ASTM C1417-2013 Standard Specification for Manufacture of Reinforced Concrete Sewer Storm Drain and Culvert Pipe for Direct Design《直接设计的钢筋混凝土污水管、雨水管和涵管制造的标准规范》.pdf

1、Designation: C1417 12C1417 13Standard Specification forManufacture of Reinforced Concrete Sewer, Storm Drain,and Culvert Pipe for Direct Design1This standard is issued under the fixed designation C1417; the number immediately following the designation indicates the year oforiginal adoption or, in th

2、e case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.1. Scope1.1 This specification covers the manufacture and acceptance of precast concrete pipe desi

3、gned to conform to the ownersdesign requirements and to ASCE 15 or an equivalent design specification.1.2 This specification is the companion to SI Specification C1417M; therefore, no SI equivalents are presented in thisspecification.2. Referenced Documents2.1 ASTM Standards:2A615/A615M Specificatio

4、n for Deformed and Plain Carbon-Steel Bars for Concrete ReinforcementA706/A706M Specification for Low-Alloy Steel Deformed and Plain Bars for Concrete ReinforcementA1064/A1064M Specification for Carbon-Steel Wire and Welded Wire Reinforcement, Plain and Deformed, for ConcreteC33 Specification for Co

5、ncrete AggregatesC76 Specification for Reinforced Concrete Culvert, Storm Drain, and Sewer PipeC150 Specification for Portland CementC260C260/C260M Specification for Air-Entraining Admixtures for ConcreteC494/C494M Specification for Chemical Admixtures for ConcreteC497 Test Methods for Concrete Pipe

6、, Manhole Sections, or TileC595 Specification for Blended Hydraulic CementsC618 Specification for Coal Fly Ash and Raw or Calcined Natural Pozzolan for Use in ConcreteC655 Specification for Reinforced Concrete D-Load Culvert, Storm Drain, and Sewer PipeC822 Terminology Relating to Concrete Pipe and

7、Related ProductsC989 Specification for Slag Cement for Use in Concrete and MortarsC1017/C1017M Specification for Chemical Admixtures for Use in Producing Flowing Concrete2.2 Other Standards:ASCE 15 Standard Practice for the Direct Design of Buried Precast Reinforced Concrete Pipe Using Standard Inst

8、allations(SIDD)3ACI 318 Building Code Requirements for Reinforced Concrete43. Terminology3.1 Definitions:3.1.1 For definitions of terms relating to concrete pipe, see Terminology C822.3.1.2 group of pipe sections, neach days production run of pipe sections of a single concrete strength for a specifi

9、c project.3.1.3 lot of pipe sections, ntotal of the number of groups of pipe sections of a single concrete strength produced for a specificproject.1 This specification is under the jurisdiction of ASTM Committee C13 on Concrete Pipe and is the direct responsibility of Subcommittee C13.05 on Special

10、Projects.Current edition approved Sept. 1, 2012July 1, 2013. Published October 2012July 2013. Originally approved in 1998. Last previous edition approved in 20112012 asC1417 11.C1417 12. DOI: 10.1520/C1417-12.10.1520/C1417-13.2 For referencedASTM standards, visit theASTM website, www.astm.org, or co

11、ntactASTM Customer Service at serviceastm.org. For Annual Book of ASTM Standardsvolume information, refer to the standards Document Summary page on the ASTM website.3 Available from American Society of Civil Engineers (ASCE), 1801 Alexander Bell Dr., Reston, VA 20191, http:/www.asce.org.4 Available

12、from American Concrete Institute (ACI), P.O. Box 9094, Farmington Hills, MI 48333-9094, http:/www.aci-int.org.This document is not an ASTM standard and is intended only to provide the user of an ASTM standard an indication of what changes have been made to the previous version. Becauseit may not be

13、technically possible to adequately depict all changes accurately, ASTM recommends that users consult prior editions as appropriate. In all cases only the current versionof the standard as published by ASTM is to be considered the official document.Copyright ASTM International, 100 Barr Harbor Drive,

14、 PO Box C700, West Conshohocken, PA 19428-2959. United States13.1.4 running average, naverage concrete compressive strength of all groups of pipe sections of a single concrete strengthproduced for a specific project, generally determined as each group is tested.4. Basis of Acceptance of Design4.1 Ma

15、nufacturing Design DataThe manufacturer shall submit the following manufacturing design data for the concrete pipeto the owner for approval.4.1.1 Pipe wall thickness.4.1.2 Concrete strength.4.1.3 Reinforcement:4.1.3.1 Specification,4.1.3.2 Reinforcement Type 1, 2, or 3, where:Type 1: Smooth wire or

16、plain barsType 2: Welded smooth wire reinforcement, 8 in. maximumspacing of longitudinalsType 3: Welded deformed wire reinforcement, deformed wire,deformed bars, or any reinforcement with stirrups,anchored thereto4.1.3.3 Design yield strength,4.1.3.4 Placement and design concrete cover,4.1.3.5 Cross

