ANSI ICEA S-120-742-2016 STANDARD FOR HYBRID OPTICAL FIBER AND POWER CABLE FOR USE IN LIMITED POWER CIRCUITS.pdf

1、 STANDARD FOR HYBRID OPTICAL FIBER AND POWER CABLE FOR USE IN LIMITED POWER CIRCUITS ANSI/ICEA S-120-742-2016 2016 by INSULATED CABLE ENGINEERS ASSOCIATION, Inc. ANSI/ICEA S-120-742-2016 This page has been left intentionally blank ICEA S-120-742-2016 STANDARD FOR HYBRID OPTICAL FIBER AND POWER CABLE

2、 FOR USE IN LIMITED POWER CIRCUITS Publication S-120-742 First Edition May 19th , 2016 Published By Insulated Cable Engineers Association, Inc. Post Office Box 1568 Carrollton, Ga 30112, USA (770) 830-0369 Approved December 2nd, 2015 by INSULATED CABLE ENGINEERS ASSOCIATION, Inc. Approved ,May 19th

3、,2016 by ANSI ASC C-8 AMERICAN NATIONAL STANDARDS INSTITUTE ICEA S-120-742-2016 ii Copyrighted by the ICEA Contents may not be reproduced in any form without permission of the INSULATED CABLE ENGINEERS ASSOCIATION, INC. Copies of this publication may be obtained from: IHS 15 Inverness Way East Engle

4、wood, Co 80113-5776, USA Telephone: (800) 854-7179 ICEA S-120-742-2016 iii NOTICE AND DISCLAIMER The information in this publication was considered technically sound by the consensus of persons engaged in the development and approval of the document at the time it was developed. Consensus does not n

5、ecessarily mean that there is unanimous agreement among every person participating in the development of this document. The Insulated Cable Engineers Association, Inc. (ICEA) standards and guideline publications, of which the document contained herein is one, are developed through a voluntary consen

6、sus standards development process. This process brings together persons who have an interest in the topic covered by this publication. While ICEA administers the process and establishes rules to promote fairness in the development of consensus, it does not independently test, evaluate, or verify the

7、 accuracy or completeness of any information or the soundness of any judgments contained in its standards and guideline publications. ICEA disclaims liability for personal injury, property, or other damages of any nature whatsoever, whether special, indirect, consequential, or compensatory, directly

8、 or indirectly resulting from the publication, use of, application, or reliance on this document. ICEA disclaims and makes no guaranty or warranty, expressed or implied, as to the accuracy or completeness of any information published herein, and disclaims and makes no warranty that the information i

9、n this document will fulfill any of your particular purposes or needs. ICEA does not undertake to guarantee the performance of any individual manufacturer or sellers products or services by virtue of this standard or guide. In publishing and making this document available, ICEA is not undertaking to

10、 render professional or other services for or on behalf of any person or entity, nor is ICEA undertaking to perform any duty owed by any person or entity to someone else. Anyone using this document should rely on his or her own independent judgment or, as appropriate, seek the advice of a competent

11、professional in determining the exercise of reasonable care in any given circumstances. Information and other standards on the topic covered by this publication may be available from other sources, which the user may wish to consult for additional views or information not covered by this publication

12、. ICEA has no power, nor does it undertake to police or enforce compliance with the contents of this document. ICEA does not certify, test, or inspect products, designs, or installations for safety or health purposes. Any certification or other statement of compliance with any health or safety-relat

13、ed information in this document shall not be attributable to ICEA and is solely the responsibility of the certifier or maker of the statement. ICEA S-120-742-2016 iv This page has been left blank intentionally. ICEA S-120-742-2016 v FOREWORD ICEA Standards are adopted in the public interest and are

14、designed to eliminate misunderstanding between the manufacturer and user and to assist the user in selecting and obtaining proper products for his particular need. Existence of an ICEA Standard does not in any respect preclude the manufacture or use of products not conforming to the Standard. The us

15、er of this Standard is cautioned to observe any applicable health or safety regulations and rules relative to the manufacture and use of cable made in conformity with this Standard. This Standard hereafter assumes that only properly trained personnel using suitable equipment will perform manufacture

16、, testing, installation and maintenance of cables defined by this Standard. Questions of interpretation of ICEA Standards can only be accepted in writing, and the reply shall be provided in writing. Suggestions for improvements in this Standard are welcome. Questions and suggestions shall be sent to

17、: Secretary Insulated Cable Engineers Association, Inc. Post Office Box 1568 Carrollton, GA 30112, U.S.A United States of America Alternatively, you can contact ICEA by utilizing the Contact link in the ICEA web site: The members of the ICEA Communications Cable Section, Working Group 742, who part

18、icipated in this project, were: Jim Register, Chairman G. Dorna R. Gould M. D. Kinard J. Mohler J. Ryan J. Shinoski D. Taylor P. VanVickle T.West ICEA S-120-742-2016 vi TABLE of CONTENTS SECTION PAGE Part 1: INTRODUCTION 1 1.1 Scope 1 1.2 General . 2 1.3 Units 3 1.4 Definitions 3 1.5 References 6 1.

