Pile Design and Construction Practice, Fifth edition

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Pile groups under compressive loading 289 5.3 BURLAND, J. B. Interaction between structural engineers and geotechnical engineers, The Structural Engineer, Vol. 84, No. 8, 2006, pp. 29–37. 5.4 HANSEN, J. B. A general formula for bearing capacity, Danish Geotechnical Institute, Bulletin No. 11, 1961; also, A revised and extended formula for bearing capacity, Danish Geotechnical Institute, Bulletin No. 28, 1968, and Code of Practice for Foundation Engineering, Danish Geotechnical Institute, Bulletin No. 32, 1978. 5.5 MEYERHOF, G. G. Some recent research on bearing capacity, Canadian Geotechnical Journal, Vol. 1, 1963, pp. 16–26. 5.6 JAMIOLKOWSKI, M. et al. Design parameters for soft clays, Proceedings of the 7th European Conference on Soil Mechanics, Brighton, 1979, pp. 21–57. 5.7 STROUD, M. A. The standard penetration test in insensitive clays, Proceedings of the European Symposium on Penetration Testing, Stockholm, 1975, Vol. 2, pp. 367–75. 5.8 BURLAND, J. B., BROMS, B. B., and DE MELLO, V. Behaviour of foundations and structures, Proceedings of the 9th International Conference on Soil Mechanics, Tokyo, Session 2, 1977. 5.9 JARDINE, R., FOURIE, A., MASWOSE, J., and BURLAND, J. B. Field and laboratory measurements of soil stiffness, Proceedings of the 11th International Conference on Soil Mechanics, San Francisco, Vol. 2, 1985, pp. 511–14. 5.10 MARSLAND, A. In-situ and laboratory tests on glacial clays at Redcar, Proceedings of a Symposium on Behaviour of Glacial Materials, Midlands Geotechnical Society, 1975, pp. 164–80. 5.11 TERZAGHI, K. Theoretical Soil Mechanics, John Wiley, New York, 1943, p. 425. 5.12 BUTLER, F. G. General Report and state-of the-art review, Session 3, Proceedings of the Conference on Settlement of Structures, Cambridge, 1974, Pentech Press, London, 1975, pp. 531–78. 5.13 BROWN, P. T. and GIBSON, R. E. Rectangular loads on inhomogeneous soil, Proceedings of the American Society of Civil Engineers, Vol. 99 (SM10), 1973, pp. 917–20. 5.14 CHRISTIAN, J. T. and CARRIER, W. D. Janbu, Bjerrum and Kjaernsli’s chart reinterpreted, Canadian Geotechnical Journal, Vol. 15, 1978, pp. 123–8. 5.15 FOX, E. N. The mean elastic settlement of a uniformly-loaded area at a depth below the ground surface, Proceedings of the 2nd International Conference, ISSMFE, Rotterdam, Vol. 1, 1948, pp. 129–32. 5.16 SKEMPTON, A. W. and BJERRUM, L. A contribution to the settlement analysis of foundations on clay, Geotechnique, Vol. 7, No. 4, 1957, pp. 168–78. 5.17 BURLAND, J. B. and KALRA, J. C. Queen Elizabeth Conference Centre: geotechnical aspects, Proceedings of the Institution of Civil Engineers, Vol. 80, No. 1, 1986, pp. 1479–503. 5.18 SCHULTZE, E. and SHERIF, G. Predictions of settlements from evaluated settlement observations for sand, Proceedings of the 8th International Conference, ISSMFE, Moscow, Vol. 1, 1973, p. 225. 5.19 BURLAND, J. B. and BURBIDGE, M. C. Settlement of foundations on sand and gravel, Proceedings of the Institution of Civil Engineers, Vol. 78, No. 1, 1985, pp. 1325–37. 5.20 MEIGH, A. C. Cone Penetration Testing–Methods and Interpretation, CIRIA/Butterworth, 1987. 5.21 ROBERTSON, P. K. and CAMPANELLA, R. G. Interpretation of cone penetration tests, parts 1 and 2, Canadian Geotechnical Journal, Vol. 20, 1983, pp. 718–45. 5.22 BALDI, G., BELLOTI, R., GHIONNA, V., JAMIOLKOWSKI, M., and PASQUALINIE. Cone resistance of dry medium sand, Proceedings of the 10th International Conference, ISSMFE, Stockholm, Vol. 2, 1981, pp. 427–32. 5.23 MEIGH, A. C. The Triassic rocks, with particular reference to predicted and observed performance of some major structures, Geotechnique, Vol. 26, 1976, pp. 393–451. 5.24 LUNNE, T. and CHRISTOFFERSEN, H. P. Interpretation of cone penetration data for offshore sands, Proceedings of the Offshore Technology Conference 15, Houston, 1983, Vol. 1, pp. 181–92. 5.25 SCHMERTMANN, J. H. Static cone to compute static settlement over sand, Journal of the Soil Mechanics and Foundations Division, American Society of Civil Engineers, Vol. 96, No. SM3, May 1970, pp. 1011–43.