17、-sectional diameters,4.1.3.6 Spacing,4.1.3.7 Cross-sectional area,4.1.3.8 Description of longitudinal members, and4.1.3.9 If stirrups are used, developable stirrup design stress, stirrup shape, placement, and anchorage details.4.1.4 Design factors and the assumed orientation angle.4.1.5 Pipe laying

18、length and joint information.4.2 Approval of the manufacturing design data shall be based on its conformance to the owners design requirements and toASCE 15 or to an equivalent design specification.5. Basis of Acceptance of Concrete Pipe5.1 Acceptance of pipe shall be on the basis of concrete compre

19、ssion tests, materials tests, conformance to the manufacturingdesign data, conformance to this specification, and inspection of manufactured pipe for defects.5.2 When mutually agreed in writing by the owner and the manufacturer, a certification may be made the basis of acceptanceof the concrete pipe

20、. This certification shall consist of a statement by the manufacturer that the concrete pipe conforms to themanufacturing design data and to this specification, and that the concrete and materials have been sampled and tested and conformto this specification.5.3 Age for AcceptancePipe shall be consi

21、dered ready for acceptance when they conform to the requirements of thisspecification.6. Material6.1 Reinforced ConcreteThe reinforced concrete shall consist of cementitious materials; mineral aggregates; admixtures, ifused; and water in which steel has been embedded in such a manner that the steel

22、and concrete act together.6.2 Cementitious Material:6.2.1 CementCement shall conform to the requirements for portland cement of Specification C150 or shall be portlandblast-furnace slag cement or portland-pozzolan cement conforming to the requirements of Specification C595, except that thepozzolan c

23、onstituent in the Type IP portland-pozzolan cement shall be fly ash.6.2.2 Slag CementSlag cement shall conform to the requirements of Grade 100 or 120 of Specification C989.6.2.3 Fly AshFly ash shall conform to the requirements of Specification C618, Class F or Class C.6.2.4 Allowable Combinations o

24、f Cementitious MaterialsThe combination of cementitious materials used in the concrete shallbe one of the following:6.2.4.1 Portland cement only.6.2.4.2 Portland blast-furnace slag cement only.6.2.4.3 Portland-pozzolan cement only.6.2.4.4 A combination of portland cement and slag cement.6.2.4.5 A co

25、mbination of portland cement and fly ash, or6.2.4.6 A combination of portland cement, slag cement (not to exceed 25 % of the total cementitious weight), and fly ash (notto exceed 25 % of the total cementitious weight).C1417 1326.3 AggregatesAggregates shall conform to the requirements of Specificati

26、on C33, except that the requirement for gradationshall not apply.6.4 AdmixturesThe following admixtures and blends are allowable:6.4.1 Air-entraining admixture conforming to Specification C260C260/C260M;6.4.2 Chemical admixture conforming to Specification C494/C494M;6.4.3 Chemical admixture for use

27、in producing flowing concrete conforming to Specification C1017/C1017M; and6.4.4 Chemical admixture or blend approved by the owner.6.5 Steel ReinforcementReinforcement shall consist of wire and welded wire conforming to Specification A1064/A1064M;or of bars conforming to Specifications A615/A615M, G

28、rade 40 or 60, or A706/A706M, Grade 60.7. Joints7.1 The joints shall be designed and the ends of the concrete pipe sections shall be formed so that the sections can be laidtogether to make a continuous line of pipe, compatible with the permissible variations given in Section 15.8. Manufacture8.1 Con

29、creteThe aggregates shall be sized, graded, proportioned, and mixed with cementitious material and water andadmixtures, if any, to produce a thoroughly mixed concrete of such quality that the pipe will conform to the design requirementsof this specification. The water-cementitious material ratio of

30、all concrete shall be 0.53, or less, by weight. Minimum concretestrength shall be 4000 psi.8.2 FinishPipe shall be substantially free of fractures, large or deep cracks, and surface roughness. The ends of the pipe shallbe normal to walls and center line of the pipe, within the limits of variations g

31、iven in Section 15.9. Circumferential Reinforcement9.1 A line of circumferential reinforcement for any given total area may be composed of up to two layers for pipe with wallthicknesses of less than 7 in. or three layers for pipe with wall thickness of 7 in. or greater. The layers shall not be separ

32、ated bymore than the thickness of one longitudinal plus 14 in. The multiple layers shall be fastened together to form a single cage. If themultiple layers of a cage contain circumferential splices, the individual layers shall be rotated so that the splices are staggered.Allother specification requir

33、ements, such as laps, welds, tolerances of placement in the wall of the pipe, and so forth, shall apply tothis method of fabricating a line of reinforcement. The design shall be based on the centroid of the layers.9.2 Reinforcement placement and concrete cover shall conform to the approved manufactu