19、6 Information to be Supplied by the User . 6 1.7 Modification of this Standard . 6 1.8 Quality Assurance 6 1.9 Fire Resistance Code Requirements 6 1.10 Electrical Power Code Requirements 7 1.11 Safety Considerations . 7 Part 2: OPTICAL FIBERS 8 2.1 General 8 Part 3: OPTICAL FIBER CORE UNITS 9 3.1 Ge

20、neral 9 Part 4: CABLE ASSEMBLY, FILLERS, STRENGTH MEMBERS, FIBER AND UNIT IDENTIFICATION 10 4.1 Cabling of Multi-Fiber Optical Cables. 10 4.2 Identification of Fibers within a Unit . 10 4.3 Identification of Units within a Cable 10 4.4 Strength Members 10 4.5 Assembly of Cables 10 4.6 Filling and Fl

21、ooding Material 11 Part 5: COVERINGS 12 5.1 General 12 Part 6: MARKING AND PACKAGING 13 6.1 General 13 Part 7: TESTING AND TEST METHODS 14 7.1 Testing . 14 7.2 Extent of Testing . 14 7.3 Standard Test Conditions 14 7.4 Electrical Testing. 14 7.5 Reference Test Documents . 15 ICEA S-120-742-2016 vii

22、SECTION PAGE Part 8: FINISHED CABLE OPTICAL PERFORMANCE REQUIREMENTS 17 8.1 General 17 Part 9: REFERENCES 18 TABLES Table 1-1 Temperature Ranges. 2 Table 4-1 Identification of Copper Conductors . 11 Table 7-1 Standard Test Conditions 14 Table 7-2 Test Requirements by Cable Type .15 ANNEXES ANNEX A O

23、rdering Information (Informative). A-1 ANNEX B 1625 nm Single- mode Cabled Fiber Performance Requirements (Normative). B-1 ANNEX C ICEA Telecommunication Cable Standards (Informative) C-1 ANNEX D Maximum Tension on Cable Conductors. D-1 ICEA S-120-742-2016 viii This page has been left blank intentio

24、nally. ICEA S-120-742-2016 1 PART 1 INTRODUCTION 1.1 SCOPE This Standard covers performance requirements for limited power hybrid copper and fiber communications cables intended for use in the buildings, or for short distances external to the building of communications users. The optical fiber is in

25、tended for communications use while the copper conductors are intended for limited power applications in accordance with Articles 725 and 800 of the National Electric Code (NEC) ANSI/NFPA 70. Typically, these cables utilize conductor sizes that range from 10 AWG to 20 AWG. Generally these cables are

26、 limited to a maximum of 100 VA. However, refer to NEC document for detailed requirements. Materials, constructions and performance requirements are included in the Standard, together with applicable test procedures. Products covered by this standard are intended only for operation under conditions

27、normally found in communication systems. Typically, these products are installed both in exposed areas (surface mounted to walls or building baseboards or in non-stationary configurations) and in concealed areas (within walls, attics, etc.), with or without external protection (such as conduit), dep

28、ending upon product type and specific use. These products normally convey communications signals (voice, video, data, etc.) from place to place within a building. Products covered by this Standard may be factory terminated with connectors or splicing modules. This standard is intended to serve as a

29、reference to the most recent appropriate standards; ICEA S-83-596 for optical fiber communications cables intended for indoor use, ICEA S-104-696 for optical fiber communications cables intended for indoor-outdoor use and UL13 for Power Limited Circuit Cables with the addition of any additional requ

30、irements to ensure a functional cable design. This standard is written from the application perspective of an Distributed Antenna System (DAS), however, other use cases that involve hybrid fiber/copper in a Limited Power application as defined by the National Electric Code, are considered to apply.

