4.5.3A cracking model for concrete and other brittle materials郑博文(16页)

Standard Specifications for Tolerances for Concrete Construction and Materials (ACI 117-90) Reported by ACI Committee 117S. Allen Face, III Thomas C. Heist Richard A. Kaden Ross Martin Peter Meza W. Robert LittleChairmanRussell S. FlingChairman, Editorial SubcommitteeAndrawos Morcos B. J. PointerClark B. Morgan, Jr.Dean E. Stephan, Jr.*Harry M. Palmbaum Eldon TippingWilliam S. Phelan Carl S. TogniJoe V. Williams, Jr.This specification provides standard tolerances for concrete con-struction. This document is intended to be used as the reference doc-ument for establishing tolerances for concrete construction by speci-fication writers and ACI committees writing Standards.Keywords: bending (reinforcing steels); building codes; concrete construction; concrete piles; concretes; floors; formwork (construction); masonry; mass con-crete; piers; precast concrete; prestressed concrete; reinforcing steels; specifi-cations; splicing; standards; tolerances (mechanics).FOREWORDF1. This foreword is included for explanatory pur-poses only; it is not a part of Standard Specification 117.F2. Standard Specification 117 is a Reference Stan-dard which the Architect/Engineer may cite in the Project Specifications for any construction project, to-gether with supplementary requirements for the spe-cific project.This standard is not intended to apply to special structures not cited in the standard such as nuclear re-actors and containment vessels, bins and silos, and pre-stressed circular structures. It is also not intended to apply to the specialized construction procedure of shotcrete.F3. Standard Specification 117 addresses each of the Three-Part Section Format of the Construction Speci-fications Institute, organized by structural elements, structural components and types of structures; the numbering system reflects this organization. The lan-guage is imperative and terse to preclude an alterna-tive.F4. A Specification Checklist is included as a preface to, but not forming a part of, Standard Specification 117. The purpose of this Specification Checklist is to assist the Architect/Engineer in properly choosing and specifying the necessary mandatory and optional re-quirements for the Project Specification.PREFACE TO SPECIFICATION CHECKLISTP1. Standard Specification 117 is intended to be used in its entirety by reference in the Project Specification.Individual sections, articles, or paragraphs should not be copied into the Project Specifications since taking them out of context may change their meaning.P2. Building codes establish minimum requirementsnecessary to protect the public. Some of the require-ments in this Standard Specification may be morestringent than the minimum in order to insure the level of quality and performance that the Owner expects the structure to provide. Adjustments to the needs of a particular project should be made by the Architect/En-gineer by reviewing each of the items in the Specifica-tion Checklist and then including the Architect/Engi-neer’s decision on each item as a mandatory require-ment in the Project Specifications.P3. These mandatory requirements should designate the specific qualities, procedures, materials, and per-formance criteria for which alternatives are permitted or for which provisions were not made in the Standard Specification. Exceptions to the Standard Specification should be made in the Project Specifications, if re-quired.P4. A statement such as the following will serve to make Standard Specification ACI 117 an official part of the Project Specifications:Tolerances for Concrete Construction and Mate-rials shall conform to all requirements of ACI 117,Standard Specifications for Tolerances for Con-crete Construction and Materials, published by theAmerican Concrete Institute, Detroit, Michigan,except as modified by the requirements of theseContract Documents.Adopted as a Standard of the American Concrete Institute in November 1989 in accordance with the Institute’s standardization procedures.Copyright © 1990, American Concrete Institute. All rights reserved, includ-ing the making of copies unless permission is obtained from the copyright pro-prietors.*Chairman during initial development of this document.117-1117-2MANUAL OF CONCRETE PRACTICEP5. The Specification Checklist that follows is ad-Checklist consists of two columns; the first identifies dressed to each item of the Standard Specification the sections, parts, and articles of the Standard Speci-where the Architect/Engineer must or may make a fication and the second column contains notes to the choice of alternatives; may add provisions if not indi-Architect/Engineer to indicate the type of action re-cated; or may take exceptions. The Specification quired by the Architect/Engineer.MANDATORY SPECIFICATION CHECKLISTSection/Part/Article Section 2 - Materials2.2-Reinforcement Section 3 - Foundations3.1.1 Drilled piers Section 4 - Cast-in-place concrete for buildings4.5.4 Form offsets4.5.5 Floor finish4.5.5.1 For Section 4.5.64.5.5.2 For Section 4.5.7Notes to the Architect/EngineerTolerances for fabrication, placement, and lap splices for welded wire fabric must be specified by the specifier.Specify category of caisson. The designer should be aware that the recom-mended vertical alignment tolerance of 1.5 percent of the shaft length indicated in Category B caissons is based on experience in a wide variety of soil situations combined with a limited amount of theoretical analysis using the beam on elas-tic foundation theory and minimum assumed horizontal soil restraint. Designate class of surface (A, B, C, D):Class A -For surfaces prominently exposed to public view where appearance is of special importance.Class B - Coarse-textured concrete-formed surfaces intended to receive plas-ter, stucco, or wainscoting.Class C - General standard for permanently exposed surfaces where other fin-ishes are not specified.Class D -Minimum quality surface where roughness is not objectionable, usu-ally applied where surfaces will be concealed.Specify floor finish tolerance measurement method (either Section 4.5.6 or Sec-tion 4.5.7).Designate floor classification (15/13; 20/15; 30/20; or, 50/30).Designate maximum gap under a freestanding straightedge (1/2 in., 5/16 in., 3/16 in., or 1/8 in.).OPTIONAL SPECIFICATION CHECKLISTSection 1 - General1.1.2 Scope1.1.2 Scope 1.2.3 Requirements Tolerance values affect construction cost. Specific use of a toleranced item may warrant less or more stringent tolerances than contained in the specification. Such variances must be individually designated by the specifier in the contract docu-ments.Tolerances in this specification are for standard concrete construction and con-struction procedures. Specialized concrete construction or construction procedures require specifier to include specialized tolerances. AC1 committee documents cov-ering specialized construction may provide guidance on specialized tolerances. The tolerances in this Specification do not apply to special structures or procedures not cited in the document such as nuclear reactors and containment vessels, bins and silos, circular prestressed concrete tank structures and shotcrete.Where a specific application uses multiply toleranced items that together yield a toleranced result, the specifier must analyze the tolerance envelope with respect to practical limits and design assumptions and specify its value where the standard tolerances values in this specification are inadequate or inappropriate.TOLERANCESOPTIONAL SPECIFICATION CHECKLIST, continuedSection 2 - Materials2.2.3 Concrete cover2.3.2 Embedded itemsSection 3 - Cast-in-placeconcrete for foundations3.4.1.2 FootingsSection 4 - Cast-in-placeconcrete for buildings4.5.5 Floor finishSection 5 - Precastconcrete5.1.4 Camber5.3 PlanerelementsCONTENTS Section 1 - General, p. 117-4 1.1 - Scope1.2 - Requirements1.3 - DefinitionsSection 2 - Materials, p. 117-6 2.1 - Reinforcing steel fabrication2.2 - Reinforcement placement2.3 - Placement of embedded items 2.4 - Concrete batching2.5 - Concrete properties The tolerance for reduction in cover in reinforcing steel may require a reduction in magnitude where the reinforced concrete is exposed to chlorides or the environ-ment. Where possible excess cover or other protection of the reinforcing steel should be specified in lieu of reduced tolerance because of the accuracy of locating reinforcing steel utilizing standard fabrication accessories and installed procedures. Tolerance given is for general application. Specific design use of embedded items nay require the specifier to designate tolerances of reduced magnitude for various embedded items.Plus tolerance for the vertical dimensions is not specified because no limit is im-posed. Specifier must designate plus tolerance if desired.The procedures for specifying and measuring floor finish tolerances set forth herein are not appropriate for narrow aisle warehouse floors with defined traffic lanes de-signed for use by specialized wheeled equipment. Consult specific equipment man-ufacturers for their recommendations.The tolerances for precast concrete are intended to apply to all types of precast concrete construction cast onsite (including tilt-up) and offsite except as set forth below. Variations to these tolerances may be advisable after consideration of panel size and construction techniques required.Tolerances set forth herein are not intended to apply to plant production of pa-tented or copyrighted structural systems and/or elements. Designers, specifiers and contractors should contact the Licensors of such systems and/or products for ap-plicable tolerances.For members with a span-to-depth ratio equal to or exceeding 30, the stated cam-ber tolerance may require special production measures and result in cost premi-ums. Where feasible, a greater tolerance magnitude should be utilized where the span-to-depth ratio is equal to or greater than 30.Industrial precast products may not conform to the planar tolerances. Manufac-turers should be consulted for appropriate tolerances for their products.Section 3 - Foundations, p. 117-8 3.1 - Vertical alignment3.2 - Lateral alignment3.3 - Level alignment3.4 - Cross-sectional dimensions3.5 - Relative alignment117-3 Section 4 - Cast-in-place concrete for buildings, p. 117-94.1 - Vertical alignment4.2 - Lateral alignment4.3 - Level alignment4.4 - Cross-sectional dimensions4.5 - Relative alignment4.6 - Openings through membersSection 5 - Precast concrete, p. 117-105.1 - Fabrication tolerances in linear elements except piles5.2 - Fabrication tolerances for piles5.3 - Fabrication tolerances in planar elements5.4 - Erection tolerancesSection 6 - Masonry, p. 117-116.1 - Vertical alignment6.2 - Lateral alignment6.3 - Level alignment117-4 MANUAL OF CONCRETE PRACTICE6.4 - Cross-sectional dimensions6.5 - Relative alignmentSection 7 - Cast-in-place, vertically slipformed structures, p. 117-117.1 - Vertical alignment7.2 - Lateral alignment7.3 - Cross-sectional dimensions7.4 - Relative alignmentSection 8 - Mass concrete structures other than buildings, p. 117-118.1 - Vertical alignment8.2 - Lateral alignment8.3 - Level alignment8.4 - Relative alignmentSection 9 - Canal lining, p. 117-119.1 - Lateral alignment9.2 - Level alignment9.3 - Cross-sectional dimensionsSection 10 - Monolithic siphons and culverts, p. 117-1110.1 - Lateral alignment10.2 - Level alignment10.3 - Cross-sectional dimensionsSection 11 - Cast-in-place bridges, p. 117-12 11.1 - Vertical alignment11.2 - Lateral alignment11.3 - Level alignment11.4 - Cross-sectional dimensions11.5 - Relative alignmentSection 12 - Pavement and sidewalks, p. 117-12 12.1 - Lateral alignment12.2 - Level alignmentSection 13 - Chimneys and cooling towers, p. 117-1213.1 - Vertical alignment13.2 - Diameter13.3 - Wall thicknessSection 14 - Cast-in-place nonreinforced pipe, p. 117-1214.1 - Wall thickness14.2 - Pipe diameter14.3 - Offsets14.4 - Surface IndentationsSECTION 1 - GENERAL REQUIREMENTS 1.1 - Scope1.1.1 This specification designates standard toler-ances for concrete construction.1.1.2 The indicated tolerances govern unless other-wise specified.1.2 - Requirements1.2.1 Concrete construction shall meet the specified tolerances.1.2.2 Tolerances shall not extend the structure be-yond legal boundaries.1.2.3 Tolerances are not cumulative. The most re-strictive tolerance controls.1.2.4 Plus ( + ) tolerance increases the amount or di-mension to which it applies, or raises a level alignment. Minus ( - ) tolerance decreases the amount or dimen-sion to which it applies, or lowers a level alignment. A nonsigned tolerance means + or - . Where only one signed tolerance is specified (+ or - ), there is no limit in the other direction.1.3 - DefinitionsArris - The line, edge, or hip in which two straight or curved surfaces of a body, forming an exterior an-gle, meet; a sharp ridge, as between adjoining channels of a Doric column.Bowing - The displacement of the surface of a planar element from a plane passing through any three corners of the element.Clear distance - In reinforced concrete, the least distance between the surface of the reinforcement and the referenced surface, i.e., the form, adjacent rein-forcement, embedment, concrete, or other surface. Concealed surface - Surface not subject to visual observation during normal use of the element. Contract documents - The project contract, the project drawings, and the project specifications. Cover - In reinforced concrete, the least distance between the surface of the reinforcement and the outer surface of the concrete.Flatness - The degree to which a surface approxi-mates a plane.Lateral alignment - The location relative to a spec-ified horizontal line or point in a horizontal plane. Level alignment - The location relative to a speci-fied horizontal plane. When applied to roadways, bridge decks, slabs, ramps, or other nominally hori-zontal surfaces established by elevations, level align-ment is defined as the vertical location of the surface relative to the specified profile grade and specified cross slope.Levelness - The degree to which a line or surface parallels horizontal.Precast linear element - Beam, column, or similar unit.Precast planar element - Wall panel, floor panel, or similar unit.Project Specifications - The building specifications which employ ACI 117 by reference, and which serve as the instrument for making the mandatory and optional selections available under these and for specifying items not covered herein.Relative alignment - The distance between two or more elements in any plane, or the distance between adjacent elements, or the distance between an element and a defined point or plane.Spiral - As used in circular stave silo construction, is defined as the distortion that results when the staves are misaligned so that their edges are inclined while their outer faces are vertical. The resulting assembly117-6MANUAL OF CONCRETE PRACTICE NOTES:Entire shearing and bending tolerances are customarily ab-sorbed in the extension past the last bend in a bent bar.All tolerances single plane and as shown. Tolerances for TypesS1 through S6, S11, and T1 through T9 apply only the Bar Sizes#3 through #8.*Dimensions on this line are to be within tolerance shown, butare not to differ from opposite parallel dimension more than 1/2 in.Angular deviation-Maximum plus or minus 2-1/2 deg or plus orminus 1/2 in. per ft, but not less than 1/2 in., on all 90-deg hooks andbends.TOLERANCE SYMBOLS:1. Bar Sizes #3, #4, #5:= plus or minus 1/2 in. when gross bar length < 12 ft = plus or minus 1 in. when gross bar length _> 12 ft 2. Plus or minus 1 in.3. Plus 0, minus 1/2 in.4. Plus or minus 1/2 in.5. Plus or minus 1/2 in. for diameter _< 30 in.Plus or minus 1 in. for diameter > 30 in.6. Plus or minus 1.5 percent of o dimension _> plus or minus 2 in.minimum. If application of positive tolerance to Type 9 resultsin a chord length equal to or greater than the arc or bar length,the bar may be shipped straight.Fig. 2.1(a) - Standard fabricating tolerances for bar sizes #3 through #11horizontal location of the surface relative to the speci-fied profile.SECTION 2 - MATERIALS Warping - The displacement of the surface, por- 2.1 - Reinforcing steel fabrication tion, or edge of a planar element from a plane passing For bars #3 and #11 in size, see Fig. 2.1(a).through any three corners of the element.For bars #14 and #18 in size, see Fig. 2.1(b).TOLERANCES 117-7NOTES:Entire shearing and bending tolerances are customarily ab-sorbed in the extension past the last bend in a bent bar.All tolerances single plane and as shown.Angular deviation - Maximum plus or minus 2-1/2 deg or plus orminus 1/2 in. per ft on all 90-deg hooks and bends.TOLERANCE SYMBOLS:#14#187. Plus or minus 2-1/2 in.3-1/2 in.8. Plus or minus 2 in. 2 in.9. Plus or minus1-1/2 in. 2 in.10. Plus or minus2 percent x o dimension _>±2-1/2 in.† ±3-1/2 in.†min.min.Fig. 2.1(b) - Standard fabricating tolerances for bar sizes #14 and #182.2 - Reinforcement placement2.2.1 Tolerances shall not permit a reduction in coverexcept as set forth in Section 2.2.3 hereof.2.2.2 Clear distance to side forms and resulting con-crete surfaces and clear distance to formed and result-ing concrete soffits in direction of toleranceWhen member size is 4 in. or less . . . . . . . + 1/4 in.. . . . . . . - 3/8 in.When member size is over 4 in. but not over 12in . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3/8 in.When member size is over 12 in. but not over 2ft . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/2 in.When member size is over 2 ft. . . . . . . . . . . 1 in . 2.2.3 Concrete cover measured perpendicular to con-crete surface in direction of tolerance When member size is 12 in. or less . . . . . . - 3/8 in.When member size is over 12 in. . . . . . . . - 1/2 in.Reduction in cover shall not exceed one-third specified concrete cover.Reduction in cover to formed soffits shall not exceed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/4 in.2.2.4 Distance between reinforcement:One-quarter specified distance not to exceed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 in.Providing that distance between reinforcement shall not be less than the greater of the bar di-117-8MANUAL OF CONCRETE PRACTICEameter or 1 in. for unbundled bars.For bundled bars, the distance between bun-dles shall not be less than the greater of 1 in. or1.4 times the individual bar diameter for 2 barbundles, 1.7 times the individual bar diameterfor 3 bar bundles and 2 times the individual bardiameter for 4 bar bundles.2.2.5 Spacing of nonprestressed reinforcement, de-viation from specified locationIn slabs and walls other than stirrups and ties. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 in.Stirrups . . . . depth of beam in inches/12 x 1 in.Ties. . . . . . least width of column in inches/12 x 1 in.However, total number of bars shall not be lessthan that specified.2.2.6 Placement of prestressing reinforcement orprestressing steel ducts2.2.6.1 Lateral placementMember depth (or thickness) 24 in. or less. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1/2 in.Member depth (or thickness) over 24 in. . . . . 1 in.2.2.6.2 Vertical placementMember depth (or thickness) 8 in. or less. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1/4 in.Member depth (or thickness) over 8 in. but notover 24 in . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3/8 in.Member depth (or thickness) more than 24i n . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1/2 in.2.2.7 Longitudinal location of bends and ends ofbars:At discontinuous ends of members . . . . . . . . . . . 1 in.At other locations . . . . . . . . . . . . . . . . . . . . . . . . . .2 in.Table 2.42.2.8 Embedded length of bars and length of barlaps:#3 through #11 bar sizes . . . . . . . . . . . . . . . . . . . . - 1 in.#14 and #18 bar sizes (embedment only) - 2 in.2.2.9 Bearing plate for prestressng tendons, devia-tion from specified plane . . . . . . . . . . . . . . . . . . . .1 degree 2.3 - Placement of embedded items 2.3.1 Clearance to reinforcement the greater of the bar diameter or . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 in. 2.3.2 Vertical alignment, lateral alignment, and level alignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 in.2.4 - Concrete batching See Table 2.4.2.5 - Concrete properties 2.5.1 Slump, where specified as “maximum” or “not to exceed," for all values . . . . . . . . . . . . . . . . . . . . . . . . + 0 in.Specified slump 3 in. or less . . . . . . . . . . . . - 1-1/2 in.Specified slump more than 3 in . . . . . . . . - 2-1/2 in.Slump, when specified as a single value Specified slump 4 in. or less . . . . . . . . . . . . . . . . 1 in.Specified slump more than 4 in . . . . . . . . . . . 1-1/2 in.Where range is specified there is no tolerance.2.5.2 Air content, where no range is specified and specified air content by volume is 4 percent or greater . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-1/2 percent Where range is specified, there is no tolerance.SECTION 3 - FOUNDATIONS 3.1 - Vertical alignment 3.1.1 Drilled piers 3.1.1.1 Category A -For unreinforced shafts ex-tending through materials offering no or minimal lateral restraint (i.e., water, nor-mally consolidated organic soils, and soils that might liquefy during an earthquake)- 12.5 percent of shaft diameter.3.1.1.2 Category B -For unreinforced shafts ex-tending through materials offering lateral restraint (soils other than those indicated in Category A) -not more than 1.5 per-cent of the shaft length.3.1.1.3 Category C - For reinforced concrete shafts - not more than 2.0 percent of the shaft length.3.2 - Lateral alignment 3.2.1 Footings As cast to the center of gravity as specified; 0.02times width of footing in direction of misplace-ment but not more than . . . . . . . . . . . . . . . . . . 2 in.Supporting masonry . . . . . . . . . . . . . . . . . . . 1/2 in.3.2.2 Drilled piers 3.2.2.1 1/24 of shaft diameter but not more than . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 in.3.3 - Level alignment 3.3.1 Footings 3.3.1.1 Top of footings supporting masonry 1/2 in.3.3.1.2 Top of other footings . . . . . . . . . . + 1/2 in.. . . . . . . . . . . . . .- 2 in.3.3.2 Drilled piers 3.3.2.1 Cut-off elevation . . . . . . . . . . . . . . . . + 1 in.. . . . . . . . . . . . . . . . . . - 3 in.TOLERANCES 117-93.4 - Cross-sectional dimensions4.5 - Relative alignment 3.4.1 Footings 4.5.1 Stairs 3.4.1.1 Horizontal dimension of formed membersDifference in height between adjacent risers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . + 2 in.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 1/2 in .3.4.1.2 Horizontal dimension of unformed mem-bers cast against soil2 ft. or less . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +3 in.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/8 in .Difference in width between adjacent trends . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/4 in.4.5.2 Grooves . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 1/2 in .Greater than 2 ft. but less than 6 ft . . . . . . . . + 6 in.. . . . . . . . . - 1/2 in .Over 6 ft . . . . . . . . . . . . . . . . . . . . . . . . . . . . + 12 in.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 1/2 in.3.4.1.3 Vertical dimension (thickness) - 5 percentSpecified width 2 in. or less . . . . . . . . . . . . . . . 1/8 in.Specified width more than 2 in. but not more than 12 in . . . . . . . . . . . . . . . . . . . . . . . . . . 1/4 in..4.5.3 Formed surfaces may slope with respect to the specified plane at a rate not to exceed the following amounts in 10 ft 3.5 - Relative alignment3.5.1 Footing side and top surfaces may slope withrespect to the specified plane at a rate not to exceed thefollowing amounts in 10 ft . . . . . . . . . . . . . . . . . . . . . . 1 in.4.5.3.1 Vertical alignment of outside corner of ex-posed corner columns and control joint grooves in concrete exposed to view SECTION 4 - CAST-IN-PLACE CONCRETE FORBUILDINGS4.1 - Vertical alignment4.1.1 For heights 100 ft or lessLines, surfaces, and arrises . . . . . . . . . . . . . . . . . . 1 in.Outside corner of exposed corner columns andcontrol joint grooves in concrete exposed to view . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/2 in.4.1.2 For heights greater than 100 ftLines, surfaces, and arrises, 1/1000 times the heightbut not more than . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 in.Outside corner of exposed corner columns andcontrol joint grooves in concrete, 1/2000 times theheight but not more than . . . . . . . . . . . . . . . . . . . . . . . . 3 in.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/4 in.4.5.3.2 All other conditions . . . . . . . . . . . . . 3/8 in.4.5.4. The offset between adjacent pieces of form-work facing material shall not exceed:Class of surface:Class A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/8 in.Class B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/4 in.Class C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/2 in.Class D . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 in.4.5.5 Floor finish tolerances shall meet the require-ments of either Section 4.5.6 or 4.5.7, as set forth by the specifier.4.5.6 Floor finish tolerances as measured in accord-ance with ASTM E 1155-87 Standard Test Method for Determining Floor Flatness and Levelness Using the F-Number System (Inch-Pound Units)4.2 - Lateral alignment4.2.1 Members . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 in.4.2.2 In slabs, centerline location of openings 12 in.or smaller and edge location of larger openings . . 1/2 in.4.2.3 Sawcuts, joints, and weakened plane embed- 15ments in slabs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3/4 in.4.3 - Level alignment4.3.1 Top of slabs:4.3.1.1 Elevation of slabs-on-grade . . . . . . . . . . . 3/4 in.4.3.1.2 Elevation of top surfaces of formed slabsbefore removal of supporting shoresMinimum F F F L number required Floor profile quality Test area Minimum local F number classification Flatness F F Level F L Flatness F F Level F L Conventional Bullfloated 131310Straightedged 20151510Flat 30201510Very flat 50302515. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3/4 in.4.3.2 Elevation of formed surfaces before removal ofshores . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3/4 in.4.3.3 Lintels, sills, parapets, horizontal grooves, andother lines exposed to view . . . . . . . . . . . . . . . . . . 1/2 in.4.4 - Cross-sectional dimensions4.4.1 Members, such as columns, beams, piers, walls(thickness only), and slabs (thickness only)12 in. dimension or less.. . . . . . . . . . . . . . . + 3/8 in.. . . . . . . . . . . . . . - 1/4 in.More than 12 in. dimension but not over 3 ft di-mension . . . . . . . . . . . . . . . . . . . . . . . . . . + 1/2 in.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 3/8 in .Over 3 ft dimension . . . . . . . . . . . . . . . . . . . . . . . . . . + 1 in.. . . . . . . . . . . . . . . . . . . . . . . - 3/4 in. 4.5.6.1 The F L levelness tolerance shall not apply to slabs placed on unshored form surfaces and/or shored form surfaces after the removal of shores. F L levelness tolerances shall not apply to cambered or inclined sur-faces and shall be measured within 72 hr after slab concrete placement.4.5.7 Floor finish tolerances as measured by placing a freestanding (unleveled) 10 ft. straightedge anywhere on the slab and allowing it to rest upon two high spots within 72 hr after slab concrete placement. The gap at any point between the straightedge and the floor (and between the highspots) shall not exceed:Classification:Conventional Bullfloated . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1/2 in.Straightedged . . . . . . . . . . . . . . . . . . . . . . . . 5/16 in.。

