mil-hdbk-299(sh) kilitary handbook cable...

EEimzElMIL-HDBK-299(sH)3 April 1989

KILITARY HANDBOOK

CABLE COMPARISON HANDBOOKDATA PERTAINING TO ELECTRIC SHIPBOARD CABLE

AHSC N/A FSC 6145DIsTRIBuTE ON STATEMENT A. Approved for public release; distribution unlimited

Downloaded from http://www.everyspec.com

FIIL-HDBK-299(SH)3 April 1989

DEPARTMENT OF DEPENSEWashington, DC 20362-5101

Cable Comparison Hsndbook

I 1. This specification is approved for use within the Naval Sea Systems Commsnd,Department of the Navy, snd.is available for use by all Departments and Agenciesof the Department of Defense.

2. Beneficial ,comments (recommendations, additions, deletions) and any pertinentdata which may be of use in improving this document should be addressed to:COmmsn&r, Naval Sea Systems Command, SSA 55Z3 , Department of the Navy,Washington, DC 20362-5101 by usfng the self-addressed Standardization D,ocumentImprovement Proposal (DD Porm 1426) appearing at the end of this document or byletter.

ii,,


I .

MIL-HDBK-299(SH)3 April 1989

FOREWOSD

1. This document supplements dap”artmental manuals, directives, militarystandards, and so forth, and provides ,baslC information on shipboard cables. Itcontains listings of shipboard cables.,.dsta cables, and supersession information,and should provids valuable facts and guidance to personnel responsible for thedesign, handling, installation, and maintenance of shipboard cable.

2. The “Cable Comparison Handbook- was firat published in 1946 to facilitateutilization of electrical shipboard cable, snd to assist in the planning of cableinsta,llationa. A reprint was issued in 1948, and revised editio& were-printedin 1953, 1956, 1960, 1964, 1975,,and 1977.. T%is 1988 edition containsinformation on current cables. The information is based on currerit data, Section304 of the General Specifications for Ships of the United States Navy, andMIL-C-915, MIL-C-24640, and MIL-C-24643.

3. For many years most of the shipboard power and lighting cables for fixedinstallation used silicone -glass insulation, polyvinyl chloride jacket, aluminumarmor,. m,d watertight co~tmtion. It was.determined that cables with all ofthese features were not necessary for mamy applications, especially for

aPPlicatiO~ wifiin watertight compartments and rion-critical areas above thewatertightness level. Therefore, for applications within watertight compartmentsand non-critical areas, a new family of non-watertight lover cost cables wasdesigned. This new fanily of cables is electrically and dimensionallyinterchangeable with silicone -glasa insulated cables of equivalent size’s,and iscovered by MIL-C-915.

Additionally, cablea jacketed with polyvinyl chloride presented the dangersof toxic fumes and dense, impenetrable smoke when undergoing combustion. Thesehazards became increasingly evident when an electrical fire smoldered through the

)” Because of the overwhelming amountcable ways aboard the DDC 19 (USS ‘)11~ .of smoke and fumes, firefighters were unable to effectively control the fire, anda large amount of damage resulted. A new fsmily of low smoke, low toxic cable,constricted with a polyolef in jacket vice polyvinyl chloride jacket, conforms torigid toxic and smoks indaxes and effectively reduces the hazards associated withthe pol~inyl chloride jacketed cables. I%e new 10V smoka”cable is covered byMIL-c-24643.

A family of lightweight cables has also been introduced to aid in theelimination of excessive weight from the fleet. Considering the substantialamount of cable present on a ahip or submarine, a reduction in cable weight willhave a considerable impact on the overall load, thus improving performance andincreasing efficiency. This new fcmily of lightweight cables is constructed fromcross-linked polyalkene cnd mica polyimida insulation, and a cross-linkedpolyolef in jacket. The lightweight cable is covered by FIIL-c-24640.

4. Cables are listed in this handbook by general classification according to

application and design. Electrical shipboard cables are under control of theDefense Industrial Supply Center, and are covered in Navy Stock List of GeneralStores, FSC 6145.

iii


1.

Paragraph 1.1.1

2.2.12.1.12.2

3.3.13.2 .’

4.4.14.1.14.1.2 ‘“4.1.34.1.44.1.56.1.6

6.1.74.1.8

5.5.1

5.2

5.3

5.45.4.15.4:25.4.2.15.4.35..4.45.4.55.4.65.4.75.h.7.l5.4.7.25.4.7.35.4.7.45.6.7.55.4.7.65.4.85.h.9

NIL-HDBK-299(SH)3 April 1989

CONTENTS

SCOPE ..............................................Scope .............................................

SEFEMNCEODOCUHENTS ...............................Government documents ..............................Specif lcati0n9 ....................................Or&r of precedence .................................

DEFINITIONS ......................’..................Ampacity ..........................................Circuit integrity ..;....... .......~...............

GENSRAL DESCRIPTION OF DATA AND CABLE TYPES ........General description of data and cable types .. ....Cable types and construction ......................Identification information ........................Csble available through ti,litsry specifications ...Commercially- available cables .....................Supersession dsta .................................Physical characteristics snd electricalratings of cables ................................

Ampacity derating factors .........................Ampacity ratings for degaussing cable .............

D.ETAIL2D KEQUIKEMENTS ..............................Cable ~“s and construction characteristics (asspecified in MIL-C-24643) list ...................

Csble q’pes and construction characteristics (asspecified in MIL-C-24640) list ...................

Csble -es and construction characteristics (asspecified in MIL-C-915) list ......................

I&ntification information ........................Stsndard idsntification code (STD) ................Telephone identification code (TEL) ...............COnductOr pairing .................................Special identification code (SPL) .................Twisted pair identification cods ..................Tvisted triad identification code .................Letter identification code (LTR) ..................Methods of applying i&ntificatiOn ................Methodl ..........................................Hethod2 ..........................................14ethod3 ..........................................llethod4 ..........................................Iiethod5 ..........................................Method6 ..........................................Manufacturer’s identification tape ................Year of manufacture ...............................

11

11‘11

1

12222

“2

233

.3

3.

9

111212151516161616161617171717171818

iv


141L-HDBK-299(sH)3 April 1989

CONTENTS - Continued

IParagraph 5.5

5.5.15.5.25.5.3

5.5.4

5.65.7‘5.85.9

6.6.1

Table I.11.III .Iv.v.VI.VII .VIII .xx.

x.X3.XII .XIII.

XIV .

xv.

NI .

XVII .

XVIII.

Brief explanation of cable ratings andcharacteristics tables ...........................

First five columna ................................Overall dismeter ...................................Kated voltage, smpaci~, and’minimum radiusof bend ..........................................

Conductor identification. ..........................”Cable classification (MIL-C-24643) ................Ccble classification (MIL-C-24640) ................Cable classification (NIL-C-915) ..................Ampacity rating .;.................................

Noms....................... ........................!kbject term (keyword) listing ...................

TABLSS

lUi-C-24643 cable application data ..................llIL-c-2k640 cable application data .................HIL-C-915 cable application data ...................Commercial cable application data ..................Superseasion dsta ..................................141L-c-24643 cable ratinga and characteristics ......KIL-c-24640 cable ratings and characteristics ......141L-C-915 cable ratings and characteristics ........Ampaci~ &rating factors for smbienttemperatures above 50”C ........................ ..

Ampacities of dagaussing cable .....................Voltage drop equations for ac circuits .............Voltage drop equations for dc circuits .............Drop.factors for NTSGA cable, 450-volt,three-phase, 60-Hz power systerns ..................

Drop factors for LSTSGA cable, 450-volt,three-phsae, 400-Hz power ,systema .................

Drop factors for Lq6SGA cable, 450-volt,three-phase, 400-Kz power system ..................

Cable characteristics - LqTSGA cable - interiorCo-iCations , weapons control snd electronicsystems ...........................................

Drop factors for IL3TSGAcable, 120-volt,three-phase or single-phase, 60-Hr lightingsysterns (using I and Iw) ..........................

Drop factors for ISTSGA cable, 120-volt,three-phase or single-phase, 60-Hz lightingsystams (using watts snd vars) .....................

E?B.i

28”2828

282828556472

7.474

1921232324305665

72737778

79

80

81

g2

83

Wt

v


MIL-HDBK-299(SH)3 April “1989

Paragraph 10.io.1

20.20.120.2

30.30.1

40.40.140.240.3

50.

50.150.250.3

50.4

. . 50.4.150.4.2

CONTSNTS - Continued

APPENDIX

Es@

SCOPE ..............................................Scope .............................................

KsFsRENcEDm~i ..............................,Government documants ...............................Other publications ................................

DEFINITIONS ..’................ .......................Symbols and abbreviations .........................

GENSSAL DESCRIPTION OF SQUATIONS AND CALCULATIONS ..General description of voltage drop equations .....Three -phase line currents for single -phase loads ..Lighting system calculations using wattsandvars .........................................

DETAILED DESCRIPTIONS OF SQUATIONS AND CALCULATIONS(DERIVATIONS) .......................................Power Systems - derivation of drop factors (DF) ...Lighting systems - derivation of drop factors (DF)..Lighting systems - derivation of drop factors (DF)uaingload watts andvars ........................Derivation of resistance and reactance valuesfor cables .......................................

Calculation of resistance values for cables .......Calculation of reactance values for cables ........

7575

757575

7575

767685

86

“878790

92

9696101

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vi


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1. SCOPE

1.1 w. This handbook is intended to aid supply and installingactivities in utilization of electric shiuboard cable, uarcicularlv in rhe

I.

selection of alternate or substitute cables for use in lieu of specified typesand sizes which might not be immediately available. It is also intended to aidin selecting currently available items for replacement of obsolete items. Thishandbook does not cover shore-we cable, magnet wire, coaxial cables, or radiofrequency special cables used in connection with minesweeping and harbor defense.

,. 2. REFEMNCSD DOCUMSNTS

I

2.1 Government documents. .,,

2.1.1 Suecif ica;ions. Unless othe&ise specified, the followingspecifications of the issue listed in that issue of the Department of DefenseIndex of Specifications and Standards (DoDISS) specifieda part of this handbook to the extent specified herein.

SPECIMCATIONS

KILITAKYKIL-,C-915 - Cable and Cord, Electrical,

General Specification for.

ii the solicitation form

for Shipboard Usa,

MIL-C-24640 ,-.Cable, Electrical, Lightweight, for Shipboard Use,General Specification for.

KIL-C-24643 - Cable and Cord, Electrical, Low Smoke, for ShipboardUse, General Specification for.

(Copies of specifications required by contractors in connection withspecific acquisition ftictions should be obtained from the contracting activityor as directed by the contracting officer. )

2.2 Order of urecedenee. In the event of a conflict berveen the text of.this handbook arid the references cited herein, the text of this handbooktake precedence.

3. DEFINITIONS

3.1 @DaCity. Ampacity is ,an electrical property denoting currentcapacity.

shall

carrying

3.2 Circuit inte~. Circuit integrity indicates cable construction andprovides addsd protection that will allow that cable to function for a longerperiod under fire conditions.

.4. GSNEWU DESCRIPTION OF DATA AND CMLE TYPES

4.1 General descrirition of date and cable tvr.es. General informationconcerning cable types is specified in,4.1.1 through 4.1.8, below.

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MIL-HDSK-299(SH)3 April 1989

4.1.1 Cabl~ ction. A list of cable types and constructioncharacteristics is provided in 5.1, 5.2, and 5.3. Cables listed are inaccordance with NIL-c-24643 (for 10V smoke cable) , MIL-C-24640 (for lightweightcable) , and M3L-C-915 (for shipbosrd cables) . Cables are listed alphabeticallywithin application snd design characteristics. This listing provides a briefdescription of the number of conductors and the type of insulation and jacketingemployed in construction.

4.1.2 Jdentifi cation informatio~. A list of conductor identificationmethods smployed for various qpes of cables is provided in 5.~.

4.1.3 ~ sDecificatiOtis tables 1. 11. andn. Tables I, II, +d III provide a listing of cables, available throughmilitary specifications, according to general application. This list is intendedto aid in the selection of cables for different applications.

4.1.4 ~~. Table IV provides a listof commercially-available cables according to general application.

4.1.5 $upersession data (table V)-. Table V lists cable types’alphabetically tisiingNIL-C-915 cable designations. Cable types which werecovered by previous specifications are listed with the corresponding presenttype.

‘4.1.6 my sical character sties and electr ical ratines of cables (tables VI.v~>. Tables VI, VII, snd VIII contain information concerning physicalcharacteristics. tid electrical ratings at normal operating temperatures ~ Cablesmust not be loaded in excess of these maximum ratings.

applicable to tables VI,

Additional explamtionsVII, and VIII are as follows:

(a) Cables are listed according to.military specification sheet,functional category within that military specification sheet(such as watertight snd non-watertight, flexing, and non-flexing,power and lighting, communications and electronics ), and size andtype dasi~tion within each table.

(b) Rated voltages are not listed for cable types designed for voicecommunication, analog or digital data transmission, or sendingcircuits such as s“onsrsnd pyrometer. The applicability of thesetypes must be determined from additional circuit parameters suchss signal waveform, frequency .sndpeak amplitude, signalfidslity, pulse duration and recurrence frequency, atten~tion,and frequency bandvidth.

(c) The notation Ind/Avg denotes that individual conductors can carrythe current listed under Ind, providsd the average of allcurrents in the individual conductors does not exceed the valuelisted undsr Avg.

(d) The measurement point for minimum radius of bend should be thatsurface of the cable jacket which is on the innermost pnrtion ofthe cable bend. Dimensions listed are approximately eight timesthe overall diameter of the cable or cord. However, duringinstallation or operatinn, a dimension of approximately rwelvetimes the cable overall diameter for conduit bends, sheaves, andother tuned surfaces around which the cable or cord may bepulled under tension should be used.

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141L-HDBK-299(SH)3 April 1989

(e) Unless otherwise indicated, all conductors are of the same size.Unless othervise indicated, all conductors are soft, amealedcopper. For additional dsta covering conductor stranding andconductor dimensions, see MIL-C-915, 141L-C-24640, andKIL-C-2h6h3.

k.1.7 ~aci~ deratine factors (table IX1. Table IX lists ampacityderating factors for ambient temperature above 50 degrees Gelsius (”C), (see5.9).

4.1.8 Amuacitv ratirwi for deeauss inr cable. Table X lists the ampacityratings (w.ximum amperes per conductor) for dsgaussing cables.

,, 5. DETAILSD IU?QUI~S

5.1 Cable -es and construction characteristics (as sDecified in

NIL -C-24643) list. Cable types and construction characteristics (as specified inIUL-C-24643) are as follows:

LSCVSF -

LSDCOP -

&DHOF -

LSDNW -

LSDWWA -

LSDPS -

Ii3DRW -

ISDRWA -

ISDSGA -

LSDSCU -

LSECM -

LSECILi -

LSFHOF -

400-Hertz (Hz) aircrsft seticing: three ethylene propylene rubberinsulated conductors snd one uninsulated conductor, overallcross -linksd polyolefin jacket.

Double conductor, oil-resistant, portable cord > ethylene propylenerubber or cross -linked polyethylene insulation, and cross -linkedpolyolefin jackst.

Double conductor, heat .s.ndoil-resistant, flexible: ethylene propylenerubber insulation, cross -linksd polyolefin jacket.

Double conductor: ethylene propylene rubber or cross -linkedpolyethylene insulation. cross -linked polyolef in jacket, [email protected] conductor: ethylene propylene rubber or cross- linkedpolyethylene insulation, cross. linked polyolef in jacket, armored.

Double condustor, power: silicone rubber insulation, glass braid,silicone rubber jacket, armored.

Double conductor: cross -li~d polyethylene insulation, cross-linkedpolyolefin jackst, unarmored.Double conductor: cross -linksd polyethylene insulation, cross-linked .polyolef in jackst, armored.

Double conductor: silicone rubber and glass braid insulated, cross-linked polyolef in jackst, armored.

Doubla conductor: silicone rubber and glass braid insulated, cross -linked polyolef in jackst, unarmored.

Eight pairs shielded, and eight groups of seven conductors for eachgroup: cross-linked polyethylene insulation for the conductors of eachpair, braided shield sver each pair; ethylsne prcpylene. rubber orcross-linked polyethylene insulation for the conductors of the groupsof seven; crosslinked polyolef in jacket, unarmored.

Eight pairs shielded, and eight groups of seven conductors for eachgroup: cross -linked polyethylene insulation for the conductors of eachpair, braidsd shield over each pair; ethylene propylene rubber orcross-li&d polyethylene insulation for the conductors Of the grOuPs

of seven; cross-linked polyr.lefin jacket, armored.Four conductors, heat and oil -resistant, flexible: ethylene propylenerubber insulation, cross-linked polyolefin jacket.

3



LSFNU - Four conductors: ethylene propylene rubber or cross-linked polyethyleneinsulation, cross-linked polyolef in jacket, unarmored.

ISFNWA - Four conductors: ethylene propylene rubber or cross-linked polyethyleneinsulation, cross -linked polyolef in jacket, armored.

IAWPs - Four conductors, power: silicone rubber. insulation, glass braid,silicone rubber jacket, armored.

LSFSGA - Four conductors: silicons rubber and glass insulated, cross -linkedpolyolef in jacket, armored.

LSFSGU - Four conductors: silicone rubber and glsss insulated, cross-linkedpnlynlef in jacket, unsrmored.

EMA - Multiple conductor: ethylene propylene rubber or cross-linkedpolyethylene itiulation, cross-linked polyolef in jacket, srmored.

L+MCOS - Multiple conductor, oil-resistsnt, shieldad: ethylene propylene rubber

liN.fOu -

lS1.OY -

LSMHOF -

LSI’!MOP-

ma’iw -

IShNUA -

I_SMRI -

EMS -

ISMSA -

lsLscA -

Lsnscs -

LSMSCU -

Isnu -

IsiUs -

LSPBT14 -

or cross -linked polyethylene over.pairs, or over assembly, cross:linked ‘.polyolef in jacket.Multiple conductor, degauss ing: ethylene propylene” or cross-linkedpolyethylene insulation, cross-linked polyolefin jacket, unarmored.Multiple conductor, degaussing: ethylene propylene or cross-linkedpolyethylene insulation, cross-linked polyolef in jacket, armoredbetveen double- layer jacket.Multiple conductor, heat snd oil-resistant, flexible: ethylenepropylene rubber or cross-linked polyethylene i~ulacion, cross-linkedpolyolef i? jackst.14ultiple conductor, microphone, oil-resistant, portable: ethylenepropylene rubber or,cross -linksd polyethylene insulation, cross-1 inkedpolyolefin jacket.Multiple conductor: ethylene propylene rubber or cross-linkedpolyethylene insulation, cross -linked polyolef in jackat, unsrmored.Multiple conductor: ethylene propylene rubber or cross-linkedpolyethylene insulation, cross -linkad pnlyolaf in jacket, armored.Multiple conductor: ethylene propylene rubber or cross-linkedpolyethylene insulated, without fillers, no overall jacket.

Multiple conductor, shieldsd: ethylene propylene rubber or cross -linkedpolyethylene insulation, overall braided shield, cross -linkedpolyolefin jackst, unsrmored.

Multiple conductor, shielded: ethylene propylene rubber or cross- linkedpolyethylene insulation, overall braidsd shield, cross- linkedpolyolef in jacket, armored.

Multiple conductor: silicone rubbsr insulated-glass braided conductors,cross-linked polyolefin jackst, armored.

Multiple conductor: silicone rubber insulated- glass braidsd conductors,cross-linksd polyolefin jacket, double overall shieldsd.

Multiple conductor: silicone rubber insulated- glass braidsd conductors,cross-linked polyolefin jackst, unsrmored.

Multiple conductor: ethylene propylene rubber or cross-1 inkedpolyethylene insulation, cross -linked polyolef in jacket, unarmored.

Multiple conductor: ethylene propylene rubber or cross-linkedpolyethylene insulation, cross -linked polyolef in jacket, double overallshieldsd.Pyrometer base multiple pairs: ethylene propylene rubber or cross,:linked polyethylene insulation on one copper and one constantanconductor, cross -linksd polyolefin jacket, armored.


I

I JSTHOF -

LnNw -

lSTNWA -

lSrPNW -

ISTPWWA -

- LSTPS -

LSPB’RiU -

I.SPI .

ISSHOF -

USRW -

li?.SRWA -

ISSSP -

iSssGA -

ISSSGU -

LSTWA -

tiTCJW -

ISTC.IX -

liSTCFJi -

lSTCOP -

ISTCTA -

li3TCT0 -

IST(7TX -

MIL-HDBK-299{SH)3 April 1989

Pyrometer base multiple pairs: . ethylene propylene rubber or cross-linked polyethylene insulation on one copper and one constantanconduct6r, cross -linked polyolef in jacket, unarmored.Position indicator: silicone rubber insulation, glass braid, shieldedpairs, siiicone rubber jackst, armored.Single conductor, heat snd oil-resistsnt, flexible: ethylene propylene

rubber insulation, cross-linked polyolef in jacket.Single conductor, radio: cross -linked polyethylene insulation, cross -linked polyolef in jackst, u.ns~ored.Single conductor, radio: cross -linksd polyethylene insulation, cross-linked polyolef in jacket, armored.Single conductor: ethylene propylene rubber or cross-linkedpolyethylene insulation, cross -linked polyolef in jacket.Single.conductor: silicone rubber snd glass tape insulated, cross-linked polyolef in jacket, armored.

Single conductor: silicone rubber and glass tape insulated, cross-linked polyolef in jacket, unsrmored.

Thermocouple, type J, single pair: one iron and one constantinconductor, extrudsd silicone rubber insulated, glsss braided, cross-linksd polyolef in jackst, armared.

Thermocouple, type J, s@gle pair: one iron and one constantanconductor, extrudad silicone rubber insulated, glass braided, cross-linked polyolef in jackst, unsrmored.

Thermocouple, type J, multiple pairs: extruded silicone rubberinsulated, glass braid on one iron snd one constantan conductor foreach pair, silicone rubber jacket, armored.Thermocouple, type K, multiple pairs: extruded silicone rubberinsulated, glass braid on one Chromel and one Alumel conductor foreach pair, silicone rubber jacket, aimored.

Three conductors, oil-resistsnt, portable: ethylene propylene rubberor cross-linked polyethylene insulation, cross -linked polyolef injacket.

Thermocouple, type T, single pair: one copper snd one constantanconductor, extrudsd eilicone rubber insulated, glsss braided, cross -linked polyolef in jacket,. armored.

Thermocouple, type T, single pair: one copper snd one constantanconductor, extruded silicone rubber insulated, glass braidsd, cross -linked polyolef in jacket, unsrmored.

Thermocouple, we T, multiple pairs: extrudsd silicone rubberinxulated, glssa braid on one copper and one cons tantan conductor foreach pair, cross-linked polyolefin jacket, armored.

Three conductors, heat and oil-resistant, flexible: ethylene propylenerubber insulation, cross -linked polyolef in jacket.

Three conductors: ethylens propylene rubber or cross-linkedpolyethylene insulation, crose -linked polyolef in jackst, unsrmored.Three conductors: ethylene propylene rubber or cross-linkedPolyethylene insulation, cross -linked polyolaf in jacket, armored.Tvisted pairs: ethylene propylene or cross- lfnked polyethyleneinsulation, cross -linked polyolef in jackst, unsrmored.