31、ICEA S-120-742-2016 2 The normal temperature ranges for cables covered by this Standard are listed in Table 1-1: Table 1-1 Temperature Ranges Riser and General Purpose Plenum C F C F Indoor Operation Storage and Shipping Installation -20 to +70 -40 to +70 -10 to 60 -4 to 158 -40 to 158 14 to 140 0 t

32、o +70 -40 to +70 0 to 60 32 to 158 -40 to 158 32 to 140 Indoor-Outdoor Operation Storage and Shipping Installation -40 to +70 -40 to +70 -10 to 60 -40 to 158 -40 to 158 14 to 140 -40 to +70 -40 to +70 0 to 60 -40 to 158 -40 to 158 32 to 140 The standard installation tensile rating for cables is spec

33、ified in Table 7-2. Standard Minimum Bend Diameter Interconnect All Other Cables Unloaded Condition (Installed): 50 mm 20 x Cable OD Loaded Condition (During Installation): 100 mm 40 x Cable OD For very small cables, manufacturers may specify a fixed cable minimum bend diameter (e.g., 300 mm) that i

34、s independent of the cable outer diameter (OD). For cables not having a circular cross-section, bend diameter requirements are to be determined using the thickness (minor axis) as the cable diameter and bending in the direction of the preferential bend. Products covered by this Standard shall comply

35、 with the pertinent Fire Resistance Code(s) described in Section 1.9. 1.2 GENERAL This publication is arranged so that cables may be selected from numerous constructions covering a broad range of installation and service conditions. Parts 2 and 3 designate the materials, material characteristics, di

36、mensions and tests applicable to the particular component. Part 4 covers assembly, cabling, and identification of the individual optical fiber. Part 5 includes cable coverings. Part 6 provides other pertinent requirements not otherwise addressed by Parts 1 through 5 or by Parts 7 and 8 of this Stand

37、ard. ICEA S-120-742-2016 3 Part 7 describes the test methods and performance requirements applicable to the component materials and completed cables manufactured under this Standard. If there is a conflict between Parts 1 through 6 and Part 7, the provisions of Part 7 apply. Part 8 contains routinel

38、y specified optical performance, test methods and requirements for finished cables. Part 9 contains cross-references to other standards and publications. Annex A Informative Ordering Information Annex B Normative 1625 nm Cabled Fiber Performance Requirements Annex C Informative ICEA Telecommunicatio

39、ns Cable Standards Annex D Informative Maximum Tension on Cable Conductors Example 1.3 UNITS In this Standard, metric (SI) units are used. Where approximate equivalents in alternate systems are included, they are provided for information only, and in most cases are rounded off for measurement conven

40、ience. Unless otherwise specified, the Rounding Method of ASTM E 29 shall be used. Rounding of U.S. customary units may be adjusted for measurement convenience. ICEA P-57-653 is a useful guide for metric units used in this publication. 1.4 DEFINITIONS 1.4.1 Cable Classification Products covered in t

41、his Standard shall be classified according to their level of mechanical and thermal robustness, as declared by the manufacturer. The classification of a particular cable design, along with its fire rating (see 1.4.2), determines the appropriate testing and acceptance requirements. Cable classificati

42、ons are defined below. 1.4.1.1 Backbone Cables Cables which consist of a plurality of optical fibers in designs having a higher degree of robustness as compared to interconnect cables. Backbone cables are suitable for connections between telecommunications rooms, equipment rooms and entrance facilit

43、ies. Backbone cables, typically, are sufficiently robust for placement in riser shafts, cable racks, or cable trays. Backbone cables are further classified according to their fire rating (see section 1.4.2) Vertical backbone cable: A backbone cable to be used in vertical applications where the weigh

44、t of the cable substantially contributes to the cable environment. This cable may have a higher tensile rating than horizontal backbone cables. Cables installed in vertical riser shafts are a common example. ICEA S-120-742-2016 4 Horizontal backbone cable: A backbone cable to be used primarily in ho

45、rizontal applications. This cable may have a tensile rating which is dependent on its size or fiber count and may be lower than that of vertical backbone cable. Cables installed in horizontal runs or horizontal air-handling spaces are common examples. Distribution Cables: A backbone cable design in

46、which multiple fibers (typically tight buffered) are contained under one protective jacket. Breakout Cables: A backbone cable design in which each fiber (typically tight buffered) is individually reinforced and jacketed, all surrounded by one common overall jacket. 1.4.1.3 Composite Cables1 Cables w

47、hich contain more than one type of optical fiber. 1.4.1.5 Hybrid Cables1 Cables having both optical fibers and metallic conductors. For this standard the metallic conductors are intended to provide power. 1.4.1.6 Metallic Cables Cables which contain conductive members, not normally intended to be cu

48、rrent-carrying such as metallic strength members, sheaths, shields, or armors. . 1.4.2 Fire Rating of Cables2 _ 1 ICEA Standards prior to 2012 use definitions for composite and hybrid which are the exact opposite of those shown here. The change in definitions was made in the interest of harmonizatio

49、n with International documents and other National Standards. It must be noted that the definition of composite in the National Electrical Code, 2011 and earlier, are consistent with the older ICEA definition. Due to this change, users may see the terms used interchangeably. Regarding the definition for hybrid, as altered above: IEC uses a definition which encompasses metallic conductors used for all purposes not just communic