Name: ASTM D4506-90(1995) - Standard Test Method for Determining the In Situ Modulus of Deformation of Rock Mass Using a Radial Jacking Test
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Abstract

Standard Test Method for Determining the In Situ Modulus of Deformation of Rock Mass Using a Radial Jacking Test

SCOPE
1.1 This test method is used to determine the in situ modulus of deformation of rock mass by subjecting a test chamber of circular cross section to uniformly distributed radial loading; the consequent rock displacements are measured, from which elastic or deformation moduli may be calculated. The anisotropic deformability of the rock can also be measured and information on time-dependent deformation may be obtained.
1.2 This test method is based upon the procedures developed by the U.S. Bureau of Reclamation featuring long extensometers (1) . An alternative procedure is also available and is based on a reference bar (2).
1.3 Application of the test results is beyond the scope of this test method, but may be an integral part of some testing programs.
1.4 The values stated in inch-pound units are to be regarded as the standard.
1.5 This standard does not purport to address the safety problems associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.

General Information

Status

Historical

Publication Date

31-Dec-1994

ICS

93.020 - Earthworks. Excavations. Foundation construction. Underground works

Technical Committee

D18 - Soil and Rock

Drafting Committee

D18.12 - Rock Mechanics

Current Stage

Ref Project

Relations

Replaced By

ASTM D4506-02 - Standard Test Method for Determining the In Situ Modulus of Deformation of Rock Mass Using a Radial Jacking Test

Effective Date

10-Jan-2002

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Standard

ASTM D4506-90(1995) - Standard Test Method for Determining the In Situ Modulus of Deformation of Rock Mass Using a Radial Jacking Test

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Standards Content (Sample)

ASTM D4506-90(1995) - Standard...

Designation: D 4506 – 90 (Reapproved 1995)
AMERICAN SOCIETY FOR TESTING AND MATERIALS
100 Barr Harbor Dr., West Conshohocken, PA 19428
Reprinted from the Annual Book of ASTM Standards. Copyright ASTM
Standard Test Method for
Determining the In Situ Modulus of Deformation of Rock
1
Mass Using a Radial Jacking Test
This standard is issued under the ﬁxed designation D 4506; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (e) indicates an editorial change since the last revision or reapproval.
1. Scope equal to the slope of the tangent or the secant of a stress-strain
curve. The use of the term modulus of elasticity is recom-
1.1 This test method is used to determine the in situ
mended for materials that deform in accordance with Hooke’s
modulus of deformation of rock mass by subjecting a test
law; the term modulus of deformation for materials that deform
chamber of circular cross section to uniformly distributed
otherwise (from Terminology D 653).
radial loading; the consequent rock displacements are mea-
3.2 Deﬁnitions of Terms Speciﬁc to This Standard:
sured, from which elastic or deformation moduli may be
3.2.1 deformation—the change in the diameter of the exca-
calculated. The anisotropic deformability of the rock can also
vation in rock (test chamber).
be measured and information on time-dependent deformation
may be obtained.
4. Summary of Test Method
1.2 This test method is based upon the procedures devel-
4.1 A circular test chamber is excavated and a uniformly
oped by the U.S. Bureau of Reclamation featuring long
2 distributed pressure is applied to the chamber surfaces by
extensometers (1) . An alternative procedure is also available
means of ﬂat jacks positioned on a reaction frame. Rock
and is based on a reference bar (2).
deformation is measured by extensometers placed in boreholes
1.3 Application of the test results is beyond the scope of this
perpendicular to the chamber surfaces. Pressure is measured
test method, but may be an integral part of some testing
with a standard hydraulic transducer. During the test, the
programs.
pressure is cycled incrementally and deformation is read at
1.4 The values stated in inch-pound units are to be regarded
each increment. The modulus is then calculated. To determine
as the standard.
time-dependent behavior, the pressure is held constant and
1.5 This standard does not purport to address all of the
deformation is observed over time.
safety concerns, if any, associated with its use. It is the
responsibility of the user of this standard to establish appro-
5. Signiﬁcance and Use
priate safety and health practices and determine the applica-
5.1 Using this test method, a volume of rock large enough to
bility of regulatory limitations prior to use.
take into account the inﬂuence of discontinuities on the
2. Referenced Documents properties of the rock mass is loaded. The test should be used
when values are required which represent the true rock mass
2.1 ASTM Standards:
properties more closely than can be obtained through less
D 653 Terminology Relating to Soil, Rock, and Contained
3 expensive uniaxial jacking tests or other procedures.
Fluids
3
D 4403 Practice for Extensometers Used in Rock
6. Apparatus
3. Terminology 6.1 Chamber Excavation Equipment—This includes drilling
and “smooth wall” blasting equipment or mechanical excava-
3.1 Deﬁnitions:
tion equipment capable of producing typically a 9-ft (3-m)
3.1.1 deformation—change in shape or size (from Termi-
diameter tunnel with a length about three times that dimension.
nology D 653) (see 3.2.1).
6.2 Concreting Equipment—Concreting materials and
3.1.2 modulus of deformation—the ratio of stress to strain
equipment for lining the tunnel, together with strips of weak
for a material under given loading conditions; numerically
jointing materials for segmenting the lining.
6.3 Reaction Frame—The reaction frame shall be com-
1
This test method is under the jurisdiction of ASTM Committee D-18 on Soil
prised of steel rings of sufficient strength and rigidity to resist
and Rock and is the direct responsibility of Subcommittee D18.12 on Rock
the force applied by ﬂat jacks, as depicted in Fig. 1. For load
Mechanics.
Current edition approved May 25, 1990. Published July 1990. Originally application by ﬂat jacks, the frame must be provided with
published as D 4506 – 85. Last previous edition D 4506 – 85.
smooth surfaces; hardwood planks are usually inserted be-
2
The boldface numbers in parentheses refer to the list of references appended to
tween the ﬂat jacks and the metal rings.
this standard.
3
6.4 Loading Equipment, to apply a uniformly distributed
Annual Book of ASTM Standards, Vol 04.08.
1

