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3 y$ t$ }& `! l/ O/ G! d) L6 E/ gIntegral Abutment Bridge Design Guidelines（92 Pages）
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TABLE OF CONTENTS
. R8 f9 s" B7 r1 S5 \Table of Contents...........................................................................................................................................vii
% G6 r; q" F6 R3 {$ NIntroduction.....................................................................................................................................................xi
0 S( y. c* T* J5 s0 m$ USECTION 1 Introduction to Integral Abutment Bridges...............................................................................1-1
# G' h# M% Z  Y7 L+ U1.1 Integral Abutment Bridge................................................................................................................1-1
1.2 Difference from Conventional Bridges............................................................................................1-1
1.3 Document Precedence.....................................................................................................................1-1
1.4 Definitions......................................................................................................................................1-1
5 s- A) t% J9 u0 D4 W4 b1.5 Notation..........................................................................................................................................1-3
3 T/ |" d% _- E4 Y2 q: J  `0 sSECTION 2 General Design and Location Features.....................................................................................2-1
2.1 First Choice.....................................................................................................................................2-1
2.2 Structure Geometrical Criteria.........................................................................................................2-1
. r, t1 A5 c! M0 s% N2 G2.2.1 Criteria for the Simplified Design Method.............................................................................2-1
9 r$ [% r7 `0 v; F# r" a% Y& y1 y* o2.2.2 Detailed Design for Projects That Exceed the Criteria for Simplified Design......................2-2
2.2.3 Semi-Integral, Jointed and Other Structural Alternatives......................................................2-2
% N: A  Y( |, u9 v* {( e  v. Z2.3 Laying out the Bridge......................................................................................................................2-3
# o2 S) O. i: l/ K" ?* e  {2.3.1 Conventional Layout..............................................................................................................2-3
2.3.2 Ideal Layout...........................................................................................................................2-3
) {* I/ c/ Y8 p, o1 f2.4 Hydraulic RequirementS.................................................................................................................2-5
" W7 @: N4 n3 Y. h. U1 `2.4.1 Scour Considerations..............................................................................................................2-6
2.4.2 Cofferdam Requirements.......................................................................................................2-6
2.5 Geotechnical...................................................................................................................................2-6
" G1 b( t: F6 X6 iSECTION 3 Loads........................................................................................................................................3-1
) A" T5 ^8 Z; Z5 i! k$ i% u3 J3.1 General Information........................................................................................................................3-1
4 H2 M  h$ f) q% y- h) _. T3.2 Application of Loads.......................................................................................................................3-1
2 l5 v) H/ A6 ]. A) }: {! f3.2.1 Construction Stage.................................................................................................................3-1
0 c+ x0 x+ c) R3 ^5 I' d3.2.1.1 Permanent Dead Loads on Pile Cap..............................................................................3-1
1 K( ?- g+ U: _( n* o3.2.1.2 Construction Dead and Live Loads...............................................................................3-1
" c8 S. g$ j* T3.2.1.3 Permanent Dead Load on Piles.....................................................................................3-1
3.2.2 Final Stage.............................................................................................................................3-1
3.2.2.1 Composite Permanent Dead Loads...............................................................................3-2
) C; J9 C  P9 z3.2.2.2 Live Loads....................................................................................................................3-2
3.2.2.3 Longitudinal Effects.....................................................................................................3-2
' i% f  F/ x1 r0 l# c( L3.2.2.4 Earth Loads...................................................................................................................3-2
SECTION 4 Structural Analysis and Evaluation...........................................................................................4-1
4.1 General Information........................................................................................................................4-1
1 r. l* s% U$ @7 V0 P4.2 Structural Design Criteria................................................................................................................4-1
0 V1 k' K3 o( H" ^4.3 Design Methodology......................................................................................................................4-1
4.3.1 Simplified Design Method.....................................................................................................4-1
% x8 e+ B+ s% x4.3.2 Detailed Design......................................................................................................................4-2
7 B3 o+ {: r1 G1 }& h  D, w4.4 Superstructure.................................................................................................................................4-2
