Pile Design and Construction Practice, Fifth edition

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The ground temperature around the pile in a heat extraction system using brine will be lowered by around 5�C, and there is no evidence that the shaft resistance and bearing capacity of the pile are affected by the heat transfer process in this case. Also any temperatureinduced settlement/heave is likely to be less than the displacements due to the applied loads on the foundations. If excessive heat is extracted using a lower temperature refrigerant as the absorber, temperature around the foundation can drop to near freezing. The piling technique necessary for the installation of energy piles may not be the most costeffective for the ground conditions, but depending on energy prices, climatic conditions and the type of building, pay-back for the higher initial cost in terms of energy saving is estimated to be between 2 and 10 years. Development of CFA and vibro-concrete piles to accommodate more robust heat transfer systems could provide more economical energy piles. 9.9 References Miscellaneous piling problems 475 9.1 BARKAN, D. D. Dynamics of bases and foundations (Translated from the Russian), McCraw-Hill Book Co. 1962. 9.2 HSIEH, T. K. Foundation vibrations, Proceedings of the Institution of Civil Engineers, Vol. 22, June 1962, pp. 211–26. 9.3 WHITMAN, R. V. and RICHART, F. E. Design procedures for dynamically loaded foundations, Proceedings of the American Society of Civil Engineers, Vol. 93, No. SM6, November 1967, pp. 169–93. 9.4 RICHART, F. E., HALL, F. R., and WOODS, R. D. Vibrations of Soils and Foundations, Prentice Hall, New Jersey, 1970. 9.5 IRISH, K. and WALKER, W. P. Foundations for reciprocating machines, Concrete, October 1967, pp. 327–37. 9.6 Foundations for Dynamic Equipment. American Concrete Institute, Report ACI351.3R-04, 2004. 9.7 LIZZI, F. Pali radice and reticulated pali radice, Micropiling, Underpinning, Thorburn, S. and Hutchison, J. N. (eds), Surrey University Press, 1985, pp. 84–161. 9.8 PRICE, D. G., MALKIN, A. B., and KNILL, J. L. Foundations of multi-storey blocks on the Coal Measures with special reference to old mineworkings, Quarterly Journal of Engineering Geology, Vol. 1, No. 4, June 1969. 9.9 ANDERSON, D. M. and MORGENSTERN, N. R. Physics, chemistry and mechanics of frozen ground, Proceedings of the 2nd International Conference on Permafrost, National Academy of Sciences, Washington DC, 1973. 9.10 ANDERSLAND, O. B. and LADANYI, B. Frozen Ground Engineering 2nd Edition. ACSE Press and John Wiley & Sons, New York, 2004. 9.11 TSYTOVICH, N. A. Permafrost in the USSR as foundations for structures, Proceedings of the 6th International Conference, ISSMFE, Montreal, Vol. 3, 1965, pp. 155–67. 9.12 PENNER, E. and IRWIN, W. W. Adfreezing of Leda Clay to anchored footing columns, Canadian Geotechnical Journal, Vol. 6, No. 3, August 1969, pp. 327–37. 9.13 PENNER, E. and GOLD, L. W. Transfer of heavy forces by adfreezing to columns and foundation walls in frost-susceptible soils, Canadian Geotechnical Journal, Vol. 8, No. 4, November 1971, pp. 514–26. 9.14 KINOSHITA, S. and ONO, T. Heavy forces on frozen ground, Low Temperature Science Laboratory, Teron, Kagaka, Serial A, 21, 1963, pp. 117–39. (Translated by National Science Library, National Research Council, Ottawa, Translation No. TT 1246, 1966.) 9.15 DALMATOV, B. L. Effect of frost-heaving on foundation of structures, Gosizid literatuy po streitch stuv i architektur, Leningrad-Moscow, 1957. 9.16 PENNER, E. Frost heaving forces in Leda Clay, Canadian Geotechnical Journal, Vol. 7, No. 1, February 1970, pp. 8–16.