Twisted pairs: ethylene propylene or cross-linked polyethyleneinsulation, cross-linksd polyolef in jacket, armored.

Three conductors, power supply: silicone rubber insulation, glassbraid, silicone rubber jackst, armored.

5,,


LSrRw

I ISTRWA

LSTSGA

ISTSGU

IS-TOP

LSTTRS

=TTRSA

LSTTSA

Lsmsu

LSISA

IA31SAU

tilsm

I LSISMU

MISMWA

LSISI’4WU

ISlsu

LSISUA

ISISWA

LSlswu

LS1S50MA

IS1S50MU

141L-HDsK-299(SH)3 April 1989

lhree conductors, radio: cross -linked polyethylene insulation,cross -linked .polyolefin jacket, unarmored.Three conductors, radio: cross-linked polyethylene insulation,cross- linksd polyolefin jacket, armored.Three conductors: extrudsd silicone rubber -d glass insulation,cross -linked polyolef in jackst, armored.Three conductors: extrudsd silicone rubber and glass insulation,cross -linkad polyolef in jackat, unarmored.Twisted pairs, oil-resistant, portable: ethylene propylene rubber orcross -linksd polyethylene insulation, cross-linked polyolef injackbt.Wsted pairs, radio, shiel&d, flexible: cross -linked polyethyleneinsulation, braided shield for each pair, cross -linked polyolef injacket, unarmored.Twisted pairs, radio, shielded, flexible: cross -linked polyethyleneinsulation, braided shield for each pair, cross-linked polyolef injacket, armored.

Tvisted pairs: extruded silicone rubber and polyamide special

P~Ose, cross-linked polyolef in jackst, armored.‘TwisTedpairs: extru&’d silicone rubber and polyamide special

PurPOse, cross-linked polyolefin jacket, unarmored.Single; shieldsd: cross -linked polyethylene insulation, braidedshield.on each conductor, cross -linkad poly.olefin jacket, armored.

Single, shieldsd: cross -linked polyethylene insulation, braidedshield on each conductor, cross-linked polyolef in jacket, unarmored.Singles, shielded, qultiple conductor: cross-linked polyethyleneinsulation, braided shield on each conductor, cross-linkedpolyolef in jacket, armored.Singles, shielded, multiple conductor: cross -linked polyethyleneinsulation, braided shield on each conductor, cross-linkedpolyolef in jacket, unsxmored.Singles, shielded, multiple conductor: cross -linked polyethyleneinsulation, braidsd shield over each conductor, cross-linkedpolyolef in jackat, armored.Singles, shielded, multiple conductor: cross-linked polyethyleneinsulation, braidsd shield over each conductor, cross-linkedpolyolef in jackst, unarmored.Singles, shieldsd: cross -linked polyethylene insulated, braidedshield on each conductor, cross-linked polyolef in jacket, armored.Singles, shieldsd: cross -linked polyethylene insulated, braidedshield on each conductor, cross-linked polyolefin jacket, unarmored.Singles, shieldsd: cross -linked polyethylene insulation, braidedshield on each conductor, cross -linked polyolef in jacket, armored.

Singles, shieldsd: cross -linked polye@ylene insulation, braidedshield on each conductor, cross-linked polyolefin jacket, unarmored.Singles, shieldsd, 50-ohuI,multiple conductor: cross-linkedpolyethylene insulation, braided shield on each conductor, cross-linked polyolef in jacket, armored.Singles, shieldsd, 50-ohm, multiple conductor: cross-linkedpolyethylene insulation, braided shield on each conductor, cross-linksd polyolef in jacket, unarmored.

6


LS1S50H-US -

lsls75nA -

IS1S75MU -

Isa -

.LS2AU -

LS2AUS -

LS2CS -

IS2SA -

IS2SJ -

1.S2SJA -

lS2ilJ -

LS2SUS -

L52SWA -

IS2SWAU -

152SWL-7 -

u2swlA-7 -

IS2SW0 -

L32SWUA -

IS2U -

LS2UA -

Ii32uw-42 -

E32UWA-42 -

U2UWS-42 -

HIL-HDBK-299(SH)3 April 1989’

Singles, shielded, 51)-Ohm,multiple conductor: cross-linkedpolyethylene insulation, braided shield on each conductor, cross-linked polyolef in jacket, double overall shielded.

Singles, shielded, 75-ohm, multiple conductor: cross -linkedpolyethylene insulation, braidsd shield over each”conductor, cross -linked polyolef in jacket, armored.

Singles, shielded, 75-ohm, multiple conductor: cross-linkedpolyethylene insulation, braided shield over each conductor, cross -linked polyolef in jackst, unarmored.

Tvisted pairs, shielded: crose -linked polyethylene insulation,overall br,aidcd shield, cross -linked polyolef in jacket, arqored.

Tvisted pairs, shieldsd: cross ~linked polyethylene insulation,overall braided shield, cross -linked polyolef in jacket, unarmored.

Tvisted pairs, shielded: cross-linked polyethylene insulation,overall braided shield, cross-linked polyolefin jacket, doubleoverall shielded.Pairs, shielded: cross -linked polyethylene insulation, doublebrai&d shield overall, cross -linked polyolef in jacket.Pairs, shieldsd: cross. linked polyethylene insulation, bra~ded.

shield over each ‘pair, cross -linked.polyolef in jacket, armored.Pairs, ahieldcd: ethylene propylene rubber or cross -linkedpolyethylene insulation, overall braided shield, cross -linkedpolyolef in jacket, unarmored.Pairs, ahieldcd: ethylene propylene rubber or cross -linkedpolyethylene insulation. overall braided shield. cross -linkedpol~ole~in jackct, .irmored.Pairs, shielded: cross -linked polyethylene insulation,ehield over each pair, cross-linked polyolef in jacket,Pairs, shieldsd: cross -linked polyethylene insulation,shield over each pair, cross -linked polyolef in jacket,overill shielded.Pairs, shielded: cross-linked polyethylene insulation,shield over each pair, cross -linked polyolef in jacket,Pairs, shielded: cross- linked polyethylene insulation,

shield over each pair, cross-linked polyolefin jacket,Paira, shielded: c“ross-linked polyethylene insulation,shield over each pair, cross -linked polyolefin jacket,

Pairs, shielded: cross -linked polyethylene insulation,shield over each pair, cross-linked polyolefin jacket,

Paire, shielded: croae -linked polyethylene insulation,shield over each pair, cross -linked polyolef in jacket,Pairs. shielded: cross -linked uolvethvlene insulation.

braidedunarmored.braideddouble

braidedarmored.brai&dunarmored. .braidedunsrmored.braidedarmored.braidedunarmored.braided

shieid over each pair, cross- l~nk~d p~lyolef in jackct i armored.Pairs: cross -linked polyethylene insulation, overall braided shield,cross -linked polyolef in jacket, unarmored.Pairs: cross -linked polyethylene insulation ,’overall braided shield,cross-linked polyolefin jacket, armored.

Tvieted pairs: cross -linked polyethylene insulation, overall braidedshield, cross -linksd polyolefin jacket, unarmored.

Twisted pairs: cross -limed polyethylene. insulation, overall braided .shield, cross -linked polyolef in jacket, armored.

Tvisted pairs: cross-linked polyethylene insulation, overall braidedshield, cross-linked polyole fin jacket, double overall shielded.

7


KIL-HDBK-299(sH)3 April 1989”

LS2WA

lS2WAlJ

LS3SA

=3SF

LS3SJ

LS3SJA

U3SU

LS3SUS

IS3SWA

U3SWU

LS3SWUS

U3U

LS3UA

LS4NW8

lStJlJA8

ISSJ

=4SJA

u15KvTsGA -

LS5KVTSGU -

IS6SGA -

LS6SGU -

LS7PS -

U7SGA -

Pairs: cross -linked polyethylene insulation, ovsrall braided shield,cross. linked polyolefin jacket, armorsd..;Pairs: cross -linked polyethylene insulation, overall braided shield,cross- linked polyoleffn jackst, uncnnored.

Triads, shieldsd: cross -linked polyethylene insulation, braidedshield over each triad, cross-linked polyolefin jacket, armored.

Triads, shielded, flexible: cross -linked polyethylene insulation,braided shield over each triad, polyester tape over the assembledtriads, cross -linked polyolef in jacket.

Triads, shielded: ethylene propylene rubber or cross- linkedpolyethylene insulation, overall braidsd shield, cross-linked

polyolef in jacket, unarmored.Triads, shieldsd: ethylene propylene rubber .or cross- linksdpolyethylene insulation, overall braided shield, cross -linkedpolyolefin jacket, armored.

Triads, shielded: cross -linked polyethyl.ine insulation, braidedshield over each triad, cross -linked polyolefin jacket, armored.

Triads, shielded: cross -linksd polyethylene insulation, braidedshield over eech triad, cross -linksd polyolef in jacket, doubleoverall shieldsd.

Triads, shieldscl: cross -linksd polyethylene i~ulation, braidedshield over each triad, cross -linksd polyolefin jacket, armored.

Triads, shielded: cross -linked polyethylene. insulation, braidedshield over each triad, cross -linksd polyolefin jacket, unsrmored.

Triads, ahieldsd: cross-linked polyethylene insulation, braidedshield over eech triad, cross -linksd polyolef in jacket, doubleoverall shielded.

Triads: cross -linked polyethylene insulation, marker braid on eachtriad, cross -Linked polyolef in jacket, unarmored.

Triads: cross-linked polyethylene insulation, marker braid on eachtriad, cross -linked polyolef in jacket, armored.

Four conductors: cross -linked polyethylene insulation or ethylene

propy~ene rubber, cross-linked polyolef in jacket, unarmored.Four conductors: cross -linked polyethylene insulation or ethylenepropylene rubber, cross-linked polyolefin jacket, armored.Four conductors, shielded: ethylene propylene rubber or cross-linkedpolyethylene insulation, overall braided shield, cross -linkedpolyolef in jacket, unarmored.Four conductors, shielded: ethylene propylene rubber or cross -linkedpolyethylene insulation, overall braidsd shield, cross-linkeduolvolef in iacket. armored.5000~v01t, tiree conductors: silicons rubber and glass tapeinsulation, cross -linksd polyolef in jacket, armored.

5000-volt, three conductors: silicone rubber and glass tapeinsulation, cross -linked polyolef in jacket, unarmored.

Six conductors: silicone and glass insulation, cross -linkedpolyolef in jacket, armored.Six conductors: silicone and glass insulation, cross -linkedpolyolef in jacket, unsrmored.

Saven conductors, power supply: silicone rubber insulation, glassbraid, silicone rubber jacket, armored.Seven conductors: silicone rubber cnd class insulation. cross-linkedpolyolef in jacket, armored.

..

8,,

.


ES7SGU -

IS8WW6 -

IS8NWA6 -

5.2


Seven conductors: silicone rubber and glass insulation, cross-linkedpolyolef in jacket, unarmored.Eight conductors: cross -linked polyethylene or ethylene propylenerubber insulation, cross -linked polyolef in jacket, unarmored.

Eight conductors: cross -linked polyethylene or ethylene propylenerubber insulation, cross -linked polyolef in jacket, armored.

Cable -es and construction character Sties (as snecified lx!ML -C-24640) list. Cable types and construction characteristics (as specified inMIL- C-24640) are as follows:

1“ FXWA

~’. ,KxcwHxcow

MXCWA

Hxo

Uxso

.Trx

m

Trx.s

TTXSA

lmso

‘mxw

DX

DXA

DXW

DXOW

DXWA

“h

FxA

Fxw

Fxow

Double conductor, power “supply: cross -linked polyalkene insulation,crose-linked polyolefin jacket, unarmored.

Double conductor, power supply: cross-linked polyalkene insulation,cross-linked polyolefin jacket, armored.

Two conductors: mica polyimide insulation, cross-linked polyolefinjacket, unarmored.Two conductors: mica polyimide insulation, cross-linked polyolef injacbt, overall shielded.

Two conductors: mica polyf.mide insulation, cross-linked polyolef injacket, arpored.Four conductors, power supply: cross -linked polyalkene insulation,cross -linked polyolef in fluoride jacket, unarmored.Four conductors, “power supply: cross-linked polyalkene insulation,cross -linked polyolef in flucyide jac~t, armored.

Four conductors: mica polyimide, insulation, cross-linked polyolef injackst, unarmmred.Four conductors: mica polyimide insulation, cross -linked polyolef inja.ket, overall shielded.Four conductors: mica polyim@ insulation, cross-1 inked polyolef injacket, armored.Multi-conductor, control: mica polyimide insulation, cross-linked “”polyolefin jacket, —ored.

Multi -conductor, control: mica polyimide insulation, cross-linkedpolyolef in jacket, overall shielded.

Multi-conductor, control: mica polyimide insulation, cross-linkedpolyolef in jacket, armored.

Multi-conductor, power supply: cross -linked polyalkene insulation,cross -linked polyolef in jackst, overall shieldad.

Multi -conductor; cross -linksd polyalkene insulation, cross-linkedpolyolef in jacket, overall shiel&d.

Multi-pair, twisted: cross-linked polyalkene insulation, cross -linkedpolyolef in jacket, unarmored.

t’!ulti-pair, tvisted: cross -linked polyalkcns insulation, cross -linkedpolyolef in jacket, armored.

Multi-pair, tdsted, shielded: cross -linked polyalkene insulation,cross-linked polyolefin jacket, unarmored.

Multi-pair, tvisted, shielded: cross -linked polyalkene insulation,cross -linked polyolef in jacket, armored.

Multi-pair, tvisted, shieldsd: cross-linked polyalkene insulation,cross-linked polyolefin jackat, overall shielded.

Multi-pair: mica polyfmide insulation, cross -linked polyolef in jacket,unarmored.

.

9

.


‘lTKOw

TTXWA

TK

TXA

TXW

TKow

TKWA

IXISo

Ix.sow

2XA0

2K0

2XOW

2KS

2KSA

2XS0

2XSAW

2KSAOW

2K5AWA

2XSX0

2KSW

2KSWA

3X5

3XSA

3KSW

3KSOW

KIL-HDBK-299(sH)3 April 1989

Multi-pair: mica polyi.mide insulation, cross-linked polyolef in jacket,overall shielded.

Multi -pair: mica polyimide insulation, cross-linked. polyolef in jacket,armored.

Three conductor, power supply: cross -linked polyolef in insulation,cross -linkad polyolefin jacket, unarmored.

lhree conductor, power supply: cross -linked polyolef in insulation,cross -linksd polyolef in jackat, armored.

Three conductor, power: mica polyimida insulation; cross-linkedpolyolef in jackst, unarmored.Three conductor, power: mica polyimide insulation; cross-linkedpolyolefin jackct, overall shiel~d.

Three conductor, power: mica polyimidc insulation; cross-linkedpolyolef in jacket, armored.

Multi -conductor, shieldad: cross-linked polyalkene insulation, cross-linked polyolef in j’ackst, overall shielded.

Multi-conductor, shielded: cross -linked polyalkene insulation, cross-li@ccd polyolef in jacket, overall shielded.

Multi-pair, twisted: cross -linked polyalkene insulation, cross-linkedpolyolef in jacket, overall shieldad.

Multi-pair, twisted: cross -linked polyalkene insulation, czoss -linkedpolyolef in jackat, rwerall ihieldcd.

Multi -pair, tvisted: cross -linked polyalkene insulation, cross-linkedpolyolef in jackst, overall shieldad.

Multi-pair, twisted, shielded: cross -linked polyalkene ikulation,cross -linkad polyoleffn jackst, unsrmorkd.

Multi-pair, twisted, shieldad: cross-linked polyalkene insulation,cross-linked polyolefin jacket, srmored.

Multi-pair, tiisted, shieldsd: cross -linked polyalksne insulation,cross-linked polyolefin jackat, overall shielded.

Iiulti-pair, shieldad: cross -linked polyalkene insulation, cross-linkedpolyolef in jackst, ~rmored.

Multi-pair, shieldad: cross -linked polyalkene ‘insulation, cross-linkedpolyolef in jackct, overall shielded.

Multi-pair, shielded: cross -linked polyalkene insulation, cross-1 inkedpolyolef in jacket, armored.

Multi-pair, twisted, shielded: cross -linked polyalkene insulation,cross -linkad polyolefin jacket, overall shielded.

Multi -pair, shielded: cross -linked polyalkene insulation, cross-linkedpolyolefin jackat, unarmored.

Multi-pair, shielded: cross -linkad polyalkene insulation, cross -linkedpolyolef in jackct, overall shielded.

Multi -Dair. shielded: cross -linked nolvalkene insulation. cross-linkedpolyoief ii jackct, armored.

Multi-triad, twisted, shieldsd:cross-linked polyolefin jacket,

Multi- triad, tvisted, shielded:cross -linked polyolef in jackst,

Multi -triad, tvistad, shielded:cross -linked polyolef in jackct,

Multi- triad, twisted, shieldad:cross-linked polyolefin jacket,

. .

cross -linked polyalkene insulation,unarmored.cross -linked polyalkene insulation,armored.cross -linked polyalkene insulationunarmored.cross -linked polyalkene insulation,overall Shielded.

10



3XSUA -

7XW -

7XWA -

5.3

Multi-triad, twisted, shielded: cross-linkedcross-linked polyolefin jacket, armored.

Seven conductors: mica polyimida insulation,jacket, unarmored.Seven conductors: mica polyimide insulation,jacket, armored.

polyalkene insulation,

cross -linked polyolef in

cross -linked polyolef in

Cable tvnes and construction characteristics [as sr.ecified~

lUL -C-915) list. Cable types cnd construction characteristics (as specified in141L-C:915) sre as follows:

CVSF

DLT

DSS

DSWS

FSS

Jb

MCSF-4

MSP

MSFu

nwF

S2S

THOF

TRFTPOM-6

400 -Hr aircrsft servicing: three synthstic rubber insulated conductorsand one uninsulated conductor, overall polychloroprene jacket.

Divers lifeline and telephone: four rubber insulated conductors cabledaround ah insulated steel core, reinforced polychloroprene jacketoverall.

Double conductor, shielded: robber insulation, overall braidsd shield,polychloroprene or chloroaulfomted polyethylene jacket.Double conductor, shieldad: rubber insulation, overall ,braided shield,polychloroprene jacket.Four conductors, shielded: rubber insulated, overall braided shield,po~ychloroprene or chlorosulfotited” polyethylene jacliet.

Jet aircraft servicing: four “ru6ber insulated conductors, twoconductors Navy size 250, tvo conductors Navy size 6, reinforcedpolychloropiene jacket.

Multiple conductor ,“acoustic minesweeping, power: two American WireGauge (AWG) 6 and tvo AWG 1 conductors, rubber insulation, reinforcedpolychloroprerie jacket:

Multiple conductor: fifty-nine conductors, sixteen AWG 22 havingfluorocarbon insulation and a braided copper shield, eighteen AWG 20hsving polyvinyl chloride insulation and a braided copper shield (ninesingles, one triad and khree paizs, each shielded) , twenty-five Navysize 3 having polyvinyl insulation (eight pairs and three triads, eachshielded), polychloroprene. jadcet.

Multiple conductor: fifty-nine conductors; sf.xteenAWG 22 hivingfluorocarbon insulation and a braidsd copper shield, eighteen AWG 20having polpinyl chloride incubation and a braided. copper shield (ninesingles, one triad and three pairs, each shielded) , tventy -five Navysize 3 having polyvinyl insulation (eight pairs and three triads, eachshielded) , polychloroprena jacket, watertight.

Multiple conductor: rubber or cross-linked polyethylene insulation,arctic type neoprene jacket.

Tvo conductors, shieldsd: cross-linked polyethylene insulations,braided shield, rubber insulation over shield, outer -braided shield;reinforced rubber, insulatsd, arctic type polychloroprene jacket.

Three conductors, heat and oil resistant, flexible: synthetic rubberinsulation standard thermoplastic jacket on THOF-42, cndpolychloroprene jacket on THOF-400 and THOF -500.Single conductor, flexible: “ rubber insulation, polychloroprene jacket.Telephone, porrsble, multiple conductor: copper- clad steel conductors,polypropylene insulation, six pairs cabled, polyurethane jacketapplied in tvo layera.

11


KIL-HDBK-299(SH)3 April 1989 -

TRXP - Single conductor: polychloropreneTSP - l%isted pairs: polyvinyl chloride

jacket, watertight, unarmored.TSPA - Twisted pairs: polyvinyl chloric@

jacket, watertight, armored.TSS - Three conductors. suecial uurr.ose.

jacket.insulated, special thermoplastic

insulated, special thermoplastic

. shielded: rubber insulation, overallbraided shield, poiychlor~pr~ne or chlorosulfoncted polyethylene jacket,

lSWF -●Singles, shielded: polyethylene insulation, braided shield on each

2SWF -

5ss -

7ss -

5.

conductor, arctic -e polychloroprene jacket.Pairs, shielded, watertight, flexible: polyethylene insulation, braidedshield over each pair, arctic -e polychloroprene .jacket.

Five conductors, shielded, sonar: rubber insulation, braided shield onone conductor only, end a braidsd shield over the assembled fiveconductors, polychloroprene jacket overall.Seven conductors, shielded: rubber, insulation, overall braided shield,polychloroprene or chlorosulfoncted polyethylene jacket.

4 ~dent ification information. Conductors and groups of conductors, suchas pairs and triads, are separately identified within a completed cable. Theidentification codss should be as specified in 5.4.1 through 5.4.9, inclusive.

5.4.1 standa d de t~~ .code The conductor identificationcode for standsrd cables should be as follows:

Color, conductoror group no.

1.2“345

678’9

10

1112131415

1617181920

Background First traceror base color’ Color

BlackWhiteRedGreenOrsnge

BlueWhiteRedGreenOrsnge

BlueBlackRedGreenBlue

BlackWhiteOrangeBlueRed

,..

. . .

.-.

.-.

.-.

.-.

. . .

BlackBlackBlackBlack

BlackiihiteUhiteWhiteWhite

RedRedRedRedGreen

12

Second tracercolor

.-.

. . .

..--..-..

-..-..-------..

..----. . .-..-..

---. . .. . .---..-


1’


2122232425

2627282930

3132333435

3637383940

4142434445

4647484950

515253S.i55

5657585960

MIL-HDBK-299 (SH)3 April 1989

Backgroundor base color

OrangeBlackWhiteRedGreen

OrangeBlueBlackWhiteRed

GreenOrangeBlueBlackWhite

OrangeUhitaBrovn,BrovnBrown

BrownBrownBrovnBrownWhite

RedGreenOrangeBlueBlack

WhiteRedGreenOrangeBlue

BlackWhiteRedGreenOrange

First tracercolor

GreenWhite

BlackBlackBlack

BlackBlackRedRedBlack

BlackBlackWhiteWhiteRed

UMteRed.-..

BlackWhite


WhiteOrangeRedRedOrange

BlackOrangeRedBlackBlack

OrangeOrangeOrangeBlackGreen

Second tracercolor

. . .

RedRedWhitewhite

WhiteWhiteGreenGreenGreen

OrangeGreenOrangeOrangeOrange

BlueBlue.-.......

---..-. . .-..