4.4.1 Bridge End and Anchorage General Details..........................................................................4-2
3 M3 d( m8 Z- J5 h' G+ e" G7 `! E4.5 Substructure....................................................................................................................................4-3
4.5.1 Abutment Movement..............................................................................................................4-3
: Z+ s+ q* x( `- v" J0 N; H# r- b4.5.1.1 Thermal Movement.......................................................................................................4-3
4.5.1.2 Shrinkage and Creep.....................................................................................................4-4
- X0 [+ ^. P4 L# j. 2009 by the Structures Section, Program Development Division
) R' S7 }( ~  I% L/ a$ \Vermont Agency of Transportation
# V; N3 W% s  r8 D8 {5 Pviii 2008VTRANS INTEGRAL ABUTMENT DESIGN GUIDELINE
6 N' H9 g. M- k- [6 R- \" z  |4.5.1.3 Total Allowable Movement..........................................................................................4-4
0 A2 ^4 X# @4 C7 U4.5.1.4 Grade of Steel...............................................................................................................4-4
, t0 A8 X3 ]+ d& X6 N8 F2 B6 Q4.5.1.5 Pile Selection................................................................................................................4-4
4.5.1.6 Pile Orientation.............................................................................................................4-9
4.5.2 Pile Design............................................................................................................................4-9
) Z% h! S8 V& h* ?) Q( g4.5.2.1 L-Pile Software Analysis............................................................................................4-11
4.5.2.1.1 Lateral Load at Pile Head.......................................................................................4-11
4.5.2.1.2 Pile Deflection and Moment..................................................................................4-11
4.5.2.1.3 Unbraced Lengths..................................................................................................4-12
0 B* \, u5 ]; g4 [0 y4 e- b4.5.2.1.4 Depth to Fixity.......................................................................................................4-12
4.5.2.2 Combined Axial Compression and Flexure................................................................4-16
4.5.3 Pile Cap...............................................................................................................................4-16
4.5.4 Wingwall Design..................................................................................................................4-16
4.6 Project Notes and Special Provisions............................................................................................4-16
0 R5 \, _# E8 F4.7 Load Rating..................................................................................................................................4-16
SECTION 5 Concrete Structures...................................................................................................................5-1
/ A+ E* F- C( u& a5.1 General Information........................................................................................................................5-1
" G; u/ x5 W. R% U1 {( M5.2 Prestress Superstructure Specific Details........................................................................................5-1
( r& {5 Q) o1 n) [5.2.1 Voided Slab and Box Beam Bridge Decks............................................................................5-1
5.2.2 Northeast Bulb-T (NEBT)......................................................................................................5-2
5.2.2.1 Cast-In-Place Concrete Slab Decks..............................................................................5-4
5.2.3 Design for Frame Action (Negative Moment) at Ends of Deck.............................................5-4
SECTION 6 Steel Structures........................................................................................................................6-1
' V( b, i- u9 m" v) f6.1 General Information........................................................................................................................6-1
6.2 Steel Girder Specific Details...........................................................................................................6-1
SECTION 7 Aluminum Structures................................................................................................................7-1
' w6 [7 W$ h3 P7.1 General Information........................................................................................................................7-1
* n6 ~9 w# S$ V- qSECTION 8 Wood Structures.......................................................................................................................8-1
/ |- l4 x$ ^, z, v  g+ V" M8.1 General Information........................................................................................................................8-1
SECTION 9 Deck and Deck Systems............................................................................................................9-1
9 t  \8 T  v9 U. ~4 `( ^" j9 e9.1 General Information........................................................................................................................9-1
SECTION 10 Foundations..........................................................................................................................10-1
% b- _6 \$ e% w  S2 r10.1 Initial Considerations................................................................................................................10-1
4 U5 J1 Q. F8 z$ o4 v10.1.1 Geotechnical Exploration.....................................................................................................10-1
10.1.2 Pile Design and Verification................................................................................................10-1
10.1.3 Required Information for Contract Documents....................................................................10-1
10.2 Selecting a Pile for Integral Abutments....................................................................................10-1