290 Pile groups under compressive loading 5.26 SCHMERTMANN, J. H., HARTMAN, J. P., and BROWN, P. R. Improved strain influence diagrams, Proceedings of the American Society of Civil Engineers, Vol. GT8, 1978, pp. 1131–5. 5.27 CHANDLER, F. W. and DAVIS, A. G. Further work on the engineering properties of Keuper Marl Construction Industry Research and Information Association (CIRIA), Report 47, 1973. 5.28 HAGERTY, A. and PECK, R. B. Heave and lateral movements due to pile driving, Journal of the Soil Mechanics and Foundation Division, American Society of Civil Engineers, No. SM11, November 1971, pp. 1513–32. 5.29 CHOW, Y. K. and TEH, C. I. A theoretical study of pile heave, Geotechnique, Vol. 40, No. 1, 1990, pp. 1–14. 5.30 BJERRUM, L. Engineering geology of normally-consolidated marine clays as related to the settlement of buildings, Geotechnique, Vol. 17, No. 2, 1967, pp. 83–117. 5.31 ADAMS, J. I. and HANNA, T. H. Ground movements due to pile driving, Proceedings of the Conference on the Behaviour of Piles, Institution of Civil Engineers, London, 1970, pp. 127–33. 5.32 BRZEZINSKI, L. S., SHECTOR, L., MACPHIE, H. L., and VAN DER NOOT, H. J. An experience with heave of cast-in-situ expanded base piles, Canadian Geotechnical Journal, Vol. 10, No. 2, May 1973, pp. 246–60. 5.33 COLE, K. W. Uplift of piles due to driving displacement, Civil Engineering and Public Works Review, March 1972, pp. 263–9. 5.34 FLEMING, W. G. K. and POWDERHAM, A. J. Soil down-drag and heave on piles, Institution of Civil Engineers, Ground Engineering Group, notes for meeting on 25/10/89. 5.35 HOOPER, J. A. Observations on the behaviour of a piled-raft foundation on London Clay, Proceedings of the Institution of Civil Engineers, Vol. 55, No. 2, December 1973, pp. 855–77. 5.36 COOKE, R. W., BRYDEN SMITH, D. W., GOOCH, M. N., and SILLETT, D. F. Some observations on the foundation loading and settlement of a multi-storey building on a piled raft foundation in London Clay, Proceedings of the Institution of Civil Engineers, Vol. 7, No. 1, 1981, pp. 433–60. 5.37 PADFIELD, C. J. and SHARROCK, M. J. Settlement of structures on clay soils, Construction Industry Research and Information Association (CIRIA), Special Publication 27, 1983. 5.12 Worked examples Example 5.1 Bored piles 500 mm in diameter drilled to a depth of 13.9 m below ground level into a firm to stiff clay are arranged in a group consisting of 10 rows each of seven piles, each carrying a dead load of 250 kN and an imposed load of 110 kN. From the results of tests on samples from three boreholes, the characteristic undrained shear strength of the clay increases from 60 kN/m2 at 1.5 m below ground surface to 110 kN/m2 at the base of the pile group. The fissured strength of the clay at pile toe level is 80 kN/m2 . Profiles of the undrained deformation modulus Eu and the coefficient of compressibility mv are shown in Figure 5.43. Determine the overall stability and settlement of the pile group. The first step is to calculate the factor of safety of the individual pile under the combined dead and imposed loads, from equations 4.4 and 4.7: Ultimate bearing capacity�9�80��/4�0.5 2 �0.45�(60�110)/2��0.5�12.4 � 141 �745 � 886 kN Factor of safety � 886/360 � 2.5 which is satisfactory, and because of the increasing strength of the clay below toe level, block failure of the group should not occur. However, for the purpose of comparison with the recommendation in EC7 Clause 7.6.2.1 to assume that the pile group acts as a single large-diameter pile, the stability of the group will be checked for compliance with the EC7 rules.