Blue

BlueRedBluaOrangeRed

OrangeBlackBlueBlueOrange

GreenGreenGreenBlueBlue ..

13””



6162636665

6667686970

71727376“75

7677787980

8182838485

8687888990

9192939495

96979899100



BlueBlackWhiteRedGreen

OrangeBlueBlackWhiteRed

GreenOrangeBlueBlackRed

GreenOrangeBlueRedGreen

BlueOrangeGreenBlackWhite

BlueBlackWhiteRedGreen

BlueBlackwhiteRedGreen

orangeYellowYellowYellowYellow

First tracercolor

GreenRedOrangeBlackOrange

WhiteWhiteGreenGreen

.Green

WhiteRedRedOrangeOrange

RedWhiteWhiteWhiteWhite

BlackWhiteRedGreenGreen

Green“OrangeOrangeOrangeOrange

OrAgeBlueBlueBlueBlue

Blue..-

BlackWhiteRed

Second tracercolor

OrangeBlueBlueBlueBlua

RedRedBlueBlueBlue

RedBlackBlackBlueBl”ue

BlackGreenGreenOrangeOrange

Green..-.......-.

.-.

..-----..---

---. . .---. . .---

. . .

. . .

. . .

. . .

. . .

14


IiIL-HDBK:299(SH)3 April 1989


101102103104105

106107108109110

111112113114115.

116117118119120

121122123124125

126127


YellowYellowYellowBlackWhite


WhiteGreenOrangeBlueBlack

RedGreenOrsngeBlueBlack

WhiteRedOr~eBlusBlack

UliiteRed

First tracercolor

GreenOrangeBlueYellowYellow

YellowYellowYellowYellowYellow

YellowYeLlOwYellowYellowYellow



YellowYellow

Second tracercolor

. . .

. . .

..-

.-.-..

. . .

.-.---. . .

Red

RedRedRedRedWhite

WhiteWhiteUhiteWhiteGreen

GreenGreenGreenGreenBlue

BlueBlue

5.4.2 ~eleuhone identification code (TSL~. The conductor identificationcods for telephone cables should be as follows:

Color orconductor no. GQk

1 Black2 White3 Rsd4 Green5 Orsnge6’ Blue

5.4.2.1 Conductor uairing. Theshould be ss follows:

Color orconductor no- GQl@i

7 Brovn8 Gray9 Yellow

10 Purple11 Tsn12 Pink

pairing of conductors for forming pairs

15


141L-HDBK-299(sH)3 April 1989

Number 1 paired with numbers 2 through 12 for next eleven pairs.Number 2 paired vi th numbers 3 through 12 for next ten pairs.Number 3 paired with numbers 4 through 12 for next nine pairs.Number 4 paired with numbers 5 through 12 for next eight pairs.Number 5 paired with numbers 6 through 12 for next seven pairs.Number 6 paired with numbers 7 through 12 for.next six pairs.Number 7 paired with numbers 8 through 12 for next five pairs.Number 8 paired with numbers 9 through 12 for next four pairs.Number 9 paired with numbers 10 through 12 for next three pairs.Number 10 paired with numbers 11 through 12 for next two pairs.Number 11 paired with number 12.

5.4.3 S ec a de t~ code (SPL~. The special identification code ..should be the same condtictor identification as specified in 5.6.2.

5.4.4 ~isted uair identif ication code. This code conxists of numbers insequence running from 1 through the number corresponding to the total quantity oftwisted pairs in the cable. Both conductors in each pair must be nwmbered thesame, &noting the sequence number of the pair. Distinction between the twoconductors is provided by different colored insulation. Conductors of a cablewith a single pair need not be nwmbered.

5.4.5 Nisted triad identification code. This code consists of numbers insequsnce running from 1 through the number corresponding to the total quanti~. oftwisted triads in the cable J Each of the three conductors muxt be numbered thesame, denoting the sequence number of the triad. Distinction betveen the threeconductors is provided by different colored insulation .“ Conductors of a cablewith a single triad need-not be numbered.

5.4.6 Lstter identif ication code (Lllll.consists of the letters A, B, C, and D printedwhite, red, and green ink,,respectively.

The letter identification codein block type, and with black,

5.4.7 ~ethodx of auulvin~ identif ication.

5.4.7.1 Method l,. Identification ma’thod 1 consists of surface printing ofboth number and color &signations. The legend should be printed in contrastingcolor: preferably white ink on black or dark background or black ink on white orlight background. The legend is repeated at intenals not exceeding 3 inches.Alternate legends shall be inverted; for example:

10 OWGE-BLiCK XW’Iff,-13W30 OT

The character type should be block or italic and have athe diameter over which it is applied as follows:

height in accordance with

16



I

Diameter rsnge Height of character(in h)c finch. auuroximate >

o.o&5 to 0.070. 0.025.070 to .095 1/32.095 to .115 3/64.115 to .200 1/16.190 to .250 5/6k.235 to .375 3/32.330 and larger 1/8

5.4.7.2 !!ethod 2. Identification method 2 uses opaque white polyestertapes which have been printed with both the number and color designation prior toapplication. The legen’d should .be printed with black ink, and.be repeated atintervals not exceeding 3 inches. ‘I’hecharacter type.should be block, and shouldbe approximately 3/32 -inch high.

‘5.4.7.3 Nethod 3.. I&ntification method 3 uses solid colors or solid basecolors with tracers, as required. The base color may be either the color of theinsulation. or the color of”a coating applied to the insulation. The tracersshould be approximately 1/32-inch,tide ink stripes of the required COlOr and

should be applied helically with 1-1/2 plus or minus 1/4-inch lay. If tvo tracersare required, the second tracer must be half the width of the first tracer.

5.k.7.h Method h. Identification method 4 uses colored braids. Tracersshould consist of the required colors applied by three adjscent carriers. Where

two tracers are required, they must be applied with reverse lay.

5.6.7.5 Method 5.. Identification method 5 uses the printed letter on theoutermost insulating tape or the printed letter on a polyester binder tape overthe insulating tapes. The letters should be”approximately 3/16-inch high andhave been printed at intervals not exceeding 3 inches prior to the application ofthe tape to the conductor. If the insulating tapes are vhite, no printing isrequired on the B (white) conductor.

5.4.7.6 Method 6. Identification method 6 consists of numerals printed inink on the conductor insulation. For conductors having a jacket directly overthe insulation, the “numerals may be printed in ink on the jacket, at themanufacturer’s option. Uhita ink gmst be used for a red or black background;black ink must be used for a white background. Numeral width should beproportional to the conductor 1s outside diameter (od) as follows:

Diameter range Height of character(in h)c finch. auDroximate 1

17

0.045 to 0.095 0.025.096 to .120 3/64.121 to .175 1/16.176 to- .330 3/32.331 and larger 1/8


I

IUL-HOBK-299(SH)3 APril 1989

Numeral height should be two snd one-half to three times numeral width. Each

numeric legend should be underlined. Tvo -digit legends must have the bottomnumeral underlined. Legends should be alternately inverted (see 5.6.7.1) snd berepeated at.intervals not greater than 1-1/2 inches.

5.4.8 ~anufacturer rs identification taue. Host cab’les and cords contain acontinuous, thin, moisture -resistant marksr tape, not less than I/lO-inch wids.Unless orhe=ise approved by the Naval Sea Systems Comsnd (NAVSSA), the markertape must be placed ,directly under the cable, cord binder tape, Or jacket. fietape should be printed to show the following information at inten-als not greater,gha.n1 foot: nsme and location of manufacturer, year of manufacture,specification number (such as “kIL-C-24643) , snd progressive serial number. Theserial number is not necessarily a.footage msrker. A serial number must not berepeated by a msnufacrurer in eny.one year for sny one type and size of.cable orcord.,

5.&.9 Year of manufacture. In order to facilitate storage and issue ofcable on a first in, first out bssis, cable reels, COilS, ~d containers shippedby manufacturers must be msrksd to show the year of manufacture. Msrkingsconsist of a strip.approximately 2-inches tide and colored as follovs for theparticular year of manufacture. These markings are repeated at 5-year intervals,as follows :

Year of manufacture

197919801981198219831984198519861987198819891990199119921993199419951996

Identifvinr CO1OX

BlueWhiteRedGreenOrsngeBlueWhiteRedGreenOrsngeBlueWhiteRedGreenOrangeBlusWhiteRed

.

18



TA8LS I.’ k!IL-C-24643 cable auulication data. ~

application

eneral usage:For all portions of power, lighting, interior communicationweapons control and electronics systems, except wherecircuit parameters (such as audio or radio frequsncy, lov-level microphone, smchro. scale volta~e. and other tvuesof signals)- require-’special types of cibie. Types LSfi,LS3U, IS.DNW,LST’lik7,LSFNW, ISMNW, ESHOF, LSDHOF, LSTHOF,ISFHOF, LMHOF, MDCOP, LSTCOP, snd 13MCOS should be usedonly for runs that are either totally within one compart -ment, or tot’allywithin tvo contiguous comparuuents.However, these q-pe csbles must not -be used vhere a water-tight deck or watertight bulkhead below flooding water levelII (iWL-11) is penetrated. Type SG cable should be used fo]comections between the ship service generators and theirrespective switchboards snd betveen sections of the shipservice svitchbosrds.

High voltage - 60 ilz:.For 3000- and 5000-volt, three-phase power applications.

I Casu.sltypower.

400-Hz power:For 400-H2 service for static frequency chsnger cables, busties, and feeders where csble of lover impedsnce isrequired to reduce voltage drop.

Audio and telephona:For audio, telephone, call bell, announcing, and alarmsystems. Msy also be used for other interior communicationsnd weapons control systams, provided smpere rating of thecable snd voltage drop for the system are not exceeded.Types ISTFNW and LST’TOP should be used only for runs thatare either totally within one compartment, or totallywithin tvo contiguous compartments. However, this typecable should not be used where a watertight deck or water-tight bulkhead below FQL-11 is penetrated.

See footnotes at end of table.

Cable type 2,/

Non-flexinservic

MDNWLSTNWlJ3FNwEwNwLssscuLSDSCULSTSCULSFSCULS6SCULS7SCUExScuLSHULS3U

LS5KVTScu

LS6SCU

LSTPNUIsrl’su

Repeatedflexingservice

LSSHOFtiDHOFLSTHOFIiWHOFLSMHOFLSDCOPLSTCOPLSMCOS

LSTHOF-4:

LSTTOP

19


I ,’


TABLS 1. 141L-C-24643 cable am lication data. ~ - Continued

pplication

adio

adio frequency:.For application up to 2 megahertz (KHz).Maximum total copper operating temperature must not exceed75*C.

,egaussing

. ..-

‘hermocouple and Dyromecer temperature range:me TC’&, 125 t~-Type TCJX, 150 toType TCXR, 260 to

260”C ‘.540” C870”C

:hielded circuits:For combat systems, interior communications, lighting, andpower circuits, vhere shielding of 400 Hz (that is,symhro, pulse, scale voltage) signals, or other signalsis required. Where a watertight clackor bulkhead belowFWL-11 is to be penetrated, types LSISMWU, LS2SWAU,LSISWU, LS2SWU, LS2UW, LS2WAU, or LS3SWU should be used.

Cable type U

Non-flexingservice

L5SRWLSDRW15TRW

lssscuMDSGUISTSGULSFSCULS6SGULS14DUI.SKDYLSMSCU

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:epeatedIexing:ervice

SrrRs

STTRS

See footnotes at end of table.

20



I

I

TABL2 1. MIL-C-24643 cable auulication dsta. ~ - Continued

Cable type ~

NOn - Repeatedflexing flexing

~pplication service semrice

;hieldsd circuits (continusd) LS2SUIS52UULS2WAULS2UE33SJLS3SULS3SWULS4SJLSKS

[icrophone circuits LS14COSIld’lMoP

$/ The ordsr of listing of cables. for general applications dsta has nosignificant mesning for their usage.

~ Many cablea are manufactured in variations of”armored, unarmored, sndunsrmored with overall shielded” (see 5.1) . Armored cable is required to beused on all nuclear ships for propulsion plant and reactor compartments andis desirable in all other aress unless technically prohibited. The We Of

armored cable on non-nuclesr ships is optionsl and to be determined by theoverhsul shipyard, except armored cables shsll not be installed in weatherlocations d~- to EMC co~idsrations.

TABLE II. HIL -C-24640 cable auulication dsta. J/

Csbla type ~

NOrt- Repeatedflexing flexing

Application service service

:eneral usage: DxFor all portions of paver, lighting, interior communication, TXweapons control, snd electronics systems, except where Fxcircuit parameters (such ss, audio or radio frequency, low- DXW

level micrOphOne. sYchrO, scale vOltage, and other types of TKwsignsls ) require special types of cable. Types DX, Tx, FX FKWand MXO should be used only for runs that are either totally mwithin one compartment, or totally within tvo contiguous KKccOmparQnents. However, these types of cable should not be MScwused vhere a watertight deck or watertight bulkhead belowPUL-II is penetrated.

See footnotes at end of table,

. . . . . .. .. . . .

21


MIL-HDBK-299(SH)3 APril 1989

TAILS II. JIIL-C-24640 cable aml ication data. ~ - Continued

I

Cable type ~

Non-. Repeatedflexing flexing

pplication service service

udio and telephone:For audio, telephone,, call bell, announcing snd alarm T-TXsystems. Ksy also be used for other interior communication mcnd weapons control systems, providsd smpere rating of thecable and voltage drop for the system are not exceeded.Type T1’X should be tied only for - that are eithertotally within one compartment, or totally within tvocontiguous comparunents. However,, this type of cable shouldnot be used ,where a watertight deck or watertight bulkheadbelow lWL-11 is penetrated.

adio frequency:For applications UP to ~0 ~: TTxsmaximum total copper operating temperature must not exceed

75” C.

hielded circuits:For combat systems, interior communications, lighting, and 2XA0power circuits vhere shielding of 400-Hz (synchro, pulse, IX31Soscale voltage, and so forth) signcls or other signals is 23Srequired. Types 3X.SOW, 2XSAW, 2RBW, 2XOW, and 3XSW must ‘be ~oused where a watertight deck or bulkhead below FWL-II is 3X5to be penetrated. 2X0

2XS0IXSow2XSAW2XSW2ROW3XSW

N The order of listing of cables for general applications data hcs ‘nosignificcnt mecning for their usage.

~ Many cables are manufactured in variations of armored, unarmored, andunc~ored with overall shielding (see 5.2) . Armored cable is required to beused on all nuclear ships for propulsion plant and reactor compartments andis desirable in all other areas unless technically prohibited. The use ofarmored cable on non-nuclesr ships is optional and to be determined by theoverhaul shipyard, except armored cables shall not be installed in weatherlocations due to E14Cconsiderations.

22


141L-HDRK-299(SH)3 April 1989

TAEL.E III. MIL-C-915 cable auulication data. ~

Cable type ~

NOn- Repeatedflexing flexing

application service sewice

utboard submersible:For .hydrophones, transducers, outboard dial telephones, 14SPW 14sP

retractable sntenqae snd sfmilar.equipment. Types m, TSPA TSPlSWF, snd 2SWF are for hydrophores, transducers, and lPR-A20E 5s5telephone lines in the weather. ~es lPR-A20E, lPR.-16, lPR-16 525

7PR-16, 3PR-16, lQ-16, ITR-16,’and 7SPR-16S are only forSUbm=ine outboard use.

7PR-16 DSS2SPR-16 FSS3PR-16 TSSlQ-16 nwFITR-16 DSWS7sPR-16S MCSF

lSWF2SWFTPUM

‘elding electrode circuit TRF”TPXF

here -to-ship power THOF-4002TIOF-500

iver’s line and telephone DLT00-R2 aircraft servicing CVSF-4C aircraft servicing .,. JAS-250

~ The ordar of listing of cables for,general application data has no :ignificancmeaning for their usage.

M Many cables are manufactured in variations. of armored, unarmored, snd=rmored with overall shielding (see 5.3) .

TARLR IV. Commercial cable auolication dsta. JJ

Cable rype-Application repeated flexing

service

Cords for portable tools snd equipment: Un&rvriters approvec

IFor power supply to electric typewriters, office S, SO, ST, SJ, SJO,mschines, electric drills, sanders, portable extension SJTlights, and similar equipment. Safety ground conductorsmust be green.

~ The order of listing of cables for general application data haa no significantmeaning for their usage.

23


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26


Previ0ut3or present type,and applicable HIL-C-915 Present,type, and applicable Obsolete type, and detailspecification sheet number specification sheet number specification number

3U/A..................../53 lS3U/A.............HIL-C-24643/37 3U.........UIL-C-24145/134NW8/A................../16 LS4NW8/A...........UIL-C-24643/55 None4sJ/A.................../60 LS4SJ/A............HIL-C-24643}43 FBSP......nli-c-915/24SJ/A.................../60 LS&SJ/A............HIL-C-246h3/43 ; 4SJ.......141L-C-24145/205KvTsGU/A.............../36 LS5KVTSCU/A........MIL-C-24643/22 5KVT5GA...141L-C-2194/115ss,..................../74 5ss................UIL-C-915/74 None6sGu/A................../33 LS6SCU/A,..........llIL-C-24643/19 6SOA......HIL-c-219b/67PS...................../40 LS7PS..............U1L-C-24643/267SCU/A

‘7PS.......UIL-C-23206/3................../36 LS7SCU/A...........HIL-C-2h6h3/20

7ss7SCA.......H~L-C-2194/9

...................../8 7ss................UIL-C-915/S NorIeSW6/A .................../75 W7NU6/A. ;.........k31L-C-24643/54 Norm

Nu

TABLE V. $uDerse@aion datq. - Continued

.,


)41L-HDBK-299(SH)3 April 1989

5.5 prief exnlanation of cable ratines and charatter istics tables.

5.5.1 First five columns. Each cable is identified by the Militaryspecification and specification sheet number in the left hand column, followed bythe type designation, conductor size (AWG or MM) , number of conductors, andconductor cross sectional area (circular roils).

5.5.2 Overall diameter. The noverall diameter” is the overall measurementof the finished csble, and should be the determining dimension in selecting theproper dsck or bulkhead stuffing tube size, or multi-cable tram it,inserts. Thisdiameter is alao the determining dimension for stuffing ~es for equipment.

5.5.3 J&ted v ta e ac01 e . am itv. and minimum radius of bend. Electricalcharacteristics are given under columns headed “Rated voltage” .md 8Ampaci~”m .“Minimum radius of bend” , which is approximately eight times the overalldiameter, is also given. Cables must not be used in excess of these ratings.

5.5.4 Conducto~ catio . The letters in the conductoridentif ica,tioncolumn represent the identification, and the number represents themethod of a“pplying the identification. For example, STD-1 means standardidentification applied by method 1, which is printing of the number. and colordesignation on the outer surface of the insulation or jacket of each conductor.TEL-3 means telephone identification applied by method 3, vhich is coloredinsulation on each conductor. The abbreviations used are as follows:

STII - Standard identification codeTSL - Telephone identification codeSPL - Special identification codeLTK - Latter identification code

5.6 Cable classification (uIL-C-246k31. Cables specified in MIL-C-24643are listed in table VI un&r tha following general classifications:

-(a) Watertight (with circuit integri,~) , ,non-flexing senice:

(i) Power and lighting.(2) Control.(3) Electronic, cohnunication, and

(b) Watertight, non-flexing semice:

(1) Power and lighting.(2) Electronic, communication, and

instrumentation.

instrumentation.

(c) Non-watertight (vitb circuit integrity), non-flexing se~ice:

(1) Electronic, communication, and instrumentation.

28


I

MIL-HDBK-299.(SH)3 April 1989

(d) Non-watertight, non-flexing service:

(1) Power and lighting.(2) Control.(3) Electronic, communication, and instrumentation.

(e) Non-watertight, flexing service:

(1) Power and lighting.(2) Control.(3) Electronic, communication, and instrumentation.

I

29 ,,

I


w0

TABL@ VI (a)(l).

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UnlM294rn6.4697,733

Lwsau. M3ss.3au- M-u. imls2sau. mLsssau. MOL94au. 4mUi3w2u.lsmou. zWssou. 10UU320u.Ls.3au. s

123181214232430Sw

E930137214m

1371s1114

302-4293m2-0279an264720U471303a76M6.2323Z024377a343246302+.3iam3.2642m442m

[email protected]

31.

C&m4m

:IwoMaX03

-ii-14la1097s

16141097

W630E3ml

103.63321MI0303m3423.mldm,ad3nmxom2.cmfco,mOYl,ml

3.3m4,1106S3!3

1038013K?Nimm32,!E9

Om,S12damIml1.11813711AM

H%3.310

o.4mS33.6m,A77.7s1m.9m

0.361A14Slo.%7

1X91.1631716$2334.UI63m7m

ZF,160

2-34.0

::0-37SJ8.39-3

10012313.3

30224,04.04.3Ss6.0

S3D4S3D4SrrMS3134SID4s31MS37M

mlKmKmmamlmmIaalmoladIan1030

mldmm3C&lOxl@lodm

ICCUKmmmImomm

149’197mMI46757579.7MO10W1430mm

-ir-1733%4764~.

149197Zu

101722%47tAn

LnPs.3m 4.lSl?$6Lsr3S 9ISITS. 14IS1-FS 22IS3P4. 29

All5W.738

464Y16 LSX40A. 3LS3SGA. 4LSISGA- 9LS3SOA-lSISCiA- !!

33333

Mm4,410Io,?ao13J2mmam

A61.459.673.76a.8m

.la,1S6X8334

303.04.04s5.0

S3D.1Sm.1S3D.1m-lSlT2.1

1118 .

;69

1017364764

11M

:69

1017264764

3.0246mm24679mmsoanalm2AJfa3


,,

,.

TABLE VI (a)(l). ~. .

bQ3vclaza AWCa Ma

-

310

MOm

%

1614109731

&mmx-a4m

AM*IY, e

Hz.AITAC4

UdCm6ucmr(MC64)

Lm16uam

k 0,

‘iwcU&m

1—

WCmlbkot

cable0.u8u

(ibbmeigblpmnw9+-(M)

a9671339Mm3338319743365BB

00)9.337MI313A43Em

lm3IAln3.4m1(s643375695

14173m734AW3s636331

UIRID WC

Ambkal.

(Imbu)1

3464Y16 lS3WlA- S3lsrsaA. 733,73saA. lmLS3SOA- 330lS3XlA. X0153WJA- 303LslsaA-4oo

S3.63063490

Imtm167EOIlllmX3moo413.ml

2.%06.110

103s013C9030s303363063bm

tmdm167.803211.moX93m411600

1O$MO167.8C0XamIW,OM413.6m

lm91.1841316MmLn93.m73233

“:M93

10s13013s

3n104B43xl4-!7-!8.09>

1031333133

11.813n143339163

m-lSm4S51M

%{S1’7blStD-1

m-lSn3.1S3D.1m-lS3u.1S3n.1mlS3D.1S3D.1m-lsn3.1S3U4

ELT3MLT7isLI14.3LXTL.5

IOJ3mmIaxlmooUmmlomm

1033KmmmimImoKmKmICcoK03ICOOmmKm

11014817423337134a43!

11183931@11014817433527i3m433

r333315391433

101LMla2163m.