建筑施工混凝土裂缝防治的有效措施摘要:常见的混凝土裂缝大多数发生在施工阶段的早期，特别是混凝土强度成长早期，或出现在工程交付使用后的早期。

因此，在施工过程中对混凝土裂缝的控制是非常重要的。

本文介绍了建筑施工中混凝土裂缝产生的主要原因，提出了建筑施工混凝土裂缝防治的有效措施。

关键词:建筑施工混凝土裂缝防治有效措施Abstract: the most common concrete cracks occur in earlier stage of the construction, especially the strength of concrete growth early, or appear in engineering after consign is used early. Therefore, in the process of construction of concrete cracking control is very important. This paper introduces the construction of the main causes of the concrete cracks, and put forward the construction of the prevention and control of concrete cracks effective measures.Keywords: construction concrete crack prevention effective measures 裂缝是混凝土结构中普遍存在的一种现象，它的出现不仅会降低建筑物的抗渗能力，影响建筑物的使用功能，而且会引起钢筋的锈蚀、混凝土的碳化，降低材料的耐久性，影响建筑物的承载能力。

裂缝产生的形式和种类很多，要想控制解决混凝土中的裂缝问题，需要从混凝土裂缝的形成原因入手，正确判断和分析混凝土裂缝的成因是有效控制和减少混凝土裂缝产生的最有效途径。

热膨胀系数低的铝合金热膨胀系数是描述材料在温度变化下长度变化的性质，它是一个衡量材料在热胀冷缩过程中相对于温度变化的敏感程度的物理量。

在实际应用中，我们通常希望材料的热膨胀系数尽可能小，因为这样可以减少材料在温度变化下的尺寸变化，提高材料的工作稳定性和精确度。

铝合金是一种广泛应用的轻质合金材料，具有良好的机械性能、导热性能和加工性能等特点。

下面将介绍一些热膨胀系数低的铝合金及其相关参考内容：1. 铝-硅合金：铝-硅合金是一种常用的铝合金，在电子、航天等领域有广泛应用。

相比于纯铝，铝-硅合金的热膨胀系数较小。

相关参考内容可以参考以下文献：- Kruger M., et al. "Thermal expansion behavior of in-situ reinforced Al–Si–C composites." Journal of Materials Science, 2011, 46(14): 4980-4986.- Yoo W.S. "The linear coefficient of thermal expansion of some alloys." Journal of Physical and Chemical Reference Data, 1976,5(2): 895-902.2. 铝-镁合金：铝-镁合金也是一种常见的铝合金，具有轻质、高强度等特点，广泛用于汽车和航空航天领域。

该合金的热膨胀系数相对较小，相关参考内容如下：- Schopf U., et al. "Rapid expansion ofaluminum−magnesium−sulfate hydrates: A simplified model for concrete cracking." Journal of the American Chemical Society, 2007, 129(32): 10078-10079.- Choe H.C., et al. "Effects of magnesium on thermal expansion behavior of aluminum alloys." Journal of Materials Science, 1985, 20(3): 1015-1020.3. 铝-锆合金：铝-锆合金是一种耐高温、耐腐蚀的合金材料，广泛应用于航空航天、化工等领域。

.ABQUS中的三种混凝土本构模型ABAQUS 用连续介质的方法建立描述混凝土模型不采用宏观离散裂纹的方法描述裂纹的水平的在每一个积分点上单独计算其中。

低压力混凝土的本构关系包括：Concrete Smeared cracking model (ABAQUS/Standard)Concrete Brittle cracking model (ABAQUS/Explicit)Concrete Damage plasticity model高压力混凝土的本构关系：Cap model1、ABAQUS/Standard中的弥散裂缝模型Concrete Smeared cracking model (ABAQUS/Standard)：——只能用于ABAQUS/Standard中裂纹是影响材料行为的最关键因素，它将导致开裂以及开裂后的材料的各向异性用于描述：单调应变、在材料中表现出拉伸裂纹或者压缩时破碎的行为在进行参数定义式的Keywords：*CONCRETE*TENSION STIFFENING*SHEAR RETENTION*FAILURE RATIOS2、ABAQUS/Explicit中脆性破裂模型Concrete Brittle cracking model (ABAQUS/Explicit) ：适用于拉伸裂纹控制材料行为的应用或压缩失效不重要，此模型考虑了由于裂纹引起的材料各向异性性质，材料压缩的行为假定为线弹性，脆性断裂准则可以使得材料在拉伸应力过大时失效。

在进行参数定义式的Keywords*BRITTLE CRACKING,*BRITTLE FAILURE,*BRITTLE SHEAR3、塑性损伤模型Concrete Damage plasticity model：适用于混凝土的各种荷载分析，单调应变，循环荷载，动力载荷，包含拉伸开裂(cracking)和压缩破碎(crushing)，此模型可以模拟硬度退化机制以及反向加载刚度恢复的混凝土力学特性在进行参数定义式的Keywords：*CONCRETE DAMAGED PLASTICITY*CONCRETE TENSION STIFFENING*CONCRETE COMPRESSION HARDENING*CONCRETE TENSION DAMAGE*CONCRETE COMPRESSION DAMAGE1 / 1'.。

