As excavation proceeds, material with characteristics entirely different from those anticipated by the designer may be encountered. This can lead to a change in shrinkage factors resulting with surplus material that must be disposed. Unsuitable material as mentioned in Sec 203.3 may also have to be disposed. Anytime it becomes apparent that excessive disposal of material will occur, the district operations engineer in construction and materials, should be immediately consulted. It is possible that a change in grade can reduce, if not entirely eliminate, excess material. If excess material cannot be eliminated, it can usually be deposited along fill slopes by creating berms. Before such berms are constructed, special attention should be given to right of way limits and to the effect berms will have on drainage in the area.

Placement of Embankment (Sec 203.4.16)

As larger and larger hauling equipment becomes available, embankments are being built more rapidly. This means that roads are being completed and opened to traffic in shorter construction time. In most cases the surface course is placed on the embankment before any appreciable natural consolidation can occur. This makes it essential to obtain the best product possible during the construction stage. With increased speed in roadway construction it is imperative that the inspector be alert and aggressive to see that material is properly spread and compacted. Performing standard compaction tests and density tests must be speeded up as much as possible without sacrificing accuracy. This requires the inspector to become proficient in inspection and testing techniques. To obtain proper densities; depth of lifts, moisture content, and application of compactive effort must be carefully controlled within the framework of specifications.

In addition to necessary checks of compaction, it is the inspector's responsibility to see that embankments and cuts are kept properly shaped and drained. The inspector should constantly be alert for new horizons or soil types which may require additional standard compaction tests. If they appear the inspector should see that new standards are immediately determined and put to proper use.

The purpose of compactive effort is to increase the strength of the earth structure or embankment. Density is a measure of this strength. It is expressed in terms of weight per unit volume, normally in pounds per cubic foot. If one is to inspect compaction work properly, several things must be kept in mind. The standard compaction test is based on the fact that at a certain moisture content called "optimum", soil grains may, under a given compactive effort, be forced into such close proximity that a maximum density is obtained. Results of laboratory tests, when properly charted and interpreted, indicate to a great extent the possibility for satisfactory use of the soils in actual construction work.

Mr. R. R. Proctor devised a test to be used on earth fills and dams. Proctor's theory was that soils are composed of particles ranging in size from gravel, through sand, silt, and clay, to colloids. Resistance to granular rearrangement in a dry condition is high because of friction between the particles. By addition of successive increments of a lubricant (water in this instance) resistance can be reduced and gradually overcome. Movement of the particles is facilitated and it becomes possible to compress the mass by forcing the smaller soil grains into the voids between the larger ones.

When the proper quantity of lubricating liquid is introduced, frictional resistance is reduced enough that the mass may be compressed into its densest form. At this one moisture content only, moisture is at its optimum, and the density, or weight per cubic foot, is the maximum obtainable by a given compactive effort. If compactive effort is increased at the same moisture content, density will also increase slightly. It is also apparent that the same density may be obtained at a lower moisture content by application of appreciably increased compactive effort. This is logical since the compactive effort as well as the lubricant is effective in overcoming frictional resistance of the particles. It is thus possible to obtain a greater density in the field (100% + compaction) than is determined to be the maximum by the standard laboratory test. This is possible if compactive equipment is of such weight that it exerts a greater pressure per unit area than is exerted during the test, or if there are more trips over the embankment than necessary to obtain the standard compaction. However, if compactive effort exceeds the shear resistance of the soil at the existing moisture content, deep rutting of the embankment will occur.

This theory explains why optimum moisture is higher for clays than for silts. Clays are much finer grained than silts and being of a more plate like or flat, thin structure, they have an enormously greater surface area and area of particle contact per unit volume than the silts. The frictional resistance is, therefore, comparatively higher. It then follows that the finer soil the more lubricating liquid it takes to overcome frictional resistance and permit the soil particles to be rearranged in a manner that reduces the volume of voids.

Temporary stability can be obtained in a soil mass by compactive efforts applied at a moisture content below optimum. Very little true consolidation occurs, however, because of frictional resistance between the comparatively dry soil particles. The voids ratio is quite high. Even temporary stability depends on retention of the moisture at a point near or below that at which the mass was compacted. If moisture content increases, particle rearrangement, temporary instability, and some degree of consolidation will occur. It is quite likely that if material is originally compacted at a low moisture content, complete consolidation can occur only after the material has been saturated and subsequently dried.