:

1017%476410113sla2163303m4m

160216~:

W600

110146174334334393m

1118393169110146174334334m3m

101Ill13433m334m974

r17347uIm1%la3067363m274

—

—

lo3J3b93b334031b33aa4Io31Em2034306m7.-om7im.oq

3M69J301-94%b31.M9Jb33.34mMMW32013033ml-mm301.9303M3.93m303Q676b3346773m.93m

a714143014713ml.wmlmulo.3-3mo

3OMSS1O203+3443014$11mlala3m.6313

3s33>JJ

T33333333J33

T1333

346W36 0.41134914333073103Lm30030303

A49-$73,718.611.969

1.1341266Mu1.6691,9973.333

wu

T3464Y13 LSmA- lmLl!3W3W3A. 33oL9SKV3SOA- 393LSKV3SOA- 3!4LS$KV3SIJA. 403

mm3nm

Ym30U33mJmooXml

mma3momm

oOm330330m3

3.3x.33002Am

34t43m wcfmou- lmls.mvmau.330KnW3s13u-lx!lsnw5sou-391LiKv3Sau-4m

omom3$0403

33333

Im,axl167X0330JXQ330m3413.KO

1,7401.93023303A3nMoo

3310Mu4,3M3,4176,193

11A13n143139163

1743353U391433

10I2163503m

.4C0


TABLE VI (a)(2). ~. .

(rxm@,-COntin.sd

AmwilY, U Cm6!xmr

[IL-C

MWIB

4643118

K64Ym

#i@mSuc

Aakc.1

—Llbk IYP lutu

*CCIkllad

—

710141924.w37u61Sr—

7101419ux!37446191

-i101419

;37u6191

Arud

Calasol(MCSS)

Cs6remmn

.fbmew*

(Imtlu)

0s4An,718.m.SIM.931

mu1.164lXO1s30

0344.663,72s.79a.9U.%1

1,06s1.174L310Isa

0,4s4.633.s6s.7$s.Wsol

1.(031,114Mm1.4s0

Cabb+tl!pun

*99-(b)

0,176X7mAmm396.anMI

ImsMO

oa4439.m33s0A91.n7.810.931

kn7lla7

0,148.237.mo..3s4A67S39.64s.793.593

L71O

IrAdultibdda

pcba)

WRID

SWC6mlrug!a,

(s%rucnbkat

614S01mblcnr

UWsCA- 7K6rscA. 10WMssa. 14L5MSCA- 19L%MSCA. 34LSMSC4- mma- 37W6SSCA. uLSMSCA- 61mssx. 91

&$ssC3. 7W64scs. 10LsM- 14L$M3cs 19ma ?.4S.rscs. sKbsscs. 37E3SS13 44SSKC% 61Ahsscs 91

*N UmmmW6

9B 11

9/4s9/49/69/39/39159149/3%3

~v

mmamaW6W61316

~6 lr

9/69/69r69s9rs

Mm1.s20167.0lAIOMm1.6301A30MmMmMm

334,04sso335s607Ll,no9B

S3Ts.1S3u.1m-lm-lm-lSI13.1m-lm-lm-l”S3D.1

mllaxtomlmoKmmoo1O-J31o11Ionmm

10IB18181818IBIsm18

1018lamIs16ls18lsIs

718lB1818IsM18lars

9rsli3W4W4

9/49i39/3

lbmMmMm1.630L6m1.6201.6301.6301.6301,620

63.SJ

9,093

Sru-1S1-r3-lm-lm-lm.1 ,

Sn3.1m-lS3D-1S3D-1m-l

lcmKmmalammoolmomllamKmml

mmmmOm1o11lamlamKmlammmIon

lzmmWaWE

9s9/69/49/69/59i39/39149r3913

9b9/69/69169r39,59/39/49/39n

mmmranW4W613/6

9/69/69/69/69/99119/s9149nW3

9/69/69169/69/59/39i39/49139/3

301.9309303.MS4Z02-5%33024561m3-6%2303-%63anwml$woX04%33US.OW

m3-m41ml$wn301.9504301.9X63034558mL69s9203.30423m.m43an-mum3-3043

11311013.014.016.0183

334.04s

W6W3IZ413/4

WEW3la

125W4W4

laml?A

%

Lm4scu- 7LsMscu- 10

MmMm

SrD.1SIIMsr73-IShKclJ. 14

mscu- 19.suScu- uS4scu. 30S6sscu. 37mscu. 44s4SCU. 615MSCU. 91

Mm1,630l,6mlAmMm16301.630Mm

S,o55536.07.0M9.0

m-lSKMSITS-ISrD-1m-lSr73-1S3n.1

maW6W6W6lWw4W4

W6W6WsW4W4


. .

TABLIZ Vl (a)(3).~. .

. . ..--: ..-

~ - Conlimmd

Rmtdwimp,

IIlu(14mS)

Appall -d! dueor‘+ I

NW614s41

cablecmxau

dhmcmmm

(Inch)

o.4m

—

Iumbc,$mn.Ikumm1CM@

AmdUcsl

Dn6wtm(MC$d)

Um

motudbd

w-)

so

=

WCmblum

du-knI&AWOa Mms

ChbkdgblprnwQ-(bs)

0.1?6

CUR[0

-

SWW’cAaknl

m%sds14 ‘1

U5wm Isswu. 4 14 a 4.110 .117 ml-mm

Nd4Y14 IsIrlx. 3LsrWx. 7IslWx. 12

161616

1616

;

14

lamlam2.s2s

2s2s2s24Zm4

4.110

.741

.Sa3lms

0,4s6.74a.Sm

1269

oAm

2s131s244

.lm

.n7so24’

.lM

madlm.zm7mam~

W9ml ~WI-4133$W14Z42!sum:

-.

‘-

r!464Y14 Isnxx.Isnxx. :

RR. LN64.Vll IS-WIXA. 4 211-W8

U6@ll I IXIC17J. 4 14 1 4.110 .117 la mh9s21-:

a4d4Y24. IsIm’x.Lmn%. :15rcsx7Lsrcrx. 11

21.mm21

a2nn.un2s2snnn

nan,nnnnn

26

;

76

10al3040m80m,m

oAmMSamm

.d40140Am.d40.640.mo.640mMO.640

~:5.s1.731.904

somlso.msMO.mo

1.130l.mo1.4s0Mm

.lm

.ms51Ja44

l-m.lm.195.ZmAUS04.~2.9m

1.19s1317

anSJ4LIm

2.!103.!4,05,053607,073&o

Tes,6‘ml.-6IEL-6‘m&6‘mLd‘17w6‘17iM‘nm,6TEIA‘17m.6

moYmYmmlmlmlmo

zm

1

ml-wZoMM9.1Zolamn

!464Ym Is-15A- 13IsrssA. 3I.m-lsA. 5

-’

.-

-.

-

-’.-

-.

IsImA- 10LsrssA- ummA. m

mwsaml.m42291$543mz-%nml-9544MO-%39mm4s

t

Isl-rsA- mLsrrsA. 40LmTsA- soLssTsA. 40

!444Ym Iss7wJ. MLsnwJ. 3LSITSU. 5Isl-swJ. 10mu- Mmu. mlssTmJ- 30mu. 40

iceImma m cudd table.

36

10mm40mw

MO.moMOMOMb.640MOA40

0.3m.Amso47s&-msm

IL-SOlam

0LE6.113.167X.1.374.461,Wm4

TELd‘17m,617m,6ml.6‘sELd7EL.6ml,6‘ml,6

mmlmamIolmomml


I

16Mw Isl-lw. soIsr6’su. m

- (mlrnmM cadd ubk.

wm

TABLE VI (a)(3).~. .

. . .~ -Conlinued

I n

H

0A40 Lan H 1.6$0

-rIIuuu CDRdbmd ID

MllL

W=)

T“: l’i3Mslo -xo- 1 I

----

NW614$01

lm-9s36X44X4

,,


.--—

.

w-I

TABLE VI (b)(l). ~. .

. .. . .~ - COruinued -

mmI I I

34b4%3 3SS14WA 14 1

a=-Cdw Iml

13.CW 1393amo 1.76341.740 lmoC&%30 l.no

x6s30 1.19013,ma 1s70mm 1.9s041.140 am

+=

4.110 .7s0

4110

4.110

lam=Wpnqlpm(0s)

O.sa

.136

1.1431.7U3Zst44.191S.M3

13601041X-m4.4806471

0.333

S3

.OM

.134

ndw Cmdbd m

[Imhu)

+

so m-l

a S3D4

ao m13-19s .S3D.1

10.! Sm3.113s ml14.n S17M

T7.0 S3ul9s ml

1%0 S3D.1133 SID.133,0 S3D.1

3=4s S3u.1

4s m.1

10 m-l

10 S313.1

Amrdy, & CadulOr

mu)*orlMHl 4mns

Ruco NSNda~ WC. m 40’C WC 614s43

ma Ambient Ambbm Ambknt Ambient(w

m 36 7A - . ml$13s7

nno 36 ?A I- - ml-sm8

Sa fmtmu mad d Me.


TABLE VI (b)(2). ~. .

. . .1“

kekmrz AWOa MIX

—

WnbcMfam.hlctonn&b

CDR10

6TD-1

Uw6Sdufi

Ulu.

mm

600

ml

MILC able I)pOd+mkm E1-i

k

614301Ambkm

ArudU&

Cce411am(MCN)

IXJ18menu

dimmer

(::%Mm 4

mdbm2& ~~d bead

~- @@-)(0s)

3M2 10.0

13m 10.0

34MY47 IS1363WA. m n m 0,702

34643U7 I ls13Mwu- ‘m n m .7(6J 1.$s$ SID-1 -130M341345W43 IL7UWA. t 23

:n

nnn

--#--nnnnnnn

:

.X9

.No

.ml

.ml

.mo

.mo

.m

+--mlm.mo.’m

:%,ml7X7.ml

Osn

930Mao12s0

0.4ssMO

l.omlam

.710Am.9s0 :

L&m1.360law1.4YIMmLm

0s20.&aan.9?a

1040111012801380lsn1.740

0.910

+

auo 3s

35.6s6 U.90 75

Sma

i%:m-a

ml

6mdmml

-1- -13m3m11

E3464W30 3S13WA. 14

LS13WA. 30ISSWA. W

1464Y30 Isuwu- 2Issw3J.IA13wW:L93WU- w

-, --. -

-.

.-

.--“ .

m

T.:m

:AIB &l

73

.s0 45An 3,0618 60.m 63

751236 no1s43 SJ1.5Q3 9,0

SID.’2Sn3itS3D.a.711M

-sml-S3D.2.5TTI.2S3Li.aS3D-aSKI-zS3D.2m-zS3D-2m-l

E.:sru.2SID-2

$:S3D.1S3T3.2S3D.2Sn3.1

aoml

r%601600Wdm

“ammMOanmo

600.

c%mlmotoo6006mMOal

1=m3-3wJ~ mm-E35n671182

-ii .maa33-7X8-3on-nf

wm

LU33.5WA- 73S19W’A- 10K33WA- 14L91.SWA- 19

=. :lS33WA. 37IS7SWA. ULQ.SWA. 61 iL!?d

m3.7634m3.3339303-ls90

Z317

a17s.337ms%.711.937

1,174Mm1-912

10.0

3s4sso&o63750.0859.0L

34643M U41SWAULQSWAU.LQ3WAU.-AU.LS33WAU.LS33WAU.MSWAU-lSSWAU-LQSWAU.LS3SWAU.

s71014193430374461

33n33

:n33331123

614allanlam14?au—

14

.7W7mlm,7C0,ml.703,7C0,mlml,ml

mrl

206-33403ca-933131n471m3.353730WMm3-333um3-3339mJo191m-naim-mm I2214 10.0

t3464356 Ilx.swb 7 16 SID-2 ml

=++

-. 3m.74M

3C6.36U

31B-3632

16 14 2300 .%0 .467 I 7.3 m-a m

m 2 Mm .3$3 .103 I 20 “SID.2


TABLE VI (b)(2). ~. .

. . .

- Caaimmd

M12,C

2A64M32

2454%32

2464%7

2464357

2464%7

14643i44

lA642i46

Zu4ym

z4t4Ym

* IColnol

AnpLoy, Cuil Ccaduuor

#au&,

WCImblua

i

WCLmbk.nl

Arud Ix4aomau

6!mutc,mu.

(IOduI)

a710.910

In1s2!2lSUI.’ma

E

Osm.7$).Slw

MOMm1640Ialo

E

0.750

Rmcddmgc,

tluz

w)

MN614S01

m2a272m4a432M.69922CU65442m.94nan4rmYm-.7m4m4fm4

C4mrrdlldonh U6!4

WCAm6knt

(Mm)”

O.ml

I

4.0am W I%:ml43S272.2Smw22.

Lsswu.Sswu.s.4wu-Smwv.Smw22.S2.9wu.

3711

:2227

6142422

:74

122—

a6

Jm42mw

122

ii--

r

ImL6mlAm

6C0601m6m600mmlm

momo

z6002U2momoml

-.-“

,-lAZOMmMmMmMm

L6mMmlaL6m1.6mI&oMmMm1,622

A1O1J2422.256Mm2.321

awl224392.742Ml

Mm1.28913s2Z.ml

609.095

10s,13s

-

Zo4ain634.09.09.s

10s125

Sn2.aS221-2ma

S2m261— —

16mm18mm18m18

52SWUA.522WUA-S2SWUA.S26WUA-S.SW12A-SSWUA-SSW12A-SSWUA.SLSWUA-

1>7m19u203761

S2n.aSm.aSm.zS2D-2S2D.aS2D.2m-aS2D-2S2D-2

-“-’-,

m1 I

OA92 6S17ELJ

m

=H=S29 6SIEU

.2.55 10,0 ‘mu

1.OM 4DT232A7

0.741 SB lm,z

an-ml

an-mm

2CM223

mz-mzz

tan

ma

-,-

s2LrA’s421”z6 24

S2WA. 49122 40 .ml lAm

L2m

[

n

mmm18lB18M18m

mm

49 .7C12

.522WA- 3SSWA- 7-A. 10S.MWA. 14.SSWA-*A. ~.SISWA- 3.9SWA. 37S12WA- 44

9i~3241S7n%7

Ill132

Im .L6m1.6m1.6m

O.m!SW

IzmMmlSIOI,m1.9102010

Z2m

.3mmAm

1.12.7

4s6.07385

S2m2S272-26n2.2sm.1

mfalmma6cmamml

zm600

XaQ2nan.$mzowzmZ13.m232-7603a22Jm4loJ-7msml.’mxan.6m7

-“

-.

-.

-.-

MmI,moI,mo11.alMm

1.442l.m2..?I4l.ml3399

9.0WIln12.013KI

SID.2m2-2S2D.2S2D-2S2Dl

azn328

—S2D-zS2D-2

m14m220.2$011

&3vu: 3smwu.7u cd C4I,Me.

921

1,6mMm

0.6s.!.940

4s6.0


—

TABL@ VI (b)(2). ~. .

. . ..-,.. . !

~ - codilalsd

—

ArudUdl

mldueor(Mu4)

Mm1AMMmMmL6m1.620Mm

Mm1620MmMmLao14201620Mm1,670

1.111Mm

AmQdy, Ud dm

hb@mOlx AWOa Mm

mmIsmmlaIs

laIBmmmmmlBIs

alm

+

+

4!7CSUCtikd hbkm

-..-----

&0,

4WC❑blait

cablemmll

diameter

(I:rm)l.lml.mo1.4s0l.lmMm1.45U17A

a7u1.OM13401s401s10

(kbb-ww n

W&=

awl1.0521ss3l.ws14s6

Is7a

04s9mama

U4u1,691

24W3,003lan

dwi%

(kbu),.

tDR10

SMC6

~w-M41.

(lu.sS)

NSN614.7QI

mXQuml-m13SOS-SQ14202-s0sSm-slnSM-?116an-ml

mi4s6sZo3’6XaX44.612m4%9lm4s70Xua371-1m3.s395Zma5m

Zm-sn

ml-ssm

lm.sm4Sm-smslol&5m

Zol.naml-Zm.zmo

WCLuLicOl

daa.

n&k

—

so4157n92IllLu—

911.muS7n59IllIll—

1656

=liiiRTvu. 19

7-7u9.0

10s11.012.01s.0

SsD.1mamaSm.aSITJmama

6manaaSalsol6m

lsm.14643/36 153swu. m

15swu- soLS4SWWS7

t

------

---_---_------

,--

InJ-u

T2464?.56 Ismwus. 3

Kun’lJs7Lmswus 1015swus— 14Imswus. 19mwu.s. 14Lmswus-31LsswlJs’ 37BlswsJ.s. 44

s-$1%01s,01601s,021sls.oam2s.0

sm.1Ssuam-lSllham-lmaSImSSD.2SID.a

mlmoSalal601mlmmlml

1.9202nsoZml

+

--

----

1..770.-

1.4m

1s4s

MO.-

11167mm

1la. . .

113.-

SJ5.0U

ma

SsD.1

mlluA

ml

ml

tcomlml

+

----

-_----

“_-----

2464YM s.sEa.sA m18

nnn

:

rw64

1.111Mm

a640,640.640

-.

-0s50.sm

I.ml

I 246WI0 LsPm14u- sLsPLnmsu. MLslLtrb4u. so

alnn

10soal

.649

.640&o

0340.7s0.9s0

.131

.isl

.484

35so6s

Tm.JIEL-s‘mlA

.,

6mamam

-,

w rmmtm er,6duble.


m. 1

I

laWI. 7 MI&% 12 18

TABLE VI (c)(l). ~. .

. . .~ - Cmlinued

NumbNd030.

:=

614u

AmsdCu6

Dm6mor(MU16)

1.620Mm1.620

C!blsCwel-au

dametumu.

(indlu)

O@ma

MM

%J~Fm=(It@

am$Yn

Mn

Fk6hnof bd

&L43u7.n

CDRID

Sm4SID4Sm4

Rued*mga,

0=)

Ampdly,ucb Km61nm

*

N94614S41

#161-lSmt49s-3n4#161.nn

. .


,.

Ammdw.ad d-

TABL@ VI (d)(l). ~. .

. .~ - Cantimmd

—

qumhdam

Amdcdl

Xnduclol(MCN)

lSW4.I1O

Io.ml13Lm20s30mA3d636s0,fdfm

.25&b4.410

103WIwwl

?l63LWUmm

13604,110

Io”womsm

MIW

2464343

3464W43

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34643U9

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137.244m70136169199

133344m7613616s199

i+%-%

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x

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(MI@ t)pLt+,.lkm

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oml.93.m204293M3Sm

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0L40.112.m9330mI&l.939

1.136

0.104.141a

CDR03

.R’Sm.1m-lmm-lMD.1SID.1S53)-1

m-l!n73-1.73D.1S3m.1STa.1m-lS3D.ISl13-1

M33.1S313,1S173.1m-l

bcdl mu(Inch)

0.350Am

.s43AIOAm.910

Mm1.lm

ADNW. “ 3Aa3Nw- 4mhw. 9-iDhw. 14SatW’. 35

12 13m n41 4435 ‘@n 70116 334333 1643163 193

um4133n116333163

an-l$n3030376ml-3314auua3

161410973Io

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4444

mmKmWlommIwolow

3d3-3313=3316mlwll303.3493

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mm 12m4133n116i33133

.33n44a

3?3163lW

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m3-3493303.3494303-3493mz.wd203.3497m3-3498203-34W303-3WI

ADNWA-SDNWA-X3NWA.S)NWA-SDhWA-SDNIVA-SDNWA.SDNWA.

.w?4w.5WUW.

34914

:73lm

16141097310

1614107

0s40.480595.6a.740.W

1.130llm

mmmmlammooKmmmmm

—34933

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mmmm10J3Km

11183269

1116390

303.d3nman3034373303.AS74

T10 1117 mB 39t4 t4

3034s73m3Aw3msmol3W4W3

SFNWA- 3S970VA. 4AF7qWA. 9SW4WA. 33

1614107

4444

2SM4,110

10..Wmm

0.497%7AmAm

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Ml203s4,0

53734.Sin-lm-lS173-1

10W

ma1003

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161410973

:cm

113333333

asm4,110

10,3W13moZ3B3052f?o83LWIIn,tm67SW

All.49Am,6m.7&3S@

1.1341.3631s15

L-es.107Mlml39J.?33

1.3011.4S23..?18

S313.1m-l5733.1m-lmm-tS3m-1mm-lS3m.1mm-l

mmmmOmmllam

11!8393169110148174333

1017%4764

11

#5160

1017x4764103139km216

303.3.Wmwo33mz-3w.2303.3m3m3-3wlml.mos101

136w216

110KmKmmm

146174235

Z07..3W63m3501am-wm

k fcomuu II endd ttble.


TABLE VI (d)(l). ~. .

-. .(@wdJ@@ - C&uucd

AIUC4U

um6ua0f(MC63)

uao4,1:0

10,330m.wmmamnbm43bm165M7167dm

aRID

sm.1SID.1m-lSm.im-lSru.1mlS3’D.lml

—

I“llloe,#am.km”1 &l@

—

3

:333J13

Rmnu8dbcrdmh

Wba)

M3.0u23M433.0&o7b

>h

L4

—

mImblca

—

11

:m6911014s17421S

&o

WCUbkrll

CdlKm,E AWOa Mc?4

1614109731

C&

N3N6143.01

61Dmm0,

(z)

0.46iAmAn.723B1O

1J119lJM13161S6sF

34643/49 153NWA. 32SINWA. 4IS3NWA. 9IS374WA. 143S3NWA. 23IS174WA. W

75*f mltSl?4WA- 130

24643f43 lSW- 7LQ5J. 9IS.33. 11L9m. 12lSSJ- 14lS3.31- 16

— —

1017%4764lmIllla2!6

111839Mc?)110144174233

.Im371x$.bnM

L2m13102277

1C03mlomammlCOImmmmmm

791012141618mn

7910u141618m21

a1a32z31z

—

az111.11a2

205mmm10.s063m2271Z436Lm

.2316a734

O.-m34sAmA31ml3333103s0.37s

0.2s8232.164.134.m3m4mm6Jno

S3DJSl13-3sin-3S3D.3SI’U-3.sm-.lsn3-3sin-3S3D-3

Imomm

3641,313316131063

493sn171411.8s2

3642161616

49s141414

zm-2m6203-7749

moo

mm10J3mmmmlmo

ILslm.L.QsJ.Ls324-

ls3mA.lswklSl33A-IsmlA.LS2S3A.lS36JA.L=WA-LS121A-LS3SIA.

mm23

-.

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m.mommlo.3murn233124161S001.216am

M35%.310AmAm3733m340m

bmA333m340.33s300

m271.m.163ml.093m6ml.063

310.lm.101nm’m6

u2sas20ao201s13Is

33?J7.02,03.0u

sn3-3S31MS3D-3Sr3M.slm3sin-3SID-3S3D-3S7D.3

SID-3.S3D-3S373.3S3’D3srD-3.SIDJ

:mlmomomamoam602

%’ml6mm

3641313316131063

3321141196

4933n17141183a

27M111073

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n21M1196

493!141414

‘zm.woml%303-36393LWS76

3m-36m20303743m.3%7mi-30M

203.m3303.n3a033-77513m-m37ammoan-mlT

34643/43 Um3. 9Lus3. 12Lns3. 14IS333. 16ls2s3- 18IS31. n

130m65m36313.4361.9011.316

nIs131073

912141618m

333333


TABL@ Vlfd)(l).. . .