---------------------- Page: 1 ----------------------
D 4506
1. Measuring proﬁle. 2. Distance equal to the length of active loading. 3. Control extensom
...

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1.3 All observed and calculated values shall conform to the guidelines for significant digits and rounding established in Practice D6026, unless superseded by this test method.
1.3.1 For purposes of comparing a measured or calculated value(s) with specified limits, the measured or calculated value(s) shall be rounded to the nearest decimal of significant digits in the specified limit.
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5.1 Compression testing of soil-lime specimens is performed to determine unconfined compressive strength of the cured soil-lime-water mixture to determine the suitability of the mixture for uses such as in pavement bases and subbases, stabilized subgrades, and structural fills.
5.2 Compressive strength data are used in soil-lime mix design procedures: (a) to determine if a soil will achieve a significant strength increase with the addition of lime; (b) to group soil-lime mixtures into strength classes; (c) to study the effects of variables such as lime percentage, unit weight, water content, curing time, curing temperature, etc.; and (d) to estimate other engineering properties of soil-lime mixtures.
5.3 Lime is generally classified as calcitic or dolomitic. Usually in soil stabilization, high-calcium lime [CaO] or dolomitic lime [CaO + MgO] are used. The lime is transformed from oxide to hydroxide form [[Ca(OH)2 or [Ca(OH)2 + Mg(OH)2]] by the addition of water in the soil, a slurry tank, or at a manufacturing facility. Lime may increase the strength of cohesive soil. The type of lime in combination with soil type influences the resulting compressive strength.
Note 2: The agency performing this test method can be evaluated in accordance with Practice D3740. Notwithstanding statements on precision and bias contained in this method: The precision of this test method is dependent on the competence of the personnel performing it and the suitability of the equipment and facility used. Agencies that meet the criteria of Practice D3740 are generally considered capable of competent and objective testing. Users of this test method are cautioned that compliance with Practice D3740 does not, in itself, ensure reliable testing. Reliable testing depends on many factors; Practice D3740 provides a means of evaluating some of these factors.
SCOPE
1.1 This test method covers procedures for preparing, curing, and testing laboratory-compacted specimens of soil-lime and other lime-treated materials (Note 1) for determining unconfined compressive strength. Depending on the diameter to height ratio, two procedures for determining the unconfined compressive strength of compacted soil-lime mixtures have been developed for specimens prepared at the maximum unit weight and optimum water content, or for specimens prepared at other target unit weight and water content levels. Other applications are given in Section 5 on Significance and Use.
Note 1: Lime-based products other than commercial quicklime and hydrated lime are also used in the lime treatment of fine-grained cohesive soils. Lime kiln dust (LKD) is collected from the kiln exhaust gases by cyclone, electrostatic, or baghouse-type collection systems. Some lime producers hydrate various blends of LKD plus quicklime to produce a lime-based product.
1.2 Cored specimens of soil-lime should be tested in accordance with Test Methods D2166/D2166M.
1.3 Two alternative procedures are provided:
1.3.1 Procedure A describes procedures for preparing and testing compacted soil-lime specimens having height-to-diameter ratios between 2.00 and 2.50. This test method provides the standard measure of compressive strength.
1.3.2 Procedure B describes procedures for preparing and testing compacted soil-lime specimens using Test Methods D698 compaction equipment and molds commonly available in most soil testing laboratories. Procedure B is considered to provide relative measures of individual specimens in a suite of test specimens rather than standard compressive strength values. Because of the lesser height-to-diameter ratio (1.15) of the cylinders, compressive strength determined by Procedure B will normally be greater than that by Procedure A.
1.3.3 Results of unconfined compressive strength tests using Procedure B should not be directly compared to those obtained using Procedure A.
1.4 All observed and calculated values shall conform to the guideline...