Permanent stability depends on reducing voids to a minimum, which is a necessary condition for obtaining maximum density. The aim of compactive effort is to obtain the desired stability. This will occur at maximum dry weight per unit volume for a particular soil. Accurate determination of the optimum moisture point and precise control of compactive effort and moisture content in the field is the most practical method of achieving the desired stability. If a soil mass is compacted at optimum moisture content practically all of the consolidation occurs at the time of construction by reason of the combination of lubricating moisture and adequate compacting pressure.

At any density (weight per cubic foot) below the maximum, with a given compactive effort there are two corresponding points on the density-moisture curve, one on each side of the optimum peak. Both points represent the same dry weight per cubic foot and the same voids ratio. Below the optimum moisture point, the voids are filled with air and water. Above the optimum moisture content, water has displaced most of the air causing a considerable reduction in stability. A curve in Figure 200.4 illustrates the relationship between moisture and density. The curve, for example, shows that a dry weight per cubic foot of 107.6 lbs. corresponds to moisture contents of 13.7% and 19.3%.

Theoretically, it would be best to begin compaction operations at a moisture content slightly above optimum, and continue while evaporation reduces moisture through the optimum level. Clays should generally be compacted at optimum to about three percentage points above optimum to prevent detrimental volume changes from later absorption of water.

Lift Placement

The first lift (layer) should begin in the low areas, with the intent of eventually providing an embankment layer approximately parallel to finished grade. Embankments should be kept properly shaped and drained during construction. Pockets or holes that trap water on the surface should not be permitted. The importance of uniformity in embankment construction cannot be over emphasized. Uniformity of material, layer thickness, moisture content, and compactive effort are vital to proper embankment construction.

Roadway embankment of earth materials that are to be compacted must be placed in layers (lifts). Thickness of each layer must not exceed 8 inches, loose measurement. Each layer must be compacted in accordance with the contract before the next layer is placed. Areas outside roadway limits such as fill in old channels, waste berms, etc., may be constructed in layers up to 12 inches thick, loose measurement. Such areas do not normally have specified density requirements, but must be compacted by distributed hauling.

Oversized Rock

As specified.

Non-pavement Roadway Lifts

As specified.

Rock Embankment (Sec 203.4.17)

Rock embankment is considered to be that which is constructed of material resulting from excavation of Class C material or of unclassified excavation containing material predominantly rocky in nature. Embankment constructed of such material should be built in layers (lifts) extending over the full width of the roadway. The thickness of each layer should be governed by the average size of the larger rocks, but in no case may it exceed 24 inches. Rocks too large to be placed in a 24-inch layer must be reduced in size to permit placement in the embankment. Rock should not be dumped in place but should be distributed by blading or dozing. Spalls and smaller stone fragments should be left on the surface of each layer. To allow the final surface preparation to be completed by an autograder without the interference of larger rock, the top 2 inches of the grade shall be constructed as required in Sec 203.2.2.

Good judgment is necessary to determine when material is too rocky to obtain density tests of any practical value. Generally, material having more than 20% retained on a 3/4" sieve will be considered too rocky for satisfactory density testing.

Rigid or Flexible Pavements (Sec 203.4.18)

As specified.

Compaction of Embankment and Treatment of Cut Areas with Moisture and Density Control (Sec 203.5)

A soil survey is made by the district soils and geology technologist identifies, classifies, and maps soil types by horizons, with sampling and complete testing of each type. A complete soil test report on each horizon together with moisture density curve points will accompany the soil survey report. These tests are a great help to the inspector. They furnish a guide for future standard compaction tests since they were made in the Central Laboratory under ideal conditions. The inspector should run field standards as soon as possible. The inspector should compare field results with the laboratory standard for detection of possible error. If the inspector is delayed in running his/her own standard, the inspector may temporarily use the laboratory standard for control of the work. However, such use should be kept to a minimum. It is preferred to use the inspector's standard, run under field conditions.

Compaction is the processing and consolidating of embankment material, whether earth or rock. In earth embankment, soils must be compacted to densities that will provide adequate stability under conditions to which the finished highway will be subjected. The compaction inspector must realize that no set formulas, tables, or general stress analysis can be used in designing for soil conditions.