EMIIA

24643/6s

24643f43

3466W43

I I--uable w Cardnctor NUIIILW0a@u6m & Awa dOm-

aMm6 ducmm10&b

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I14 4

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a734

llM6s30333114U”Iwo1216a7n

lml247.61.116

3an24361216

. .~.calldluwd :

Amodv. ad Omdlldm I

CableCnemll

dhwwmu

(M@

am

t.mmAm35037sX033s

39sm3m

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da

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3121 all1302.m

mF33 : s n 203.m411 21 S 3C0.W7614 11 14 11 m6@76s11 10 11 10 Znc?4429 7 9 7 31M-3M16 s “5 3QI?4493.2 : 2 m.-

,.

11 9 -- 20249759 7 -- 30448676 s -- ml=nm

I 1 1 1

11 9 - - an.35639 7 - -6 s - - 2y-6993’


. .

E

TABLE VI (d)(2). ~. .

. . .

Ampdq,a Ca!duum&!loa-

N3N6143431

2m3343

-iG

WCmbkd

rWCbmbkn:

4

WCAubkrd

kaouclozcAWa M4X

*UU,LW04-k!mOn0CW4

Amadma

Xn6uam(MC63)

316kd0kmm9rmu.

(Incbu)

a740

.m

ml

mRm WC

Mkm

34643/53Iww 8 8

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4

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16s10

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6S30

60

60-53

Sm.1

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mmrZ464Y34LShWb62464MS4L5BNWA6-6

24663/513SWNW. 7ISMNW . 10L564Nw- 14lsmtiw- 19LSMNW. 343.SMNW. 30LsA3tw- 373sdt4w. 44

sm.1

8 .m 53 S3D.1

~mmalmW6W613/6W3

17A17AmlZJEW6W6W612/5

~9149/69169/39/39/s9!4

@-9169169/69/39i39/39/4

7101419343031u

1J5201.6201.6301.6301.6301.6301.6301630

m.337.333.1%2$9mlml.447

.111

.M4

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S3D-193D.1mlS313.1Sin-lSn3.1S3T3.1S31bl

m-lSm.1m.1Sin-lm-lSin-lS313.1Sr33.1

moolmmlKmlaoIL6mmolCCO

10Mlalo1o11lmla-o1o11IaaImo

A%mmlM3m.7R$050

L34643/3115MNWA- 7

3S64NWA. 103S4MVA . 14lSlW4WA- 19ISMNWA - 34LWhWA . 30L5MNWA - 37L9MNWA . 44

Ut4Y34 Mm. 37

mm1818m18laIn

16

16

10

710141934303744—

37

16301.6031.6301.6301J3301.630ltao167.0

2SI

9/69169169149fi9fi9B9i4

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9/3

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m

1.111

1,111

14—14

117’

Aso .160 3.0 Sru.1 3X b34-c669

kcL=.3tnottialcadoft,bk.


TABLE VI (d)(3). ~

~ - Ca3dnued

AwdY, txbMOduaa I

&Numb Am d abled m8. cad m.xauducmm =@uctu dhaerInnbb (MwI

g-k)

am 0s73: mm .9s440 .mo lalm .lm la

ad :X0 .m340 .mo 1.1s!m .ml 1s.$

de0,

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C&lb=Wpnqfrlm(IL@

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(Ircbu)

amm

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W---.3W7-- an-m-- m3.m39---- 3oi34d!----

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+607510.$

10311533,0193

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10,0

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3mInm

-%-mlm40J

WIX0mlm

+

BISOM- 16 nLsls30tAA-30 33LS1S3063A-40 33ISIS50MA.70 n

L9S30MU- m nL9S50MU. 40 nL9S30MU. m n

m mm.imlm

mm .mo 1.633

sin-2~Sm&

sm3-~S3D4

sin-3

S3D.2-

S3D-3

%iEi

aEL3

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1 -- 1 mms9s--

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60 ml urn

80 .703 L4YI

11 1X 0,430% 550M .37s EmIm ,278 .930134 xi% lmo

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33

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537).2

-.

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- .- ‘io2Jm46lssA- 3 33Imlendd mbk,

6 .X0I

osm


TABLE VI (d)(3). ~. .

. . .~. COndnud

Amprhy,eM6an6Lmm

1~

40CAnblml

-

.-

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Wc

1

WCbnoucmrZe Awaa M04

(ml,CwUauAnew

J&)

0,710Am.5U310mMm1.W31.450I.mlI.m

urn.660m.930

Lc40:Lnol.mo13601.5301.?40

cZ3RID

RJkddip,maw)

&dUdl

Rlduacu

Ix!lomtlgbt961hw9-(Ou)

rumAX3618.m51.0321.3561s431X$3317

o.lm25s356SE.733.%31,1761.459

%

Rrnu9WxndmlnMrJ)

WCdcu,.

nCAh

m64Y31 L5mA. 7Lsa3A- 10W.sA. 14Is-s& 19Kl.9A- 34m. mLu5A. 37Li3.5A. 44

333333n3333333533

14m‘m?44am7443la

T14mn2448m74mnl

anm.mmm.ml.ml.m.ml.momm

.ml

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435.06.0U747511s13.0145

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Sra-aS3D2m.2.S3D-2S5D.1,Sm41mm-aS37M ,ma

=SID-2s3m-267n.25373-2S3’73.3m-2

.xm-l

633mo600Co6L33ml

c%ml

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nn33

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rL53mm.LQ5us.ls33uS-LQ6usIS,SU.SEi36usLs33usIs33usIs16usLQ3us

34643,01 3710141934m374461

33nn33n33nn“n23

6

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Osm.730ml.9ml.lm1.’3701.3401,A401.6101530

Ola..M7A9d.n3.91s1,191lAmL433

3540

7JI83110ml13Jlm16017519s

m-zS3D.2m-aS3D.3m-a6T0-1SID-3S3D.151D.2Sr33-a

am(alammo630ml693m

%’ -’

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➤ ✎� ✎✎�

TABLE VS (d)(3). ~. .

I .,.~- Ccm(inucd

I I Ammdm,exba@lda—

lumblIfDm

AmadUch

Wcducla(MR4

cum.27samns276am

.27sm.27sm.27sam

14201.6011.620MmMloM.701.620

mw 2’&%Y

So’cm14eat

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]

CaMi~Cppm(ox)

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1.123MlLs%Um

I

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mduttmw AWOm Mm

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:

(/3s)0.480ssomlnm.962

-00.610

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0,7S0.9!.0124013s0L4s0Lmolmo

2034477m3a476

ma.9u4921m9aoam-ml

34643A315tu- 10153u. lslsau- 19l.s3u- W

4.!Hi 60

4,0S.o607.0ulao

4n$.0607.0u10JI

m173L-3lT31AIE183IEL3‘s’aL3

=T‘KL-3.

17U,3 F,....-Sm -m -WI -m -m -m

-iii-tJn -6o1-talKma-a600

ab643usLSIUA. 10~UA- MIS2UA. 19lSUA-IS3UA. :ISUA- 40

3m.9m

Zo2.msan-ms6

1-1-SI13.3S3D-2SID.2SSD3SID-zSIDJSns.1

43so738S9.0103114 30M%9


?&

. .

TABLE VI(d)(3). ~.,

. . .~- COnlinucd

CDRID

SID.1m-l

Aru”dcub

m16uc10r(MIX)

Am@y, Cu6CwAmor-

4umbci4ml.!IuKlmsabk

ildllmd bed

[I%&

de01

ambknl

&_(u

sotAuo4ml

la+

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7

sowUwuo

Ill.x/ tib ~du@dm

mldlKmrw:AWOorMm

Cablemmudhclwmu(I”dlu)

1.9802.2M

able+b!P n.ppm(lb)

17813399

4wed NSN614541

ms4174W2-951O

G(RMs)

6C0al

1810

Illm

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noU,o

464YM Imsu. 3Lmu. 7Imsu. 10lmsu- 14lssu- 19

1sIs18181s

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16201.67JIMm1.620Mm16201.6Z0Mm

am.910LISQl.lxl1AMMm1.’7M1.930l.lso

0.761.m1.2$0I.lwlAWl.mImn1.9$0

O.wm.W1mu1353i.mUbi1M4m

0A44.mlmlIA16

RZ&nw]

436-!7-$M9.010s11.9no13.0

9s120I.wlti16.0ala21024.0

m-lSID.2SIII.2maSID.aSID.1maSITMSIn.a

SID.1.SID.2S17M

aSID.2SID.2

mlalalmml

zlmKm

dmm

E6Xm6QI

ml-34mloslmzola4672@a4tamz-14s9m2-S4@a?z-%mKwM7fJall’03n

Zo’L69m

anmlan34soW2mlm14eS9an4Sm

15su. 24LSwu. -wI.SSu. 37ISSu. u

4641nJrLinusLmu.sL5suslsa.ws.LinusIslsus15susISSIJs

371014lVuw37

181818181818Nm

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AIUC4ad!

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lbdiludbmd

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mcl-alldlamcw

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614W

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303.96s233.333sm44364-,

—sm. 3S3u. 7.9U. 12

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S19MV.S3PNW.SrPhw.sT9Nw-smw-S3?mv.S3QNW.Sm4w

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M3s10ISmw40

333323

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n

2nnn

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3610’30

:m80—3610303040mm

0640.640.660.640Am.660.660M

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333.310.3s:AmWI373.mo.la

m.mA13Jm560.62!.mMS

m 10MM312020u10

Mlla1sMlo20u3.0

17m377W3

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TEL-3

n?l.s

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m-xlmX62471m-m3Lt-7slBbn-33n3n3-3674ma81930148M.-

—

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033m3

mlasal2ol-9x6W1.8S?3zm.m67a31-934n2018349lm.moZIM-ml

ISIF’tWA. 10IS37NWA. 13LSIPNW’A.nLS3YNWA. W~NWA. 40

.136

.161anm3m


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TABLE VI (c)(l). ~.!

.,~ - Cmimo3d

NW6143JJI

233AMS0

#m&m

WCnbkmt

lm-.

i—

30’Cmbkat

73

CaMea.hmlldhmeter

(1::-)

1.491

a4s.460Slo3m.mdmSt411.430zlmMm

o.4a33s4.&n139313103.CCQ

O.11o.&o.K13ml.9531M3MmIblolf.m

MbUighlpcrfl.W(08)

Mm.-

alol.117Ma.173.w3393m133928114-$31

RI’M.16J2911210

E

0037.143s].769M131sm3L933X6

Smedkdtlge,.mw

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AIUC4euh WC

Ak.km

n

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m.-

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9.0..

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1464Y3

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1614u9147s

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31—az1

;a2a23

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mm33SS0

asao4110S3309M14.om33910

S4.noLnmN3s03

m4.1109.004Z11O61.X4137.ml

m~m61X4tm.tmmmrn3J2.7013mco3691.COI813.703

L3DHOQ- 3M73HOF. 4L$OHOR’ Sls33HoIa 9WDHOP. 14LSOH09- 13BHOP. 3015DHOP. 83WHOP-KDHOF- %

UFHOP- 3ISF360R 4lsF160K 9l.sFlioB 41lsFno9. aISFHOB 133

Sm600fmaml@n

%mml

603mmoml

.&’armml6036006mml602ml

33”S34130.menco1693334n

73336w93163

mBS162m32339160365sm3

193s333a.Jo

21n37u34n

:27s7m

21

2

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:2334363

16al34nS3MO—

:L33363

1733313446

11.017naln

4n435s11.0no16~

-

:347330143

1614941to133

N6w3 WOF-KSHOBL53HOF.KSHOP-LSSHO?.L3SHORLS3HOF.lssnoP.LS3NOF.

333to3303mno3m693803

11111III1

M3Jso7JIS.o83113nfl13s

363W6363m6s4m

MM?/l1 lssw MO 330

161412914

3mmo

254fJ4,11063309.04314J3m

I.lm

0.430.mo330m,7s0

L7a7

om4.136.179ml.366

66

3.54,04.75,060

mo

mlmlmlm6m

1—33333

1733313446

303a643m-%36m3a433034m6a73&67

L931ioF- 3ls3noQ. 4K3HOP- 6l.slnoF- 9Lsr360P. 14

Sm kaleacsatcudd lb!.


I1“

TABLE Vl(c)(l). ~. .

u-MILG ChbbwL?ulgulkn

14s4Y3 ls31ioP- nIs3nos uL9r340Kl.snioF. ELsrHoP- 4mIsr330s 3mEJHOB an

SmImmc$uuad C4ubla.LnN

Tkukmr NumtczZCAWO dcon-W MLn4 duclom

loram

1 31

: 3lm 3400 3m 3mo 3

Amsdcdl

Cmduaof(MUdl

aa.9104L11Ouxtm3321m4135m3m.mlfOmxo

abkmu’dldbmcternub

(Imhci)

am1.3301s207.240m3,100Iuo

__14_Gob RduI COR :-w ‘Wbd wparn

(hdla)‘(--

MM 7B SID-3YSW 10.0 SIDJyz4m 13s sl’03ym 18,0 STO.3Y43m ‘?ln SllX3y7313 may7.9SI % S3D.3J’

600mlalmlbm6mml

em

arcmbkm

m93197mmmlml tl

WC4LTCWCIdeal -km Ambbat

u ‘m 4434 93 06IB3 197 Imm4--36$ m.! 36$

3! 0273E... -

Ns74614SQ1

m3.06mmMhb9m3-w4mz.mmmomZm.lom


nL.c-

L96iHoF. 7lSdHOF- 10LSM401L 14ISUK4P. 19IS.4HOR 14MMHo& wISIHOP- 37UMHOF. 44L9dHOPJ 61

.3dJmxm AWOw NW

161616161616161616

. .

TABL@ Vl (e)(2). ~.,

—

Iumbe,*con.Iklclm1&l@

—

710141924Y1374461

AmsdC&b

mdvdot(MC64)

Ma9mL760

2s0U80U49UwlMm

-- Continued

Cdie

mu(Indw)

Osm,s6$.63s.m.7)sal!.9Xmlo1.173

4Xbb=WPIn*P(It@

aM4.w.4mwAS7341.674.m1.1X

4n4s5.953

.:7s6.09s

‘mn

RSID.1Sm.1SnMSnMSlnlSnblSI’o-l

I Ampdiy,esA

T&or6

~w ~Ambiuu

WV

,@l

z lvlml lVJm 11~too Ivlal U17Km Ills

.tio 1U4C4W IV3

la

SucLuwlu

9/6 u

9169/69/69169/69149n9n

L400

WC&km

,~u

llnIlnU/lWIII/llul1114lln

k--b6141.61

1=mbkal

916uZ03-SS4

:: m-1’m9B Im.n939/6 ana’wl9/6914 201x1939n XOJ3999n 2m.m4


TABLE W (e)(3)..~. .

. . .~ -Continued

Amsuhy,CsdCcm6uctor1#4Jn

WCAnsJklu

*—

[email protected]

-G

Wcmbkm

rWCmbkat-L

Number Au ddaa. eachbin” Cmduamlacabla (MC7A)

21 1AM

NsN6143.01

CableOvcmudhmdcrmu.

(incba)

LQm

abb=mpet11VP=(lb)

0.618

mlMOJ3n

RJdLud bedmhw)

C73RID

RudVdts’e,

(%’6103-?A91==t===- 10 SSD-3

srLP-3SID-sSm.s

-,

-.

p-mWIMlV-Is

Sn-6

-,

T4n2n

4%

m-

s

m’-03Y1

42s

203.93373oxrn6WMn7

14643n umcxPP. 1LSOCOP. IsL5moP- 1

al18Is

1818m30In t

a LOma Mma 1AM

1 lmo4 L&m5 1.0206 lmo7 Mm

O,noX3330

.6603103s0Ams%

$X64X4 LsMms a

lS6Pm3’ 4msm$ 5156PCIJS.6wms 7

34643M lmAbsoP. s

34643n IS3CQP. 2

a4643naLS3’SOP. 3s

E 10lssTOP. Is

Z4S4Y13Lslllt# 24

IS3’37S6Ls3T3m.8Lm’3Rs- 10IsPslm. 12LS17’RS 16

.130

.167,091.lm.337

-0s9

.s67

.11sAMm2.53

.333

.381MA74s]All.m

7m-s3a6m3xns303-34M303-7A3Eml.zm

SPL36PMSPL-3SPL-3SPL-S

ssq.3

Srs3.s

TEsA

17?3A3

S3u.1SPD.1Sm.1S3D.2SrD-1m-lSI’D.3

mlSmmmlsol

m

~

-.

4,0sos-$SJ

Lo1.1M1.7.103.03.3

maw

30M3S3

34

18

mmmm

+-+=

Jm

36s

A.30ml.701A30

.s80

.740

.sm,s93lmoI,lm1.190

‘-.

T6 1.030to mmm Lom30 Lom

434n4n4/03

-.

S14SIYSnsn

—

T4 lmo8 lam12 10.23

1.022: Lmu34 Lam32 Lom

n30m302030m

T4 l.mu8 lam12 l.om

mu: Lmo34 Lom33 Unl

lAn7PsA-LssTnM-L9sTnsA-lsr3nsA-LsrnLsA-Isn7ssA.isnlssA-

2468101216

w20mm3030m

0.730.’mlmlID60I.wl1,1s01140

397.394,4’m3213S7.s0s.764

455,0S56.S7n7,075

S3D.aS173.1sm.2SSD.1S30.2.s3n.2SID.2

34643n3 ...

-.-’ .M3.6473

LLY ~a; k sm.30rm4; nurmfmcfmi

w 6143.01


MIL-HDBK-299.(SH)3 April 1989

5.7 Cable classification (MIL-C-246401. Cables specified in MIL-C-246L0are listed in table VII under the following general classifications:

(a)

(b)

(c)

watertight (with circuit integrity), non-flexing se-ice:

(1) power.(2) control.(3) electronic, communication, and instrumentation.

Watertight, non-flexing si~ice:

.(1) electronic, communication, and instrumentation.

Non-watertight, non-flexing service:

(1) power.(z) electronic, comqmicatiOn and instrumentation.

55 ,,


TABL@ VU (a)(l).~. . . .

. . .

L13QdAmQadty,d Ca@JdOI

Ikofmlix“MUX- Chbb133M OxMuuu Numbs

&4@mk10 ti AWO dram.m M(M @xlOll

b&b

a4640n3 7XW 3 16 773DV- 4 14 7

34640M 7XWA- 1 16 77XWA- 4 14 7

34640n9 DXOW. 1 16DXOW- 4 14 :

34t4w19 D~- 1 16 2orU- 4 14 “ a

Hz

mAmbkm

Amac4Ucb

mouctor(MC24)

Mm4,110

3s604,110

&3m4.110

3sm4.I1O &

t3bk Ra6b=MI dA&pan

yb;m (Inc6a)

alm %0.133 .33

.133 30m 33

m 4.0.112 4s

,Om 20JM9 3s

CDR10

R#cd NW614341WC 3WC WC

Allmnt An4Jkn! MkaLwwdldhmctcr

Ulu.(Lwhu)

0339.4a

mlmw,

Sm.1SlT3.1

WI: 14no~ I Unl ~wu an4

32463313243333

rn.lrn3a3-13m

6mal

.339.434

S3’O.1Sn3.1

S3D.1SITM

Sln.1m-l

cm03

mo601

M/lo34n3-12w,

33s7.m43zK3a3

>16.334

.337303

234-91=3ua317

ml6m

laa3

w“ 34640n9 D.TWA- 3 16 2m OxWA. 4 14 z

2444JM Pxow- 3 16 4Fxow- 4 14 4

34.540nlPxw J 16 4Pxw. 4 14 4

34nonl F%WA- 1 16 4F%WA- 4 14 4

14640m3mow. 3 16 3Txow- 4 14 3

3464vm Txw- 3 16Txw 4 14 :

3s04,110

m4,110

3s004,110

“.W7333

.A9J3$4

.386339 $

K67 m@9 u

.116 u

.146 so.

.t69 10

.103 10

.09S 10

.138 3,0

.tm 4,0

.lYI 4s

S3134SI134

Sin-lsm.1

Sn3.1.$333-I

mlKm

6Xa

faml

11m

1010

1017

324.8.7183343011

343.2133n3-3134

334a319334a3m

3s804.110

29604,110

S3D.1S1734

1017

1017

36-9

329.3C4

6m

.%JS173.1SID.1

Lmo4,110

?s04.110

.266314

.316

+

ml 10.m7 3,0

.m4 10

.Jl! 10

m-l ml 11 10 11 10 32723635-ID-I m M 17 18 17 3n-3LM

S3D.1 mo 11 10 11 10 327.1153m-l 603 18 17 m 17 nl-mm

I I I34640/mTXWA- 3 16 3

TXWA. 4 14 3

* fmtnaestendd mbk


.

TABL.@W (a)(2).~.,

-- CJnlinud

—

amID

Atudad!

mtduam(MCM)

&m

4UCLmbkst

a—

3UC!mbkat

~blaIYPBOcdgmdm

‘4Uu.ba,dam.hclmlhAll@

au.Luualld!helcr

Cabb+bIp hIndmun(en)

a134.144219am

N3N614S01WC

Ambknt

(1%”)0x4A47A74513.601Ami.m.731.417

my

WEmU/a12/6W6W61W5W4S

~~U9/69/49/69A39/39i59/49/3s

uxmw. 7uxmw. 10UXCOW. 14uxmw. 19Uxww. 34Wxmw. 30uxmw- 37Mxmw. 44uxmw- 61

m181818181818la18

71014193430374461

1.630L6al1AM1.6231.620IL&aMm1.6303.6m

43S3606s73758.o9/1Ion

s3m.3m-lm-lS3m.1s3m.1S3D.1m.1m-lm-l

6006m6JI0WIa601amOqam

359A66333&w

3464M3 !4X(w. 7Uxcw. 10Wxcw. 14$3Xcw. 19Uxcw. 34UXCW- mWxcw. 37$5Xcw- 44L4XCW- 61

blXCWA- 7!4XCWA. 10WCWA- 14UXCWA- 19$4XCWA- 34t5XCWA. 30tiXCWA- 37UXCWA- 44

U1818la1818la1818

ii-101.9181818Mm18

7101419343037u61

71014193430m4461

1.630MmMmL6mlaMm1.6301.6mL6m

1,620l,mlL4mMmL1.a3IhmLao1.630l.tal

319AmAMA74-ml369Am.7X.m

364AuAmm.4.610.6mful.7s

M7.1%.165la

u.33334n4-7435.0336s

Sm.1m.1m-lm-lSID.1SnMS3D-1mm-lm.1

amammoWmoCalalm

VA13A13AmaW6W6W6Ws13/45

9169169t69/69/59/39/39/490s

U.4

mlM

S373.1S3D-1Sm.1m-lmm-lSID4m-lmud

ma600601m

%

34640n3 .110.m216144-737MA53

17AW913/6W6W613.6W6Ws13/43

9[69m9159/s9/39/39/s9149/3s

S43344 63 sm.1IMXCWA- 61

* Immue u erxl04I&Me.


TABL@ W (a)(3).~. .