: j' ?2 a3 x, q' o0 f! X$ b% U- o1 f10.2.1 Loads on Piles......................................................................................................................10-1
10.2.2 Pile Cap Geometry...............................................................................................................10-2
# A) h' T: \8 l% A10.2.2.1 Number of Piles and Pile Spacing..............................................................................10-2
# X$ d, o0 G; f# O, ?; {5 ~$ [10.2.2.2 Pile Groups.................................................................................................................10-2
10.2.2.3 Pile Length Requirement............................................................................................10-2
* I+ {# D1 f5 r5 O" F& e10.3 Service Limit State....................................................................................................................10-2
% d' b" I/ s: N10.4 Strength Limit State..................................................................................................................10-2
* X4 J6 v0 ~" ^: I+ m10.4.1 Nominal Structural Pile Resistance (NSPR)........................................................................10-3
10.4.2 Nominal Axial Pile Resistance (NAPR)..............................................................................10-3
% v) L3 s/ L7 w$ O10.4.3 Downdrag and Other Losses to Geotechnical Strength.......................................................10-3
10.4.4 Strength Limit State Resistance Factors for Driven Piles....................................................10-3
. 2009 by the Structures Section, Program Development Division
Vermont Agency of Transportation
TABLE OF CONTENTS ix
10.5 Pile Driving Analysis................................................................................................................10-4
8 P5 N9 g$ O- I. O4 t# X) b10.5.1 Pile Driving Concerns..........................................................................................................10-4
10.5.2 Maximum Pile Driving Stress..............................................................................................10-4
4 ]5 B1 G! _! ]10.5.3 Nominal Pile Driving Resistance (NPDR)...........................................................................10-5
* D" b9 ^: Q1 r; c9 H5 |+ Y/ e8 c10.5.3.1 Verification of the Nominal Axial Pile Resistance (NAPR) in Compression............10-5
10.5.4 Resistance Factors for Verifying the NAPR........................................................................10-5
1 a! r, X. ?: p10.6 Design Steps for Piles...............................................................................................................10-6
SECTION 11 Abutment, Piers and Walls....................................................................................................11-1
! s) X* t7 L) v/ r11.1 General Information..................................................................................................................11-1
9 a# v6 r. R/ b% s4 G2 {2 L, aSECTION 12 Buried Structures and Tunnel Liners....................................................................................12-1
- D8 g$ {+ u. C% I* C; O3 ^12.1 General Information..................................................................................................................12-1
SECTION 13 Railings................................................................................................................................13-1
13.1 General Information..................................................................................................................13-1
SECTION 14 Joints and Bearings...............................................................................................................14-1
14.1 General Information..................................................................................................................14-1
7 q! W5 W$ x" m6 ~% ]SECTION 15 Summary..............................................................................................................................15-1
SECTION 16 References............................................................................................................................16-1
- \# k3 u$ W$ H* O" N2 b16.1 General Information..................................................................................................................16-1
8 u# V, D+ X! r16.2 Performance.............................................................................................................................16-1
4 y9 s& E) L6 k16.3 Design Issues............................................................................................................................16-2
16.4 Analysis....................................................................................................................................16-2
16.5 Approach Slabs.........................................................................................................................16-2
, Y" E( X# q; P+ f$ ~! \16.6 Forces.......................................................................................................................................16-2
5 L- I) S1 k! B: J0 f8 X16.7 State Manual References...........................................................................................................16-3
Appendix A Design Outline.............................................................................................................................1
9 a, q, a+ w, T- H/ eAppendix B Design Example...........................................................................................................................1
! m/ Q$ r9 L3 \* {& x, [! x$ TNotes:..........................................................................................................................................................16-1
& {) B5 s$ j" u5 q& |9 I" B6 Q+ x( a7 m
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INTEGRAL ABUTMENT BRIDGES - DESIGN AND CONSTRUCTIBILITY (8 Pages)
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  F: P0 v4 H  Q! x' {5 j  _David I. Harvey, Don W. Kennedy
Associated Engineering (B.C.) Ltd., Canada
4 @( V/ h4 C/ C) z" @4 sGordon W. Ruffo
2 n) r/ K! e3 XCarston-Aimes Construction Consultants Ltd., Canada