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Pile Design and Construction Practi
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Pile Design and Construction Practi
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Contents Preface to fifth edition i
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7.3 Designing piles to resist drivi
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Preface to fifth edition Piling rig
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Preface to fifth edition xi Pearson
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Chapter 1 General principles and pr
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(a) Backfill Bulb of pressure Appli
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are allowed to be used by Eurocode
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application of different load facto
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Load transfer The contractor’s gu
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(7) Jacked-down steel tube with clo
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Types of pile 13 needed to avoid cr
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(a) (b) Precast concrete Head of ti
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Table 2.2 Modification factor K 2 b
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4d d 10 mm M.S. plate sleeve tarred
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Table 2.3 Working loads and maximum
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Cement content �300 kg/m3 �325
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Types of pile 25 Table 2.5 BS 8004
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(a) (b) (c) (d) Cast iron or cast s
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Sheathing Bottom boards Figure 2.9
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Misplaced bearers Lifting holes Cra
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Section Bayonet plug Plan Locking p
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Existing foundation Precast pile ca
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Types of pile 37 Where very long le
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Types of pile 39 rotate during driv
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Types of pile 41 Because of their r
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(a) (b) Types of pile 43 Figure 2.2
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(a) (b) Welds Welds Types of pile 4
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(a) M.S. plate shoe Welds (b) 2.2.6
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Types of pile 49 brittle fracture r
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(a) (b) (c) Hammer Driving tube Con
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Types of pile 53 all cast-in-place
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Figure 2.28 The TaperTube pile.
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(a) (b) Figure 2.29 (a) The ScrewSo
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Types of pile 59 The simplest form
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Types of pile 61 Transverse reinfor
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Types of pile 63 completion the res
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Types of pile 65 permanently in the
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Types of pile 67 (3) Construction o
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Types of pile 69 can withstand fair
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Chapter 3 Piling equipment and meth
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Piling equipment and methods 73 A r
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Maximum height 26.32 m Usable leade
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Figure 3.4 Liebherr LRH 400 48 m lo
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Piling equipment and methods 79 the
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Piling frame Single-acting hammer S
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Guides for engaging leaders Steam o
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Table 3.1 Characteristics of some s
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Table 3.2 Characteristics of some h
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Piling equipment and methods 89 Tab
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Table 3.4 Characteristics of some d
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Figure 3.16 Driving a pile casing w
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Table 3.5 Continued Piling equipmen
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Soil resistance to driving (MN) 25
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Figure 3.19 Noise-abatement tower u
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Dolly M.S. plate Plastics Hardwood
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Standard elbow bend Detachable scre
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Figure 3.24 Discharging concrete in
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Piling equipment and methods 107 Fi
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Table 3.6 Continued Piling equipmen
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Figure 3.30 Top-hinged under-reamin
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Rotary table Hydraulic motor Water
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Piling equipment and methods 121 sl
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Pile head Pile base 2 holes ∅ 4 m
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Piling equipment and methods 125 Ca
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Piling equipment and methods 127 sm
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Piling equipment and methods 131 Th
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Piling equipment and methods 133 th
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Piling equipment and methods 135 Pi
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Piling equipment and methods 137 ve
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Chapter 4 Calculating the resistanc
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O C Settlement A Reloading Load B U
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Resistance of piles to compressive