The degree of compaction that can be obtained is influenced by several factors. The most important are:

  • Moisture content of the soil.
  • Nature of the soil, its grain size and distribution, and physical properties.
  • Type and amount of compactive effort.

Compaction of an embankment develops the potential strength of the earth structure by improving bearing capacity, controlling shrinkage and swelling, and reducing permeability. Compaction is obtained in the field by hauling equipment and compacting rollers that impose pressure, impact vibration, and manipulation on the soil. Tests must be made on those jobs having specified density requirements, to check results obtained by the contractor’s compactive effort.

All data associated with field density tests made by the nuclear moisture-density method is recorded in Sitemanger. Field density is compared to the appropriate maximum density standard. Percentage of compaction is computed and entered in the space provided. Although the form is considered to be self-explanatory, it may be desirable to clarify certain items such as:

  • Specified percent of moisture. This is the percent of moisture specified in the contract if moisture control is required. Insert a dash in this space if contract does not specify moisture control.
  • Percent compaction specified. This is the percent compaction required by the contract for the particular area being tested.
  • Remarks. Show corrective action taken for tests showing insufficient density. Indicate results that are retests, and make any other comments needed to explain results of tests, and to identify original test for which retest is made.
  • Percent compaction of embankments. The percent compaction of embankments shall be determined to one decimal place and rounded off to a whole number for reporting. Only the end results (actual percent compaction) of the field density tests is to be rounded; the in-place weight per cubic foot, moisture content, etc. are to be determined and reported as shown in the examples.

This report is to be made weekly between the beginning and ending of grading operations unless grading operations are suspended. In this case a notation should appear on the last active report that reports will be suspended until work is resumed. The first report after work is resumed should also carry a note to that effect to explain the gap in reports.

All data pertaining to field density tests must be recorded in the Compaction Record Book over the signature of the tester. The original copy remains in the book. At the conclusion of the job the entire book is transmitted to the district office with the final plans to become a part of the permanent project record.

The inspector has the responsibility to insure that the proper number of moisture density tests is made at the proper locations. Effort must be made to test each lift or if it is practicable, a minimum of four density tests per day for each active grading spread. Enough tests should be run to verify results if unstable materials or unusual conditions are encountered. On very small grading projects, the number of tests may be reduced to be consistent with the size of grading spread. It is desirable to make as many density tests as possible on each workday to provide proper documentation of results being obtained.

Nuclear Moisture-Density Gauges

Moisture-Density tests are performed using Troxler Moisture-Density Gauges. The Nuclear Moisture-Density gauges provide moisture and density measurements in a much shorter time than other methods. A compaction inspector is capable to monitor a large volume grading operation.

The US Nuclear Regulatory Commission (NRC) and the US Department of Transportation (DOT) regulates the possession, use, and transportation of portable nuclear gauges. MoDOT’s Radiation Safety Officer from the Construction and Materials Division manages oversight of our radiation safety program. MoDOT’s program is extensive and in order to ensure compliance, Assistant Radiation Safety Officers are designated by MoDOT's Radiation Safety Officer to help with the program’s requirements and oversight.

The NRC requires every nuclear gauge to be inventoried and wipe tested at six month intervals. During an inspection a wipe test of the source is performed and the gauge is checked for radiation levels. When this testing is performed, arrangements are made with the project offices to set up a time for the inventory/wipe tests. It is important to have the gauges at the time and place requested. An annual audit of the department’s radiation safety program is also required. MoDOT’s Radiation Safety Officer or an assistant will schedule these reviews.

MoDOT’s material license, NRC, and DOT requirements, in addition to Operator Manuals, Emergency Procedures, maintenance guides, gauge inventory, wipe analysis, employee-training records can be found on at http://scweb4/hq/co/radiation.

Radiation Safety

Employees who transport or use nuclear gauges must undergo training at least once every three years. Since resident engineers are responsible for the nuclear program in their office annual radiation safety training will be provided. The Radiation Safety Officer and the district and headquarter assistants receive annual training in emergency response.

Employees must be mindful of radiation safety at all times. Adherence of ALARA (As Low As Reasonable Attainable) principles must be exercised. Eating and smoking is prohibited in the proximity where gauges are stored, maintained or used.