' g. y/ w7 R: y. W; g- WIntegral Abutment Bridges Current Practice in the United States And Canada（20 Pages）
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+ q$ S2 E1 L! I' W/ X- ^. x! B

目录

& X: c: D% I8 {! T$ _9 D

INTEGRAL BRIDGE ABUTMENTS（50 Pages）
R. J. Lock
CUED/D-SOILS/TR320 (June 2002)
M.Eng. Project Report
8 N) i% S' P& x, E5 I$ d INTEGRAL BRIDGE ABUTMENTS.pdf (1.47 MB, 下载次数: 3, 售价: 1 元堡币)

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1.0 INTRODUCTION ..............................................................................................4
1.1 Purpose and Scope of Project .................................................................................... 5
8 y4 d' n5 R+ j2 Y1 G: D; l1.2 Mode of Bridge Movement ....................................................................................... 6
1.3 Magnitude of Deck Expansion .................................................................................. 6
: `4 ^& d, @7 g" z0 V% _2 x2.0 LITERATURE REVIEW - Model Test Procedures...........................................7
* B- i6 J$ }% G3 k2 [! n4 \2.1 TRL Report 146: Cyclic loading of sand behind integral bridge abutments............. 7
2.2 Integral Bridges: A fundamental approach to the time-temperature loading problem
, {. v8 G+ R7 m1 V- x+ C, A* O(England et al., 2000) .......................................................................................................... 11
+ {# w: P; I+ ^' M0 N1 }3.0 EARTH PRESSURES - Experimental Results.................................................13
# I/ ~* l0 A0 b$ Y. W: ?3.1 BA 42/96 - The Design of Integral Bridges ............................................................ 13
9 J/ r6 p8 L/ u% f0 Q3.2 TRL Report 146: Cyclic loading of sand behind integral bridge abutments
(Springman et al. 1996) ....................................................................................................... 14
3.3 Integral Bridges: A fundamental approach to the time-temperature loading problem
* K4 M7 c. W$ C(England et al., 2000) .......................................................................................................... 16
& `  m2 d& D7 \7 K3.4 Experimental and Analytical Investigations of Piles and Abutments of Integral
9 T' q2 V- q" P9 x. F/ Z2 u9 [Bridges (Arsoy et al., 2002) ................................................................................................ 19
4 E4 F* P; v: q- y$ b4.0 EARTH PRESSURES - Field Measurements ..................................................20
4.1 Field tests................................................................................................................. 20
4.2 Testing an Integral Steel Frame Bridge: Elgaaly et al., 1992; Skew Effects on
/ }% R0 K+ I0 ?Backfill Pressures at Integral Bridge Abutments: Sandford & Elgaaly, 1993. ................... 21
4.3 Measurement of thermal cyclic movements on two portal frame bridges on the M1:
Darley & Alderman, 1995 ................................................................................................... 24
7 T) A+ B7 J- e# W. J, H; q+ _4.4 Field Study of an Integral Backwall Bridge: Hoppe & Gomez, 1996..................... 24
1 j7 S8 A0 @1 o( e; ?6 {; S4.5 Seasonal thermal effects over three years on the shallow abutment of an integral
bridge in Glasgow: Darley et al., 1998................................................................................ 26
4.6 Performance of an integral Bridge over the M1-A1 Link Road at Bramham
; q1 h$ I* C, k0 w. S* rCrossroads: Barker & Carder, 2001 .................................................................................... 27
4.7 Field Performance of Integral Abutment Bridge: Lawver et al., 2000.................... 28
4.8 Integral Bridge in West Lafayette, Indiana. Frosch, 2002....................................... 29
* v" t, D# d9 A' L. Y$ F! ^" V4.9 Coefficients of Thermal Expansion......................................................................... 30
! s+ x! B: n: o4.10 Influence of deck compression................................................................................ 31
5.0 SETTLEMENT - Experimental Results ...........................................................33
7 @: {; F+ i9 t8 e5.1 BA 42/96 - The Design of Integral Bridges ............................................................ 33
5.2 TRL Report 146: Cyclic loading of sand behind integral bridge abutments
(Springman et al. 1996) ....................................................................................................... 33
5.3 Integral Bridges: A fundamental approach to the time-temperature loading problem
(England et al., 2000) .......................................................................................................... 36
% f% [/ b& d7 A+ L+ L4 h- C3 P9 Z6.0 SETTLEMENT - Field Measurements.............................................................38
6.1 Highways Agency Maintenance Data ..................................................................... 38
6.2 Field Studies ............................................................................................................ 40
  m1 D3 P) @5 Q2 k" q9 u6.3 Approach Slabs........................................................................................................ 42
7.0 CONCLUSIONS...............................................................................................44
7.1 Superstructure.......................................................................................................... 44
# N4 N2 o% @1 Q5 j+ ^( L3 r1 Y7.2 Abutment design...................................................................................................... 44
! m3 I/ j) k1 s7.3 Settlement mitigation............................................................................................... 45
8.0 REFERENCES .................................................................................................46
; f& f$ C& z/ L# X1 n9.0 ACKNOWLEDGEMENTS..............................................................................49
APPENDIX A Earth pressure coefficient definitions .............................................50