476 Miscellaneous piling problems 9.17 FORIERO, A., St-LAURENT, N., and LADANYI, B. Laterally loaded pile study in permafrost of Northern Quebec, Canada, American Society of Civil Engineers, Journal of Cold Regions Engineering, Vol. 19, No. 3, 2005, pp. 61–84. 9.18 SEGO, D. C., BIGGAR, K. W., and WONG, G. Enlarged base (belled) piles for use in ice or ice-rich permafrost, ASCE Journal of Cold Regions Engineering, Vol. 17, No. 2, 2003, pp. 68–88. 9.19 KORHONEN, C. and ORCHINO, S. Effects of low temperature on concrete strength, ASCE Proceedings of 10th International Conference on Cold Regions Engineering, 1999, pp. 677–83. 9.20 BIGGAR, K. W. and SEGO, D. C. The curing and strength characteristics of cold setting cement fondu grout, Proceedings of 5th Canadian Permafrost Conference, Quebec, 1990, pp. 349–56. 9.21 JOHNSON, G. H. (ed.) Permafrost: Engineering Design and Construction, Wiley, New York, 1981. 9.22 HAMBLY, E. C. Bridge Foundations and Substructures, Building Research Establishment, HMSO, 1979. 9.23 BD 30/87. Backfilled retaining walls and bridge abutments, Highways and Traffic Departmental Standard, Department of Transport, 1987. 9.24 SPRINGMAN, S. M. and BOLTON, M. D. The effect of surcharge loading adjacent to piles, Transport and Road Research Laboratory, Contractor Report, 1990. 9.25 SPRINGMAN, S. M., NG, C. W. W., and ELLIS, E. A. Centrifuge and analytical studies of full height bridge abutment on piled foundation subject to lateral loading, Transport Research Laboratory, Project Report 98, 1995. 9.26 SPRINGMAN, S. M. Manual for the SIMPLE – for evaluating the effect of surcharge loading adjacent to piles, Transport and Road Research Laboratory/Cambridge University, 1992. 9.27 DARLEY, P., CARDER, D. R., and RYLEY, M. D. Lateral loading on piled foundations at Wiggenhall Overbridge (A47), Transport Research Laboratory, TRL Report 246, 1997. 9.28 RANDOLPH, M. F. and HOULSBY, G. T. The limiting pressure on a circular pile loaded laterally in cohesive soil, Geotechnique, Vol. 34, No. 4, 1984, pp. 613–23. 9.29 DE BEER, E. and WALLAYS, M. Forces induced by unsymmetrical surcharges on the soil around the pile, Proceedings of the 5th European Conference on Soil Mechanics and Foundation Engineering, Madrid, Vol. 1, 1972, pp. 325–32. 9.30 MASSARSCH, K. R. and BROMS, B. B. Pile driving in clay slopes, Proceedings of the 10th International Conference, ISSMFE, Stockholm, Vol. 3, 1981, pp. 469–74. 9.31 REID, W. M. and BUCHANAN, N. W. Bridge approach support piling, Proceedings of the Conference on Piling and Ground Treatment, Institution of Civil Engineers, London, 1983, pp. 267–74. 9.32 BEETSTRA, G. W., VAN DEN HOONARD, J., and VOGELAAR, L. J. J. Bridges and viaducts, in The Netherlands Commemorative Volume, E. H. de Leew (ed.), Proceedings of the 11th International Conference, ISSMFE, San Francisco, 1985. 9.33 BITTNER, R. B., ZHANG, X., and JENSEN, O. J. Design and construction of the Sutong bridge foundations, Deep Foundations Institute, Marine Foundations Speciality Seminar, New York, 2005, pp. 19–27. 9.34 MAY, R. W. P., ACKERS, J. C., and KIRBY, A. M. Manual on scour at bridges and other hydraulic structures, CIRIA Report C551, Construction Industry Research and Information Association, London, 2002. 9.35 CHIN FUNG KEE and McCABE, R. Penang Bridge Project: foundations and reclamation work, Proceedings of the Institution of Civil Engineers, Vol. 88, No. 1, 1990, pp. 531–49. 9.36 STANLEY, R. G. Design and construction of the Sungei Perak Bridge, Malaysia, Proceedings of the Institution of Civil Engineers, Vol. 88, No. 1, 1990, pp. 571–99. 9.37 LEVESQUE, M. Les fondations du pont de Färo en Danemark, Travaux, November 1983, pp. 33–6. 9.38 WALTHAM, A. C. and FOOKES, P. G. Engineering classification of karst ground conditions. Journal of Engineering Geology and Hydrology, Vol. 36, No. 2, Geological Society of London, 2003, pp. 101–18. 9.39 BYLE, M. J. and MACKEY, R. Grouting karst to support driven pile foundation for a truss railway bridge. In Geotrans 2004 – Geotechnical engineering for transportation projects, Yegian, M. K. and Kavazanjian, E. (eds), American Society of Civil Engineers Geotechnical Special Publication No. 126, 2004, pp. 1915–25.