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30-Sep-2022
93.020
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ASTM

ASTM D4452/D4452M-22(Practice)

Standard Practice for X-Ray Radiography of Soil Samples

SIGNIFICANCE AND USE
5.1 Many geotechnical tests require the utilization of intact, representative samples of soil. The quality of these samples depends on many factors. Many of the samples obtained by intact sampling methods have inherent anomalies. Sampling procedures cause disturbances of varying types and intensities. These anomalies and disturbances, however, are not always readily detectable by visual inspection of the intact samples before or after testing. Often test results would be enhanced if the presence and the extent of these anomalies and disturbances are known before testing or before destruction of the sample by testing. Such determinations assist the user in detecting flaws in sampling methods, the presence of natural or induced shear planes, and the presence of natural intrusions, such as gravels or shells at critical regions in the samples, the presence of sand and silt seams, and the intensity of disturbances caused by sampling.
5.2 X-ray radiography provides the user with a picture of the internal massive structure of the soil sample, regardless of whether the soil is X-rayed within or without the sampling tube. X-ray radiography assists the user in identifying the following:
5.2.1 Appropriateness of sampling methods used.
5.2.2 Effects of sampling in terms of the disturbances caused by the turning of the edges of various thin layers in varved soils, large disturbances caused in soft soils, shear planes induced by sampling, or extrusion, or both, effects of overdriving of samplers, the presence of cuttings in sampling tubes, or the effects of using bent, corroded, or nonstandard tubes for sampling.
5.2.3 Naturally occurring fissures, shear planes, etc.
5.2.4 The presence of intrusions within the sample, such as calcareous nodules, gravel, or shells.
5.2.5 Sand and silt seams, organic matter, large voids, and channels developed by natural or artificial leaching of soil components.
Note 1: The quality of the results produced by this standard is de...
SCOPE
1.1 This practice covers the determination of the quality of soil samples in thin wall tubes or of extruded soil cores by X-ray radiography.
1.2 This practice enables the user to determine the effects of sampling and natural variations within samples as identified by the extent of the relative penetration of X-rays through soil samples.
1.3 This practice can be used to X-ray soil cores (or observe their features on a fluoroscope) in thin wall tubes or liners ranging from approximately 50 to 150 mm [2 to 6 in.] in diameter. X-rays of samples in the larger diameter tubes provide a radiograph of major features of soils and disturbances, such as large scale bending of edges of varved clays, shear planes, the presence of large concretions, silt and sand seams thicker than 6 mm [1/4 in.], large lumps of organic matter, and voids or other types of intrusions. X-rays of the smaller diameter cores provide higher resolution of soil features and disturbances, such as small concretions (3 mm [1/8 in.] diameter or larger), solution channels, slight bending of edges of varved clays, thin silt or sand seams, narrow solution channels, plant root structures, and organic matter. The X-raying of samples in thin wall tubes or liners requires minimal preparation.
1.4 Greater detail and resolution of various features of the soil can be obtained by X-raying extruded soil cores, as compared to samples in metal tubes. The method used for X-raying soil cores is the same as that for tubes and liners, except that extruded cores have to be handled with extreme care and have to be placed in sample troughs (similar to Fig. 2) before X-raying. This practice should be used only when natural water content or other intact soil characteristics are irrelevant to the end use of the sample.
1.4.1 Often it is necessary to obtain greater resolution of features to determine the propriety of sampling methods, the representative nature of soil samples,...