I . . .~ - continued

Amnuh.ad!cm6ne01I(km

X&la

WCb6klo

hunter Amad -bledam. Udl WtmuInclomOXWJUSOI ditmel?,,UbIo (MCM)

(i:&)

3 Q640 o.m6 A40 m10 640 AMY1 MO &a40 MO .&a@l MO .m60 ha .4s7

3“ .mo .1936 440 Y17

MO J37: MO Anw MO w40 640 .67.1

MO: ,640 z

3 .640 .24s6 MO .33710 MO “ Ao7m b40 341so Mo .61940 #o i.n~.

MO .7s3en MO .W3

MIW ableIn106u@’ukm

amUdgbtpm:n

IMdmum(0s)

ma.Im.1s6299xl.460Lql

Iumuld bmd

[I&)u4s5,07s009slln

CIIRIO

ImL.4

IEld

Il?4-A

T3fL4

RmdWluge,

CNt(Iu.5s)

NSN6143-01

dKlOlcAwaxMm

n6.49mn64zfan7-lmnl-mlln6Jmo93w#33nb4s65

246W24 TrxOw- 1sl-mow. 3-maw. s-maw. IS

n32n33nn‘n

_

-.

-.

Trxow. 30mow- 30mow. 40

1

mall

m.nol

z.=Zn-stda.%lm?7.6az6

2464W uJ510u30m40

nnnnnn

;

rnnun22aaal

X06&aml.1632s1X3Ao7X4

mlCM.119209370ml.463593

13as3.04.04.75.06.07a

1.5’333.s435ns>6.07.0

‘midmLdlm.dTEL6

TEL4w‘lTIA:

TEL417L4‘m?L6ml.6mo,dTt56Tel/6TEL-4

uco

rT37WA.T3%WA.lTXWA-TS%WA-TSXWA-TIXWA.ITXWA.Tl%WA.

M amColWIWJ@lWImm

“-

:10umm40

,,, .

.


TABLE VII(b)(l).~. . .

—

Rioon#bend❑bbLuba)

COR10

Arudcad

ccdduacu(fAaA)

144m6~w%mu.

(14Ms)

N3N614S01

z

arc❑blau

rdubn NumbeI,AWO ofCm.rMC24 duclclll

h&b

13bleC4u811

mu(huh-)1 x

i-

3464WM lXSOW.Ixsow.Cmow.Ixsow.

3464M7 2xow-2xow-2xow-2xow-2xow-2XOW.

3212 a640MMOA40

m372mmmn3

tialw2W7XU33143s922$-3231

224aMl21492m223a932Z23a933mawZn-9w2

0314SalSM462

4,0AO?Jl6.0

-4s6,074as103Iln

(mta6U26m

S4mm6mSoomml

+

23 1432 m33 30

m 1126 24s24 43 Z-.6

18344160n

26 2426 Im26134

Tz 62333 :33 3an 2222 4223 m22 74

2XSAOW.SxsAow.2XSAOW.XiAow.axsAow.3X.9AOW.amow.3XSM3W.

3710141934w37

.640440MO440AM640A40A40

A373.!0.481.742ml.9s21.020W40

.U32s3

A42S4s.730S2.s971

53

:90io.o11s12s12.0

mSooalmlm600Kslmo

-.

-.

%m

$n 6m 14n m

23 622 1423 2s

22 6m 14m 3418 2818 m

m 118 618 14

18 1

.640640h40

.640640.640

O.sdA93691

A46.$47.741

.112

.195304

23403s

3s4/3m

.SSD.2S2W2SSS3-3

.S3U.2m-sS273-1

602aa6m

2s23032ss-22032%-IW4

2z4.9m2234m3332$-1293+-l+

------34640/U2XSAWA. 31X9AWA. 72XSAWA- 14

.1482A4A43

mo603@l

- ..

1--1-3464W162XSOW. 3

2XSOW. 72XSOW. 122XSOW. 192XSOW. 20

2A64W162XSW. 12XSW. 323LSW. 7

MmIhm1.6mMmMm

tdm1,6m1.6m

323.636.344101011’M

.327AolAmm1.2%

638,010s13313.$

sr04s173.2SK3-2S273.2m-a

@m201mlml6m

334’8211234.0212324a313224-9181323-1376

mmmaw?222.s947

.-

0.7.$8All.617

0s03.167Jla

104.03,0

.SSU2SISL2sTm3

fcoalm

mo

.-

13464LV1612XSWA- 1

seefmtnrned cd ortable.

l.dm 219’m94.s69 Lo SS7X2


TABLE VII(b)(l).. . .

. . .~ - Conlhud

—

AIUC4Udl

mducm?(MCbS)

lb30lbal

lmMm1.630L6mMmMm

16201.6301.630M30

1.6301.629t.620Mm

Almu4tY,eachCc@Auulndimk

SwcLmbkm

3VC

&o/

m❑blmt

Nm614301

QMCCwmlldbmheamu

(IrKhti)

Osm.467

S39.nl.9Xma1.011lxm

O.XE.669.s63.941

-$33.718.913

~bb=Wp nmdmum(09)

0.31031s

.371m3.’7)3Ma1.127M69

Rsdiludbead

[la=)CURm

brdllcmlzaAWCm MUi

nubb—

b14—

92133

4n5.0

in43110l~o13.016.0

S4D-2Sm.1

72349!s33MM0

33441s3314-91m334a314aau.$?24.9316334-91S4

W933349SI2’LWW43n36B3

M18

la181018InIs

M18Is18

T10In18

—

3464MB ntsmv. 33XSOW. 73XSOW. 1033KOW. 143XSOW. 193XSOW. 34

Sm.1537).2SSD4SKD-lSn3-zml

5SD-3SID.153’s)-2Sr33.1

S1-u-lSsls.aWV-aS3D.2

mo603mSaoam

7

41

m on37.413.m

.333.As6:Wl873

4n557.07J

T537.07s

-.-

m0

3n.3ml3m.4361Z?3-M63333-M63

34MM8 3XSWA. 33XSWA. 73XWA. 103XSWA- 14

- ICLUU4Cu ad cdUble.

9alm41


. .

mi-

TABLE VU (c)(l).~. .

- continued

TFFMlIX- (hbla~ liardudorNumberOetl$lUlkn dzeAWCl dmn.

w Ma duclomillable

14b4Wl DX. 3 16 2DX. 4 14 a

F=R--H+

mArud&

Cmdudor(MCM)

2s804.110

aso4110

Um4110

2s404.110

LwJ).4,110

2s804.110

w*

Q241 Omm7 ~

alm4 %

al .063 as?40

=++

.261 m inSlo m6 2s

311 qln% 2s

Ampdly,cd!Ccmdulor

lk0r60NI 401HZIXIR RJIUI NsNID : - 40’C sow WC WC 614Mll

Ambkal tiknl Ambkto Ambient(w

Stelcaltuimenddubk.


TABL@ V31(c)(2).~. .

~ - CQotimd

AmmdlY,udlam6ue0r I—

Omie

#iml

WCArdm*

~

T40’C30’CAubknt Ambled

T

WCu.bkcd

AmidUc6

mduem

Cabkm“u

Pi6ilud bedmh[incba)

—

4sho11.9

mR10

SIm.1S3m.1S3n.1

IMc6Wlugr,mu.(IO@

NSN614301

nix. tibb~6u@81b0

n&k (I%a)03mSo7.9n

6m6m6m

+

------

. ..-.--------

------------

V&36$033&363133M4C$

km.owmms3m.sm7

133umfl

U-21%3m4m4n4.9nm334mm3w2191333.21s0

+

Ixhmo. 7Ixhlso.lxMso- :

lxAo- 33XA0. 73xAo- 103xAo-33L40. :

33nn

nn23n33

716m

OMO.640Am

.649 331

.340 AnMO mlMO -611.440 .83s

m.13s.lm.343A9

mm.140.m243.311393

.061m4.133.193.mo300.YmAm

4nso607s10s

4n53697su95

3n104,0soso336s7n

alall@m630Cal

-,

-,

TU64M2 2X0. 6

2X0. 18lXO. n2X0. 41lXO.3X0. .:

$.6M 331.640 S30.W.. 433.640 m.640 .637

.640 .618

MO -7s1,4m

.Mo,A40 A29.640 ,677

6mKmml

zmlCo.CJm$

Z464W Z&. 2

X9. ;1014

2s 1923(s. 24

w

U64019 ‘lXsA ax4sA- 3IXSA. 1lXSA- 10

n

:33

;3333

2272nnnn23n

1133n

4614mn3s48a

T614

;3s48m

-.

ml.102.176,329.ml.3m.443-531

.117

.124

.m3

39so4.05,0so55637n

3060&o

.sm.zs313.2S3D.25373.2s3m.2S17J.2S173.2m-l

S3D-2SI-O.2S133.2

6mmlmlmlmlmmoa

@l

%

.-

.-

.-

.--.

.-

.t40 I .7U,A40 m.640. 916m 324.9194

224.9195mm%

61430


TABLE VU (c)(2).~ . .

. . .~ - Gantinucd

641L.C.

Ammdm UdlCwdmw* L

4a

40’Cblbklll

Audcad!

calmmmlldkmekrMu

(Iahu)

CAbbwdalpdml

mdnan, NumM. AWO dam.tM(36 duclom

laubb

bled~3G

(i%:)

NW614301

*

mblcrd Ambklll

-,--,-

----

(MCI4)

3A6W !X.90. 14olso- 19lxso- 30 -1-

’34 m‘a sn 60

36 4PN61

0A40A40A40

m l--Omd.763.937

X9 24=OYII 93 Sn34

95 S3m.aS54 11.4 Sm3-I

.101 4-4 m-l

to Sl13.1

mldolml

mo”

@o

27.4.9197w.4.9ma3mlm3

3m.9ml

32$2LW

.-Ixsxo. 434d4w13

Ixs 7 Mm I “A47

-=t=-3464M1

Z4d40i$

IOLSA. 7

dXO- 10dXO. 14

&x.90- 2dXSO- 9W60. 21U.so. 37

m. 1rrx. 13

13 177RIAO! Mmlml dm .- 3n@6d

mw43

?2%2148333.214933A.ml2M.1373

z-h mlU31

*

___-,-

----

/4rl~ 4f3A~3m6

3/4.0 anlIOA 4n3

*U

mT16 216 916 2116 37

al 3PAIR30 U PNR3

.4s~.556

Um .6W

Mi3n JmLom S91

U3m 3mlMO .641

m Laomomdm

a4d4M0

3464W4 Kmtoo

33$.1190333-1393

14d4w4

Z4d40n

r3-xA- 3TxA. u

r3’x9. 2Txs 4 +

m 3PAMm S PNR

m 3 PNRm 4PNR

+

Lom .?41mm ,434

mm AllMm .474 +--E-E

mal

daKll

WAari

9mam43344333

%

-.

._”2464M m. 2

TxsA- 4

34MO15 rrxso- 2~0- 6TX30- 8Tx.so. 10

m 2 PAIRm 6PAIR30 8PNRm 10PNR

Mm A161.030 -446I.om Allmm h7s

.l,.d 5,0 SI13-3

.316 65 S1-O.l

.284 8.0 S3W2

.311 8.0 SID-2

2244333nP.219z3mOx13?2AJ4m

damtlmam

U ln6/AvIIndimtcsthemuimumoumntforachccadueor(Ind),andIhe”midmumNrmat(Avg)fateachcondti.rduri10cmduciomInthecabkUIwed, :


HIL-HDBK-299(SH)3 April 1989

5.8 Cable classification (MIL-C-915). Cables specified in MIL-C-915 arelisted in table VIII under the following general classifications:

(a) Watertight, flexing service:

(1) power.(2) control.(3) electronic, communication and instrumentation.

(b) Non-watertight, flexing service:

(1) power and lighting.(2) electronic, co-ication, and instrumentation.

(c) Non-watertight, non-flexing se~ice:

(1) electronic, communication, and instrumentation.

.(d) Watertight, non-flexing service:

(1) electronic, comunmication, snd instrumentation..

I

I


.

AmpCity,u mdmorAL

I

TABLE VIII(a)(l).~ . .

&m

Wcdiem 7:

m.

614$.01Imbkat

b—

amIniJkm

4Q’Clmbkm

W/c. Gbk wdulpmkm

Dn&cIOlccAwla Mm

IumbtlIfaa.IXQW9itsbb

ml,c4cmUdkmeter

(I&.)

O.Ko,-

Mol

C4blaW,ti@,lF nmudu.um(Ou)

nMo,-

1AM,-

UIRID

3=’9un

9ono

DSWS 4

Uw. 4

14

61

1

—2a

10.-

HIGH0LTAC19

Uo.-

6M - lm’Mos4,- 1-

mLn

. .


I

[lu2-

)ls/w Wm. 7$6WF- 10m. 14w. t9w- Z4UwP. YIuwF- 37

tivenlm AWOwMm

161818M181818

TABLE WI (a)(2).~.,

Iwmllnabb

71014197.43)sl

Amsdem

O16umf(MUI6)

laL&9I.t.m1.6XIL6mlf.m1.620

C4blo-ddknemrmu

(Incha)

Osul.&u.&M.74!n.%.9Uml

Cabla*Wpern

mdmum(IIS)

ala2302s03J0Amm460

RdhuCm81d

&2s)ls1020uasl.o33

CIIR10

S1-04m-lm-lm.1Sro-1m-lm-l

Um651

2!mml

Am6dw.cd Ctn6udof I

&or

WCmblult

13lo2,023253,0M

Lho6&

WCbnbhnf

4WCtiled


mu

:.

TABLE VU) (a)(3).

. . ..-. .

Ampdly,e mdLmOI. .

MII.4 &bletyps*W SsI 4mm

ccductofNum6c, Ammos able axtdcdpdm

liltedtiab’AWCI dom.’ ~; dWti& ID

NSNadl. C8t.mll *S% ~“ $&c 4WC S&c

- Mild614301

duaom tiuam 61Mluu W AmbkMb UbII (MUM) .

A!nbkm Anbke,lAmbkat+? (IIKba)

(Imbu)(sMS)

91S147 lSWT. a a a am 062s alss ‘Lo S3D.3 m -“

9LWS 3SWF. 3 n 6 Am .201 202.5WT-

SsD-z m -4 II 8 :% m 111 2.0

aswwS37)J

7 233m -

14 .mo AIS s. %wF u n

SrD.a4s

X4 -.m UsO Am : S17J-1 ml -.

9wa 7s.s. 2 ls 7 IJsm O&l .lss u SPL-3 Sal -

9ula DSS- 1 18 2 Ssu .Im lLl 5PM mz

6DS 3 16 X0 .Im u SPLA

:fao 9

DSS. 4 14 4.110 303 .1s0 u SF1.J 6X 13

91SIS Fs a 18 4 1.620 #3 .14a u3 16

sew 603.4 mm SCo 110

Fs- 4 14 4:

4,110 ‘.sas 140 : 13

9LV61 Sa9 18 I 1A30 ,SCo Ln31 10 SPU m -

913n9 ‘nlm4. 6 16 u l,m .91J alti 7s ‘6EL1 KD -

9UIS w 1 1s 3 L6m Am .140 1,0 SPI,3W 3

tul 616 3 33s0 501

lss- 4.1s0 Is SW m

14 39

4,110 SOI 103 u SPu alo 13

, 1 1

--- S0314S3S

*


TABLE VIII(b)(l).

- Cmlinued

1N3N614340mRdllu

d bad

(*)

4#191a?Y3+n3-3364

WV, ,CVSP. 4, :

+-E-E-E90.-

laomn +

ml lm.-

me-mo -’

‘n

-“- +

m 7s--

-.--z93 a63153s0 %

------

9M16 ‘3HOF. 43T310F. 4034%lnoP- sc03m

3 4zlm l+1.3M ,9383 413sm 3.9303 mnml 3.lm 7.lm

10.0no‘uJ3

al

I

93,ml moml m

*mu@6303a671#aD.3cMo

91sno TR3L 103 0I’RF. 133 mTRP. Ma m

9un] lllxP- 84 1T3WF- 10s 1‘3RXF. 133 1 M

M6s7.0

M3360 +

mo 143a 167ml ml

133 LWlZY 143In 167

121141I’m—110111141

494%74m*936.3431

.-

e38.91m

t914.9310#913.3ofJ#91W317

------

91313 IDLT ].18 411”al”7’Olw 60 5373.3 ‘l-l-l-l-ISe CaolM4uN ad d Ubk.


. .

TABLE Vlll(b)(2).

.-~. COntinuul

I 1’

m10

I I I‘hidU

anduacw(MIX)

Mm

C&ommudihnacrmn(imlU4) (In)

0.z4a

Rdhudtad

(t%.)’20

I I Ampdly,d Ccmdtiw.Inm mu)

&.nalHI 41mtll I%R 1.5 PC-E-Cal%I.. —.= --- --- ..-

mu. AmbIwt A@Melu Anbkm Amblmt(nMS)

ma W - . - - mum


411A

W67 USP

I

nm16

TABLE VIIl(c)(l).~. .

. . .---- .-

~ - COntimud

Numbda+kumh &l@

16laas

maim I 1AM

L

Im1.111 .- .-lsal .-

-

Ib6knC4bdMI(L

103.-

%

Am ty,e

LkO1faHl~R RNC6ID @w% =

Ambkm Ambkti(nMS)

- -.- --- --

sealmmuu ● d C4Lbla

TIuor

6COHINSN

WC 614S01AnMr.tuAmbkat

m

. .


MIIX.

9WM

WmP

!3W21

,.

TABLE Vlll(d)(l),~. .

. . .. . .

~ - COdnud

R-1-%1 1

ISPA. n n~A- : n a

Arudeta

Cmduculr(MN)

O.’m1.111ls80

aaoMO

.440A40

amC?..mll

dhlwal

(Ixu)MIS.-

amIml

am1.111

abler+tFrh’mnbmlm~

1s0.-

amAlr

-J1O.650

hdlludbud

(h%)Iu

.-,-

(DRID

m-l

cmduaomIntheC,bh** d.. . ,. -

y Galtlup,minoraddmijnrdmde,.

Ampdy,h Culdnmlmad

tiorallh 40)HZRJtcd I(5NWtsm arc m WC J(PC 6145.01

Amblrat Ambbc4 AuMe@4 Ambklu(&”q

X0m

I -- - #wl.lm,--- --- -_

~z WY _ _ #91LWn7-’- - @40.sill

1 1 1 I4/! w - - ~1

- - - ls5w41



5.9 Anmacitv rating. To obtain the ampacity rating for an ambienttemperature of either 60 or 70”c, first determine the ampacity rating for 40”cambient from tables VI, VII, or VIII. Then multiply that value by the applicablederating factor shown in table IX. Cables listed in this table should not beused in ambient temperatures above 70-C. Cables nnt listed in this table shouldnot be used in ambient temperatures above 60”c. The +mpacity derating factor&es not change for those cables listed with armored variants.

TABLS Ix. ~ deratirrzfactnrs fo bient temperatures above SO-C.

Ambient temperature

(“c)

Cable type 60 70

UDHOF 0.78 0.67LSD~ .78 .67DXLSDSCU .80 .69DWXDsS .63 ..... ..

FRw .78 ,67LSFSCU .80 .69FxwFSS . .63 ..

LW4Du .72 .-ISMHOF .80 .69LSMNW .78 .67 “U3mscu .80 .69nxcw

LSSHOF .78 .67

LSTHOF .78 .67LSWW .78 .67TsF .63 ..TSXF .63 --U3TSCU .80 .69TxwTSS .63 .-

L$5KVTSCU .80 .69LS6SCU .80 .69LS7SGU .80 .697XW7ss .63 .-.

72


.


TASLS X. Amnacities of deraus3inE cables.

(Maximum amperes for each conductor, at 40 and 50”C ambient temperatures)

30r4 5t07 1 cable in conduit1 cable 2 cables cables cables of 8 or more

Cable in air in air in air in air cables in airtype

and size 40” 50” 60“ 50” &o” 50” .40”. 50” .40” 50”

LSDSGU/A-16 66 61 60 56 55 51 49 b6 46 4323 86 79 79 73 72 67 64 60,.. 61 5650 139 128 128 119. 117 109 lofl 97 98 90

75 185 “171 170 159 156 146 139 130 132 122100 219 201 202 187 184 171 164 153 155 143200 339 312 312 290 285 265 254 237 241 222

LsTsGu/A-9 43 40 39 36 34 30 29 27 27 2614 56 52 51 48 47 44 42 39 40 3723 76 70 70 65 64. ““59 57 53 54 5050 121 111 111 103 102 94 91 84 8675 163

79150 150 140 137 128 122 114 116 106

100 191 176. 176, 164 160 150 143 134 136 125

150 259 238 238 221 218 202 194 181 184 169200 298 275 27’4 256 250 234 224 209 212 195300 383 352 352 32ci 322 296 287 264 276 .253400 478 4.40 440 405 401 370 358 330 344 317

LSFsGu/A-9 43 40 41 38. 38 36 36 34 34 3223 76 70 72 67 68 ‘“”’63 64 60 61 5650 121 112 115 107 109 101 103 95 9775 163

90151 154 144 146 136 138 129 130 , 121

100 191 178 182 169 172 160 162 151 153150 258

142240 245 228 232 216 220 204 207 192

200 298 277 283 263 268 249 253 235 238 221

s6sGu/A-loo 163 153 150 140 136 127 122 114 116 108125 192 173 175 163 160 147 144 133 136 125150 225 204 207 190 188 173 169 156 160 147200 250 243 235 222 219 202 188 182 177 172

LMDU-6 15 14 14 13 14 12 13 12 12 1114 25 22 24 21 22 20 21 19 20 1823 34 30 32 28 30 27 29 25 27 2440 49 43 66 41 44 39 41 37 39 3660 65 59 62 57 58 54 55 52 51 50

73


PIIL-HOBK-299(Sli)3 April 1989

TAME X. Aumac tie 0~ cables. - Continued

(Mc.ximumamperes for each conductor, at 40 and 50”C ambient temperatures)

30r4 5t07 1 cable in conduit1 cable 2 cables cables

Cablecables of 8 or more

in air in air in air in air cables in airme

snd size 40” so” 40” 50” 40” 50” &o” 50” 40” 50”

L314DY-6 15 lk 14 13 14 12 13 12 12 il14 25 22 24 21’ 22 20 21 19 20 1823 34 30 32 28 30 27 29 25 27 2640 49 43 k6 41 44 39 .41 37 3960 65 59 62 57 58

3654 55

52.51 50

SUSCU/A/S-7 98 8.5 7.5 8 7 7,5 7 7 6.510 9 8 8.5 7.5 8 7 7.5 7 7 6.516 9 8 8.5 7.5 8 7 7.5 7 7 6.619 9’ 8 8.5 7.5 87 7.5 7 7 6.624 9 8 8.5 7.5 8 7 7.5 7 7 6.5

30 98 8.5 7.5 87 7 7 6.’5’37 9 8 “8.5 7.5 8 7 7.5 .7 7 6.544 5.5 5 5.0 4.5 .5 4.5 4.5 4 .4.5 k.O i

6. NOTES

6.1 Sub ect te~ sting.

AmpacityCable, degaussingCable, flexing serviceCable, non=flexing sen-iceCO&s, identificationConductor, multipleInsulationJacket, armoredJacket, unarmoredNon-watertightShield, braidsdWatertight

Preparing activity:Navy - SH(Project 6145-N328)


MIL-NDBK-299(SH)3 April 1989

I

I

,.I

APPENDIK

ELECTRICAL CABLE VOLTAGE DROP CALCUUTIONS FOR POWSR AND LIGHTING SYSTEMS

10. SCOPE

10.1 -. This appendix is intendsd for uxs ss a guide in determiningvoltage drops for csbles used in alternating current (at) snd direct current (dc)pover, lighting, interior communication, weapons control and electronic systems.