5 W# j. k; i& G7 a! ]" ?
6 |' x$ V; ?8 B9 q; ^  g) ?# l' uTHE 2005 – FHWA CONFERENCE 会议论文集（343Pages）
Integral Abutment and Jointless Bridges
$ I8 R+ H, J! `2 E; e(IAJB 2005) March 16 – 18, 2005
Baltimore, Maryland
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9 `6 @- F* w  n
& @* w3 o6 T- n9 v) {/ l% R) o3 ~* [Session I: Current Practices with Design Guidelines and Foundation Design
3 |+ m9 y" w$ u; E  ]  k1 e. {Integral Abutment and Jointless Bridges                                                                    
9 G  R7 x. ~0 k" _* rV. Mistry                               3

2 t: U, R+ t! d, P, ]  nIntegral Abutments and Jointless Bridges (IAJB)          2004 Survey Summary         
4 i  S5 C1 U5 z4 q; oR. Maruri, S.Petro                 12
: I6 t$ O# |3 M# d  r9 i2 J
The In-Service Behavior of Integral Abutment Bridges:  Abutment-Pile Response   
1 h" h; ~- H6 t* S. a# SR. Frosch, M. Wenning, V. Chovichien 30

New York State Department of Transportation's Experience with Integral Abutment Bridges
A. Yannotti, S. Alampalli, H. White        41
1 S7 s: L' d- G( L9 h. L
8 `/ D) u* Q" b$ g  JIntegral Abutment Design and Construction: The New England Experience            
D. Conboy, E. Stoothoff                        50
2 M8 _5 \; m8 l* }, c: @3 h
VDOT Integral Bridge Design Guidelines                                                                  
( k. z1 y% {! _, s  TK. Weakley                                            61

Session II: Case Studies
9 s: U# b0 V# ^Case Study: A Jointless Structure to Replace the Belt Parkway Bridge  Over Ocean Parkway
S. Jayakumaran, M. Bergmann, S. Ashraf, C. Norrish 73
; X* g, N/ X4 N, F; _; J+ T0 J1 k
Case Study – Jointless Bridge Beltrami County State Aid Highway 33 Over Mississippi River in Ten Lake Township,
Minnesota J. Wetmore, B. Peterson                             84

Design and Construction of Dual 630-foot, Jointless, Three-spanContinuous Multi-girder Bridges in St. Albans, West Virginia,
6 r$ |# u& |" y; RUnited States, Carrying U.S. Route 60 over the Coal River
J. Perkun, K. Michael                                                  97
1 E: m/ t% R/ |% U% A+ P  }- ?
Integral Abutment Bridges with FRP Decks – Case Studies
' b# D; `% X+ y0 i& uV. Shekar, S. Aluri, H. GangaRao                             113

New Mexico’s Practice and Experience in Using Continuous Spans for Jointless Bridges
8 o4 Y3 z6 A& n% r! ~2 Y S. Maberry, J. Camp, J. Bowser                            125

Integral Abutment Bridges – Iowa and Colorado Experience
D. Liu, R. Magliola, K. Dunker                               136
! y" |4 B2 ~3 n6 J5 J) v, f
3 U1 m7 G7 P. x% BMoose Creek Bridge – Case Study of a prefabricated Integral Abutment Bridge in Canada
' g7 H! c# T9 M; ~! e/ z I. Husain, B. Huh, J. Low, M. McCormick                 148
Session III: Maintenance and Rehabilitation
Session IV: Construction Practices
Author Index
1 G5 [" q( U7 c* m
& T; L' @8 t  j* k/ J

what‘s   this  dongdong？

一般银看不懂 this dongdong costs too much

回复 greetingpine 的帖子

8 x5 I; m5 p/ B3 g" }- n加钱其实只是为了防止被人随便转到其他论坛上，要不我就把级别弄高点

! o, X1 t% W- i# K. e这篇贴和 子菁版主的 美国道路桥梁深度考察报告

联合起来看，来了解国外的桥梁设计方法。

我觉得。。。国内很多地方的设计，虽然一部分原因是设计理念的差距，这部分差距是很大，但是另一个很重要的原因是市场的因素

工程投入、历史积累、理念等多方面的差距
  w: E& R/ W5 d( u5 l/ E+ Q% h有对比才有进步，取长补短。