Dosimetry Gauge operators are not required to carry a TLD, dosimetry monitoring is optional since MoDOT is able to provide documentation demonstrating that unmonitored individuals are not likely to exceed 10 percent of the applicable limits. However, though the levels are well within the permissible limits, monitoring for employees who regularly use the gauges and provide oversight is provided with a Direct-Reading dosimeter (pic). A Direct-Reading dosimeter is a pocketsize, carbon fiber electroscope with an iron chamber for detecting and indication of integrated exposure to gamma and x-ray. Dosimeter instructions are located at http://scweb4/hq/co/radiation.

MoDOT’s licensed repairmen and employees who declare their pregnancy are provided with Thermo Luminescent Dosimeters (TLD). TLDs are sensitive to radiation and when it is developed the amount of radiation exposure can be determined.

The TLD is not transferable and must remain with the individual operator. TLDs are replaced on a quarterly basis. Old TLDs are forwarded to the District Assistant Radiation Safety Officer at: Central Laboratory, Radiation Management Office, Room 160A, 1617 Missouri Blvd Jefferson City, Mo. 65109.

Gauge Storage

MoDOT's NRC materials license permits storage of the nuclear gauges in the project office; a building adjacent to the project office or other MoDOT facility. A radiation exposure survey must have been made on any office gauge storage area and must be on file in the project office NRC file. A radiation placard is affixed to the doors of interior storage areas. A NCR Form 3 may be placed below the radiation placard or on the project office or testing laboratory bulletin board.

If a gauge is to be stored for an appreciable period of time, it should be secured in an area at least 15 feet from any work area. Only those personnel with a current training card in their possession will be allowed to use or transport nuclear gauges.

The storage facility or vehicle is to be locked at all times when no employees are present. NEVER LEAVE A NUCLEAR GAUGE UNATTENDED if it is not properly secured.

Gauge Transportation

Transportation of nuclear gauges is regulated by the U.S. Department of Transportation. Only those personnel that are nuclear gauge operators or those technicians or supervisory personnel who have satisfactorily completed their radiation safety training and have in their possession a current training card will be allowed to use or transport nuclear gauges. When performing tests in the field, always lock the gauge handle and return it to the transportation case before moving to another test site.

When a nuclear gauge is transported, it may be transported in the trunk of a passenger car or locked in a metal transportation box bolted securely to a pickup truck bed near the tailgate. On a non-routine basis, a heavy chain may be used to secure a gauge to the bed of a pickup. If a chain is necessary to transport the gauge, the chain must be placed through both handles of the gauge's shipping case and locked to the bed of the vehicle. All slack from the chain must be removed. Chaining a gauge in the back of a truck is intended only as a temporary measure and must not be done on a routine basis.

Regulations require the Bill of Lading be visible through the window of the transportation packet. The transportation packet consists of "Transportation Information" (Bill of Lading), "Troxler Nuclear Gauge Emergency Response Information" and "Emergency Procedures for Damaged Gauges". While in transportation, the transportation packet must be placed within arms reach of the driver wearing a seatbelt. If the gauge operator is not in the vehicle the bill of lading must be placed on the drivers seat or drivers side door pouch if gauge in the vehicle. This ruling applies at all times, whether the gauge is being transported in a vehicle to and from the job site or is being transported to and from the headquarters garage.

If a nuclear gauge is damaged or stolen, follow the "Emergency Procedures for Damaged Gauges" in the transportation packet.

Operation

Gauge users must have a current training card in their possession to transport or operate a nuclear gauge. Along with a radiation safety training card gauge users must have a current Operations Level 2 Technicians Training card.

Refer to the instruction manual furnished with each instrument for operation instructions. Gauge models 3430 and 3440 Operator and Instruction Manuals may be down loaded from the Troxler Labs web site located at http://www.troxlerlabs.com.

Maintenance

Employees are allowed to perform routine maintenance with the gauges. Examples or routine maintenance are: replacing batteries and scraper rings, and lubricating and cleaning the sliding block cavity. If the gauge is being used to test low-slump concrete, it is imperative the concrete be cleaned from the machine after each use. It is very important to practice ALARA principles when performing routine maintenance. At no time, can an employee remove the probe from the gauge. Non-routine maintenance is to be performed only by certified, licensed repairmen. If you have any questions regarding a question of routine maintenance, call Roger Wilson, (573) 751-5081.

Routine maintenance procedures are found in the users manual and at http://scweb4/hq/co/radiation.

