Penetration testing in the UK Penetration testing in the UK Proceedings of the geotechnology conference organized by the Institution of Civil Engineers and held in Birmingham on 6-8 July 1988 Thomas Telford, London Conference sponsored by the Institution of Civil Engineers, the British Geotechnical Society, the Midland Geotechnical Society and the Midland Branch of the Institution of Civil Engineers Organizing Committee: I. K. Nixon (Chairman), K. W. Cole, C. Craig, S. Thorburn, T. R. M. Wakeling British Library Cataloguing in Publication Data Penetration testing. 1. Engineering geology I. Institution of Civil Engineers 624.1/51/0287 ISBN 978-07277-1377-3 First published 1989 © The Institution of Civil Engineers, 1988,1989, unless otherwise stated. All rights, including translation, reserved. Except for fair copying, no part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means electronic, mechanical, photcopying, recording or otherwise, without the prior written permission of the publisher. Requests should be directed to the Publications Manager, Thomas Telford Ltd, Thomas Telford House, 1 Heron Quay, London E14 9XF. Papers or other contributions and the statements made or the opinions expressed therein are published on the understanding that the author of the contribution is solely responsible for the opinions expressed in it and that its publication does not necessarily imply that such statements and or opinions are or reflect the views or opinions of the ICE Council or ICE committees. Published for the Institution of Civil Engineers by Thomas Telford Ltd, Thomas Telford House, 1 Heron Quay, London E14 9XF. Contents Keynote address. A. C. MEIGH 1 Report on ISOPT-1. B. A. LEACH 9 Session 1. Standard penetration test Introduction to Papers 1-9 Parti. F.M.JARDINE 23 Part 2. M. A. STROUD 29 1. SPTs in chalk: a rethink. R. N. MORTIMORE and D. JONES 51 2. Diagenetic alteration and micro-structural characteristics of sands: neglected factors in the interpretation of penetration tests. M. E. BARTON, M. R. COOPER and S. N. PALMER 57 3. Contribution to the chalk classification by means of visual and penetration techniques. S. PERELBERG, D. G. GUY and D. A. FERNANDO 61 4. Penetration testing in the design of foundations for large silos on Lias Clay. F. G. BUTLER 65 5. Water tank foundations on alluvial soil-subsoil explorations. A. V. JALOTA, S. C. JAIN and D. K. JOSHI 71 6. The standard penetration test and foundation movements on glacial tills and weak rocks. J. M. W. HOLDEN and M. YILMAZ 77 7. The application of the SPT in weak sandstone and mudstone rocks. R. P. THOMPSON and B. A. LEACH 83 8. The use of the standard penetration test for the design of bored piles in the Keuper Marl of Cardiff. N. S. KILBORN, G. TREHARNE and V. ZARIFIAN 87 9. The effect of water on SPT results in sand. M. S. MOJABI and G. G. THOMAS 93 Discussion on Papers 1-9. S. THORBURN, P. K. ROBERTSON, K. W. COLE, R. P. THOMPSON, A. D. BARLEY, M. E. BARTON M, . JAMIOLKOWSKI, J. M. W. HOLDEN, T. R. M. WAKELING, G. THOMPSON, L. THREADGOLD, D. M. TONKS, F. M. JARDINE, I. K. NIXON, R. N. MORTIMORE, P. R. VAUGHAN, J. M. PAISLEY, M. J. TURNER, J. M. REID, B. A. LEACH, K.-J. MELZER, I .L. WHYTE, N. P. LEE, R. McNICOL and M. S. MOJABI Session 2. Dynamic probing Introduction to Papers 10-13.1. K. NIXON 105 10. Dynamic soundings in site investigations: some observations and correlations. D. M. TONKS and I. L. WHYTE 113 11. The use of continuous dynamic probing in ground investigation. G. B. CARD and D. P. ROCHE 119 12. Application of dynamic cone penetrometer testing in East Anglia. P. J. CEARNS and A. McKENZIE 123 13. Factors governing the use of continuous dynamic probing in UK ground investigation. R. D. SCARFF 129 Discussion on Papers 10-13.1. K. NIXON, C. N. EDMONDS, I. L. WHYTE, K.-J. MELZER, A. McKENZIE, A. C. MEIGH, J. J. M. POWELL, M. J.TURNER, M.SCOTT and G.B. CARD 133 Session 3. Piezocone penetration test Introduction to Papers 14-19. G. T. HOULSBY 141 14. Interpretation of piezocone results in overconsolidated clays. A. J. LUTENEGGER and M. G. KABIR 147 15. Interpretation and use of the piezocone test in UK clays. J. J. M. POWELL, R. S. T. QUARTERMAN and T. LUNNE 151 16. Finite element analysis of cone penetration. S. M. WILLSON, B. W. IMS and I. M. SMITH 157 17. The use of the piezocone test for monitoring the strength of rock paste. P. A. BRAITHWAITE, G. S. GHATAORA and J. S. COUTTS 161 18. Piezocone tests in a china clay tailings dam. T. R. M. WAKELING 167 19. The use of piezocone in the design of a deep basement in London Clay. M. M. LONG and N. J. O'RIORDAN 173 Discussion on Papers 14-19. P. K. ROBERTSON, J. J. M. POWELL, K. BEEN, G. T. HOULSBY, M. JAMIOLKOWSKI, M. BATTAGLIO, D. BRUZZI, A. J. LUTENEGGER, A. C. MEIGH, Z. M. NYIRENDA, G. C. SILLS, C. H. ADAM, T. R. M. WAKELING, A. J. BOND, M. G. JEFFERIES