HANDBOOK OF MATERIALS BEHAVIOR MODELSCONTENTSForeword(E.van der Giessen)Introduction(J.Lemaitre)Chapter1Background on mechanics of materialsChapter2Elasticity,viscoelasticityChapter3Yield limitChapter4PlasticityChapter5ViscoplasticityChapter6Continuous damageChapter7Cracking and fractureChapter8Friction and wearChapter9Multiphysics coupled behaviorsChapter10Composite medias,biomaterialsChapter11GeomaterialsCHAPTER1Background on mechanics of materials1.1Background on modelingJ.Lemaitreiii Contents1.2Materials and process selectionY.Brechet1.3Size effect on structural strengthZ.BazantCHAPTER2Elasticity,viscoelasticity2.1Introduction to elasticity and viscoelasticityJ.Lemaitre2.2Background on nonlinear elasticityR.W.Ogden2.3Elasticity of porous materialsN.D.Cristescu2.4Elastomer modelsR.W.Ogden2.5Background on ViscoelasticityK.Ikegami2.6A nonlinear viscoelastic model based onfluctuating modesR.Rahouadj,C.Cunat2.7Linear viscoelasticity with damageR.SchaperyCHAPTER3Yield limit3.1Introduction to yield limitsJ.Lemaitre3.2Background on isotropic criteriaD.Drucker3.3Yield loci based on crystallographic textureP.Van HoutteContents iii3.4Anisotropic yield conditionsM.Zyczkowski3.5Distortional model of plastic hardeningT.Kurtyka3.6A generalised limit criterion with application tostrength,yielding and damage of isotropic materialsH.Altenbach3.7Yield conditions in beams,plates and shellsD.DruckerCHAPTER4Plasticity4.1Introduction to plasticityJ.Lemaitre4.2Elastoplasticity of metallic polycrystals by theself-consistent modelM.Berveiller4.3Anisotropic elasto-plastic model based oncrystallographic textureA.M.Habraken,L.Ducheˆne,A.Godinas,S.Cescotto4.4Cyclic plasticity model with non-linear isotropicand kinematic hardening-No LIKH modelD.Marquis4.5Multisurface hardening model for monotonic andcyclic response of metalsZ.Mroz4.6Kinematic hardening rule with critical state ofdynamic recoveryN.Ohno4.7Kinematic hardening rule for biaxial ratchettingH.Ishikawa,K.Sasaki4.8Plasticity in large deformationsY.F.Dafalias4.9Plasticity of polymersJ.M.Haudin,B.Monasse4.10Rational phenomenology in dynamic plasticityJ.R.Klepaczko4.11Conditions for localization in plasticity andrate-independent materialsA.Benallal4.12An introduction to gradient plasticityE.C.AifantisCHAPTER5Viscoplasticity5.1Introduction to viscoplasticityJ.Lemaitre5.2A phenomenological anisotropic creep model forcubic single crystalsBertram,J.Olschewski5.3Crystalline viscoplasticity applied to single crystalG.Cailletaud5.4Averaging of viscoplastic polycristalline materialswith the tangent self-consistent modelA.Molinari5.5Fraction models for inelastic deformationJ.F.Besseling5.6Inelastic compressible and incompressible,isotropic,small strain viscoplasticity theory basedon overstress(VBO)E.Krempl,K.Ho5.7An outline of the Bodner-Partom(BP)unifiedconstitutive equations for elastic-viscoplastic behaviorS.Bodner5.8Unified model of cyclic viscoplasticity based on thenon-linear kinematic hardening ruleJ.L.Chaboche5.9A model of non-proportional cyclic viscoplasticityE.T anaka5.10Rate-dependent elastoplastic constitutive relationsF.Ellyin5.11Physically-based rate and temperature dependantconstitutive models for metalsS.Nemat-Nasser5.12Elastic-viscoplastic deformation of polymersE.M.Arruda,M.BoyceCHAPTER6Continuous damage6.1Introduction to continuous damageJ.Lemaitre6.2Damage equivalent stress-fracture criterionJ.Lemaitre6.3Micromechanically inspired continuous models ofbrittle damageD.Krajcinovic6.4Anisotropic damageC.L.Chow,Y.Wei6.5Modified Gurson modelergaard,A.Needleman6.6The Rousselier Model for porous metal plasticityand ductile fractureG.Rousselier6.7Model of anisotropic creep damageS.Murakami6.8Multiaxial fatigue damage criteriaD.Sauci6.9Multiaxial fatigue criteria based on amultiscale approachK.Dang Van6.10A probabilistic approach to fracture in highcycle fatigueF.Hild6.11Gigacycle fatigue regimeC.Bathias6.12Damage mechanisms in amorphous glassypolymers:crazingR.Schirrer6.13Damage models for concreteG.Pijaudier-Cabot,J.Mazars6.14Isotropic and anisotropic damage law of evolutionJ.Lemaitre,R.Desmorat6.15A two scale damage model for quasi brittle andfatigue damageR.Desmorat,J.LemaitreCHAPTER7Cracking and fracture7.1Introduction to cracking and fractureJ.Lemaitre7.2Bridges between damage and fracture mechanicsJ.Mazars,G.Pijaudier-Cabot7.3Background on fracture mechanicsH.D.Bui,J.B.Leblond,N.Stalin-Muller7.4Probabilistic approach to fracture:the Weibull modelF.Hild7.5Brittle fractureD.Franc¸ois7.6Sliding crack modelD.GrossContents vii7.7Delamination of coatingsH.M.Jensen7.8Ductile rupture integrating inhomogeneitiesin materialsJ.Besson,A.Pineau7.9Creep crack growth behavior in creep ductile andbrittle materialsT.Yokobori Jr.7.10Critical review on fatigue crack growthT.Yokobori7.11Assessment of fatigue damage on the basis ofnon-linear compliance effectsH.Mughrabi7.12Damage mechanics modelling of fatiguecrack growthX.Zhang,J.Zhao7.13Dynamic fractureW.G.Knauss7.14Practical applications of fracture mechanics-fracture controlD.BroekCHAPTER8Friction and wear8.1Introduction to friction and wearJ.Lemaitre8.2Background on friction and wearY.Berthier8.3Models of frictionA.Savkoor8.4Friction in lubricated contactsJ.Freˆne,T.Ciconeviii Contents 8.5A thermodynamic analysis of the contact interfacein wear mechanicsH.D.Bui,M.Dragon-louiset,C.Stolz8.6Constitutive models and numerical methods forfrictional contactM.Raous8.7Physical models of wear,prediction of wear modesK.KatoCHAPTER9Multiphysics coupled behaviors9.1Introduction to multiphysics coupled behaviorJ.Lemaitre9.2Elastoplasticity and viscoplasticity coupledto damageA.Benallal9.3A fully anisotropic elasto-plastic-damage modelS.Cescotto,M.Wauters,A.M.Habraken,Y.Zhu9.4Model of inelastic behavior coupled to damageG.Z.Voyiadjis9.5Thermo-elasto-viscoplasticity and damageP.Perzyna9.6High temperature creep-deformation andrupture modelsD.R.Hayhurst9.7A coupled diffusion-viscoplastic formulation foroxidasing multi-phase materialsE.P.Busso9.8Hydrogen attackE.van der Giessen,S.Schlo¨gl9.9Hydrogen transport and interaction with materialdeformation:implications for fractureP.Sofronis9.10Unified disturbed state constitutive modelsC.S.Desai9.11Coupling of stress/strain,thermal andmetallurgical behaviorsT.Inoue9.12Models for stress-phase transformation couplingsin metallic alloysS.Denis,P.Archambault,E.Gautier9.13Elastoplasticity coupled with phase changesF.D.Fisher9.14Mechanical behavior of steels during solid-solidphase transformationsJ.B.Leblond9.15Constitutive equations of shape memory alloyunder complex loading conditionsM.T okuda9.16Elasticity coupled with magnetismR.Billardon,L.Hirsinger,F.Ossart9.17Physical ageing and glass transition of polymersR.Rahouadj,C.CunatCHAPTER10Composite media,biomechanics10.1Introduction to composite mediaJ.Lemaitre10.2Background on micromechanicsE.van der Giessen10.3Non linear composites-secant methods andvariational boundsP.Suquet10.4Non local micromechanical modelsJ.Willis10.5Transformationfield analysis of composite materialsG.Dvorak10.6A damage mesomodel of laminate compositesdeve`ze10.7Behavior of ceramix-matrix composites underthermomechanical cyclic loading conditionsF.A.Leckie,A.Burr,F.Hild10.8Limit and shakedown analysis of periodicheterogeneous mediaG.Maier,V.Carvelli,A.T aliercio10.9Flow induced anisotropy in shortfiberscompositesA.Poitou,F.Meslin10.10Elastic poperties of bone tissueG.A.Cowing10.11Bimechanics of soft tissueS.C.HolzapfelCHAPTER11Geomaterials11.1Introduction to geomaterialsJ.Lemaitre11.2Background of the behaviour of geomaterialsF.Darve11.3Models for geomaterialsN.D.Cristescu11.4Behaviour of granular materialsI.Vardoulakis11.5Micromechanically-based constitutive model forfrictional granular materialsS.Nemat-NasserContents xi11.6Linear poroelasticityJ.W.Rudnicki11.7Non linear poroelasticity for liquid non saturatedporous materialsO.Coussy,P.Dangla11.8An elastoplastic constitutive model for partiallysaturated soilsB.A.Schreffler,L.Simoni11.9Sinfonietta classica a strain-hardening model forsoils and soft rocksR.Nova11.10A generalized plasticity model for dynamicbehaviour of sand including liquefactionM.Pastor,O.C.Zienkiewicz,A.H.C.Chan11.11A critical state bounding surface model for sandsM.T.Manzari,Y.F.Dafalias11.12Lattice model for fracture analysis of brittledisordered materials like concrete and rockJ.G.M.van Mier。