If a density test shows results slightly below minimum requirements, it is desirable to retest the lift in question after additional compactive effort. If original test results are more than two percentage points below minimum requirements, a retest is mandatory. Otherwise, if a retest is impractical, compactive effort must be continued until the inspector is satisfied that proper density has been obtained. Records and reports must show what action was taken after any unsatisfactory test. It is preferred that at least one density test be made at each structure (pipe culvert, box culvert, bridge) during backfilling operations. This may not always be possible or practical, but it must be kept in mind that as many tests as possible should be made during backfilling of structures to assure adequate densities at these very critical locations. When tests are not specified as a basis for determining acceptability of earthwork compaction, the inspector must use experience and judgment to determine when satisfactory compaction is being obtained. Certain equipment will be specified. It should be inspected before use. Information about the equipment and its use should be made a part of job records by notes in the inspector's diary. If the contract contains no provision for compaction, the only compaction required will be that obtained by distributing equipment movements over the entire fill area, and the inspector can require no other compactive effort.

Documentation

All data associated with the nuclear moisture-density method is recorded in Sitemanger. Field density is compared to the appropriate maximum density standard. Percentage of compaction is computed and entered in the space provided. Although the form is considered to be self-explanatory, it may be desirable to clarify certain items such as:

  • Specified percent of moisture. This is the percent of moisture specified in the contract if moisture control is required. Insert a dash in this space if contract does not specify moisture control.
  • Percent compaction specified. This is the percent compaction required by the contract for the particular area being tested.
  • Remarks. Show corrective action taken for tests showing insufficient density. Indicate results that are retests, and make any other comments needed to explain results of tests, and to identify original test for which retest is made.
  • Percent compaction of embankments. The percent compaction of embankments shall be determined to one decimal place and rounded off to a whole number for reporting. Only the end results (actual percent compaction) of the field density tests is to be rounded; the in-place weight per cubic foot, moisture content, etc. are to be determined and reported as shown in the examples.

This report is to be made weekly between the beginning and ending of grading operations unless grading operations are suspended. In this case a notation should appear on the last active report that reports will be suspended until work is resumed. The first report after work is resumed should also carry a note to that effect to explain the gap in reports.

All data pertaining to field density tests must be recorded in the Compaction Record Book over the signature of the tester. The original copy remains in the book. At the conclusion of the job the entire book is transmitted to the district office with the final plans to become a part of the permanent project record.

Maximum Density Compaction Requirements (Sec 203.5.1)

Ninety percent compaction is required for backfilled and compaction in cut areas unless the fill is within 18” of the roadway surface and roadway embankments, except in non-roadway areas of surcharged embankments, excess or unsuitable material, berms, old channels, or waste areas. Ninety-five percent compaction is required for the top 18” of a roadway fill, fills within 100 feet of a bridge or deck that is to used as a riding surface and for deep fills. Compaction is performed by distributing equipment across a roadway approach with aggregate surfacing, and with 4 passes of a tamping roller or by 2 passes with a vibratory roller for rocky fills.

Moisture Control (Sec 203.5.2)

The success of compaction operations depends extensively on proper moisture control. Optimum moisture, as determined by the standard compaction test, is an excellent guide to the moisture content at which soils should be compacted.

Sec 203 establishes moisture content limits for some soils. Often contracts contain specific moisture controls as a requirement. Moisture tests taken to control embankment construction should be made during the placing of embankment material. If the tests are made for subgrade control, they should be made immediately prior to placing the base material.

Rubbery Embankment

The area that must support the embankment should be carefully inspected. The presence of soft or very wet conditions may suggest; the need to remove unsuitable materials, the need to install underdrain facilities to remove spring or seepage water, or merely the need to aerate and dry materials that have become saturated due to poor surface drainage. If swamp, marsh, old lakebeds, etc., are within the construction limits, these are normally considered during the design stage.

If the contract fails to address such areas, the district soils & geology technologist should be consulted. All areas where embankment is to be placed are to be stripped (scalped) as specified in Sec 203.4.12.

Loessial Soils

As specified.

Top Lift Thicknesses (Sec 203.5.3)

As specified.

Structure Approach (Sec 203.5.4)

As specified.

Rocky Fill (Sec 203.5.5)

Compactive effort on rock embankments will normally consist of at least four complete coverages of each layer with a tamping type roller or two complete coverages of each layer with a vibratory roller.