and P. R. VAUGHAN 177 Session 4. Basic cone penetration test Introduction to Papers 20-30. D. W. BIDDLE 189 20. The static cone penetration test as lithology identifier. N. A. TRENTER and C. MILLER 193 21. Characterization of sandfills with the cone penetration test. M. G. JEFFERIES, B. T. ROGERS, K. M. GRIFFIN and K. BEEN 199 23. Interpretation of piezocone soundings in clay — a case history. R. G. CAMPANELLA, J. P. SULLY and P. K. ROBERTSON 203 24. Investigation of cone penetration test in British clay carried out by the Building Research Establishment 1960-86. A. MARSLAND and J. J. M. POWELL 209 25. Interpretation of material state from the CPT in sands and clays. K. BEEN, J. H. A. CROOKS and M. G. JEFFERIES 215 26. The use of cone penetration tests in glacial till. M. J. D. DOBIE 219 27. Penetration testing in glacial till. P. J. BAKER and R. GARDENER 223 28. An example of the use of cone penetration testing in the design of underground structures and temporary works in cohesive soils. J. M. REID and K. W. TURNBULL 227 29. The application of statistical methods to the interpretation of cone tests and use in subsequent design. B. W. IMS and F. E. TOOLAN 231 30. Determination of representative CPT-parameters. H. HARDER and G. VON BLOH 237 31. The use of 'penetrators' for the measurement of the undrained shear strength of soft marine clays. T. J. FREEMAN 241 32. Piezocone measurements with four pore pressure positions. G. C. SILLS, R .E. MAY, T. HENDERSON and Z. NYIRENDA 247 33. The implications of observed deformations during cone penetration. P. K. CHEN and R. H. BASSETT 251 Discussion on Papers 20-33. M. J. D. DOBIE, H. ERWIG, A. C. MEIGH, J. J. M. POWELL and N. A. TRENTER 257 Session 5. Pressuremeter, dilatometer and other developments Introduction to Papers 34-44. C. CRAIG 265 34. The interpretation of the Marchetti dilatometer test in UK clays. J. J.M.POWELL and I. M. UGLOW 269 35. Shear wave velocity measurements during penetration testing. P. HEPTON 275 37. Interpretation of pore pressure measurements from advanced cone penetration testing. E. SKOMEDAL and J. MARTYN BAYNE 279 38. Tests in a small calibrated chamber: experimental and numerical analysis. AL MUKHTAR MUZAHIM 285 39. The use of cone penetration testing to obtain environmental data. M. R. HORSNELL 289 41. Comparison between results from flat dilatometer and self-boring pressuremeter tests. B. G. CLARKE and C. P. WROTH 295 42. Stiffness of sands from CPT, SPT and DMT — a critical review. G. BALDI, R. BELLOTTI, N. GHIONNA and M. JAMIOLKOWSKI 299 44. High pressure dilatometer tests in Upper Chalk at Hull. A. R. WOODLAND, C. L. NG and D. CORKE Discussion on Papers 33-44. B. G. CLARKE, S. MARCHETTI, P. K. ROBERTSON, D. CORKE and G. T. HOULSBY 313 Closing address. Future trends for penetration testing. M. JAMIOLKOWSKI and P. K. ROBERTSON 321 Appendix 1. Cone penetration test: international reference test procedure. ISOPT-1 343 Appendix 2. Standard penetration test: international reference test procedure. ISOPT-1 357 Appendix 3. Dynamic probing: international reference test procedure. ISOPT-1 361 Appendix 4. Demonstration competition. I. K. NIXON 367 Papers 22, 36, 40 and 43 were withdrawn Keynote address A. C. MEIGH, OBE, DSc(Eng), FICE, Woodward-Clyde Consultants INTRODUCTION screw-shaped point (Figure 1) and the above The interpretation of the results of penetration outline of the test procedure, are enough to tests is mainly empirical, and in some cases tell us that it is unlikely that anyone will entirely empirical. That is to say, deriving produce a theoretical model. The test is from experiment and observation rather than from entirely empirical. theory. Nevertheless, as pointed out by Wroth I do not wish to denigrate the WST; it appears (1988), any correlation between results of in- to be a very useful tool in some ground situ tests and soil properties should be: conditions, particularly in the preliminary stages of an investigation for determining the (i) based on physical insight; depth and thickness of strata. (ii) set against a theoretical background; Anyone faced with interpreting the results of and WSTs should study carefully the Working Party (iii) expressed in dimensionless form. Report to ISOPT I by Bergdahl, Broms and Muromachi and the Conference paper by Bergdahl I would add only that the dimensionless forms and Ottossan. should be satisfactory practically as well as theoretically. I will touch on this point later. I intend shortly to make a brief overview of 034-0' the various types of penetration test, taking Dimensions in mm into account the preceding comments. This overview