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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
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Pile groups under compressive loadi
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24.0 m 16.0 m The comparative group
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where c � cohesion intercept of s
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Inclination factor, i c Inclination
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z/B 0 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7
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Compressive stress 1.5 q n q n B A
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E u/c u 3000 2500 2000 1500 1000 50
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0 0 1 2 3 4 H/B 5 6 7 8 9 0 1 2 3 4
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D LB LB D 0.50 0 0.1 0.2 0.3 0.4 0.
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Initial tangent constrained modulus
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factor N for which Schmertmann sugg
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0 0 2 4 H/B 6 8 10 Influence factor
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Overall loading 100 kN/m2 (a) (b) (
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(a) (b) (c) (d) Pile groups under c
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Depth below ground level in m 5 10
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For the arrangement of the piles sh
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Soft clay Sand B/2 5 11.2 m Figure
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Unit negative skin friction at top
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Chapter 6 The design of piled found
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(a) Tie rod Wholly compression Whol
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esistance of cylindrical augered fo
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in the ground is assumed to be equa
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Section 3.3.1. Enlargements cannot
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Piles to resist uplift and lateral
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Spacer Top of hard rock Drilling pi
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where m is the modular ratio of ste
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Table 6.3 Examples of bond stress b
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Top of rock 30˚ 30˚ Figure 6.15 F
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(b) P/n & �Vm Vc 2.0 1.8 1.6 1.4
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Table 6.4 Partial resistance factor
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and adjustment, starting with a ver
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Coefficient of subgrade modulus var
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where e is the height from the grou
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and Thus from Figure 6.24 deflectio
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(a) Deflection coefficient Ay (c) D
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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
Page 440 and 441: 8.21 GERWICK, B. C. Construction of
Page 442 and 443: Soil resistance p in kN per m of de
Page 444 and 445: From Figures 6.29a and b the comput
Page 446 and 447: giving 9.7y � 0.26, y � 0.26
Page 448 and 449: From �7.5 to �3.0 m: no increas
Page 450 and 451: Miscellaneous piling problems 435 W
Page 452 and 453: 9.2 Piling for underpinning Miscell
Page 454 and 455: Miscellaneous piling problems 439 B
Page 456 and 457: Miscellaneous piling problems 441 T
Page 458 and 459: Miscellaneous piling problems 443 p
Page 460 and 461: Longitudinal reinforcement is provi
Page 462 and 463: Light-gauge steel lining tubes Stow
Page 464 and 465: When inspecting the geological cond
Page 466 and 467: Miscellaneous piling problems 451 f
Page 468 and 469: natural ‘freeze-back’ around th
Page 470 and 471: Miscellaneous piling problems 455 b
Page 472 and 473: Miscellaneous piling problems 457 w
Page 474 and 475: Drainage layer 8.0 m 6.0 m Fill 1.0
Page 476 and 477: p m/c u 10.5 2p 0 and the mean hori
Page 478 and 479: Bridge abutment support piles Emban
Page 480 and 481: Figure 9.23 Drilling equipment for
Page 482 and 483: Max. water level +16 m Min. water l
Page 484 and 485: 2-4 m marine clay dredged out MHW R
Page 486 and 487: Miscellaneous piling problems 471 o
Page 488 and 489: Miscellaneous piling problems 473 c
Page 492 and 493: 9.40 URANOWSKI, D. D., DODDS, S., a
Page 494 and 495: The durability of piled foundations
Page 496 and 497: and European Standards as shown in
Page 500 and 501: martesia with some teredo, and at C
Page 512 and 513: economics, taking into account the
Page 514 and 515: Depth of borehole 1.5 B 1 in 4 B Gr
Page 516 and 517: Ground investigations, contracts an
Page 520 and 521: (a) DCP n (blows/100 mm) 40 35 30 2
Page 530 and 531: Table 11.2 Daily pile record for dr
Page 532 and 533: 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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Ground investigations, contracts an
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Ground investigations, contracts an
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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
Page 563 and 564:
548 Subject index contiguous piles
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550 Subject index Pali Radice piles
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