Designation: d 2434 – 68 (Reapproved 2006) Standard Test Method for Permeability of Granular Soils
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- 6. Preparation of Specimens
| FIG. 1 Constant-Head Permeameter
TABLE 1 Cylinder Diameter Maximum Particle Size Lies Between Sieve Openings Minimum Cylinder Diameter Less than 35 % of Total Soil Retained on Sieve Opening More than 35 % of Total Soil Retained on Sieve Opening 2.00-mm (No. 10) 9.5-mm ( 3 ⁄ 8 -in.) 2.00-mm (No. 10) 9.5-mm ( 3 ⁄ 8 -in.) 2.00-mm (No. 10) and 9.5-mm ( 3 ⁄ 8 in.) 76 mm (3 in.) ... 114 mm (4.5 in.) ... 9.5-mm ( 3 ⁄ 8 -in.) and 19.0-mm ( 3 ⁄ 4 in.) ... 152 mm (6 in.) ... 229 mm (9 in.) D 2434 – 68 (2006) 2 http://qstandard.org/ 5.3 From the material from which the oversize has been removed (see 5.2 ), select by the method of quartering, a sample for testing equal to an amount approximately twice that required for filling the permeameter chamber. 6. Preparation of Specimens 6.1 The size of permeameter to be used shall be as pre- scribed in Table 1 . 6.2 Make the following initial measurements in centimetres or square centimetres and record on the data sheet ( Fig. 3 ); the inside diameter, D, of the permeameter; the length, L, between manometer outlets; the depth, H 1 , measured at four symmetri- cally spaced points from the upper surface of the top plate of the permeability cylinder to the top of the upper porous stone or screen temporarily placed on the lower porous plate or screen. This automatically deducts the thickness of the upper porous plate or screen from the height measurements used to determine the volume of soil placed in the permeability cylinder. Use a duplicate top plate containing four large symmetrically spaced openings through which the necessary measurements can be made to determine the average value for H 1 . Calculate the cross-sectional area, A, of the specimen. 6.3 Take a small portion of the sample selected as pre- scribed in 5.3 for water content determinations. Record the weight of the remaining air-dried sample (see 5.3 ), W 1 , for unit weight determinations. 6.4 Place the prepared soil by one of the following proce- dures in uniform thin layers approximately equal in thickness after compaction to the maximum size of particle, but not less than approximately 15 mm (0.60 in.). 6.4.1 For soils having a maximum size of 9.5 mm ( 3 ⁄ 8 in.) or less, place the appropriate size of funnel, as prescribed in 4.3 , in the permeability device with the spout in contact with the lower porous plate or screen, or previously formed layer, and fill the funnel with sufficient soil to form a layer, taking soil from different areas of the sample in the pan. Lift the funnel by 15 mm (0.60 in.), or approximately the unconsolidated layer thickness to be formed, and spread the soil with a slow spiral motion, working from the perimeter of the device toward the center, so that a uniform layer is formed. Remix the soil in the pan for each successive layer to reduce segregation caused by taking soil from the pan. 6.4.2 For soils with a maximum size greater than 9.5 mm ( 3 ⁄ 8 in.), spread the soil from a scoop. Uniform spreading can be obtained by sliding a scoopful of soil in a nearly horizontal position down along the inside surface of the device to the bottom or to the formed layer, then tilting the scoop and drawing it toward the center with a single slow motion; this allows the soil to run smoothly from the scoop in a windrow without segregation. Turn the permeability cylinder sufficiently for the next scoopful, thus progressing around the inside perimeter to form a uniform compacted layer of a thickness equal to the maximum particle size. 6.5 Compact successive layers of soil to the desired relative density by appropriate procedures, as follows, to a height of about 2 cm (0.8 in.) above the upper manometer outlet. 6.5.1 Minimum Density (0 % Relative Density)—Continue placing layers of soil in succession by one of the procedures described in 6.4.1 or 6.4.2 until the device is filled to the proper level. 6.5.2 Maximum Density (100 % Relative Density): 6.5.2.1 Compaction by Vibrating Tamper— Compact each layer of soil thoroughly with the vibrating tamper, distributing the light tamping action uniformly over the surface of the layer in a regular pattern. The pressure of contact and the length of time of the vibrating action at each spot should not cause soil to escape from beneath the edges of the tamping foot, thus tending to loosen the layer. Make a sufficient number of coverages to produce maximum density, as evidenced by practically no visible motion of surface particles adjacent to the edges of the tamping foot. 6.5.2.2 Compaction by Sliding Weight Tamper—Compact each layer of soil thoroughly by tamping blows uniformly distributed over the surface of the layer. Adjust the height of drop and give sufficient coverages to produce maximum density, depending on the coarseness and gravel content of the soil. tải về 126.61 Kb. Chia sẻ với bạn bè của bạn:
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