will be from the viewpoint of the practising geotechnical engineer. But first a comment about standardisation. You may know that for some years the ISSMFE have been working towards proposals for standardisation of certain aspects of penetration testing. At ISOPT 1, held in Florida in March of this year, working parties presented reports which included for each type of test a proposed International Reference Test Procedure (IRTP), and Bernard Leach will be outlining these. An empirical approach can only be successful if the test procedures are standardised to a large degree. It is of prime importance that these reference test procedures are followed. THE WEIGHT SOUNDING TEST I will start with a test about which I need say least, the weight sounding test (WST). As far as I know it has not been used in this country; it is extensively used in Sweden, *New point 0 Norway, Finland and Denmark, where it is the 35-0 ± 0-2mm most commonly used penetration testing method. Worn point 0 To my surprise, I now learn that it has also 32-0 ± 0-2mm been used in Poland, Hungary, Czechoslovakia, Japan, Singapore, the Philippines and Algeria. So we may meet it on our travels. In the WST, the point is penetrated by the application of weights added in stages, without rotation of the probe, to maintain a constant rate of penetration, and when it will not penetrate further under a weight of 1 kN it is rotated and the number of half-turns per 0.2m of Fig. 1. Weight sounding test; screwpoint penetration is recorded. The peculiar (Bergdahl et al, 1988) Penetration testing in the UK. Thomas Telford, London, 1989 KEYNOTE ADDRESS THE STANDARD PENETRATION TEST Table 1. Approximate corrections to measured N Equally empirical, and likely to remain so, is values (Skempton, 1986) the Standard Penetration Test (SPT). Over the years it has been extensively used and extensively criticised: extensively used in this Rod length: >10 m 1.0 country because it suits our geology and is 6-10 m 0.95 convenient for use in light cable percussion 4-6 m 0.85 boring and in rotary drilling; criticised here 3-4 m 0.75 and elsewhere for a number of reasons: (i) its vulnerability and sensitivity to Standard sampler 1.0 faulty operation; US sampler without liners 1.2 (ii) the differences in methods of driving the sampler; and (iii) difficulties in interpretation. (How Borehole diameter: 65-115 m 1.0 did one choose between the 150 mm 1.05 multiplicity of methods of determining 2 00 mm 1.15 allowable bearing capacity in cohesionless soils?) But now, recent advances are giving the SPT a new lease of life. Over the last ten years or In the IRTP, under "Boring Methods and so, much research has gone into factors which Equipment", it is stated that "in situations affect the amount of energy delivered to the rod where comparisons of SPT results are important, system; type of hammer, release system, anvil calibrations will be made to evaluate the weight. We now talk in terms of rod energy efficiency of the equipment in terms of energy ratio, ER , the ratio of the energy delivered to transfer; and again, in the working party the rods to the theoretical free-fall energy of report, it is recommended that "in situations the hammer. By means of dynamic load cells it where comparisons of SPT results are important is now possible to measure the delivered energy it is considered that energy input should be (Schmertmann and Palacios, 1979). The measured and methods of calibration have been importance of normalising SPT blow counts to a presented for guidance". Somewhat lacking in standard rod energy ratio has been recognised, force. Surely, comparison is always important; and Seed et al (1984) have proposed a ratio of it is the essence of the empirical approach. 60 per cent. Hence Skempton (1986), following Seed, has recommended that measured SPT values should be N, = N ER /60 normalised to a rod energy ratio of 60 per cent. oun r Based on the study of a number of sites and some (Incidentally the Pilcon and Dando equipment laboratory test data, Skempton. also recommends used in the UK both have a rod energy ratio of certain corrections to be applied to measured N about 60%.) values; for rod length where it is less than The proposed IRTP presented at ISOPT 1 deals 10m, for borehole diameter where it is greater with boring methods and equipment. This should than 115mm, and for the use of the US sampler go a long way towards removing differences in without a liner. (Table 1) In the IRTP there procedure and eliminating unsuitable features, is no correction for rod length, although in the although the SPT will still be somewhat calibration procedure a correction is included vulnerable to operator error. The IRTP does not based on the ratio of mass