20. RSFSRENCED oocunsNTs

20.1 Government documents.

This paragraph is not applicable to this appendix.

20.2 Qther uublications. The following documents form a part of thishandbook to the extent specified herein. Unless othervise specified, the issuesof the documents,yhich are DoD adopted shall be those listed in the issue of theDoDISS specified in the solicitation. The issues of documents which have notbeen adopted shall be those in effect on the date of the cited DoDISS.

AMERICAN SOCIETY FOR TESTINGAND MATERIALS (ASTM)B8 - Standard Specification for Concentric-Lay-StrandedCopper

Conductors, Hard, Hedium-Hard, or Soft.B “258- Stsndard Specification for Standard Nominal Dismeters and

Cross-SectionalAreas of AWG Sizes of Solid Round WiresUsed as Electrical Conductors.

(Application for copies should be addressed to the American Society forTesting snd Materiala, 1916 Rsce Street, Philadelphia, PA 19103.)

(Nongovernment standsrds are generally available for reference fromlibraries. They are also distributed among nongovernment stan&r&’ bodies andusing Fedsral agencies.)

30. DEFINITIONS

30.1 Svmbols and”abbreviations. Selected symbols and abbreviations used inthis appendix are as follows:

E-

v-L-

cmil -

E is the symbol for sending end or bus (normally switchboard)voltage. It is li”ne-to-neutral rated voltage for thres-phase acsystems (line-to-line rated voltage divided by the squsre root of3), snd three-wire & systemx, and line-to-line rated voltage for dcsnd eingle phase alternating current systems.

V is che abbreviation for receiver or load voltage.L is the abbreviation for the length, in feet, of a single conductorin circuits hsving equsl conductor lengths in all legs of thecircuit.Cmil is th& abbreviation for thea single leg of the circuit.

75

circular mil cross-sectional area of


141L-HDBK-299(SH)APPSNDLX3 April 1989

pf8

9

aa

.$.PD%”

DF

I

- Pf is the abbreviation for power factor of the load.- The symbol .9represents the angle betveen the load voltage vector and

the load current vector.- The symbol @ represents the angle betveen the resistance vector and

the impedance vector for a cable (cable impedance angle).- The symbol a represents the valus of 6 subtracted from 9(a - .9- 6).- The s%bol a also represents the temperature coefficient of

Iavg -

ILL -

K-

u-

u~ -

u-

Uu -

R-

x-

z-

z-

resistance at measured temperature.The symbol 6 represents dansity.The symbol p represents resistivity.The symbol DZ represents the total voltage.drop expressed as apercent of the rated voltage E.

The abbreviation DF represents the drop factor, which is used insblified equations for calculating voltage drops.The abbreviation I represents the current, in amperes, flowing in oneleg of the circuit.The abbreviation Iavg represents the average of current, in amperes,flowing in the outsids conductors of a three-wire dc circuit,.assuming a 25 percent current unbalance.The abbreviation IU represents the difference between two linecurrents in a three-phase circuit.

The abbreviation K represents the apparent power, in volt-amperes’,for one phase of a circuit (K - V x I).

The abbreviation U represents the resistive power, in watts, for oneleg of a circuit (W - V x I x COS8).

The abbreviation WU represents the net of resistive power in twolegs of a circuit.

The abbreviation U represents the reactive povar, in vars, for oneleg of a circuit (U -.V x I x sinO).

The abbreviation U~ represents”the net of reactive power in MO legsof a circuit.

The abbreviation R rapresents the total cable resistance, @ ohms,for each leg of a circuit.

The abbreviation X represents the total cable reactance, in ohms, foreach leg of a circuit.The abbreviation Z represents the total cable impedance, in ohms, foreach leg of a circuit (equal to the square root of the sum of thecable resistance for each leg squared and cable reactance for eachleg squared).

The abbreviation z represents the impedance, in ohms, for each leg ofa circuit for 1 foot of cable.

&o. GSNSRAL DESCRIPTION OF EQUATIONS AND CALCUUTIONS

60.1 General description of voltage dron eauations. Tables XI and XIIcontain equations for calculating voltage drops in ac and dc circuits,resDectivelv. Table XI (for ac circuits) contains detailed methods forcalculating voltagecalculating voltagemethbds involve theXIII, XIV, XV, XVI,

drops for all setiici types, and simplified methods fordrops for power and lighting se=ices. ‘I%esimplifieduse of a drop factor (DF) which shall be selected from tablesXVII, and XVIII, as applicable. These drop factors were

76


I

MIL-HDBK-299(SH)AFPSNDIX3 April 1989

calculated using the impedance characteristic of type LSTSGA and LS6SGA cableain accordance with MIL-C-246&3. Althoud calculations are baaed ,uDonfullcoverage aluminum-armored cablea (armored cables represent worst caae impedancevaluas) they may be used for equivalent size unarmored cables. The tabulateddrop factors for qpe ISTS~ cable,may be used for other cable q’pes with similarimpedance characteristics, including lightveigbt cablea in accordance withMIL-C-24660. For any nonsi.milarcables, drop factors may be calculated by usingthe impedance characteristics of the cable in the appropriate equation .containe.dherein vhich &rive from the”s.fmplifiedmethod specified in 50.1 for powersystems, 50.2 for lighting aysteme (I and IU method), and 50.3 for lightingsystems (watts and vara method).

TABLS XI. Voltage drou aauations for ac circuits.

Type ofservice Detailed method equation Simplified method equation

Lighting service only:

D% -

()

2(1OO)L ~ coaoingle pheae, E DZ - 2Lx IxDFall types of (from table XVII)service OR

DZ -4LXWXDF”(from table XVIII)

Lighting aenice only:

hree-phase,.()

~X - @OO)L & CO.SaDZ-LXIUXDF

all service (from type XVII)types except ORpower DX - LX2WLLXDF

(from table XVIII)

hree-phaae, Dx

[ ‘z a’

- 100L(cos

() ]

+&& 2& DZ - L x I x DF (frompower service EE 2 table XIII, XIV, or(see note) XV as appropriate)

NOTE: 2his equation may be used on power systems through 4160 volts.

77


MIL-HDBK-299(SH)APPENDIK3 April 1989

I

I

TABLE XII. v~s

-e of service Equstion

vo-wire,all service types

D% -ps x IX2LX1 00

except power cmilx E

2400XIXL where RSS - 12, which iscmil x E. the resistivi~ of copper

,. at an assumed operatingtemperature of 45”C

Lo-wire,power se~ice

D%.- ‘s ‘~i; fEx 100

2600x IxL where RSS - 13, which iscmil x E the resistivity of copper

at ~ assumed operating,temperature of 65-C

hree-wire,lighting service

D% -RES x .(1avv + O.25 Iave) x Lxl 00

cmil x E

1500 x Iave x L vhere RES - 12, which is,-cmil x E the resistivi~ of copper

at an assumed operatingtemperature of 45”C .

‘hree-wire,power service DZ _ ‘s x (Iavr + O.25 Iavp) x Lxl 00

cmil x E

.1625X Iav!zx L where RSS - 13, vhich iscmilx E the resistivity of copper

at an aasumed operatingtemperature of 65”G

78


ble 450-volt.three-ghase.60-Hz vower sW&tllM.uTASL2 XIII.

Cable characteristics

ize. Area Ohms par 1000 factI/

Drop factor values at pow, factors(COS t) below 2/

0.5(

08.9

68.7

27.7

22.1

14.2

6.1

4.1

3.4

2.4

2.2

1.7

I.&

—

0.3(

—

5.3

‘3.8

:1.6

.7.3

,1.1

4.7

3:2

2,7

2.0

1.7

1.5

1.3—

0.60

-

23.6

77.9

31.3

25.0

16.0

6.8

4.5

3.7

2.6

2.2

1.8

1.5

—

0.40

—

5.7

0.4

4.3

9.5

2.5

5.4

3.7

3.1

2.2

1;9

1.6

1..4—

Ar@s LI:degreea) 1.0 0.95

79.6

12.9

b4.9

35.7

22.5

9.2

5.9

4.8

‘3.1

2.5

1.9”

1.4

I Clrdlz

0.9( 0.85 0.8[ 0.7’

T3 2,580

4 It,llo

~~9 10,380

4.872 0.043 ,.872

,.059

,.211

1.961

.605

.243

,155

.lzfl

.080

;066

.050

,Ofbo

0.51

.77

1.61

2.03

3.03

6.39

9.63

12.09

18.12

22.42

30.33

38.89

87.5

17.7

46.6

37.0

23.2

9.3

5.9

4.7

3.0

2.4

1.7

1.2

,71.4

,07.8

63.0

34.2

21.6

8.9

5.8

4.7

3.1

2,5

1.9

1.5

63.2

02,7

41.0

32.6

20.7

8.5

5.6

4.5

3.0

2.5

1.9

1.5

,55.1

97.7

39.0

31.1

19.8

8.2

5.6

4.4

2.9

2.5

1.9

1.5

39.’3

87.7

35.1

28.0

17:9

7.5

5.0

h.1

2.8

2.3

1.8

1.5

3.058 .041

1.211 .034

14 13,0900.960I

.034

.604 .032

.241 .027

.153 .026

.121 .026

,076 .025

23 20,820

50 52,620

75 83,690

100 105,600

150 167,800

200 211,600 .061 .025

I300 300,000 ,063I

,025

*.0311 .025

See IJO.1 for unarmore$5cable and other cable types.Multiply valuesby 10 for drop factrms.Derivationsof R, X, and Z shallbe as spec~fied k 50.4.Conductorresistanceat 65”C.Based upon full coveragealuminum-arioredcables.


TABLEXIV. w fact~. 450-vti three-Ohaae.@JO-HZ DQMIUxMU. u

Cable characteristics Drop factorvalues at power factora (cm 0) below u

,Iza Area ohms per 1000 feet y AnfJepcmil (degrees) 1.0 0.95 0.90 0.85 O.BO 0.70 0.60 0.50 O.ko 0.30

R~ x~ z

3 2,5804.872 0.286 4.8,81 3.36 187.6 182.2 175.1 167.6 160.1 144.9 129.8 115.2 101.6 89.9

4 4,110 3.058 .274 3.071 5.12 117.8 11s.4’111.3 106.9 102.4 93.2 83.9 74.9 66.2 58.5

9 10,3801.211 .229 1.232 10.71 46.7 47,1 46.0 4fA.6 &3.1 39.9 36.5 33.0 29.6 26.3

14 13,0900.960 .221 0.985 12.96 37.1 37.8 37,i 36.1 35.0 32.6 30.0 27.3 24.6 22.0

23 20,820 ,604 .211 .640 19.26 23.4 ‘24.6 24.5 24.1 23.6 22.3 20.9 19.3 17.7 16.0

50 52,620 .241 .181 .302 36,88 9.5 11.1 11.4 11.6 11.6 11.5 11.2 10.8 10.3 9.7

75 2.3,690 .153 .173 .231 48.48 6.3 7.8 8.3 8.6 8.7 8.9 8.9 8.7 8.5 B.2

100 105,600 .129 .176 .218 53.83 5.4 7.0 1.5 7.8 8.1 8.3 8.4 8.3 8.2 B.O

150 167,800 .083 ..168 .iB8 63.63 3.9 5.3 5.9 6.2 6.5 6.9 7.1 7.2 7.2 7,1

200 211,600 .069 ,168 .182 67.65 3.6 4.9 5.4 5.8 6,1 6.5 6.8 6.9 7.0 7.0

300 300,000 .061 .173 .183 70.55 3.3 4.7 5.3 5.7 6.0 6.5 6.8 7.0 “7.0 7.1

400 413,600 .073 .166 .181 66.31 3.5 4.9 5.5 5.9 6.2 6.6 6.8 6.9 7.0 6.9

3,/Sea 40.1 for unarmored.cable and other cable types.~ f4ultiplyvaluesby 10-’ for drop factors. -‘,w Derivationsof R, X, and Z shallbe as specifiedin 50.4.~ Conductor reaLstance at 65-C.w Based upon full coveragealuminum-armoredcables.


,,

.

TASLSXV. PKOD fac~e. 450-v~. 400-HZ~.u .

Cable characteristics

-H+iza Area ~ Ohms per 1000 feet~

cmilR~ X~

100 211,2000.064 0.088

125 266,200 .052 .086

150 335,600 .062 .084

200 423,200 .035 .084

z

.109

.101

.094

,091

Angle pdegrees]

53.83

58.83

63.64

67.65

Drop factor values at power Pactors(COS 4) belowU

1.0

2.7

2.3

1.9

1.7T0.95 0.90

3.5 3.8

3,0 3,3

2.7 2.9

2.4 .2.7 t

0.85 0.8(

3.9 4.0

3.5 3.6

3.1 3.3

2.9 3.1

0.70

-

4.2

3.8

3.4

3.3

0.6(

i.2

3.9

3.6

3.6

0.50

4.2

3.9

3.6

3.5

O.&(

&.1

3.8

3.6

3.5—

0.3C

—4.0

3.8

3.6

3.5—

U See 40.1 for unarmoredcable and other cable typee.~ Multiplyvaluesby 10-5 for drop factors.V For type 6SC cable at 400 Hz, two physicallyopposite conductors ace connected in parallel for eech phase..4/ Derivationsof R. X. and Z shallbe as euecifiedin $0.4.~ Conductorreeistanc~at 65”c.W Based upon full coveragealuminum-armoredcables.


TARLS XVI. G e St c~ or communications,

I yeauons control and electronicsvstems. ~

mN

60 HZ 400.Hz

Ohms pet 1000 feet ~ Ohms per 1000 feet ~

Size Area Angle fJ ‘ Angle f3cmil R~ x~ z (degrees) R~ Xy z (degrees)

3 2,580 4.546 0.043 4.546 0.54 4.546 0.287. 4.555 3.61..

4 4,110 2.853 .041 2.853 ,82 2.853 .274 2.866 5.49

9 10,380 1.130 .034 1.131 1.72 1.130 .229 1.153 11.46

14 13,090 0.896 .034 0.897 2.17 0.896 .224 0.924 14.04

23 20,820 .562 .032 .563 3.26 .563 .211 .601 20.56

50 52,620 .,525 .027 .zzi 6.84 .225 .181 .289 38.81

75 83,690 .1.43 .026 .145 10.30 .143 ,173 .224 50.42

100 105,600 .113 .026 .116 12.96 .120 .176 .213 55.71

150 167,800 .071. ,025 ,075 19.40 .677 ;168 .185 65.38

200 211,600 .057 .025 .062 23.68 .064 .168 .180 69.15

300 300,000 .041, .026 .049 32.38 .059 .,173 .183 71.17

400 .413,600 .028 .025 .038 41.76 .068 .166 .179 67.72

~ See 40.1 for unarmored cable and other cable types.~ Derivationsof R, X, and Z as specified in 50.4.~ C.nductor resistance at 45-C,~ Eased upon full coverage aluminum-armoredcables.

,.,’


mw

TABLE XVII. Prnf accore ~ for LSTSGA cable. lzo-volt. three-vhase or sin~le-c.hatie.6;-Hz liuhtine svstems (usinE I and lLL1. 2/

Drop”factor values ~ at power factor angle O (singlq-phase)of angle u ~ (three-phase).

(Angles in degrees below)

ize -70 -65 -60 -55” -50 -45 -40 -30 -20 -10 0 10 20 30

3 130.7 160.5 109.2 216.4 242.0 265.7 287.4 32k.1 351.0 367.1 312.2 365.9 348.5 320.5

4 83.1 101.8 119.8 136.8 152.8 167.6 181.2 204.0 220.7 230.7 233.6 229.5 218.4 200.6

9 34.3 41.7 “48.7 55.4 61.7 67..i 72.7 81:5 87.9 91.6 92.5 90.6 K6.O 78.7

lb 27.7 33.5 39,1 44’.4 49.3 53.8 58.0 64.9 69.9 72.7 73.4 71,8 68.0 62.1

23 18.3 21.9 25.3 2K.6 31.7 34.5 37.0 fbl.3 44.2 45.9 46.1 i5.o 42.4 38.6

50 8.4 9.8 11.2 12.4 13.6 14.5 15.6 17.1 18.1 18.5 18.4 <17.8 16.’5 1,4.8

75 6.0 6.9 7,.7 8.5 9.2 9.8 ‘1O.4 11.2 11.7 11.9 11.7 11.1 10.3 9.0

100 5.2 5.9 6.5 7.1 7.6 8.1 g.5 9.1 9.5 9.5 9.3 8.8 8.0 6.9

150 4.0 4.4 4.7 5.1 5.4 5.6 5.8 6.1 6.2 6.1 5.8 5.4 4.8 4.0

200 3.6 3.9 4.1 4.4 4.6 4.8 4.9 5.1 5.1 4.9 4.6 4.2 3.6 3.0

300 3.2 3.3 3.5 3.6 3.8 3.8 3:9 3.9 3.8 3.6 “’3.3 2.8 2.3 1.7

400 2.8 2.9 3.0 3.1 3.1 3.1 3.1 3.1 2.9 2.7 2.4 2.0 1.5 1.0L

~ 45*C ambient.~ See 40.1 for unarmored cable, and other cable types.~ Multiply values by 10“5 for drop factors. Cable characteristicsat 60 Hz in table XVI were used

calcul~ting the drop factors.~ See ,50.2for definitionof angle a. Negative angle indicates current lags

(lagging load); positive angle indicates current leads referencedvoltagebehind referenced voltage(laading,load).

‘!


TABLE XVIII. Pr D fa tOrc s ~ for LSTSGA cable. 12O-volt. three-pha

600-Hz

se or sfnele-uhase

n~ 8Vsterns [using watts and vars1. 2/.

I Drop factor valuea ~ at power factor angle # (single-phaae) of angle o ~ (three-phase)

;ize -70 -65

3 166.1 165.2

.!!105.7 104.8

9 43.6 42.9

14 35.2 24.5

23 23.2 22.5

50 10.7 10.1

75 7.7 7.1

100 6.7 6.1

150 5.1 4.5

200 4.5 4.0

300 4.0 3,4

400 3.5 3.0

-60

.64.5

,Oh.2

42.4

34.0

22.0

9.7

6.7

5.7

4.1

3.6

3.1

2.6

.55

164.0

103.7

42.0

33.6

21.7

9.4

6.4

5.4

3.8

3.3

2.8

2.3

Q

-50 -45

63.7 i63.4

03.4 103,1

41.7 41.5

33,3 33.1

21.4 21.2

9.2 9.0

6.2 6.0

5.2 5.0

3.6 3.5

3.1 2.9

2.5 2.4

2.1 1.9

,leain degr(

-40 -30

.63.1 162.7

02.8 102.4

.41.3 40.9

32.9 32.6

21.0 20.7

8:8 8.6

5.9 5.6

4.8 4.6

3.3 3.1

2.8 2.5

2.2 2.0

1.8 1.5

below)

-20 -10

62.4 162.1

02.1 101.8

40.7 40.4

32.3 32.1

20.5 20.3

8.4 8.2

5.4 5.3

4.4 4.2

2.9 2.7

2.3 2.2

1,.8 1.6

1.4 1.2

0. 10

.61.8 161.5

.01.6 101.3

40.2 40.0

31.9 31.7

20.1 19.8

8.0 7.8

5.1 4.9

fi.o ‘3.9

2.5 2.4

2.0 1.9

1.4 1.3

1.0 0.9

20

61.3

01.0

39.8

31.5

19.6

7.7

4.7

3.7

2.2

1.7

1.1

0.7

30

160.9.

100.7

39.5

31.2

19.4

7.4

4.5

3.5

2.0

1.5

0.9

0,5

M 45°C ambient~ See 40.1 for unarmored cable and other cable types.

3/ Multic.lvvalue in table bv 10-7 for droD factor. The drOD factora in this table are eaual to the drODfact~r~ in table XVII di~i.dedby 2 x V.x coa#, where V -“115 volts.

~ See 50.2 for definition of angla a. Negativa angle indicates current lags behind referenced voltage(lagging load) ; positive angle indicatea current leada referencedvoltage (leading load).

,’ ,.


MIL-HOBK-299(SH)APPENDIX3 April 1989

,:40.2 nree-nh ase line currents for sin=le-uhase loads. IrIordsr to

determine the line currents for a three-phsse fceder serving single-phase“loads.(such as lighting circuits), phase currents shall be combined vectorially. .Thismsy be accomplished in the following msnner, with reference to the followingdiagram.

= indi.ates the total of single-phcse load for ea.h phase.

I ?n, YBC,,and ~u are currents in’each phase.

~A, ?B, and TC are currents in each line.. . .

V~, VBC, and Vw are phsse voltages.

1. Ihe bar over the V and I indicate they are vectors. V and I without tbe barsindicate scalars (msgnituds only).

Total phase currents ‘~, ~BC, and ~CA shall be calculated by summing.vectorial~ .thgcurrents for the loads in.each respective phase. The phasevoltages V-, VBC, and VW shall be derived by the following:

I

If the power factor angles of the currents in AB, BC, and CA phases are 6’AB,6BC,and OW, referencing the phase currents with the respective voltages, then:

B5


MIL-HOBK-299(SH)APPENDIK3 April 1989

The line currents IA, IB, snd IC ?hsll”then be calculated using the followingequati0n5:

:~ -7~-Y~.

;B - YBC - Yu

Tc - & - ?B~

Note thst if all three-Dhase currents are eaual to ma$cnitude(Iwthen

- IBC - 1~) , and are 1!20electrical dcgree~ out of p~ase from each other,IA- IB - IC -WI~ (where I- - IBc - 1~) . This simplified method ,of

calculating the current msv be used to estimate its value onlv if there is a,SMS1l imbalance betveen the three-phase currents.

.

40.3 L“ tin~. For lightingsystems, watts (W snd w~) and vars (U snd UU) can be used instead of amperes(I and 1~) in voltage drop equstions to avoid the necessity of calculating allphase snd line currents. This is sn advantage when watt and var values ofcannected loads are known. They represent the resistive (real) snd reactive(i.maginsry)components of volt-ampere vectors, ~d may be added vectOriallY. ..

For single-phase circuits, watts (W) cnd vars (U) shall be the sums of theconnected load valuss.

For three-phase circuits, volt-ampere (K) vectors may be handled in the samemanner ss the current (I) vectars. The same subscript notation is applicable,snd is used herein. Equations msy also be written to express scalar values af W,h’~, U, snd U~ in terms of phase watts snd vars. Care shall be exercised inusing these equations, because some signs are different for inductive andcapacitive loads. The equations below are for inductive loads (see 50.3 forderivations).

