Difference between revisions of "Category:701 Drilled Shafts"
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columns cast in drilled holes. See [[751.37 Drilled Shafts|EPG 751.37 Drilled Shafts]] for design guidance and additional information. | columns cast in drilled holes. See [[751.37 Drilled Shafts|EPG 751.37 Drilled Shafts]] for design guidance and additional information. | ||
− | This type of foundation is identified in [http://modot. | + | This type of foundation is identified in [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=11 Sec 701] of the Standard Specifications as Drilled Shafts. A drilled shaft is generally considered a deep foundation. Drilled shafts are to be constructed with or without a casing. When casing is used it can be either a temporary or permanent steel casing. Requirements for plan reporting of steel casing are given in [http://epg.modot.org/index.php?title=751.37_Drilled_Shafts#751.37.1.3_Casing EPG 751.37.1.3 Casing]. |
The shaft portion of a drilled shaft is usually founded on rock (limestone, dolomite or other suitable material with q<sub>u</sub> ≥ 100 ksf) or weak rock (shale or other suitable material with 5 ksf ≤ q<sub>u</sub> ≤ 100 ksf) with a smaller diameter rock socket drilled into same. The inspector should carefully study all general specifications and special provisions pertaining to drilled shafts and become familiar with the designer's intent. | The shaft portion of a drilled shaft is usually founded on rock (limestone, dolomite or other suitable material with q<sub>u</sub> ≥ 100 ksf) or weak rock (shale or other suitable material with 5 ksf ≤ q<sub>u</sub> ≤ 100 ksf) with a smaller diameter rock socket drilled into same. The inspector should carefully study all general specifications and special provisions pertaining to drilled shafts and become familiar with the designer's intent. | ||
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The integrity of the rock socket shall be verified by a foundation inspection hole. This is usually performed after the shaft is drilled. Setting up over a drilled hole can be difficult. The contractor can perform the inspection hole in advance if they submit a procedure that assures the correct location is cored. If the integrity of the cores are questionable the Bridge Division should be contacted to see if the rock socket length should be extended. | The integrity of the rock socket shall be verified by a foundation inspection hole. This is usually performed after the shaft is drilled. Setting up over a drilled hole can be difficult. The contractor can perform the inspection hole in advance if they submit a procedure that assures the correct location is cored. If the integrity of the cores are questionable the Bridge Division should be contacted to see if the rock socket length should be extended. | ||
− | Most problems with drilled shafts occur during the concrete pour. The concrete placement requirements in [http://modot. | + | Most problems with drilled shafts occur during the concrete pour. The concrete placement requirements in [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=11 Sec 701] should be reviewed carefully. |
− | '''Question: Per [http://modot. | + | '''Question: Per [http://www.modot.org/business/standards_and_specs/SpecbookEPG.pdf#page=11 Sec 701.4.17.2.1 Installation of Pipes], “The pipes shall be filled with water and plugged or capped before shaft concrete is poured.” Why is this necessary?''' |
The water in the tube helps to regulate the temperature of the CSL tube. Without the water, the tube will heat up from the hydrating concrete and cause de-bonding. This de-bonding from the concrete will cause erroneous CSL readings and show up as an anomaly. Typically, de-bonding is more prevalent in the upper 6 ft. of the tube. The water also serves a second purpose: it helps the energy transmission from the wall of the tube to the probes and vice versa. | The water in the tube helps to regulate the temperature of the CSL tube. Without the water, the tube will heat up from the hydrating concrete and cause de-bonding. This de-bonding from the concrete will cause erroneous CSL readings and show up as an anomaly. Typically, de-bonding is more prevalent in the upper 6 ft. of the tube. The water also serves a second purpose: it helps the energy transmission from the wall of the tube to the probes and vice versa. |
Revision as of 13:46, 13 June 2016
Substructure foundations may be designed to transmit loads to foundation strata by concrete columns cast in drilled holes. See EPG 751.37 Drilled Shafts for design guidance and additional information.
This type of foundation is identified in Sec 701 of the Standard Specifications as Drilled Shafts. A drilled shaft is generally considered a deep foundation. Drilled shafts are to be constructed with or without a casing. When casing is used it can be either a temporary or permanent steel casing. Requirements for plan reporting of steel casing are given in EPG 751.37.1.3 Casing.
The shaft portion of a drilled shaft is usually founded on rock (limestone, dolomite or other suitable material with qu ≥ 100 ksf) or weak rock (shale or other suitable material with 5 ksf ≤ qu ≤ 100 ksf) with a smaller diameter rock socket drilled into same. The inspector should carefully study all general specifications and special provisions pertaining to drilled shafts and become familiar with the designer's intent.
The integrity of the rock socket shall be verified by a foundation inspection hole. This is usually performed after the shaft is drilled. Setting up over a drilled hole can be difficult. The contractor can perform the inspection hole in advance if they submit a procedure that assures the correct location is cored. If the integrity of the cores are questionable the Bridge Division should be contacted to see if the rock socket length should be extended.
Most problems with drilled shafts occur during the concrete pour. The concrete placement requirements in Sec 701 should be reviewed carefully.
Question: Per Sec 701.4.17.2.1 Installation of Pipes, “The pipes shall be filled with water and plugged or capped before shaft concrete is poured.” Why is this necessary?
The water in the tube helps to regulate the temperature of the CSL tube. Without the water, the tube will heat up from the hydrating concrete and cause de-bonding. This de-bonding from the concrete will cause erroneous CSL readings and show up as an anomaly. Typically, de-bonding is more prevalent in the upper 6 ft. of the tube. The water also serves a second purpose: it helps the energy transmission from the wall of the tube to the probes and vice versa.