34、ring data. The nominal concretecover over the circumferential reinforcement shall not be less than 1 in. in pipe having a wall thickness of 212 in. or greater, andshall not be less than 34 in. in pipe having a wall thickness of less than 212 in. The location of the reinforcement shall be subjectto t

35、he permissible variations in dimensions given in Section 15. Requirements for placement and protective covering of theconcrete from the inner or outer surface of the pipe do not apply to that portion of a cage that is flared so as to extend into thebell or reduced in diameter so as to extend into th

36、e spigot.9.3 Where the wall reinforcement does not extend into the joint area, the maximum longitudinal distance to the lastcircumferential from the inside shoulder of the bell or the shoulder of the spigot shall be 3 in., except that if this distance exceedsone half of the wall thickness, the pipe

37、wall shall contain at least a total reinforcement area of the minimum specified area per linearfoot times the laying length of the pipe section. The minimum cover on the last circumferential near the spigot shoulder shall be12 in.9.4 Where reinforcement is in the bell or spigot, the minimum end-cove

38、r on the last circumferential shall be 12 in. in the bellor 14 in. in the spigot.9.5 The continuity of the circumferential reinforcing steel shall be maintained during the manufacture of the pipe, except when,as agreed upon by the owner, lift eyes or holes are provided in each pipe or the pipe is co

39、nverted into a manhole tee.10. Welds, Splices, and Development of Circumferential Reinforcement10.1 General:10.1.1 When pipe are not marked to show a specific orientation in the ground, any weld to, or splice of, a circumferential shallbe considered to be at the point of the maximum flexural stress.

40、10.1.2 When pipe are marked to show a specific orientation in the ground, any weld to, or splice of, a circumferential shall beconsidered to be at a distance determined by the orientation angle closer to the point of maximum flexural stress than the markingindicates.10.1.3 Splices of smooth and defo

41、rmed wire shall be welded and shall meet the requirements of 10.3 and 10.4.10.2 Notation:Awa = actual steel area of the individual circumferential wire, in.2C1417 133Awr = steel area required for the individual circumferential wire for flexure, in.2, either at the splice, for splices, or at the poin

42、tof maximum moment, for quadrant mat reinforcement.db = diameter of reinforcing wire or bar, in.f c = design compressive strength of concrete, lb/in.2.fy = design yield strength of reinforcement, lb/in.2.Fw = embedded weld factor (see 10.4.3).Ld = development length of reinforcing wire or bar, in.Pt

43、 = pull test strength of wire or bar at break, lbf.s = spacing of wire to be developed or spliced, in.10.3 Welds:10.3.1 For butt splices of circumferentials or where welds are made to circumferentials, pull tests of representative specimensof the circumferential across the finished weld shall demons

44、trate a strength of no less than 1.1 times the design yield strength ofthe circumferential except as provided in 10.4.10.3.1 At the option of the manufacturer, a more detailed analysis may be made and the requirements of this section used insteadof When 10.3.1. For butt splices of circumferentials o

45、r where welds are made to circumferentials, pull tests,splices are welded, pulltests Pt,of representative specimens of the circumferential across the finished weld shall demonstrate a strength of no less than:shalldevelop at least 50 % of the minimum specified ultimate tensile strength of the steel,

46、 andPt 51.1 Awr fy (1)there shall be a minimum lap of 2 inches. For butt-welded splices in bars or wire, permitted only with helically wound cages,pull tests of representative specimens shall develop at least 75 % of the minimum specified ultimate tensile strength of thesteel.or no less than:P t 50.

47、5 Awa fy (2)whichever is greater.10.4 Lapped Splices of Circumferential Reinforcement:10.4.1 Where lapped circumferentials are spliced by welding, they shall be lapped no less than 2 in. Pull tests of representativespecimens shall develop no less than 0.9 times design yield strength of the circumfer

48、ential.10.4.2 At the option of the manufacturer, a more detailed analysis may be made and the requirements of 10.4.2 and 10.4.3 usedinstead of 10.4.1. Where lapped circumferentials are spliced by welding, they shall be lapped no less than 2 in. Pull tests, Pt, ofrepresentative specimens shall develo

49、p no less than:Pt 5F w Awr fy (3)or not less than the strength required by Eq 2, whichever is the greater.10.4.3 The embedded weld factor, Fw, relates the pull test strength of the non-embedded splice specimens to the strength of thesplice embedded in the concrete of the pipe wall.10.4.3.1 If the pull test break is in the wire, Fw shall be taken as 0.90.10.4.3.2 If the pull test break is in the weld, Fw shall be taken as 0.70.10.4.1 If lapped splices of circumferentials consisting of deformed bars #6 or less are not welded, they shall be lapped not