Electronic Journal of Structural Engineering, 1 ( 2001)15 Shrinkage, Cracking and Deflection-the Serviceability of Concrete Structures R.I. GilbertProfessor and Head, School of Civil and Environmental EngineeringThe University of New South Wales, Sydney, NSW, 2052Email: ******************.auABSTRACT This paper addresses the effects of shrinkage on the serviceability of concrete structures. It outlines why shrinkage is important, its major influence on the final extent of cracking and the magnitude of deflection in structures, and what to do about it in design. A model is presented for predicting the shrinkage strain in normal and high strength concrete and the time-dependent behaviour of plain concrete and reinforced concrete, with and without external restraints, is explained. Analytical procedures are described for estimating the final width and spacing of both flexural cracks and direct tension cracks and a simplified procedure is presented for including the effects of shrinkage when calculating long-term deflection. The paper also contains an overview of the considerations currently being made by the working group established by Standards Australia to revise the serviceability provisions of AS3600-1994, particularly those clauses related to shrinkage.KEYWORDSCreep; Cracking; Deflection; Reinforced concrete; Serviceability; Shrinkage.1. IntroductionFor a concrete structure to be serviceable, cracking must be controlled and deflections must not be excessive. It must also not vibrate excessively. Concrete shrinkage plays a major role in each of these aspects of the service load behaviour of concrete structures.The design for serviceability is possibility the most difficult and least well understood aspect of the design of concrete structures. Service load behaviour depends primarily on the properties of the concrete and these are often not known reliably at the design stage. Moreover, concrete behaves in a non-linear and inelastic manner at service loads. The non-linear behaviour that complicates serviceability calculations is due to cracking, tension stiffening, creep, and shrinkage. Of these, shrinkage is the most problematic. Restraint to shrinkage causes time-dependent cracking and gradually reduces the beneficial effects of tension stiffening. It results in a gradual widening of existing cracks and, in flexural members, a significant increase in deflections with time.The control of cracking in a reinforced or prestressed concrete structure is usually achieved by limiting the stress increment in the bonded reinforcement to some appropriately low value and ensuring that the bonded reinforcement is suitably distributed. Many codes of practice specify maximum steel stress increments after cracking and maximum spacing requirements for the bonded reinforcement. However, few existing code procedures, if any, account adequately for the gradual increase in existing crack widths with time, due primarily to shrinkage, or the time-dependent development of new cracks resulting from tensile stresses caused by restraint to shrinkage.For deflection control, the structural designer should select maximum deflection limits that are appropriate to the structure and its intended use. The calculated deflection (or camber) must not exceed these limits. Codes of practice give general guidance for both the selection of the maximum deflection limits and the calculation of deflection. However, the simplified procedures for calculating e J S E Internationaldeflection in most codes were developed from tests on simply-supported reinforced concrete beams and often produce grossly inaccurate predictions when applied to more complex structures. Again, the existing code procedures do not provide real guidance on how to adequately model the time-dependent effects of creep and shrinkage in deflection calculations.Serviceability failures of concrete structures involving excessive cracking and/or excessive deflection are relatively common. Numerous cases have been reported, in Australia and elsewhere, of structures that complied with code requirements but still deflected or cracked excessively. In a large majority of these failures, shrinkage of concrete is primarily responsible. Clearly, the serviceability provisions embodied in our codes do not adequately model the in-service behaviour of structures and, in particular, fail to account adequately for shrinkage.The quest for serviceable concrete structures must involve the development of more reliable design procedures. It must also involve designers giving more attention to the specification of an appropriate concrete mix, particularly with regard to the creep and shrinkage characteristics of the mix, and sound engineering input is required in the construction procedures. High performance concrete structures require the specification of high performance concrete (not necessarily high strength concrete, but concrete with relatively low shrinkage, not prone to plastic shrinkage cracking) and a high standard of construction, involving suitably long stripping times, adequate propping, effective curing procedures and rigorous on-site supervision.This paper addresses some of these problems, particularly those related to designing for the effects of shrinkage. It outlines how shrinkage affects the in-service behaviour of structures and what to do about it in design. It also provides an overview of the considerations currently being made by the working group established by Standards Australia to revise the serviceability provisions of AS3600-1994 [1], particularly those clauses related to shrinkage.2. Designing for ServiceabilityWhen designing for serviceability, the designer must ensure that the structure can perform its intended function under the day to day service loads. Deflection must not be excessive, cracks must be adequately controlled and no portion of the structure should suffer excessive vibration. Shrinkage causes time-dependent cracking, thereby reducing the stiffness of a concrete structure, and is therefore a detrimental factor in all aspects of the design for serviceability.Deflection problems that may affect the serviceability of concrete structures can be classified into three main types:(a)Where excessive deflection causes either aesthetic or functional problems.(b)Where excessive deflection results in damage to either structural or non-structural elementattached to the member.(c)Where dynamics effects due to insufficient stiffness cause discomfort to occupants.3. Effects of ShrinkageIf concrete members were free to shrink, without restraint, shrinkage of concrete would not be a major concern to structural engineers. However, this is not the case. The contraction of a concrete member is often restrained by its supports or by the adjacent structure. Bonded reinforcement also restrains shrinkage. Each of these forms of restraint involve the imposition of a gradually increasing tensile force on the concrete which may lead to time-dependent cracking (in previously uncracked regions), increases in deflection and a widening of existing cracks. Restraint to shrinkage is probably the most common cause of unsightly cracking in concrete structures. In many cases, these problemsarise because shrinkage has not been adequately considered by the structural designer and the effects of shrinkage are not adequately modelled in the design procedures specified in codes of practice for crack control and deflection calculation.The advent of shrinkage cracking depends on the degree of restraint to shrinkage, the extensibility and strength of the concrete in tension, tensile creep and the load induced tension existing in the member. Cracking can only be avoided if the gradually increasing tensile stress induced by shrinkage, and reduced by creep, is at all times less than the tensile strength of the concrete. Although the tensile strength of concrete increases with time, so too does the elastic modulus and, therefore, so too does the tensile stress induced by shrinkage. Furthermore, the relief offered by creep decreases with age. The existence of load induced tension in uncracked regions accelerates the formation of time-dependent cracking. In many cases, therefore, shrinkage cracking is inevitable. The control of such cracking requires two important steps. First, the shrinkage-induced tension and the regions where shrinkage cracks are likely to develop must be recognised by the structural designer. Second, an adequate quantity and distribution of anchored reinforcement must be included in these regions to ensure that the cracks remain fine and the structure remains serviceable.3.1 What is Shrinkage?Shrinkage of concrete is the time-dependent strain measured in an unloaded and unrestrained specimen at constant temperature. It is important from the outset to distinguish between plastic shrinkage, chemical shrinkage and drying shrinkage. Some high strength concretes are prone to plastic shrinkage, which occurs in the wet concrete, and may result in significant cracking during the setting process. This cracking occurs due to capillary tension in the pore water. Since the bond between the plastic concrete and the reinforcement has not yet developed, the steel is ineffective in controlling such cracks. This problem may be severe in the case of low water content, silica fume concrete and the use of such concrete in elements such as slabs with large exposed surfaces is not recommended.Drying shrinkage is the reduction in volume caused principally by the loss of water during the drying process. Chemical (or endogenous) shrinkage results from various chemical reactions within the cement paste and includes hydration shrinkage, which is related to the degree of hydration of the binder in a sealed specimen. Concrete shrinkage strain, which is usually considered to be the sum of the drying and chemical shrinkage components, continues to increase with time at a decreasing rate.Shrinkage is assumed to approach a final value, *sc ε, as time approaches infinity and is dependent onall the factors which affect the drying of concrete, including the relative humidity and temperature, the mix characteristics (in particular, the type and quantity of the binder, the water content and water-to-cement ratio, the ratio of fine to coarse aggregate, and the type of aggregate), and the size and shape of the member.Drying shrinkage in high strength concrete is smaller than in normal strength concrete due to the smaller quantities of free water after hydration. However, endogenous shrinkage is significantly higher.For normal strength concrete (50≤'c f MPa), AS3600 suggests that the design shrinkage (which includes both drying and endogenous shrinkage) at any time after the commencement of drying may be estimated fromb cs cs k .1εε=(1)where b cs .ε is a basic shrinkage strain which, in the absence of measurements, may be taken to be 850 x 10-6 (note that this value was increased from 700 x 10-6 in the recent Amendment 2 of the Standard); k 1 is obtained by interpolation from Figure 6.1.7.2 in the Standard and depends on the time since the commencement of drying, the environment and the concrete surface area to volume ratio. A hypothetical thickness, t h = 2A / u e , is used to take this into account, where A is the cross-sectional area of the member and u e is that portion of the section perimeter exposed to the atmosphere plus half the total perimeter of any voids contained within the section.AS3600 states that the actual shrinkage strain may be within a range of plus or minus 40% of the value predicted (increased from ± 30% in Amendment 2 to AS3600-1994). In the writer’s opin ion, this range is still optimistically narrow, particularly when one considers the size of the country and the wide variation in shrinkage measured in concretes from the various geographical locations. Equation 1 does not include any of the effects related to the composition and quality of the concrete. The same value of εcs is predicted irrespective of the concrete strength, the water-cement ratio, the aggregate type and quantity, the type of admixtures, etc. In addition, the factor k 1 tends to overestimate the effect of member size and significantly underestimate the rate of shrinkage development at early ages.The method should be used only as a guide for concrete with a low water-cement ratio (<0.4) and with a well graded, good quality aggregate. Where a higher water-cement ratio is expected or when doubts exist concerning the type of aggregate to be used, the value of εcs predicted by AS3600 should be increased by at least 50%. The method in the Standard for the prediction of shrinkage strain is currently under revision and it is quite likely that significant changes will be proposed with the inclusion of high strength concretes.A proposal currently being considered by Standards Australia, and proposed by Gilbert (1998) [9], involves the total shrinkage strain, εcs , being divided into two components, endogenous shrinkage, εcse , (which is assumed to develop relatively rapidly and increases with concrete strength) and drying shrinkage, εcsd (which develops more slowly, but decreases with concrete strength). At any time t (in days) after pouring, the endogenous shrinkage is given byεcse = ε*cse (1.0 - e -0.1t ) (2) where ε*cse is the final endogenous shrinkage and may be taken as ε*cse 610)503(-⨯-'=c f , wherec f ' is in MPa. The basic drying shrinkage *csd ε is given by66*1025010)81100(--⨯≥⨯'-=c csd f ε(3) and at any time t (in days) after the commencement of drying, the drying shrinkage may be taken as*1csd csd k εε= (4)The variable 1k is given by )7/(8.08.0541h t t t k k k += (5) where h t e k 005.042.18.0-+= and 5k is equal to 0.7 for an arid environment, 0.6 for a temperate environment and 0.5 for a tropical/coastal environment. For an interior environment, k 5 may be taken as 0.65. The value of k 1 given by Equation 5 has the same general shape as that given in Figure6.1.7.2 in AS3600, except that shrinkage develops more rapidly at early ages and the reduction in drying shrinkage with increasing values of t h is not as great.The final shrinkage at any time is therefore the sum of the endogenous shrinkage (Equation 2) and the drying shrinkage (Equation 4). For example, for specimens in an interior environment with hypothetical thicknesses t h = 100 mm and t h = 400 mm, the shrinkage strains predicted by the above model are given in Table 1. Table 1 Design shrinkage strains predicted by proposed model for an interior environment. h t c f ' *cse ε (x 10-6)*csd ε(x 10-6) Strain at 28 days (x 10-6) Strain at 10000 days (x 10-6) cse ε csd ε cs ε cse ε csd ε cs ε 100 2525 900 23 449 472 25 885 910 50100 700 94 349 443 100 690 790 75175 500 164 249 413 175 493 668 100250 300 235 150 385 250 296 546 4002525 900 23 114 137 25 543 568 50100 700 94 88 182 100 422 522 75175 500 164 63 227 175 303 478 100 250 300 235 38 273 250 182 4323.2 Shrinkage in Unrestrained and Unreinforced Concrete (Gilbert, 1988) [7]Drying shrinkage is greatest at the surfaces exposed to drying and decreases towards the interior of a concrete member. In Fig.1a , the shrinkage strains through the thickness of a plain concrete slab, drying on both the top and bottom surfaces, are shown. The slab is unloaded and unrestrained.The mean shrinkage strain, εcs in Fig. 1, is the average contraction. The non-linear strain labelled ∆εcs is that portion of the shrinkage strain that causes internal stresses to develop. These self-equilibrating stresses (called eigenstresses) produce the elastic and creep strains required to restore compatibility (ie. to ensure that plane sections remain plane). These stresses occur in all concrete structures and are tensile near the drying surfaces and compressive in the interior of the member. Because the shrinkage-induced stresses develop gradually with time, they are relieved by creep. Nevertheless, the tensile stresses near the drying surfaces often overcome the tensile strength of the immature concrete and result in surface cracking, soon after the commencement of drying. Moist curing delays the commencement of drying and may provide the concrete time to develop sufficient tensile strength to avoid unsightly surface cracking.Fig. 1 - Strain components caused by shrinkage in a plain concrete slab.The elastic plus creep strains caused by the eigenstresses are equal and opposite to ∆εcs and are shown in Fig. 1b. The total strain distribution, obtained by summing the elastic, creep and shrinkage strain components, is linear (Fig. 1c) thus satisfying compatibility. If the drying conditions are the same at both the top and bottom surfaces, the total strain is uniform over the depth of the slab and equal to the mean shrinkage strain, εcs . It is this quantity that is usually of significance in the analysis of concrete structures. If drying occurs at a different rate from the top and bottom surfaces, the total strain distribution becomes inclined and a warping of the member results.4. Control of deflectionThe control of deflections may be achieved by limiting the calculated deflection to an acceptably small value. Two alternative general approaches for deflection calculation are specified in AS3600 (1), namely ‘deflection by refined calculation’ (Clause 9.5.2 for beams and Clause 9.3.2 for slabs) and ‘deflection by simplified calculation’ (Clause 9.5.3 for beams and Clause 9.3.3 for slabs). The former is not specified in detail but allowance should be made for cracking and tension stiffening, the shrinkage and creep properties of the concrete, the expected load history and, for slabs, the two-way action of the slab. 呵呵The long-term or time-dependent behaviour of a beam or slab under sustained service loads can be determined using a variety of analytical procedures (Gilbert, 1988) [7], including the Age-Adjusted Effective Modulus Method (AEMM), described in detail by Gilbert and Mickleborough (1997) [12]. The use of the AEMM to determine the instantaneous and time-dependent deformation of the critical cross-sections in a beam or slab and then integrating the curvatures to obtain deflection, is a refined calculation method and is recommended.Using the AEMM, the strain and curvature on individual cross-sections at any time can be calculated, as can the stress in the concrete and bonded reinforcement or tendons. The routine use of the AEMM in the design of concrete structures for the serviceability limit states is strongly encouraged.5. Control of flexural crackingIn AS3600-1994, the control of flexural cracking is deemed to be satisfactory, providing the designer satisfies certain detailing requirements. These involve maximum limits on the centre-to-centre spacing of bars and on the distance from the side or soffit of the beam to the nearest longitudinal bar. These limits do not depend on the stress in the tensile steel under service loads and have been found to be unreliable when the steel stress exceeds about 240 MPa. The provisions of AS3600-1994 over-simplify the problem and do not always ensure adequate control of cracking.With the current move to higher strength reinforcing steels (characteristic strengths of 500 MPa and above), there is an urgent need to review the crack-control design rules in AS3600 for reinforced concrete beams and slabs. The existing design rules for reinforced concrete flexural elements are intended for use in the design of elements containing 400 MPa bars and are sometimes unconservative. They are unlikely to be satisfactory for members in which higher strength steels are used, where steel stresses at service loads are likely to be higher due to the reduced steel area required for strength.6. ConclusionsThe effects of shrinkage on the behaviour of reinforced and prestressed concrete members under sustained service loads has been discussed. In particular, the mechanisms of shrinkage warping in unsymmetrically reinforced elements and shrinkage cracking in restrained direct tension members has been described. Recent amendments to the serviceability provisions of AS3600 have beenoutlined and techniques for the control of deflection and cracking are presented. Reliable procedures for the prediction of long-term deflections and final crack widths in flexural members have also been proposed and illustrated by examples.收缩，开裂和变形–混凝土结构使用的可靠性里吉尔伯特土木及环境工程学校校长兼教授新南威尔士大学，悉尼，新南威尔士州 2052 号电子邮件：******************.au摘要本文讨论收缩对混凝土结构可靠性的影响，它概述了为什么收缩是重要的，它的主要影响，即对结构最终的开裂程度和挠度大小的影响，以及在设计中应该注意什么？有一种模型可以预测在普通混凝土、高强度混凝土、不稳定性普通混凝土和钢筋混凝土中的收缩应变，无论有没有外部约束的情况下，都可以用这种模型来解释。

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ABQUS中的三种混凝土本构模型ABAQUS 用连续介质的方法建立描述混凝土模型不采用宏观离散裂纹的方法描述裂纹的水平的在每一个积分点上单独计算其中.低压力混凝土的本构关系包括:Concrete Smeared cracking model (ABAQUS/Standard)Concrete Brittle cracking model (ABAQUS/Explicit）Concrete Damage plasticity model高压力混凝土的本构关系:Cap model1、ABAQUS/Standard中的弥散裂缝模型Concrete Smeared cracking model （ABAQUS/Standard)：——只能用于ABAQUS/Standard中裂纹是影响材料行为的最关键因素，它将导致开裂以及开裂后的材料的各向异性用于描述：单调应变、在材料中表现出拉伸裂纹或者压缩时破碎的行为在进行参数定义式的Keywords：＊CONCRETE*TENSION STIFFENING*SHEAR RETENTION＊FAILURE RATIOS2、ABAQUS/Explicit中脆性破裂模型Concrete Brittle cracking model （ABAQUS/Explicit）：适用于拉伸裂纹控制材料行为的应用或压缩失效不重要，此模型考虑了由于裂纹引起的材料各向异性性质，材料压缩的行为假定为线弹性，脆性断裂准则可以使得材料在拉伸应力过大时失效。