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Standard
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30-Sep-2022
93.020
D18

ASTM

ASTM D2434-22(Test Method)

Standard Test Methods for Measurement of Hydraulic Conductivity of Coarse-Grained Soils

ABSTRACT
This test method covers the determination of the coefficient of permeability by a constant-head method for the laminar flow of water through granular soils. The procedure is to establish representative values of the coefficient of permeability of granular soils that may occur in natural deposits as placed in embankments, or when used as base courses under pavements. The different apparatus used in determining the granular soil permeability are presented. The methods in preparing the test specimen are presented in details. The testing and calculation procedure for granular soil permeability determination are presented.
SIGNIFICANCE AND USE
5.1 These test methods are used to measure one-dimensional vertical flow of water through initially saturated coarse-grained, pervious (that is, free-draining) soils under an applied hydraulic gradient. Hydraulic conductivity of coarse-grained soils is used in various civil engineering applications. These test methods are suitable for determination of hydraulic conductivity for soils with k > 10–7 m/s.
Note 2: Clean coarse-grained soils that are classified using Practice D2487-17 as GP, GW, SP, and SW can be tested using these test methods. Depending on fraction and characteristics of fine-grained particles present in soils, these test methods may be suitable for testing other soil types with fines content greater than 5 % (for example, GP-GC, SP-SM).
5.2 Coarse-grained soils are to be tested at a void ratio representative of field conditions. For engineered fills, compaction specification can be used to provide target test conditions, whereas for natural soils, field testing of in-situ density can be used to provide target test conditions.
5.3 Use of a dual-ring permeameter is included in these test methods in addition to a single-ring permeameter for the rigid wall test apparatus. The dual-ring permeameter allows for reducing potential adverse effects of sidewall leakage on measured hydraulic conductivity of the test specimens. The use of a plate at the outflow end of the specimen that contains a ring with a diameter smaller than the diameter of the permeameter and the presence of two outflow ports (one from the inner ring, one from the annular space between the inner ring and the permeameter wall) allows for separating the flow from the central region of the test specimen from the flow near the sidewall of the permeameter.
Note 3: Sidewall leakage has been reported to have significant influence on flow conditions for coarse-grained soils due to presence of larger voids at the boundary and higher void ratio in this region of the specimen. Three modificat...
SCOPE
1.1 These test methods cover laboratory measurement of the hydraulic conductivity (also referred to as coefficient of permeability) of water-saturated coarse-grained soils (for example, sands and gravels) with k > 10–7 m/s. The test methods utilize low hydraulic gradient conditions.
1.2 This standard describes two methods (A and B) for determining hydraulic conductivity of coarse-grained soils. Method A incorporates use of a rigid wall permeameter and Method B incorporates the use of a flexible wall permeameter. A single- or dual-ring rigid wall permeameter may be used in Method A. A dual-ring permeameter may be preferred over a single-ring permeameter when adverse effects from short-circuiting of permeant water along the sidewalls of the permeameter (that is, prevent sidewall leakage) are suspected by the user of this standard.
1.3 The test methods are used under constant head conditions.
1.4 The test methods are used under saturated soil conditions.
1.5 Water is used to permeate the test specimen with these test methods.
1.6 Units—The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.
Note 1: Hydraulic conductivity has traditionally been reported in cm/s in the US, even though the official SI unit for hydraul...

Standard
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Standard
16 pages
English language
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14-Mar-2022
93.020
D18