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for spread foundations in various c
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structural actions and A2 to geotec
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Geometrical data are concerned with
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Figure 4.3 Failure surfaces for com
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Depth below ground level in m 5.6 1
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(a) (b) Peak adhesion factor a p Le
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orehole or test profile over the pe
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Effective length Shaft friction not
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4.3 Piles in coarse-grained soils 4
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Depth below ground surface (m) Resi
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Depth of penetration (m) 0 0 5 10 1
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using standard penetration tests or
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� � Resistance of piles to comp
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Safety factors generally used in th
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Depth to NAP datum (m) Cone resista
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The conditions at the interface can
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The shear modulus G in equation 4.3
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2.0 OD tubular steel pile with clos
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where Resistance of piles to compre
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eached the point of ultimate resist
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(4) Obtain the safe end-bearing loa
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Vertical force, t t-z curve Vertica
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where the bearing capacity factor:
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and RQD of the rock as shown in Tab
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Depth below ground level (m) 0 5 10
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settlement of the pile are summariz
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Rock socket reduction factor a 1.0
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Table 4.17 � and � values of we
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Influence factor, l p 2.0 1.6 1.2 0
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(a) (b) No load on pile head Residu
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a closed end into a deep deposit of
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Average shearing strength along pil
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It is assumed that the shear streng
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Depth below ground level (m) Figure
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Figure 4.45 Depth below ground leve
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Depth of h(m) Segment (m bql) � h
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For a wall thickness of 19 mm in mi
Page 254 and 255: Resistance of piles to compressive
Page 256 and 257: Pile groups under compressive loadi
Page 258 and 259: 24.0 m 16.0 m The comparative group
Page 260 and 261: where c � cohesion intercept of s
Page 262 and 263: Inclination factor, i c Inclination
Page 266 and 267: z/B 0 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7
Page 268 and 269: Compressive stress 1.5 q n q n B A
Page 270 and 271: E u/c u 3000 2500 2000 1500 1000 50
Page 272 and 273: 0 0 1 2 3 4 H/B 5 6 7 8 9 0 1 2 3 4
Page 276 and 277: D LB LB D 0.50 0 0.1 0.2 0.3 0.4 0.
Page 284 and 285: Initial tangent constrained modulus
Page 286 and 287: factor N for which Schmertmann sugg
Page 290 and 291: 0 0 2 4 H/B 6 8 10 Influence factor
Page 294 and 295: Overall loading 100 kN/m2 (a) (b) (
Page 298 and 299: (a) (b) (c) (d) Pile groups under c
Page 306 and 307: Depth below ground level in m 5 10
Page 308 and 309: For the arrangement of the piles sh
Page 312 and 313: Soft clay Sand B/2 5 11.2 m Figure
Page 316 and 317: Unit negative skin friction at top
Page 320 and 321: Chapter 6 The design of piled found
Page 322 and 323: (a) Tie rod Wholly compression Whol
Page 324 and 325: esistance of cylindrical augered fo
Page 326 and 327: in the ground is assumed to be equa
Page 328 and 329: Section 3.3.1. Enlargements cannot
Page 330 and 331: Piles to resist uplift and lateral
Page 332 and 333: Spacer Top of hard rock Drilling pi
Page 334 and 335: where m is the modular ratio of ste
Page 336 and 337: Table 6.3 Examples of bond stress b
Page 338 and 339: Top of rock 30˚ 30˚ Figure 6.15 F
Page 340 and 341: (b) P/n & �Vm Vc 2.0 1.8 1.6 1.4
Page 342 and 343: Table 6.4 Partial resistance factor
Page 344 and 345: and adjustment, starting with a ver
Page 346 and 347: Coefficient of subgrade modulus var
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Page 350 and 351: and Thus from Figure 6.24 deflectio
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(a) (b) (c) Depth coefficient Z 0 1
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Horizontal load H; Bending moment =
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Methods of drawing sets of p-y curv
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Calculations to determine the ultim
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(a) (b) Pressure Soil reaction p Ps
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Z�x/R 0 1.0 2.0 3.0 4.0 5.0 M(z)
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(a) yroGc H0 Ep Gc 1/7 (b) 0 0 0.1
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(a) determining the compressive and
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A X Z B R A Resultant R R B Y C D R
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6.8 FREEMAN, C. F., KLAJNERMAN, D.,
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Thus the load to be carried by anch
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If high-tensile steel (which has a
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sustained horizontal load which can
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Calculating the allowable horizonta
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Pile cap (Weight�2475 kN) F E D C