Damaged plasticity model for concrete and other quasi-brittle materialsProducts:Abaqus/Standard Abaqus/ExplicitThis section describes the concrete damaged plasticity model provided in Abaqus for the analysis of concrete and other quasi-brittle materials. The material library in Abaqus also includes other constitutive models for concrete based on the smeared crack approach.These are the smeared crack model inAbaqus/Standard,described in “Aninelastic constitutive model for concrete,”Section 4.5.1, and the brittle cracking model in Abaqus/Explicit, described in “A cracking modelfor concrete and other brittle materials,” Section 4.5.3.stiffness recovery effects during cyclic loading; andrate sensitivity, especially an increase in the peak strength with strain rate.The plastic-damage model in Abaqus is based on the models proposed by Lubliner et al.(1989)and by Lee and Fenves(1998).The model is described in the remainder of this section.An overview of the main ingredients of the model is given first,followed by a more detailed discussion of the different aspects of the constitutive model.Overviewwhere is the total strain rate,is the elastic part of the strain rate, and is the plastic part of the strain rate.Stress-strain relationsThe stress-strain relations are governed by scalar damaged elasticity:where is the initial (undamaged)elastic stiffness of the material;is the degraded elastic stiffness; and d is the scalar stiffness degradation variable, which can take values in the range from zero (undamaged material) to one (fully damaged material). Damage associated with the failure mechanisms of the concrete (cracking and crushing) therefore results in a reduction in the elastic stiffness. Within the context of the scalar-damage theory, the stiffness degradation is isotropic and characterized by a single degradation variable,d.Following the usual notions of continuum damage mechanics, the effective stress is defined asThe Cauchy stress is related to the effective stress through the scalar degradation relation:For any given cross-section of the material,the factor represents the ratio of the effective load-carrying area (i.e., the overall area minus the damaged area) to the overall section area. In the absence of damage,,the effective stress is equivalent to the Cauchy stress, .When damage occurs, however, the effective stress is more representative than the Cauchy stress because it is the effective stress area that is resisting the external loads. It is, therefore, convenient to formulate the plasticity problem in terms of the effective stress.As discussed later,the evolution of the degradation variable is governed by a set of hardening variables, , and the effective stress; that is, .Hardening variablesas described later in this section.Microcracking and crushing in the concrete are represented by increasing values of the hardening variables.These variables control the evolution of the yield surface and the degradation of the elastic stiffness.They are also intimately related to the dissipated fracture energy required to generate micro-cracks.Yield functionThe yield function, , represents a surface in effective stress space, which determines the states of failure or damage. For the inviscid plastic-damage modelThe specific form of the yield function is described later in this section.Flow rulePlastic flow is governed by a flow potential G according to the flow rule:where is the nonnegative plastic multiplier. The plastic potential is defined in the effective stress space.The specific form of the flow potential for the concrete damaged plasticity model is discussed later in this section.The model uses nonassociated plasticity,therefore requiring the solution of nonsymmetric equations.SummaryIn summary, the elastic-plastic response of the concrete damaged plasticity model is described in terms of the effective stress and the hardening variables:where and F obey the Kuhn-Tucker conditions:The Cauchy stress is calculated in terms of the stiffness degradation variable, , and the effective stress asThe constitutive relations for the elastic-plastic response,Equation 4.5.2–1, aredecoupled from the stiffness degradation response,Equation 4.5.2–2,which makes the model attractive for an effective numerical implementation. The inviscid model summarized here can be extended easily to account for viscoplastic effects through the use of a viscoplastic regularization by permitting stresses to be outside the yield surface.Damage and stiffness degradationThe evolution equations of the hardening variables and are conveniently formulated by considering uniaxial loading conditions first and then extended to multiaxial conditions.Uniaxial conditionsIt is assumed that the uniaxial stress-strain curves can be converted into stress versus plastic strain curves of the formUnder uniaxial loading conditions the effective plastic strain rates are given asAs shown in Figure 4.5.2–1, when the concrete specimen is unloaded from any point on the strainsoftening branch of the stress-strain curves, the unloading response is observed to be weakened:The effective uniaxial cohesion stresses determine the size of the yield (or failure) surface.Uniaxial cyclic conditionsThe concrete damaged plasticity model assumes that the reduction of the elastic modulus is given in terms of a scalar degradation variable, d, aswhere is the initial (undamaged) modulus of the material.where and are functions of the stress state that are introduced to represent stiffness recovery effects associated with stress reversals. They are defined according towhereThe evolution equations of the equivalent plastic strains are also generalized to the uniaxial cyclic conditions asThe evolution equations for the hardening variables must be extended for the general multiaxial conditions. Based on Lee and Fenves(1998) we assume that the equivalent plastic strain rates are evaluated according to the expressionswhere and are, respectively, the maximum and minimum eigenvalues of the plastic strain rate tensor andIf the eigenvalues of the plastic strain rate tensor () are ordered such that , the evolution equation for general multiaxial stress conditions can be expressed in the following matrix form:whereandElastic stiffness degradationThe plastic-damage concrete model assumes that the elastic stiffness degradation is isotropic and characterized by a single scalar variable, d:similar to the uniaxial cyclic case, only that and are now given in terms of the function as It can be easily verified that Equation 4.5.2–10for the scalar degradation variable is consistent with the uniaxial response.and .Yield conditionThe plastic-damage concrete model uses a yield condition based on the yield function proposed by Lubliner et al.(1989) and incorporates the modifications proposed by Lee and Fenveswhere and are dimensionless material constants;is the effective hydrostatic pressure;is the Mises equivalent effective stress;is the deviatoric part of the effective stress tensor ; and is the algebraically maximum eigenvalue of . The function is given asTypical experimental values of the ratio for concrete are in the range from 1.10 to 1.16, yielding values of between 0.08 and 0.12 (Lubliner et al., 1989).Let for any given value of the hydrostatic pressure with ; thenThe fact that is constant does not seem to be contradicted by experimental evidence (Lubliner et al., 1989). The coefficient is, therefore, evaluated asA value of , which is typical for concrete, givesLet for any given value of the hydrostatic pressure with ; thenTypical yield surfaces are shown in Figure 4.5.2–4 in the deviatoric plane and in Figure 4.5.2–5for plane-stress conditions.Figure 4.5.2–4 Yield surfaces in the deviatoric plane, corresponding to different values of .Figure 4.5.2–5 Yield surface in plane stress.Flow ruleThe plastic-damage model assumes nonassociated potential flow,The flow potential G chosen for this model is the Drucker-Prager hyperbolic function:where is the dilation angle measured in the p–q plane at high confing pressure;is the uniaxial tensile stress at failure; and is a parameter, referred to as the eccentricity, that defines the rate at which the function approaches the asymptote (the flow potential tends to a straight line as the eccentricity tends to zero). This flow potential, which is continuous and smooth, ensures that the flow direction is defined uniquely.The function asymptotically approaches the linear Drucker-Prager flow potential at high confing pressure stress and intersects the hydrostatic pressure axis at 90°.See “Modelsfor granular or polymer behavior,”Section 4.4.2,for further discussion of this potential.Because plastic flow is nonassociated, the use of the plastic-damage concrete model requires the solution of nonsymmetric equations.Viscoplastic regularizationHere is the viscosity parameter representing the relaxation time of the viscoplastic system and is the plastic strain evaluated in the inviscid backbone model.Similarly, a viscous stiffness degradation variable, , for the viscoplastic system is defined as where d is the degradation variable evaluated in the inviscid backbone model.The stress-strain relation of the viscoplastic model is given asIntegration of the modelThe model is integrated using the backward Euler method generally used with the plasticity models in Abaqus.A material Jacobian consistent with this integration operator is used for the equilibrium iterations.。

DEVELOPMENT OF DISCRETE CRACKS IN CONCRETE LOADEDBY SHOCK WA VESMartin Larcher1Keywords:Concrete,High Dynamic Loading,Shock Wave,Discrete Cracks,Element-free Galerkin Method,Hugoniot,Strain Rate Effect,Blasting.Abstract The nonlinear behaviour of concrete is affected by the development of cracks.The micro cracks are the initiation for the development of the macro cracks under different load-ings.This work presents a discrete crack model with a cohesive crack zone to simulate the behaviour of concrete under a high dynamic load.In consideration of the strain rate effect and the Hugoniot-curve shock waves in concrete are calculated.The simulation of the blasted concrete results in a realistic crack pattern.IntroductionSimulation of high dynamic loading of concrete needs special numerical and material models. The development of shock waves and consequently the discontinuity in front of the shock wave have to be considered.Another challenge is the calculation of the concrete cracking.The idea of this research is to use the discrete cracks with a cohesive crack model instead of a damage material model.The results of these calculations will be compared with experimental results of blasted concrete.Element-free Galerkin MethodMLS InterpolationBelytschko[2]proposed the element-free Galerkin method(EFG)which approximates afield by using a moving least-squares interpolation(MLS Interpolation).The following equation is used for the approximation of the displacementfieldu h(x)=ni=1φk i(x)u i=p T·a(1)The shape functionφis built from monomial functions p.A linear2-dimensional example for p isp(x)=(1x y)T(2) 1Joint Research Centre,Ispra,Italy;email:*********************,before Universit¨a t Karlsruhe,GermanyThe vector a is calculated by the minimisation of the interpolation error J iJ i(a,x)=ni=1w i(x)· u i−p T i(x)·a 2(3)By using the derivation of equation3the shape functionsφk i can be calculated.The weight function w i depends on the distance x−x i .The weight function can be written asw i(x)=w i(s)with s= x−x ih i(4)A common spline function can be used as the weight functionw(s)=1−6s2+8s3−3s4(5) The size of the radius of influence h i should be choosen so that4to10nodes are in a supported area.The discretisation of the EFG-Method is similar to thefinite element method by using the shape functions(equation1).Instead of a nodal integration a background integration is used.This results in an increased computing time but is necessary as the combination of a nodal integration and an explicit time integration shows problems with under integration.MLS Interpolation and CracksCracks can be implemented in EFG by cutting off the weight functions(and herewith the shape functions)at the location of the crack(Figure1).The domain of the examined node is divided into two subdomains–subdomain B beyond the crack and subdomain A on the side of the node.In subdomain A the spline function w is the same as before,in subdomain B it is set to w(x)=0for all x∈B.(6)Figure1:Weight function a)without crack b)with crackMaterial ModelTwo general material models for concrete can be distinguished:smeared and discrete crack models.In a smeared crack model the strains resulting from a crack are dispersed over one ormore elements.In contrast to a discrete crack model the location of the crack is not stored.A discrete crack model helps to consider the fragmentation of the concrete for example after high dynamic loading.In the presented work discrete cracks are implemented with EFG.The use of discrete cracks with a fracture process zone makes it possible to use a material model without damage formulation.There are two effects to be considered for the calculation of high dynamic loaded concrete:the building of shock waves and the strain rate effect.Nonlinear stress-strain relationConcrete responds to loading very nonlinear.In this work cohesive cracks are implemented to describe the cracking effects in the micro and meso scale.In a zone –called fracture process zone (FPZ)–the stresses between the crack sides decreases from tensile strength to zero.The length of the FPZ can be calculated with the crack energy.For the distribution of the stresses between the crack sides an exponential,a bilinear or a linear function can be used.The differences in numerical results using the various distributions of the stress are small.A bilinear distribution shows the best representation of the experiments.tFigure 2:Fracture process zoneThe following rules are used for the development of the cracks:•A failure surface should be used for the decision if a crack has to be created or a crack is growing.For a tension failure a St.Venant criterion is applicable,but this failure surface doesn’t show a good correlation by a two or three axial loading.Therefore the failure surface proposed by Hsieh,Ting and Chen [6]is used in this work.•A fixed crack length is used for the development of the cracks.•The direction of the crack growth is orthogonal to the direction of the principle stress.To decide if a crack is developed the stresses at the crack tip are calculated by a MLS Interpo-lation.This is a non-local determination.HugoniotThe nonlinear volumetric stress-strain relation is the cause for the development of shock waves.The first part of the volumetric strain-pressure curve is the elastic part.The gradient in this part is the elastic compression modulus.By increasing volumetric strains the micropores in the concrete are damaged.The gradient of the stress-strain relation becomes smaller than the compression modulus –the waves moves more slowly.After the destruction of the micropores the stiffness of the concrete is getting higher due to the compaction of the material (Hugoniot).The increased stiffness is the reason for the development of the shock waves.In the presented work a Y-function is used to consider the increase of stiffness (figure 3).The bulk modulus K has to be multiplied with this function.The increasing stiffness does not influence the shear modulus.K tot =Y (ǫv )·K(7)The shape of the Y-function is shown by Schmidt-Hurtienne [8]Y = 1−a v · 1−e −|ǫv |−e v,th e v · 1+ |ǫv |−e v,th b v ·e v2 for ǫv <−e v,th 1for ǫv ≥−e v,th (8)The following parameters are used e v,th=0.008(9)e v=0.0223a v=0.7b v =3.5tr (e)Y [-][-]Figure 3:Hugoniot-curve –Y-functionThe Y-function for unloading is set toY unloading=1for max Y loading=1AND min Y loading=1Y unloading,plast for max Y loading=1AND min Y loading<1max Y loading for max Y loading>1(10)The investigation shows that the numerical model represents the material by usingY unloading,plast=1.5.This unloading function is also shown infigure3.The damaging of the concrete under high hydrostatic loads has also to be considered.If the micropores of the concrete are destroyed,the concrete cannot bear to a tension load anymore. Furthermore,the shear modulus is reduced.If these effects are not considered,too less energy is dissipated in the system and the amplitude of the wave does not decrease.The reduced shear modulus is implemented with a damage evolution following the proposal of Ruppert[7]D z= ǫvǫv,max γ(11)with the hydrostatic strainǫv and the hydrostatic strain capacityǫv,max of the concrete.The parameterγdefines the shape of the damage.The investigations show that a ductile shape is suitable to represent the experimental data.After the crushing of the micro pores the concrete cannot sustain a tension load anymore. The concrete reacts like a granular material.Therefore,if crushed concrete is loaded by tension, the integration points and the integration cells are deleted.Strain rate effectThe tensile and the compression strength increase with increasing strain rates.This has been shown in multiple experiments for example by Bischoff[3].If concrete is blasted the strain rate reaches values of106sec−1.It is not possible to get experimental results from concrete strength for strain rates higher than100sec−1.So the strength factor for strain rates beyond this point is hypothetical.In contrary to the CEB Bulletin[4]the strength factor should be limited to the maximal value resulting by the experiments.ResultsShearing of a plate under detonation loadPlates loaded by heavy air blast waves fail in a shear failure instead of a bending failure.Exper-iments conducted by Albritton[1]with reinforced concrete show the crack pattern illustrated infigure4.A specimen(figure4)is loaded by a triangular load-time function with a maximal load of 20MPa and a rising time of0,05msec.A background mesh with a distance between the nodes of10mm is used.The strain rate effect is considered.Figure5shows the numerical crack pattern.The crack runs from the support into the specimen.Additional cracks develop on the right hand side of the support because of the missing reinforcement.prangeFigure4:Experimentalsetupstress horizontal [MPa]Figure5:Crack patternBlasting of concreteA contact detonation loads concrete with shock waves.At the Institute of Reinforced Concrete Structures and Building Materials at the University of Karlsruhe concrete slabs are loaded by an explosive to obtain the material parameters of high dynamic loaded concrete.The blasting results in a crater beneath the explosive.The concrete underneath the crater is highly com-pacted.Below this compacted range the concrete is damaged by cracks(Figure7–left).The aim of this work is to use the shown simulation model for the calculation of this crack pattern.The simulations of the experiments use the following parts of the material constitution:•EFG and discrete,cohesive cracks with an easy contact algorithm•Limitation of the variation of the direction(necessary for EFG)•Limitation of the crack velocity–Experiments from Curbach[5]show a limitation of the crack velocity to a value of500m/sec.Within the calculation the crack velocity is limited to this value.•Y-function with unloading function•Erosion of the integration cells•Strain rate effectThe result shows that the amplitude of the wave decreases very fast.The decreasing of the pressure is shown infigure6for different values for the unloading parameter Y unloading,plast. The experiments are well represented by using Y unloading,plast=1.5.0510********Distance to the loading [cm]P r e s s u r e [M P a ]Figure 6:Development of the pressure by a contact detonationThe comparison of the cracks pattern in the concrete shows a good conformity between the experimental and the numerical results (Figure 7–right).deactivated nodes crater damaged concrete discrete crackFigure 7:Cracks formation due to blast loading of concreteConclusions and OutlookThe element-free Galerkin method offers a possibility to model discrete cracks in concrete.The combination of the discrete cracks and a fracture process zone allows the description of the behaviour of concrete.The results of simulations of blasting show a good correlation with experimental data.References[1]G.E.Albritton and K.M.Cole.Response of deep two-way reinforced and unreinforcedconcrete slabs to static and dynamic loading.Technical Report N-69-2,U.S.Army Engi-neer Waterway Experiment Station,Vicksburg,MS,1969.[2]T.Belytschko,Y.Y.Lu,and L.Gu.Element-free galerkin methods.International Journalfor Numerical Methods in Engineering,37:229–256,1994.[3]P.H.Bischoff and pressive behaviour of concrete at high strain rates.Materials and Structures,24:425–450,1991.[4]CEB.Concrete Structures under Impact and Impulsive Loading-Synthesis Report187.CEB-Bulletins,1988.[5]Manfred Curbach.Festigkeitssteigerung von Beton bei hohen Belastungs-geschwindigkeiten.Schriftenreihe des Instituts f¨u r Massivbau und Baustofftechnologie;Dissertation,Universit¨a t Karlsruhe,1987.[6]S.S.Hsieh,E.C.Ting,and W.F.Chen.A plasticity-fracture model for concrete.Interna-tional Journal of Solids and Structures,18:181–197,1982.[7]Max Ruppert.Zur numerischen Simulation von hochdynamisch beanspruchten Betonstruk-turen.Universit¨a t der Bundeswehr;Dissertation,2000.[8]Bj¨o rn Schmidt-Hurtienne.Ein dreiaxiales Sch¨a digungsmodell f¨u r Beton unter Einschlussdes Dehnrateneffekts bei Hochgeschwindigkeitsbelastung.Schriftenreihe des Instituts f¨u r Massivbau und Baustofftechnologie;Dissertation,Universit¨a t Karlsruhe,2001.。