Lift Consistency (Sec 203.5.6)

As specified.

Deep Fills (Sec 203.5.7)

As specified.

Compacting in Cut (Sec 203.5.8)

Roughness often appears in the base and surface course of a roadbed at the transition from sizeable excavation to sizeable embankment sections. This can result from lack of attention to embankment foundation preparation in these critical areas. This situation is similar to the junction of a sidehill excavation and its laterally adjacent embankment. Cut compaction is an item that involves both excavation and compaction. Cut compaction is performed in all Class A material areas, after removal of the roadway excavation material to the required section. To perform cut compaction, a plane 12 inches below the top of the proposed grading section is temporarily exposed. The material may be pushed to one side, or hauled out and later replaced, at the contractor's option. The exposed material to a depth of 6 inches is manipulated and compacted to not less than specified density. Material is replaced above this plane in layers not exceeding 8 inches, loose thickness, and compacted to required densities.

Cut compaction shall be performed to an additional depth of 12 inches for 50 feet on each side of the intersection of the natural ground and the top of the subgrade; then graded uniformly in 30 feet to meet the depth requirements of Sec 203 (also see Figure 200.18). The existing ground for the full width between roadway slopes under embankments of less than 18 inches in height shall be treated in accordance with Sec 205.3. The excavation shall be carried to only such depth as to insure having 18 inches of material of the required density and moisture below the top of the finished subgrade.

Field Laboratory (Sec 203.5.9)

As specified.

Compaction of Embankment not Constructed with Density or Moisture and Density Control (Sec 203.6)

When tests are not specified as a basis for determining acceptability of earthwork compaction, the inspector must use experience and judgment to determine when satisfactory compaction is being obtained. The contractor’s equipment should be made a part of job records by notes in the inspector's diary. If the contract contains no provision for compaction, the only compaction required is that obtained by distributing equipment movements over the entire fill area.

Compaction of Embankment Without Specified Compaction Results or Specified Compaction Equipment (Sec 203.7)

As specified.

Method Of Measurement (Sec 203.8)

Job records must be kept in such a manner that all partial and final payments can be easily and clearly supported by recorded data. This data should include when the work was completed, calculations or notes to support the quantity allowed, and the signature of the person who made the calculations and measurements. Records of quantities should be posted daily so that progress reports and payment estimates may be kept up-to-date.

Excavation

The inspector should obtain a daily load count from the contractor, or should estimate the amount of material moved during the day, to help the resident engineer determine quantities for weekly reports and payment estimates. Load counts are taken solely for the purpose of estimating the contractor’s production. Final payment cannot be made based on the contractor’s load counts. The contractor's daily load counts should be verified by the inspector by counting loads for a short time period and projecting a total for the day. This should be done once or twice a week. This estimated projection should be approximately equal to the total given by the contractor. These checks should be recorded in the inspector's diary.

All estimated excavation quantities (that is, quantities that have not been computed) are to be measured and computed for final pay quantity. Any other changes outlined in the standard specifications are to be documented and computed for final payment. Excavation is measured and payment is made on a volume basis, usually per cubic yard. When field measurements are required, the usual method is to take cross sections at intervals where breaks in the terrain occur. This method for taking cross sections is explained in 238.4 Construction Surveying. By use of original and final cross sections an area is computed at each station where a section was taken. By multiplying the average area of two consecutive sections by the distance between sections, the volume between sections can be computed.

Basis of Payment (Sec 203.9)

Plan quantities are normally used for final payment for Class A and Unclassified Excavation unless ground elevations shown on the plans are found to be incorrect. Actual ground elevations are considered to agree with those shown on the plans if the average elevation of the section does not vary from that shown on the plans by more than one foot.

Occasionally, a project will run short of excavated material to complete the embankment. If the contract indicated excavation on the project was sufficient to complete the project but did not, additional compensation may be due to allow for acquisition of borrow and possibly for additional hauling required to complete the grade. Provisions of Sec 104.3 should be followed.

Compacting in Cut

Payment will be made for the entire volume of materials handled and compacted, including the 6 inch layer compacted in place, as compacting in cuts. This includes removal and replacement of material above the exposed 6-inch plane. In any event, payment for excavation is not a separate item but is included in the cost of compacting in cut.