per unit length of deal with interpretation, as one might expect. the rod to mass of the hammer. The IRTP also In the Working Party report, which includes limits the borehole diameter to between 63.5 and the IRTP, the importance of the rod energy ratio 150mm but makes no correction for diameter. It is recognised, and a method of calibration for makes no correction for use of the US sampler rod energy ratio is included. Unfortunately, without liner. (Although not contemplated in the IRTP lacks force in this respect; under the IRTP, the liner is frequently omitted from "reporting of results", it is required to the US sampler at present). report, inter alia: 6) dimensions and weights of drive rods D =.O 15 35 50 65 85 100% r 7) type of hammer and release mechanism or method Very Loose Medium Dense Very 8) height of free fall, and loose dense 16) Calibration results, where appropriate*: (#1)60=0 15 25 42 58 This is followed by an explanatory note "Calibrations of drive rods and hammer This is derived from the Terzaghi-Peck classi- assemblies, where appropriate,* would normally fication. For D > 0-35 it corresponds to r be carried out for each rig and separately from the investigation work. They would be applicable to a particular project, based on the personnel and equipment involved". Fig. 2. Average correlation between SPT blow count and relative density; NC sands (Skempton, * Underlining added. 1986) 2 MEIGH Table 2. Effect of ageing (Skempton, 1986) where N is greater than 15 (Terzaghi and Peck, 1948), and in gravel or sandy gravel N is multiplied by 1.25. In assessing settlement, Age: years 'Veo'V adjustments are made for foundation shape and thickness of the sand layer. A time factor is included and an allowance is made for the effect -2 Laboratory tests 10 35 of overconsolidation. Recent fills 10 40 Burland and Burbidge is based on the analysis 2 Natural deposits >10 55 of 200 case histories. It is empirical; but a reading of Burbidge's MSc thesis on which the paper depends, reveals that it is firmly based on physical insight (Wroth's first requirement). Skempton has revised the Terzaghi and Peck However, Burland and Burbidge predates Rod classification of relative density (Figure 2). Energy Ratio; and it includes no corrections for This applies to medium sands; for fine sands, N borehole diameter, rod length or use of the US is reduced in the ratio 55/60, and for coarse sampler without liner. We should encourage sands N is increased in the ratio 65/60. Professor Burland to find another post graduate Finally, Skempton found an effect of ageing on student to revise Burland and Burbidge taking the SPT values on sands, giving typical results these factors into account. Hopefully, this for a NC sand (Table 2). would reduce the spread between upper and lower There is much more of interest in Skempton's limit values of the compressibility factor I . paper, including the effects of The use of the SPT in weak and weathered rocks overconsolidation. The paper is recommended was pioneered in this country in the 1950's. It reading for all concerned with the use and is a major topic in Session 1. interpretation of the SPT. On the question of interpretation of SPT DYNAMIC PROBING results, another milestone has been the Dynamic probing (DP) is probably the oldest introduction by Burland and Burbidge (1985) of a method of penetration testing in foundation method of estimating, from SPT results, the engineering. From information provided to the settlement of foundations on cohesionless soils. ISSMFE working party on dynamic probing, it This should replace the previous methods. It appears that it is used only occasionally in follows on from a paper by Burland et al (1977). this country. Of the four categories of probe, I still find their plot of settlement/applied only two are used here; light (DPL), mass 10kg pressure against breadth of footing (Figure 3) or less, and superheavy (DPSH), mass greater useful as an indicator of whether settlement is than 60 kg. We have no national recommended a problem or not. procedure or standard. Burland and Burbidge's method is a direct One bogey which has affected the use of DP in method, proceding from average N to a the past is the problem of skin friction on the compressibility factor I . N is corrected for rods. This has been overcome in the IRTP by very silty and fine sands below the water table Tentative upper limit 20- for loose sands 1-0- 0-8_ 0-6_ Upper limit for medium /dense sand 0-2. Upper limit for CO 0-08. dense sand <D 0-06. CL e pli 0- QL. ro CZ 0-02_ 0-01, 0-1 0-2 U 0-6 0-8 1 2 L 6 810 20 60 80100 200 Breadth,fl(m) Fig. 3. Observed settlement of footings on sand of various relative densities (after Burland, Broms and de Mello, 1977)