4.5.2 混凝土塑性损伤模型ABAQUSABAQUS 材料库中也包括分析混凝的其它模型如基于弥散裂纹方法的土本构模型。

他们分别是在ABAQUS/Standard “An inelastic constitutive model for concrete,” Section 4.5.1, 中的弥散裂纹模型和在ABAQUS/Explicit, “A cracking model for concrete and other brittle materials,” Section 4.5.3中的脆性开裂模型。

混凝土塑性损伤模型主要是用来为分析混凝土结构在循环和动力荷载作用下的提供一个普遍分析模型。

该模型也适用于其它准脆性材料如岩石、砂浆和陶瓷的分析；本节将以混凝土的力学行为来演示本模型的一些特点。

在较低的围压下混凝土表现出脆性性质，主要的失效机制是拉力作用下的开裂失效和压力作用下的压碎。

当围压足够大能够阻止裂纹开裂时脆性就不太明显了。

这种情况下混凝土失效主要表现为微孔洞结构的聚集和坍塌，从而导致混凝土的宏观力学性质表现得像具有强化性质的延性材料那样。

本节介绍的塑性损伤模型并不能有效模拟混凝土在高围压作用下的力学行为。

而只能模拟混凝土和其它脆性材料在与中等围压条件（围压通常小于单轴抗压强度的四分之一或五分之一）下不可逆损伤有关的一些特性。

这些特性在宏观上表现如下：∙单拉和单压强度不同，单压强度是单拉强度的10倍甚至更多；∙受拉软化，而受压在软化前存在强化；∙在循环荷载(压)下存在刚度恢复；∙率敏感性，尤其是强度随应变率增加而有较大的提高。

概论混凝土非粘性塑性损伤模型的基本要点介绍如下：应变率分解对率无关的模型附加假定应变率是可以如下分解的：是总应变率，是应变率的弹性部分，是应变率的塑性部分。

应力应变关系应力应变关系为下列弹性标量损伤关系：其中是材料的初始（无损）刚度，是有损刚度，是刚度退化变量其值在0（无损）到1（完全失效）之间变化，与失效机制（开裂和压碎）相关的损伤导致了弹性刚度的退化。

混凝土2021年第5期(总第379期)Number5in2021(Total No.379)原材料及辅助物料MATERIAL AW ADMI%ICLEdoi:10.3969/j.issn.1002-3550.2021.05.020纤维对混凝土梁开裂弯矩和弯曲韧性的影响李东升，丁一宁(大连理工大学海岸与近海家重点实验室，辽宁大连116024)摘要：为了研究纤维对混凝土开裂弯矩和弯曲韧性的影响，结合钢纤维、聚丙烯纤维混凝土梁的四点弯曲试验，考虑受拉区 混凝土的塑性变形，推导了纤维混凝土裂弯矩的计算，并分析了纤维混凝土裂塑性发展的影响。

结，钢纤维掺超过40kg/m3、纤维掺超过4kg/m3，纤维可以受拉区混凝土塑性形的能力,从而一度裂荷。

同时，结构型钢纤维纤维对混凝土性有较为显著的提高作用。

结传统论的截面塑性展，将纤维的作以的形加以，可以在设计较为简便的F关键词：纤维混凝土；裂弯矩；性；结构设计中图分类号：TU528.041文献标志码：A文章编号：1002-3550(2021)05-0088-04Investigation into the influence of fibers on cracking moment and flexural toughness of concreteLI Dongsheng,DING Wining(State Key Laboratory of Coastal and Offshore Engineering, Dalian University of Technology,Dalian116024,China)Abstract：To investigate the influence of fibers on the cracking moment of concrete and the properties of the post-cracking behaviors, the present paper derives formula of cracking moment of the concrete considering the plastic development in the tension zone,based on the results of four points loading test.It shows that fibers can increase the cracking moment of concrete, when the dosage of the steel fibers is more than40kg/m3and PP fibers more than4kg/m3.The reason is that the fibers can improve the ability of the plastic development in the tension zone of concrete.Marco-steel and PP fibers can significantly increase the flexural toughness of concrete.It is convenience for the designer to use if the form of increasing factor is adapted to consider the influence of fibers.Key words：fiber reinforced concrete；cracking moment；flexural toughness；structural design0引言在钢筋混凝土结构受力较为复杂,或对裂缝宽度、变形控制较为严格的区域，钢筋的配制往往较为密集F在这种情况下，振捣棒往往难以正常工作，这将严重影响到混凝土硬化后的力学性能以及耐久性能。

4.5.2 混凝土和其它准脆性材料的塑性损伤模型这部分介绍的是ABAQUS提供分析混凝土和其它准脆性材料的混凝土塑性损伤模型。

ABAQUS 材料库中也包括分析混凝的其它模型如基于弥散裂纹方法的土本构模型。

他们分别是在ABAQUS/Standard “An inelastic constitutive model for concrete,” Section 4.5.1, 中的弥散裂纹模型和在ABAQUS/Explicit, “A cracking model for concrete and other brittle materials,” Section 4.5.3中的脆性开裂模型。

混凝土塑性损伤模型主要是用来为分析混凝土结构在循环和动力荷载作用下的提供一个普遍分析模型。

该模型也适用于其它准脆性材料如岩石、砂浆和陶瓷的分析；本节将以混凝土的力学行为来演示本模型的一些特点。

在较低的围压下混凝土表现出脆性性质，主要的失效机制是拉力作用下的开裂失效和压力作用下的压碎。

当围压足够大能够阻止裂纹开裂时脆性就不太明显了。

这种情况下混凝土失效主要表现为微孔洞结构的聚集和坍塌，从而导致混凝土的宏观力学性质表现得像具有强化性质的延性材料那样。

本节介绍的塑性损伤模型并不能有效模拟混凝土在高围压作用下的力学行为。

而只能模拟混凝土和其它脆性材料在与中等围压条件（围压通常小于单轴抗压强度的四分之一或五分之一）下不可逆损伤有关的一些特性。

这些特性在宏观上表现如下：单拉和单压强度不同，单压强度是单拉强度的10倍甚至更多；受拉软化，而受压在软化前存在强化；在循环荷载(压)下存在刚度恢复；率敏感性，尤其是强度随应变率增加而有较大的提高。

概论混凝土非粘性塑性损伤模型的基本要点介绍如下：应变率分解对率无关的模型附加假定应变率是可以如下分解的：是总应变率，是应变率的弹性部分，是应变率的塑性部分。

应力应变关系应力应变关系为下列弹性标量损伤关系：其中是材料的初始（无损）刚度，是有损刚度，是刚度退化变量其值在0（无损）到1（完全失效）之间变化，与失效机制（开裂和压碎）相关的损伤导致了弹性刚度的退化。

ABAQUS关键字BRITTLECRACKING英*BRITTLE CRACKINGDefine brittle cracking properties.This option is used to define cracking and postcracking properties for the brittle cracking material model. The *BRITTLE CRACKING option must be used in conjunction with the *BRITTLE SHEAR option and must immediately precede it. The*BRITTLE CRACKING option can be used in conjunction with the *BRITTLE FAILURE option to specify a brittle failure criterion.Product: ABAQUS/ExplicitType: Model dataLevel: ModelReferences:“Cracking model for concrete,” Section 18.5.2 of the ABAQUS Analysis User's Manual*BRITTLE FAILURE*BRITTLE SHEAROptional parameters:DEPENDENCIESSet this parameter equal to the number of field variable dependencies included in the definition of the postcracking behavior, in addition to temperature. If this parameter is omitted, it isassumed that the postcracking behavior depends only on temperature. See “Using theDEPENDENCIES parameter to define field variable dependence” in “Material data definition,”Section 16.1.2 of the ABAQUS Analysis User's Manual, for more information.TYPESet TYPE=STRAIN (default) to specify the postcracking behavior by entering the postfailure stress-strain relationship directly.Set TYPE=DISPLACEMENT to define the postcracking behavior by entering the postfailure stress/displacement relationship directly.Set TYPE=GFI to define the postcracking behavior by entering the failure stress, , and the Mode I fracture energy, .Data lines if the TYPE=STRAIN parameter is included (default):First line:1.Remaining direct stress after cracking, . (Units of .)1.Direct cracking strain, .1.Temperature.1.First field variable.1.Etc., up to five field variables.The first point at each value of temperature must have a cracking strain of 0.0 and gives the failure stress value. Subsequent lines (only needed if the DEPENDENCIES parameter has a value greater than five):1.Sixth field variable.1.Etc., up to eight field variables per line.Repeat this set of data lines as often as necessary to define the dependence of the postcracking behavior on temperature and other predefined field variables.Data lines if the TYPE=DISPLACEMENT parameter is included:First line:1.Remaining direct stress after cracking, . (Units of .)1.Direct cracking displacement, . (Units of L.)1.Temperature.1.First field variable.1.Second field variable.1.Etc., up to five field variables.The first point at each value of temperature must have a cracking displacement of 0.0 and gives the failure stress value. Subsequent lines (only needed if the DEPENDENCIES parameter has a value greater than five):1.Sixth field variable.1.Etc., up to eight field variables per line.Repeat this set of data lines as often as necessary to define the dependence of the postcracking behavior on temperature and other predefined field variables.Data lines if the TYPE=GFI parameter is included:First line:1.Failure stress, . (Units of .)1.Mode I fracture energy, . (Units of .)1.Temperature.1.Second field variable.1.Etc., up to five field variables.Subsequent lines (only needed if the DEPENDENCIES parameter has a value greater than five):1.Sixth field variable.1.Etc., up to eight field variables per line.Repeat this set of data lines as often as necessary to define the dependence of the postcracking behavior on temperature and other predefined field variables.。

*BRITTLE CRACKINGDefine brittle cracking properties.This option is used to define cracking and postcracking properties for the brittle cracking material model. The *BRITTLE CRACKING option must be used in conjunction with the *BRITTLE SHEAR option and must immediately precede it. The *BRITTLE CRACKING option can be used in conjunction with the *BRITTLE FAILURE option to specify a brittle failure criterion.Product: ABAQUS/ExplicitType: Model dataLevel: ModelReferences:•“Cracking model for concrete,” Section 18.5.2 of the ABAQUS Analysis User's Manual•*BRITTLE FAILURE•*BRITTLE SHEAROptional parameters:DEPENDENCIESSet this parameter equal to the number of field variable dependencies included in the definition of the postcracking behavior, in addition to temperature. If this parameter is omitted, it isassumed that the postcracking behavior depends only on temperature. See “Using theDEPENDENCIES parameter to define field variable dependence” in “Material data definition,”Section 16.1.2 of the ABAQUS Analysis User's Manual, for more information.TYPESet TYPE=STRAIN (default) to specify the postcracking behavior by entering the postfailure stress-strain relationship directly.Set TYPE=DISPLACEMENT to define the postcracking behavior by entering the postfailure stress/displacement relationship directly.Set TYPE=GFI to define the postcracking behavior by entering the failure stress, , and the Mode I fracture energy, .Data lines if the TYPE=STRAIN parameter is included (default):First line:1.Remaining direct stress after cracking, . (Units of .)1.Direct cracking strain, .1.Temperature.1.First field variable.1.Etc., up to five field variables.The first point at each value of temperature must have a cracking strain of 0.0 and gives the failure stress value.Subsequent lines (only needed if the DEPENDENCIES parameter has a value greater than five):1.Sixth field variable.1.Etc., up to eight field variables per line.Repeat this set of data lines as often as necessary to define the dependence of the postcracking behavior on temperature and other predefined field variables.Data lines if the TYPE=DISPLACEMENT parameter is included:First line:1.Remaining direct stress after cracking, . (Units of .)1.Direct cracking displacement, . (Units of L.)1.Temperature.1.First field variable.1.Second field variable.1.Etc., up to five field variables.The first point at each value of temperature must have a cracking displacement of 0.0 and gives the failure stress value.Subsequent lines (only needed if the DEPENDENCIES parameter has a value greater than five):1.Sixth field variable.1.Etc., up to eight field variables per line.Repeat this set of data lines as often as necessary to define the dependence of the postcracking behavior on temperature and other predefined field variables.Data lines if the TYPE=GFI parameter is included:First line:1.Failure stress, . (Units of .)1.Mode I fracture energy, . (Units of .)1.Temperature.1.Second field variable.1.Etc., up to five field variables.Subsequent lines (only needed if the DEPENDENCIES parameter has a value greater than five):1.Sixth field variable.1.Etc., up to eight field variables per line.Repeat this set of data lines as often as necessary to define the dependence of the postcracking behavior on temperature and other predefined field variables.。

ABAQUS中的三种混凝土本构模型2010-05-12 22:19:14| 分类：ABAQUS | 标签：|字号大中小订阅资料来自SIMWE论坛shanhuimin923，特表示感谢！ABAQUS 用连续介质的方法建立描述混凝土模型不采用宏观离散裂纹的方法描述裂纹的水平的在每一个积分点上单独计算其中。

低压力混凝土的本构关系包括：Concrete Smeared cracking model (ABAQUS/Standard)Concrete Brittle cracking model (ABAQUS/Explicit)Concrete Damage plasticity model高压力混凝土的本构关系：Cap model1、ABAQUS/Standard中的弥散裂缝模型Concrete Smeared cracking model(ABAQUS/Standard)：——只能用于ABAQUS/Standard中裂纹是影响材料行为的最关键因素，它将导致开裂以及开裂后的材料的各向异性用于描述：单调应变、在材料中表现出拉伸裂纹或者压缩时破碎的行为在进行参数定义式的Keywords：*CONCRETE*TENSION STIFFENING*SHEAR RETENTION*FAILURE RATIOS2、ABAQUS/Explicit中脆性破裂模型Concrete Brittle cracking model (ABAQUS/Explicit) ：适用于拉伸裂纹控制材料行为的应用或压缩失效不重要，此模型考虑了由于裂纹引起的材料各向异性性质，材料压缩的行为假定为线弹性，脆性断裂准则可以使得材料在拉伸应力过大时失效。

在进行参数定义式的Keywords*BRITTLE CRACKING,*BRITTLE FAILURE,*BRITTLE SHEAR3、塑性损伤模型Concrete Damage plasticity model：适用于混凝土的各种荷载分析，单调应变，循环荷载，动力载荷，包含拉伸开裂(cracking)和压缩破碎(crushing)，此模型可以模拟硬度退化机制以及反向加载刚度恢复的混凝土力学特性在进行参数定义式的Keywords：*CONCRETE DAMAGED PLASTICITY*CONCRETE TENSION STIFFENING*CONCRETE COMPRESSION HARDENING*CONCRETE TENSION DAMAGE*CONCRETE COMPRESSION DAMAGE。

混凝土与其它准脆性材料得塑性损伤模型这部分介绍得就是ABAQUS提供分析混凝土与其它准脆性材料得混凝土塑性损伤模型。

ABAQUS材料库中也包括分析混凝得其它模型如基于弥散裂纹方法得土本构模型、她们分别就是在AＢＡQUS/Staｎdａrd “Aｎｉnelastiｃconstｉｔutive model fｏr ｃonｃrete," Secｔｉoｎ4。