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The resultant of the vertical and h
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The Brinch Hansen bearing capacity
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Modulus of elasticity of pile � 2
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Chapter 7 Some aspects of the struc
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(a) (b) (c) Lifting rope Lifting po
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7.3 Designing piles to resist drivi
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Structural design of piles and pile
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should not arise if the piles are d
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(a) (b) (c) M.S.plate cover M.S.cap
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45˚ Structural design of piles and
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X Column Y9 Y9 Y Critical section f
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7.9 The design of pile capping beam
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Damp-proof course Cranked vent Grou
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(a) (b) Deck of wharf Fender Rubber
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(a) (b) y y e z f A The bending mom
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Piling for marine structures 403 th
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Pipe trunkways Hose handling platfo
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Piling for marine structures 407 8.
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Piling for marine structures 409 sh
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In SI units, equation 8.8 becomes f
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The natural frequency of the member
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The empirical equation of Korzhavin
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Piling for marine structures 417 re
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Table 8.3 Minimum safety factors fo
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Piling for marine structures 421 th
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Piling for marine structures 423 sh
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8.21 GERWICK, B. C. Construction of
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Soil resistance p in kN per m of de
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From Figures 6.29a and b the comput
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giving 9.7y � 0.26, y � 0.26
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From �7.5 to �3.0 m: no increas
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Miscellaneous piling problems 435 W
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9.2 Piling for underpinning Miscell
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Miscellaneous piling problems 439 B
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Miscellaneous piling problems 441 T
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Miscellaneous piling problems 443 p
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Longitudinal reinforcement is provi
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Light-gauge steel lining tubes Stow
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When inspecting the geological cond
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Miscellaneous piling problems 451 f
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natural ‘freeze-back’ around th
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Miscellaneous piling problems 455 b
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Miscellaneous piling problems 457 w
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Drainage layer 8.0 m 6.0 m Fill 1.0
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p m/c u 10.5 2p 0 and the mean hori
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Bridge abutment support piles Emban
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Figure 9.23 Drilling equipment for
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Max. water level +16 m Min. water l
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2-4 m marine clay dredged out MHW R
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Miscellaneous piling problems 471 o
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Miscellaneous piling problems 473 c
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The ground temperature around the p
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9.40 URANOWSKI, D. D., DODDS, S., a
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The durability of piled foundations
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and European Standards as shown in
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martesia with some teredo, and at C
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economics, taking into account the
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Depth of borehole 1.5 B 1 in 4 B Gr
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Ground investigations, contracts an
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(a) DCP n (blows/100 mm) 40 35 30 2
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Table 11.2 Daily pile record for dr
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Paper fixed to pile by adhesive tap
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Figure 11.10 Patented arrangement f
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following expressions: (11.1) Load
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(b) Settlement of pile head in mm S
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(a) Settlement � (mm) 0 0 4 8 Gro
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experience to give reasonably relia
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Appendix Properties of materials A.
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Subdivisions of Grades A to C chalk
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544 Name index Davis, E. H. 354 Dav
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546 Name index Schaaf, S. A. 424 Sc
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548 Subject index contiguous piles
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550 Subject index Pali Radice piles
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