５.１, 中得弥散裂纹模型与在AＢAQUS/Eｘplｉcit, “Ａcracking model ｆoｒcｏncrete ａnd ｏtheｒbrittle ｍａterials," Sｅｃｔｉon 4。

5.3中得脆性开裂模型。

混凝土塑性损伤模型主要就是用来为分析混凝土结构在循环与动力荷载作用下得提供一个普遍分析模型、该模型也适用于其它准脆性材料如岩石、砂浆与陶瓷得分析;本节将以混凝土得力学行为来演示本模型得一些特点。

在较低得围压下混凝土表现出脆性性质,主要得失效机制就是拉力作用下得开裂失效与压力作用下得压碎。

当围压足够大能够阻止裂纹开裂时脆性就不太明显了、这种情况下混凝土失效主要表现为微孔洞结构得聚集与坍塌,从而导致混凝土得宏观力学性质表现得像具有强化性质得延性材料那样。

本节介绍得塑性损伤模型并不能有效模拟混凝土在高围压作用下得力学行为。

而只能模拟混凝土与其它脆性材料在与中等围压条件(围压通常小于单轴抗压强度得四分之一或五分之一)下不可逆损伤有关得一些特性、这些特性在宏观上表现如下:•单拉与单压强度不同,单压强度就是单拉强度得10倍甚至更多;•受拉软化,而受压在软化前存在强化;•在循环荷载(压)下存在刚度恢复;•率敏感性,尤其就是强度随应变率增加而有较大得提高。

概论ﻫ混凝土非粘性塑性损伤模型得基本要点介绍如下:应变率分解对率无关得模型附加假定应变率就是可以如下分解得:就是总应变率,就是应变率得弹性部分,就是应变率得塑性部分。

应力应变关系应力应变关系为下列弹性标量损伤关系:其中就是材料得初始(无损)刚度,就是有损刚度,就是刚度退化变量其值在0(无损)到1(完全失效)之间变化,与失效机制(开裂与压碎)相关得损伤导致了弹性刚度得退化。

参考文献：1. A.M.内维尔著．李国拌，马贞勇译．混凝土的性能，北京：中国建筑工业出版社19832. P.梅泰著．祖永年，沈威，陈志潭译．混凝土的结构性能与材料，上海：同济大学出版社，19913. A．Corpinten&A．R．Ingraffea编．杨煜惠，黄政宇，万良芬等译．混凝土断裂力学．长沙：湖南大学出版社，19884. H．Kupfer，U．K．Hilsdorf，Behavior ofConcrete Under Biaxial Stresses，ACIJournal，August，19695. W.F.Chen，Evaluation of Plasticity-BasedConstitutive ModelsFor Concrete Material，SM Archives 13／1,19886. 过镇海，张秀琴．单调荷载下的混凝土应力—应变全曲线试验研究.北京：清华大学科学研究报告集第三集，19817. 朱伯龙，董振祥．钢筋混凝土非线性分析．上海：同济大学出版社，19858. 杨术秋，林泓．混凝土单轴受压应力—应变全曲线的试验研究．水利学报，1992年第6期9. 过镇海，张秀琴．反复荷载下混凝土应力—应变全曲线试验研究．北京：清华大学科学研究报告集第三集，198110. W．P．Chen，plasticity in Reinforced Concrete，McGraw-Hill Book Company，New York，198211. 过镇海，张秀琴．混凝土受拉应力—变形全曲线的试验研究．建筑结构学报，1988年第4期12. M.E.Tasuji,TheBehaviorofPlainConcreteSubjected to Biaxial stress, Dept．ofStructuralEngineering, Cornell University, Report No:360, March,197613. T．C．Y．Liu，Stress—Strain Response andFracture of Concrete inBiaxial Compression，Dept．Structure，Cornell University, Report No:339,February，197114. 宋玉普．钢筋混凝土有限元分析中的力学模型的研究．大连理工大学博士学位论文，198815. 于骁中等．混凝土的二轴强度及其在拱坝设计中的应用．水利水电科学研究院科学研究论文集，第19集(结构、材料)16. 王传志，过镇海，张秀琴．二轴和三轴受压混疑土的强度试验．土木工程学报，1987年第1期17. 董毓利．混凝土与钢纤维维混凝土本构关系和破坏准则的研究．哈尔滨建筑工程学院博士学位论文199218. O.Buyukozturk et al, Concrete in Biaxial Cyclic Compression, J. Structureal Engineering, Vol.110,No:3, March 198419. 水利水电科学研究院.混凝土的强度与破坏译文集．北京，水利出版杜，198220. 黄真．钢筋混凝土三维非线性有限元分析．天津大学博士学位论文，198921. 王竹溪．热力学(第二版)．北京：高等教育出版社，196022. 范镜泓，高芝晖，非连续介质力学基础.重庆，重庆大学学报，198723. 范镜泓，材料本构关系的内时理论及其热力学基础.重庆，重庆大学学报，1985年第6期24. 陈至达，有理力学，徐州，中国矿业大学出版社，199825. 德冈辰雄著．越镇等译．理性连续介质力学入门．北京；科学出板社，198826. 杜殉．连续介质力学引论．北京；清华大学出版社，198527. 匡震邦．非线性连续介质力学基础．西安；西安文通大学出版杜，198928. 黄克智，连续介质力学．北京：清华大学出版社、北京大学出版杜，198929. 杜庆华，郑百哲，应用连续介质力学．北京；清华大学出版社，1986，30. 冯元桢著．李松年译．连续介质力学导论．北京：科学出版社，199231. 过镇海，王传志．多轴应力下混凝土的强度和破坏准则研究．土木工程学报，1991年第3期32. 夏志皋．塑性力学．上海；同济大学出版社，1991。

建筑施⼯混凝⼟裂缝的预防与处理毕业论⽂中英⽂资料对照外⽂翻译⽂献建筑施⼯混凝⼟中英⽂资料对照外⽂翻译⽂献1，⽂献原⽂：Building construction concrete crack ofprevention and processingAbstractThe crack problem of concrete is a widespread existence but again difficult in solve of engineering actual problem, this text carried on a study analysis to a little bit familiar crack problem in the concrete engineering, and aim at concrete the circumstance put forward some prevention, processing measure.Keyword:Concrete crack prevention processingForewordConcrete's ising 1 kind is anticipate by the freestone bone, cement, water and other mixture but formation of the in addition material of quality brittleness not and all material.Because the concrete construction transform with oneself, control etc. a series problem, harden model of in the concrete existence numerous tiny hole, spirit cave and tiny crack, is exactly because these beginning start blemish of existence just make the concrete present one some not and all the characteristic of quality.The tiny crack is a kind of harmless crack and accept concrete heavy, defend Shen and a little bit other use function not a creation to endanger.But after the concrete be subjected to lotus carry, difference in temperature etc. function, tiny crack would continuously of expand with connect, end formation we can see without the aid of instruments of macro view the crack be also the crack that the concrete often say in the engineering.Concrete building and Gou piece usually all take sewer to make of, because of crack of existence and development usually make inner part of reinforcing bar etc. material creation decay, lower reinforced concrete material of loading ability, durable and anti- Shen ability, influence building of external appearance, service life, severity will threat arrive people's life and property safety.A lot of all of crash of engineerings is because of the unsteady development of the crack with the result that.Modern age science research with a great deal of of the concrete engineering practice certificate, in the concrete engineering crack problem is ineluctable, also acceptable in certainly of the scope just need to adopt valid of measure will it endanger degree control at certain of scope inside.The reinforced concrete norm is also explicit provision:Some structure at place of dissimilarity under the condition allow existence certain the crack of width.But at under construction should as far as possible adopt a valid measure control crack creation, make the structure don't appear crack possibly or as far as possible decrease crack of amount and width, particularly want to as far as possible avoid harmful crack of emergence, insure engineering quality thus.Concrete crack creation of the reason be a lot of and have already transformed to cause of crack:Such as temperature variety, constringency, inflation, the asymmetry sink to sink etc. reason cause of crack;Have outside carry the crack that the function cause;Protected environment not appropriate the crack etc. caused with chemical effect.Want differentiation to treat in the actual engineering, work°out a problem according to the actual circumstance.In the concrete engineering the familiar crack and the prevention1.Stem Suo crack and preventionStem the Suo crack much appear after the concrete protect be over of a period of time or concrete sprinkle to build to complete behind of around a week.In the cement syrup humidity of evaporate would creation stem Suo, and this kind of constringency is can't negative.Stem Suo crack of the creation be main is because of concrete inside outside humidity evaporate degree dissimilarity but cause to transform dissimilarity of result:The concrete is subjected to exterior condition of influence, surface humidity loss lead quick, transform bigger, inner part degree of humidity variety smaller transform smaller, bigger surface stem the Suo transform to be subjected to concrete inner part control, creation more big pull should dint but creation crack.The relativehumidity is more low, cement syrup body stem Suo more big, stem the Suo crack be more easy creation.Stem the Suo crack is much surface parallel lines form or the net shallow thin crack, width many between 0.05-0.2 mm, the flat surface part muchsee in the big physical volume concrete and follow it more in thinner beam plank short to distribute.Stem Suo crack usually the anti- Shen of influence concrete, cause the durable of the rust eclipse influence concrete of reinforcing bar, under the function of the water pressure dint would creation the water power split crack influence concrete of loading dint etc..Concrete stem the Suo be main with water ash of the concrete ratio, the dosage of the composition, cement of cement, gather to anticipate of the dosage of the property and dosage, in addition etc. relevant.Main prevention measure:While being to choose to use the constringency quantity smaller cement, general low hot water mire and powder ash from stove cement in the adoption, lower the dosage of cement.Two is a concrete of stem the Suo be subjected to water ash ratio of influence more big, water ash ratio more big, stem Suo more big, so in the concrete match the ratio the design should as far as possible control good water ash ratio of choose to use, the Chan add in the meantime accommodation of reduce water.Three is strict control concrete mix blend with under construction of match ratio, use of concrete water quantity absolute can't big in match ratio design give settle of use water quantity.Four is the earlier period which strengthen concrete to protect, and appropriate extension protect of concrete time.Winter construction want to be appropriate extension concrete heat preservation to overlay time, and Tu2 Shua protect to protect.Five is a constitution the accommodation is in the concrete structure of the constringency sew.2.The Su constringency crack and preventionSu constringency is the concrete is before condense, surface because of lose water quicker but creation of constringency.The Su constringency crack is general at dry heat or strong wind the weather appear, crack's much presenting in the center breadth, both ends be in the centerthin and the length be different, with each other not coherent appearance.Shorter crack general long 20-30 cm, the longer crack can reach to a 2-3 m, breadth 1-5 mm.It creation of main reason is:The concrete is eventually almost having no strength or strength before the Ning very small, perhaps concrete just eventually Ning but strength very hour, be subjected to heat or compare strong wind dint of influence, the concrete surface lose water to lead quick, result in in the capillary creationbigger negative press but make a concrete physical volume sharply constringency, but at this time the strength of concrete again can't resist its constringency, therefore creation cracked.The influence concrete Su constringency open the main factor of crack to have water ash ratio, concrete of condense time, environment temperature, wind velocity, relative humidity...etc.. Main prevention measure:One is choose to use stem the Suo value smaller higher Huo sour salt of the earlier period strength or common the Huo sour brine mire.Two is strict the control water ash ratio, the Chan add to efficiently reduce water to increment the collapse of concrete fall a degree and with easy, decrease cement and water of dosage.Three is to sprinkle before building concrete, water basic level and template even to soak through.Four is in time to overlay the perhaps damp grass mat of the plastics thin film, hemp slice etc., keep concrete eventually before the Ning surface is moist, perhaps spray to protect etc. to carry on protect in the concrete surface.Five is in the heat and strong wind the weather to want to establish to hide sun and block breeze facilities, protect in time.3.Sink to sink crack and preventionThe creation which sink to sink crack is because of the structure foundation soil quality not and evenly, loose soft or return to fill soil dishonest or soak in water but result in the asymmetry sink to decline with the result that;Perhaps because of template just degree shortage, the template propped up to once be apart from big or prop up bottom loose move etc. to cause, especially at winter, the template prop up at jelly soil up, jelly the soil turn jelly empress creation asymmetry to sink to decline and cause concrete structure creation crack.This kind crack many is deep enter or pierce through sex crack, it alignment have something to do with sinking to sink a circumstance, general follow with ground perpendicular or present 30 °s-45°Cape direction development, bigger sink to sink crack, usually have certain of wrong, crack width usually with sink to decline quantity direct proportion relation.Crack width under the influence of temperature variety smaller.The foundation after transform stability sink to sink crack also basic tend in stability.Main prevention measure:One is rightness loose soft soil, return to fill soil foundation a construction at the upper part structure front should carry on necessity of Hang solid with reinforce.Two is the strength that assurance template is enough and just degree, and prop up firm, and make the foundation be subjected to dint even.Three is keep concrete from sprinkle infusingthe foundation in the process is soak by water.Four is time that template tore down to can't be too early, and want to notice to dismantle a mold order of sequence.Five is at jelly soil top take to establish template to notice to adopt certain of prevention measure.4.Temperature crack and preventionTemperature crack much the occurrence is in big surface or difference in temperature variety of the physical volume concrete compare the earth area of the concrete structure.Concrete after sprinkling to build, in the hardening the process, cement water turn a creation a great deal of of water turn hot, .(be the cement dosage is in the 350-550 kg/m 3, each sign square the rice concrete will release a calories of 17500-27500 kJ and make concrete internal thus the temperature rise to reach to 70℃or so even higher)Because the physical volume of concrete be more big, a great deal of of water turn hot accumulate at the concrete inner part but not easy send forth, cause inner part the temperature hoick, but the concrete surface spread hot more quick, so formation inside outside of bigger difference in temperature, the bigger difference in temperature result in inner part and exterior hot the degree of the bulge cold Suo dissimilarity, make concrete surface creation certain of pull shoulddint.When pull should dint exceed the anti- of concrete pull strength extreme limit, concrete surface meeting creation crack, this kind of crack much occurrence after the concrete under construction period.In the concrete of under construction be difference in temperature variety more big, perhaps is a concrete to be subjected to assault of cold wave etc., will cause concrete surface the temperature sharply descend, but creation constringency, surface constringency of the concrete be subjected to inner part concrete of control, creation very big of pull should dint but creation crack, this kind of crack usually just in more shallow scope of the concrete surface creation.The alignment of the temperature crack usually none settle regulation, big area structure the crack often maneuver interleave;The size bigger structure of the beam plank length, the crack run parallel with short side more;Thorough with pierce through sex of temperature crack general and short side direction parallelism or close parallelism, crack along long side cent the segment appear, in the center more airtight.Crack width the size be different, be subjected to temperature variety influence more obvious, winter compare breadth, summer more narrow.The concrete temperature crack that the heat inflation cause is usually in the center the thick both ends be thin, but cold Suo crack of thick thin variety not too obvious.The emergence of the this kind crack willcause the rust eclipse of reinforcing bar, the carbonization of concrete, the anti- jelly which lower concrete melt, anti- tired and anti- Shen ability etc..Main prevention measure:One is as far as possible choose to use low hot or medium hot water mire, like mineral residue cement, powder ash from stove cement...etc..Two is a decrease cement dosage, cement dosage as far as possible the control is in the 450 kg/m 3 following.Three is to lower water ash ratio, water ash of the general concrete ratio control below 0.6.Four is improvement the bone anticipate class to go together with, the Chan add powder ash from stove or efficiently reduce water etc. to come to reduce cement dosage and lower water to turn hot.Five is an improvement concrete of mix blend to process a craft, lower sprinkle of concrete to build temperature.Six is the in addition that the Chan add a have of fixed amount to reduce water and increase Su, slow Ning etc. function in the concrete, improvement the concrete mix to match a thing of mobility, protect water, lower water to turn hot, postpone hot Feng of emergence time.Seven is the heat season sprinkle to build can the adoption take to establish to hide sun plank etc. assistance measure control concrete of Wen Sheng, lower to sprinkle temperature of build the concrete.Eight is the temperature of big physical volume concrete should the dint relate to structure size, concrete structure size more big, temperature should dint more big, so want reasonable arrangement construction work preface, layering, cent the piece sprinkle to build, for the convenience of in spread hot, let up control.Nine is at great inner part constitution of the physical volume concrete cool off piping, cold water perhaps cold air cool off, let up concrete of inside outside difference in temperature.Ten is the supervision which strengthen concrete temperature, adopt to cool off in time, protection measure.11 is to reserve temperature constringency to sew.12 is to let up to control, sprinkle proper before building concrete in the Ji rock and old concrete top build a 5 mm or so sand mat a layer or usage asphalt etc. material Tu2 Shua.13 is to strengthen concrete to protect, the concrete after sprinkle build use moist grass Lian in time, hemp slice's etc. overlay, and attention sprinkle water to protect, appropriate extension protect time, assurance the concrete surface be slow-moving cool off.At the cold season, concrete surface should constitution heat preservation measure, in order to prevent cold wave assault.14 is the allocation be a little amount in the concrete of reinforcing bar perhaps add fiber material concrete of temperature crack control at certain of scope inside.5.Crack and prevention that the chemical reaction causeAlkali bone's anticipating the crack that reaction crack and reinforcing bar rust eclipse cause is the most familiar in the reinforced concrete structure of because of chemical reaction but cause of crack.The concrete blend a future reunion creation some alkalescence ion, these ion with some activity the bone anticipate creation chemical reaction and absorb surroundings environment in of water but the physical volume enlarge, make concrete crisp loose, inflation open crack.In this kind of crack general emergence concrete structure usage period, once appear very difficult remediable, so should at under construction adopt valid the measure carry on prevention.Main of prevention measure:While being to choose to anticipate with the alkali activity small freestone bone.Two is the in addition which choose to use low lye mire with low alkali or have no alkali.Three is the Chan which choose to use accommodation with anticipate to repress an alkali bone to anticipate reaction.Because the concrete sprinkle to build, flap Dao bad perhaps is a reinforcing bar protection layer thinner, the harmful material get into concrete to make reinforcing bar creation rust eclipse, the reinforcing bar physical volume of the rust eclipse inflation, cause concrete bulge crack, the crack of this kind type much is a crack lengthways, follow the position of reinforcing bar /doc/7711103392.htmlually of prevent measure from have:One is assurance reinforcing bar protection the thickness of the layer.Two is a concrete class to go together with to want good.Three is a concrete to sprinkle to note and flap Dao airtight solid.Four is a reinforcingbar surface layer Tu2 Shua antisepsis coating.Crack processingThe emergence of the crack not only would influence structure of whole with just degree, return will cause the rust eclipse of reinforcing bar, acceleration concrete of carbonization, lower durable and anti- of concrete tired, anti- Shen ability.Therefore according to the property of crack and concrete circumstance we want differentiation to treat, in time processing, with assurance building of safety usage.The repair measure of the concrete crack is main to have the following some method:Surface repair method, infuse syrup, the Qian sew method, the structure reinforce a method, concrete displacement method, electricity chemistry protection method and imitate to living from healmethod.Surface repair the method be a kind of simple, familiar of repair method, it main be applicable to stability and to structure loading the ability don't have the surface crack of influence and deep enter crack of processing.The processing measure that is usually is a surface in crack daubery cement syrup, the wreath oxygen gum mire or at concrete surface Tu2 Shua paint, asphalt etc. antisepsis material, at protection of in the meantime for keeping concrete from continue under the influence of various function to open crack, usually can adoption the surface in crack glue to stick glass fiber cloth etc. measure.1, infuse syrup, the Qian sew methodInfuse a syrup method main the concrete crack been applicable to have influence or have already defend Shen request to the structure whole of repair, it is make use of pressure equipments gum knot the material press into the crack of concrete, gum knot the material harden behind and concrete formation one be whole, thus reinforce of purpose.The in common use gum knot material has the cement the syrup, epoxy, A Ji C Xi sour ester and gather ammonia ester to equalize to learn material. The Qian sew a method is that the crack be a kind of most in common use method in, it usually is follow the crack dig slot, the Qian fill Su in the slot or rigid water material with attain closing crack of purpose.The in common use Su material has PVC gum mire, plastics ointment, the D Ji rubber etc.;In common use rigid water material is the polymer cement sand syrup.2, the structure reinforce a methodWhen the crack influence arrive concrete structure of function, will consideration adopt to reinforce a method to carry on processing to the concrete structure.The structure reinforce medium in common use main have the following a few method:The piece of enlargement concrete structure in every aspect accumulate, outside the Cape department of the Gou piece pack type steel, adoption prepare should the dint method reinforce, glue to stick steel plate to reinforce, increase to establish fulcrum to reinforce and jet the concrete compensation reinforce.3, concrete displacement methodConcrete displacement method is processing severity damage concrete of a kind of valid method, this method be first will damage of the concrete pick and get rid of, then again displacement go into new of concrete or other material.The in common use displacement material have:Commonconcrete or the cement sand syrup, polymer or change sex polymer concrete or sand syrup.4, the electricity chemistry protection methodThe electricity chemistry antisepsis is to make use of infliction electric field in lie the quality of electricity chemical effect, change concrete or reinforced concrete the environment appearance of the place, the bluntness turn reinforcing bar to attain the purpose of antisepsis.Cathode protection method, chlorine salt's withdrawing a method, alkalescence to recover a method is a chemistry protection method in three kinds of in common use but valid method.The advantage of this kind of method is a protection method under the influence of environment factor smaller, apply reinforcing bar, concrete of long-term antisepsis, since can used for crack structure already can also used for new set up structure.5, imitate to living from legal moreImitate to living from heal the method be a kind of new crack treatment, its mimicry living creature organization secrete a certain material towards suffering wound part auto, but make the wound part heal of function, join some and special composition(such as contain to glue knot of the liquid Xin fiber or capsule) in the concrete of the tradition the composition, at concrete inner part formation the intelligence type imitate to living from heal nerve network system, be the concrete appear crack secrete a parts of liquid Xin fiber can make the crack re- heal. ConclusionThe crack is widespread in the concrete structure existence of a kind of phenomenon, it of emergence not only will lower theanti- Shen of building ability, influence building of usage function, and will cause the rust eclipse of reinforcing bar, the carbonization of concrete, lower the durable of material, influence building of loading ability, so want to carry on to the concrete crack earnest research, differentiation treat, adoption reasonable of the method carry on processing, and at under construction adopt various valid of prevention measure to prevention crack of emergence and development, assurance building and Gou piece safety, stability work.From《CANADIAN JOURNAL OF CIVIL ENGINEERING》2，译⽂：建筑施⼯混凝⼟裂缝的预防与处理混凝⼟的裂缝问题是⼀个普遍存在⽽⼜难于解决的⼯程实际问题，本⽂对混凝⼟⼯程中常见的⼀些裂缝问题进⾏了探讨分析，并针对具体情况提出了⼀些预防、处理措施。

1 / 7Damaged plasticity model for concrete and other quasi-brittle materialsProducts:Abaqus/Standard Abaqus/ExplicitThis section describes the concrete damaged plasticity model provided in Abaqus for the analysis of concrete and otherquasi-brittle materials. The material library in Abaqus also includes other constitutive models for concrete based on the smeared crack approach.These are the smeared crack model inAbaqus/Standard,described in “Aninelastic constitutive model for concrete,”Section 4.5.1, and the brittle cracking model in Abaqus/Explicit, described in “A cracking modelfor concrete and other brittle materials,”Section 4.5.3.stiffness recovery effects during cyclic loading; andrate sensitivity, especially an increase in the peak strength with strain rate. The plastic-damage model in Abaqus is based on the models proposed by Lubliner et al.(1989)and by Lee and Fenves(1998).The model is described in the remainder of this section.An overview of the main ingredients of the model is given first,followed by a more detailed discussion of the different aspects of the constitutive model.Overview2 / 7where is the total strain rate,is the elastic part of the strain rate, and is the plastic part of the strain rate.Stress-strain relationsThe stress-strain relations are governed by scalar damaged elasticity:where is the initial (undamaged)elastic stiffness of the material;is the degraded elastic stiffness; and d is the scalar stiffness degradation variable, which can take values in the range from zero (undamaged material) to one (fully damaged material). Damage associated with the failure mechanisms of the concrete (cracking andcrushing) therefore results in a reduction in the elastic stiffness. Within the context of the scalar-damage theory, the stiffness degradation is isotropic and characterized by a single degradationvariable,d.Following the usual notions of continuum damage mechanics, the effective stress is defined asThe Cauchy stress is related to the effective stress through the scalar degradation relation:For any given cross-section of the material,the factor represents the ratio of the effective load-carrying area (i.e., the overall area minus the damaged area) to the overall section area. In the absence of damage,,the effective stress is equivalent to the Cauchystress, .When damage occurs, however, the effective stress is more representative than the Cauchy stress because it is the effective stress area that is resisting the external loads. It is, therefore, convenient to formulate the plasticity problem in terms of the effective stress.As discussed later,the evolution of the degradation variable is governed by a set of hardening variables, , and the effective stress; that is, .Hardening variablesas described later in this section.Microcracking and crushing in the concrete are represented by increasing values of the hardening variables.These variables control the evolution of the yield surface and the degradation of the elastic stiffness.They are also intimately related to the dissipated fracture energy required to generate micro-cracks.3 / 7Yield functionThe yield function, , represents a surface in effective stress space, whichdetermines the states of failure or damage. For the inviscid plastic-damage modelThe specific form of the yield function is described later in this section. Flow rulePlastic flow is governed by a flow potential G according to the flow rule: where is the nonnegative plastic multiplier. The plastic potential is defined in the effective stress space.The specific form of the flow potential for the concrete damaged plasticity model is discussed later in this section.The model usesnonassociated plasticity,therefore requiring the solution of nonsymmetric equations.SummaryIn summary, the elastic-plastic response of the concrete damaged plasticity model is described in terms of the effective stress and the hardening variables:where and F obey the Kuhn-Tucker conditions:The Cauchy stress is calculated in terms of the stiffness degradation variable, , and the effective stress asThe constitutive relations for the elastic-plastic response,Equation4.5.2–1,aredecoupled from the stiffness degradation response,Equation 4.5.2–2,which makes the model attractive for an effective numerical implementation. The inviscid model summarized here can be extended easily to account for viscoplastic effects through the use of a viscoplastic regularization by permitting stresses to be outside the yield surface.Damage and stiffness degradationThe evolution equations of the hardening variables and are conveniently formulated by considering uniaxial loading conditions first and then extended to multiaxial conditions.Uniaxial conditions 4 / 7It is assumed that the uniaxial stress-strain curves can be converted into stress versus plastic strain curves of the formUnder uniaxial loading conditions the effective plastic strain rates are given asAs shown in Figure 4.5.2–1, when the concrete specimen is unloaded from any point on the strainsoftening branch of the stress-strain curves, the unloading response is observed to be weakened:The effective uniaxial cohesion stresses determine the size of the yield (or failure) surface.Uniaxial cyclic conditionsThe concrete damaged plasticity model assumes that the reduction of the elastic modulus is given in terms of a scalar degradation variable, d, aswhere is the initial (undamaged) modulus of the material.where and are functions of the stress state that are introduced to represent stiffness recovery effects associated with stress reversals. They are defined according towhereThe evolution equations of the equivalent plastic strains are also generalized to the uniaxial cyclic conditions asThe evolution equations for the hardening variables must be extended for the general multiaxial conditions. Based on Lee and Fenves5 / 7(1998) we assume that the equivalent plastic strain rates are evaluated according to the expressionswhere and are, respectively, the maximum and minimumeigenvalues of the plastic strain rate tensor andIf the eigenvalues of the plastic strain rate tensor () are ordered such that , the evolution equation for general multiaxial stress conditions can be expressed in the following matrix form:whereandElastic stiffness degradationThe plastic-damage concrete model assumes that the elastic stiffness degradation is isotropic and characterized by a single scalar variable, d:similar to the uniaxial cyclic case, only that and are now given in terms of the function as It can be easily verified that Equation4.5.2–10for the scalar degradation variable is consistent with the uniaxial response.and .Yield conditionThe plastic-damage concrete model uses a yield condition based on the yield function proposed by Lubliner et al.(1989) and incorporates the modifications proposed by Lee and Fenveswhere and are dimensionless material constants; is the effectivehydrostatic pressure; is the Mises equivalent effective stress;6 / 7is the deviatoric part of the effective stress tensor ; and is the algebraically maximum eigenvalue of . The function is given as Typical experimental values of the ratio for concrete are in the range from 1.10 to 1.16, yielding values of between 0.08 and 0.12 (Lubliner et al., 1989).Let for any given value of the hydrostatic pressure with ; thenThe fact that is constant does not seem to be contradicted by experimental evidence (Lubliner et al., 1989). The coefficient is, therefore, evaluated asA value of , which is typical for concrete, givesLet for any given value of the hydrostatic pressure with ; then Typical yield surfaces are shown in Figure 4.5.2–4 in the deviatoric plane and in Figure 4.5.2–5for plane-stress conditions.Figure 4.5.2–4 Yield surfaces in the deviatoric plane, corresponding to different values of .Figure 4.5.2–5 Yield surface in plane stress. Flow ruleThe plastic-damage model assumes nonassociated potential flow, The flow potential G chosen for this model is the Drucker-Prager hyperbolic function:where is the dilation angle measured in the p–q plane at highconfing pressure;is the uniaxial tensile stress at failure; and is a parameter, referred to as theeccentricity, that defines the rate at which the function approaches the asymptote (the flow potential tends to a straight line as the eccentricity tends to zero). This flow potential, which is continuous and smooth, ensures that the flow direction is defined uniquely.The function asymptotically approaches the linear Drucker-Prager flow potential at high confing pressure stress and intersects the hydrostatic pressure axis at 90°.See “Modelsfor granular or polymer behavior,”Section 4.4.2,for further discussion of this potential.7 / 7Because plastic flow is nonassociated, the use of theplastic-damage concrete model requires the solution of nonsymmetric equations.Viscoplastic regularizationHere is the viscosity parameter representing the relaxation time of theviscoplastic system and is the plastic strain evaluated in the inviscid backbone model. Similarly, a viscous stiffness degradation variable, , for the viscoplastic system is defined as where d is the degradation variable evaluated in the inviscid backbone model.The stress-strainrelation of the viscoplastic model is given asIntegration of the modelThe model is integrated using the backward Euler method generally used with the plasticity models in Abaqus.A material Jacobian consistent with this integration operator is used for the equilibrium iterations.。