WA = WM + 0.5 W~ - 0.866 U~

WB - WBC + 0.5 WM - 0.866 Um

WC - kt~ + 0.5 WBC - 0.866 UBC

UA - U~ + 0.5 U~ + 0.866 W~

UB - UBC + 0.5 U~ + 0.866 W~

UC - Ua + 0.5 UBC + 0.866 WBC

86

_-


1. KIL-HDBK-299(SH)APPENDIX3 April 1989

1.’

I

Where total.load on each of the three phases is capacitive, the signs of thelast terms in the equations listed above shsll be reversed. Similar sets ofequations may be vritten for combinations of inductive and capacitive loads.

For checking current carving capacity of conductors, only the largest phasevolt-amperes (K) value shall be considered. General equations ,sballbe asfollows:

nLL-cos-lf~)ortai-l~~)

Note: ~ is a positive angle if U~ is ppsitive: aLL is numericallygreater thsn 90 degrees if W= is negative.

50. DsTAID DESmIFTIONS OF @ATIONS ‘km CALCUMTIONS (DERIVATIONS)

50.1 Power svstens - deriVatiOn of drOD factors (DF>. This sectioncontains the derivation of the equations used to calculate drop factors forvoltage drop calculations in power systems. Tables XIII and XIV contain dropfactors for type LSTSGA cable which were calculated by using the derivedequation: Similarly, the drop factors shovn in table XV for type IS6SGA cable ..were calculated by also using this equation. Ibis equation may be used tocalculate drop factors for other eypes of cables, if the cable impedancecharacters tics are known.

Voltage relations for voltage drop calculations may be indicated in a vector .diagram as follows: _-

..87


141L-HDSK-299(SH)APPENOLX3 April 1989

,?(:. . ,‘0,, .+

‘.r,.,,%.. ‘~:e,

~.

.,,” II

,.’~i [R ‘x

v E

a’1

From the diagram:

E2 - (V + 12 COS CI)2+ (IZ Sin a)2 (equation 1)

From equation 1:

v--1’-+~ ‘ (equstion 2)

Voltage drop is given by the equation:

D-(Y)lOO-(1-:)100Substituting for V in equation 3 from equation 2:

(equation 3)

-’++=-m=’] ‘eqwti0n4) ~

m sin2a may be expressed (approximately)binomial series expansion which are:

[() ]

1=21-2E sin2a

Substituting into equation 4:

by the first tvo terms of its

(equation 5)

--

88


MIL-HDBK-299(SH)APPSNDIK3 April 1989

L2c100(2) Cosa

A- E

l-hen,

, L X A - IOO(Z)’COSU zE ,since z-L,

snd let

B- -’

Then,

L2XB-9

Equstion 5 msy then.be revritten as follows:

D% - IX LX A+(IXL)2B

Lst drop factor (DF) be defined as follows:

DF-A+(Ix LxB)

(equation 6)

(equstion 7)

l?henequation 6 msy be vritten as follows:

DZ -Ix LxDF, (equation 8)

Since 2E2>>E, &>B, for ti>B, equation 8 becomss d# s I x L x A, vhere d# -sssumed voltage drop.

Therefore,

Substituting this value into equstion 7 as follows:

L

12k?s!z,snd DF - E

(equation 9)

89


MIL-HOBK-299(SH)AFPZNDLX3 April 1989

Substituting into equation 8 as follows:

D% . I.L. w[oo +@,-’j]—

Therefore, drop factors shown in tables XIII, XIV, snd XV are calculated fromeWtiOn 9 by using the appropriate cable $.mpedencecharacteristics and loadpower factors. The assumed voltage drop (~% ) equals 10 for the drop factorsgenerated in these tables. The percentage voltage drop (D%) for a given loadcondition and length of cable may be calculated by multiplying the appropriatedrop factor value as shown in (tables XIII, XIV, and XV) by the length of cable.

50.2 Lichtine svseema - derivation of dror.factors (DFI. This sectioncontains,the derivation of the equations used to calculate voltage dropcalculations in lighting systems. Table XVII contains drop factors for typeL5TSGA cable which were calculated using the derived equation. This equation msybe used to,calculate drop factors for other cables, if the cable characteristicsare lmown. The circuit.for a three-phase lighting system may be represented asfollows:

Voltage loop equations may be vritteu for loops BAabB, CBbcC, and ACCSA asfollows:

-l?~ + ZLIA + Vab “-ZLIB - 0

-EBC + ZLIB + Vbc - ZLIC _ O

-~ + ZLIC + Vca - ZLIA _ O

where ZL - impedance, in ohms for each phase of both cable and load.

The above loop equations may be rewritten’as follows:

E~-V~- (IA - IB) ZL

EBC - Vbc - (IB - Ic) ZL

%A-vca - (Ic - IA) ZL

..

90


I

MIL-HOBK-299(SH)

I

I

APPSNOIX3 April 1989

For the first equation in the above set of three, a vector diagram may bedrawn as follows:

\

t

0 ‘.‘.\

(“IA-IB) ‘

Since angie e is very small,

Cos(c+a)scosa.

and Vab s Vab cosa

Therefore, from the vector diagram,

Vab ~, EN - (IA-IB)ZL COSIY (equation 1)

The general quation for voltage drops is given by:

., .~),oo .(.),OO (equation2,

For phaae AS specifically, equation 1 may be vritten aa

.( )VA

DZ-1 - Em 100

Substituting in equecion 3 from equation 1 for V*,

( )

(lA - IB) ZL cosD% -l-l+ x 100

Em

Since # - u + B.

(equation 3)

..

91

--


I ..

.

MIL-HOBK-299(SH)APPENB7.X3 April 1989

Therefore,

“D’ -(lA-*::’”) 100,’

(equation 4)

Eq&tion 4 may be generalized by letting IL represent the difference in linecurrents (IA-IB, IB-IC or IC-IA), and E represent the line-to-line rated sourcevoltage (Em i EBC, or E&) .

Equation 4 may then be irrittenas folloys:,,.

02 -I~x

~

Since ZL - L

o% - Im

Let drop factor

SQs.tZLX E x 100

equation 5 may

mXL XZLXEX

(equation 5)

be rewritten as follows: .

100 (equation 6)

(DF),be defined as follows:

uDF - ZLX E x 100 (equation 7)

Substituting eqqation 7 into equation 6,

DZ - I~x LxDF (equation 8)

Therefore, drop factors in table XVII are calculated from equation 7 by u ingappropriate cable impe~ce characteristics and load power factora. The entriesof table XVII are prapared for a given power factor using the relationshipe - a + # from the vector diagram in 50.2.

50.3 ~L actors usi load wattsand vars. I?hissection contains the derivation of the equations used tocalculate voltage drop in lighting systems by the load watts and vars method.Table KVIII contains drop factora for type 15TSW cable vhich were calculatedusing the &rived equationa. The equations may be used to calculate drop factorsfor other cable types, if the cable characteristics are Imown. The followingvector diagram is used in derivation of the equations:

.

. .

--

92


1“I

I

K. the totalmultiplying ply3se

KIL-HDBK-299(SH)APPEWDIX3 April 1989

“m

&

‘CA

%

VA8‘JAa

1.481~~~

/ >TA7[QN,.“EC

power (real and imaginary) for each phase, may becurrent by phase voltage. For example, for phase

found byAs,

In rectangular form, KAB. - VM (l+jO) x 1~ (COSOW + jsinOAg)

Since vMIMc05e0 -

V@~sinfl~ -

Equation 1 may be.vritten as follows:

W~, and

UAB,

KM . w#@ + jupJ.

KBC and ~ may be referenced to the same axis as Km; for inductive loads,their vector values shall be as follows:

KBC cos (-120” - #BC) and

@ co, (120” - o~)

Using the trigonometric identity as follows:..

c08(e1 - e2) - COS01COS62 + sin91sinfJ2.’. .

.-

93


and

snd

snd

the

I

snd

PIIL-HDBK-299(SH)APPKWDXK3 April 1989

These terms can be written ss follows:

KBCICOS (-12f)”)cos (#BC).+ Sin (-120”) sin (OBC)

~[cos 120” c0sr3~ + sin 120” sin # Bc]

since sin(-120”) - ;0.866 snd COS(-120”) - -0.5

sin 120” - 0.866 snd COS 120” - -0.5

equation becomes KBC (-0.5 COSOP,C - 0.866 sin#BC) snd

KCA (’-0.5”cOs@CA + 0.866 s!nd~)

As indicated above, these tvo quantities can be rewritten as follows:

-0.5WBc - 0.866UBC and

-- -0.5VCA + 0.866UCA

Since line A vole-smperes is the difference between phase AS volt-smperesphase CA volt-smperes, then:

Substituting for l?~ and UW,

VA - KM COSt?~ - ~ COS (120”- #~)

V* -wAg- (-0.5 WCA + 0.666 UCA)

WA . w~ + 0.5WCA - 0.866 UCA (equation 2)

siMihrly fOr WB,

WB-WBC-tlU.

- KBC (-0.5 COS8BC - 0.866 Sin@BC) - w~

-ti~ - 0.5WBc - 0.866 UBC (equstion 3)

Since ‘IJ(AB) - ‘A - WB

94 ,,

--


I

MIL-HDBK-299(SH)APPSNDIX3 April 1989

Substituting from equations 2 and 3,

%L(AB) - 2w/@ + 0.5 (WBC + Wm) + 0.866 (UBC - UW)

and 2w~(Ag) - 4w~ + wB~ + WW + 1.73 (UBC - UM)

By an analysis similar to tb”t shown above, the equation for 2 UU(AB) msybe found.

Equations for WU(BC), WLL(CA), ULL(BC) and U~(CA) “maybe fO~d byreferring the K vectors to the same sxis of VBC for WLL(BC) and ULL(BC), and VCAfor WU(W) and ULL(W) . Equs%ions for capacitive loads, or mixed inductive and

I capacitive 10a&, may also be &rived by assigning the proper sign to each phase~gle (negative for inductive and positive for capacitive) in determining valuesof cosine and sine (~ 120” ~ 0). It shouLd be noted that if these equations aredivided by load voltage, V, similar expressions involving resistive and reactive.—‘c-orients of current will result. In-some casks, use of these equations may bemore convenient than the vector rotation method when currents are used incalculations.

The general voltage.drop equ.atiorifor lighting systems as derived in 50.2 is

.Dz - Iux LxDF (equation 4)

Since W~ - Iu (V) (cosa ), subs~ituting 2W~ - 21~’ (V) (cosa ) intoequation 4 will give

LX2WLLXDFD% - (equation 5)

1.

I2(v) Cosa

I LX a new drop factor (DF’) be &fined as follows:

DFDF’ - 2(V) COSa

Therefore,

D% - LX2WLLXDF’..

The three-phase voltage drop equation (equation=gle, in accOrkCe with the following derivation:

I5) may be revritten, without

95

.-.

..-


MIL-HDBK-299(SH)APPEWDLX3 April 1989

I

AS shovn in 50.2,

Cos (a + 81DF - Z~X E x 100,

where # - a+fl

Substituting for DF in equation 5,

I L x Wu x ZL (COSQ cosfl~ sinn sir@) x 100

IDX - E(V) COSQ

Using a trigonometric identity,

100 x L x W~ x ZL (cosa cos~ ~ sinm si@)

02 - E(V) COSa.

100 x L X Ku X (R COSU f X Sinm)

E(V)

100 x L X (RW~ ~ X’U~)

120 x 115

DZ - 725 (L) (RW~ ~ XU~) x 10-5, vhere R and X are cable co~t~ts =shown in table XIV. Plus is used in the above equation for inductive loads, andminus is used for capacitive loa&. In order to calculate the percentage voltagedrop, entries in table XVIII may be used vitb the value of power specified andlength of the cable.

50..4 ge vat 0 0 es stanceri i n f r i and reactance values for cables. Thissection contains the derivation of.valuss for cable resistance and reactance usedin tables KIII, XIV, KV, and XVI. The cables identified in this dmcument haveconductor.diameters of stamdsrd AWG, rather than Navy siZes. Navy sizes areclose to equivalent AWG sizes. However, the differences are enough to affeetcable impedsnce values.

The i,&al method of determining resistance and reactance valuas forparticular cable types is by test measurements. In the absence of.test data,however, these values may be derived mathematically.

50.4.1 Ca cu at 0 0~ or cab eS. The method used hereinfor calculating the resistance of electrical cables is based upon the onespecified.in ASTM B 258 snd ASTM B 8. This gensral method may be used tocalculate with reasonable accuracy the resistance,of sny cable with concentric-lay-strandsd conductors. lhe overall approach is as follows:

96

.-

.

,-...--


1,

MIL-HDBK-299(SH)APPF.NDIK3 April 1989

(1) Calculate & resistance at 20”C for solid conductors usingASTM B 258.

(2) Adjwt for concentric-lay-strandedconductors using ASTM B 8.(3) Adjust for ac resistance by’multiplying by the ac/dc resistance

ratio at the &sired frsquency (60 or 400 Hz).(4) Adjust to temperature for which cable service is &signed. As

specified in ASTM B 258,“& ,resistanceat 20°C in ohms per 1000feet is given by:

()R& - % 105.35

where p (resistivity) is 875.20 ohm-pounds per mile squared, andis 6 (dsnaity) 8.89 grams per centimeter cubed. Therefore,

R& - 10.371.47d2

where d is the diameter of.the conductor in mfls. Therefore. thefolloving chart for tj@e’5G-“equivalentsolid.conductors shali begenerated.

~ (ohms per 1000 ft) atDesienation Qia. (mils~ 20”C

SG-3 50.8 4.018SG-4 64.1 2.522SG-9 101.9 0.999SG-14 114.4 “’” .792SG-23 144.3 .498SG-50 229.4 .197SG-75 289.3 .124SG-1OO 324.9 .098SG-150 409.6 .062SG-200 460.0 .049SG-300 547.7 .035SG-400 643.1 .025

This data for solid conductors must be adju.stedfor concentric.lay-strandedSG conductors. Because of the lay in stranded conductors, the resistance foreach unit length of a strandsd conductor is slightly greatsr titanthat for anequivalent diameter solid conductor. ASTM B 8 provides a precise mathematicalmethod for &riving the multiplying factor (k, in percent) that is used to modify& resistance of a solid conductor for ,- equivalent concentric-lay-stranded ..conductor. A lay factor (mind) is @termined for each wire in a concentric-lay-strandsd conductor from ‘..-

“nd - ~

.,.

,-..,_-

97


MIL-HDBK-299(SH)APPSNDLX3 April 1989

where n equals the length of lay/diameter of helical path of wire. The layfactor m for the complete strandsd conductor is the numerical average of the layfactors (mind) for each of the individual wires in the conductor. Finally, theincrement factor k is calculated from

K- 100 (m-1)

K is the percentage valus increase in resistance of a solid conductor for anequivalent concentric-lay-stranded conductor. In lieu of performing manycalculations based upon &tailed conductor geometry,.which.would be required bythe above method, the folloving n6minal increment factors may be used:

Number of strands Jncrement factor (nercent~

7 3:19 437 561 591 5

127 5

Therefore, concentric-lay-stranding of a solid conductor results in anominal increase in electrical resistance from 3‘to 5 percent, depending upon thenumber of strands in a conductor. The.above chart for dc resistance of solid

I conductors msy be used to generate ,achsrt for concentric.lay-stranded conductorsby applying the above increment factors.

~ (ohms per 1000 ft)Desienation flumberof stran& at 20”C

SG-3 7 4.139SG-.4 7 2.598SG-9 7 1.029SG-14 7 0.816

were

SG-23 7SG-50 19SG-75 37SG-1OO 61SG-150 61SG-200 61SG-300 91SG-400 127

The ‘folloving ac/dt resistsnce ratios were calculatedadjusted to 65”C, since the ac resistance values were

;513.205.130.103.065.052.037.026

(dc resistance valuesat that temperature).

..Desireation Ac/dc ratio at 60 Hz Ac/dc ratio at LOO Hz

-...SG-3 1.00 1.00SG-4 1.00

..1.00

SG-9 1.00 1.00 -.SG-14 1.00 1.00SG-23 1.00 1.00

--

98


MIL-HOBK-299(SH)APPSNDIX3 April 1989

Desireation

SG-50SG-75SG-1OOSG-150SG-200SG-300SG-400

Ac/dc ratio at 60 Hz

1.001.001.001.001.001.001.00

Acldc ratio at 400 HZ

1.001.001.061.091.141.432.35

Therefore, the above chart for & resistance of concentric-lay-st!randadconductors msy be used to generate a chart of ac resistances, 60 and 400 w20”C, by multiplication of the appropriate ac~dc resistance ratio.

Ac resistance, 60 Hz Ac resistance, 400 HzDesisnation (ohms r.er1000 ft)- (ohms per 1000 ft)

SG-3 4.139 4.139SG-4 2.598 2.598SG-9 1.029SG-14

1.0290.816 0.816

SG-23 .513SG-50 .205.SG-75 .130SG-1OO .103SG-150 .665SG-200 .052SG-300 .037SG-400 .026

Finally, ac resistances must be adjusted for the designservice. Resistance values at a selectad temperature may bemeasured resistance values at snother temperature by

I Rt _ Rto [1 + a (t-to)]

Where:

For

ForiS 65”c.

The,.

at

.513

.205

.130

.109

.071

.059

.053

.061

temperature of cablecalculated from

Rt - required resistance.Rto - messked resistance.

t - temperature at which resistance is required.

to - temperature at which resistance was measured.a - temperature coefficient of resistance at measured temperature.

to - 20”C, a - 0.00393 per l“c, and to - 25”C, a - 0.00385 per l-C.

tables XIII (60 Hz) and XIV (400 Hz), the applicable temperature value .-l’herefore,resistances in tha above chart must be multiplied by . -.

1 + 0.00393 (65-20) - 1.177 ,. ..

following data results:

_-

99


KIL-HOBK-299(SH)APPENOIX3 April 1989

Ac resistance, 60 HzDesignation (ohms Der 1000 ft1

SG-3 4.872SG-4 3.058SG-9 1.211SG-14 0.96SG-23 .604SG-50 .241SG-75 .153SG-1OO .121SG-150 .076SG-200 .061SG-300 .063SG-400 .031

Ac resistance, 400 Hz(ohms uer 1000 ft)

4.8723.0581.2110.96.606.241.153.129.083.069.061.073

These are the resistance values shown in tables XIII (60 Hz) and XIV (400L).

For table XVI, the applicable temperature value is 45”C. Therefore,resistances at 20”c must be multiplied by

1 + 0.00393 (45-20) _ 1.098

The following &ta resul’ts:

Designation

SG-3SG-4SG-9SG-14SG-23SG-50SG-75SG-1OOSG-150SG-200SG-300SG-400

‘Ac resistance, 60 Hz~1 000 ft

4.~562.853 “1.1300.896,.562.225.143.113.071.057.041.029

Ac resistance, 400 Hz(ohms uer 1000 ft)

4.4562.8531.1300.896.563 “.225.143.120.077.064.059.068

These are the resiscance values shovn in table XVI.

For type 6SG cable shown in cable xv, two conductors are connected inparallel for each phase of a three-phsse circuit. Therefore. the resistance for ..each phase is one-half of the aC resist=ce (at

required &sign temperature of 65-C. Resulting400 Hz) calculated“earlierat the -values are as follows:,

..

,-

-:


I,.

I KIL-HDBK-299(SH)APPENDIX3 April 1989

pesicnation

6sG-1OO6SG-1256sG-150.6sG-200 ~~

Ac resistance, 400 Hz~ 000 t

0.0640.0520.0420.035

50.4.2 Calculation”of reactance values for cables. Calculation of cablereactcnces is much more complicated than the “calculation”of cable resistances.’The principal rsason for this is that cable reactance are not only dependentwon the geometry of the conductors in the cable; but also on the cable.’s ..externcl environment (for exxmple, conducting armor mxterial and proximity tosurrounding steel). The folloving inductance (reactance‘dividedby the quanti~of tvo times the frequency times m) values are for Navy size cables.

I

Pe i=ns ation

SG-3SG-kSG-9SG-14SG-23 .,SG-50SG-75SG-1OOSG-150SG-200SG-300

Inducta.ncemill ihenries ner 1000 ft~

0.109.104.098.085.080.074.072.072.069.069.069

I SG-400 .066

In terms of the .magni~e of impedance for a cable, these values of’inductance are relatively in.significant in comparison to resistance, except for’large size cables at 400 Hz. Conxequsntly, in the absence of reactance data,reasonsblv accurate voltage drous can be calculated on the basis of resistance-.alone for cables with relatively insignificant inductance. In Or&r to quantifythe effect on reactxnce in converting from Navy sizes to AWG sizes, the ratio ofthe change in the ratio of the distsnce betveen the center of conductors snd theconduccor diameter.for each size is used sx a multiplying factor to determine anew inductance value. While this method may not be precise, it does provide (onan order of magnitu& bssis) a reaxonsble inductancevalue for AWG sizes basedupon the data for Navy sizes. Conductor dicmetersare derived from MIL-C-9,15forold ratio snd N3L-C-24643 for new ratio. New inductancevalues are as follows:

I New inductanceDesivnatiorl ~ New ratio Jmillihenries uer 1 )-000 ft

I

SG-3 2.17 2.26 0.113SG-4 1.88 . 1.97 .109

ISG-9 1.73 1.61 .091SG-lk 1.92 2.02 .089

101

..

.,. --.-


MIL-HDBK-299(SH)APPSNDIK ‘ -3 April 1989

Desienation

SG-23SG-50SG-75SG-100SG-150SG-200SG-300SG-600

Old ratio New ratio

IFrom these adjusted

I be calculated to produce

1.811.311.281.251.221.231.191.16

Desienatioq. .

SG-3SG-hSG-9SG-14SG-23SG-50SG-75SG-100SG-150SG-200SG-300SG-400

1.891.281.221.211.191.201.191.16

new inductance values,the following data:

Ac resistance, 60.Hz(ohms ner 1000 ft~

o.o&3.041.034.034.032.027.026.026.025.025.025.025

New inductance

.083

.073

.068

.069

.067

.067

.069

.066

reactance at 60 and 400 Hz may

Ac resistance, 400 Hz(ohms ner 1000 ft)

0.286.274.229.221.211.181.173 .,.176.168.168.173.166

Since tvo conductors are connected in parallel for each phase, the reactance

per phase is one-half of reactance at 400 ,Hz. The reactance values used for 6SGcable are as follows:

,“ Ac resistance, 400 Hz.g&&r@& (ohms ber 1000 ft)

6SG-1OO 0.0886SG-125 .0866SG-150 .08h6SG-200 .084

Finally, impedance values are calculated by taking the square root of thesum of the resistance squared and reactance squared.

. .

,---

-=

102



INDEX

Cable Information

a3!2

Cable application data ...........................’..................Cable classification ,..............................................Identification information 1.........................................Methods of applying identification .................................Ratings and characteristics ........................................Supersession data ...................................................Types and construction characteristics .............................Year of manufacture ................................................

Cable Ratings and Characteristics

CVSF . . . . . . . . . . . . . . . . . . . . .DLT ......................DX .......................DXA ......................DXOW .....................DXW ......................DXWA .....................DSS ......................DSWS .....................FSS ......................Fx .......................FxA ......................Fxow .....................

“.FKW ......................FXWA .....................JAS ......................UCVSF ...................LSDCOP ...................LSDHOF ...................L5DNW ....................NDNWA ...................LSDPS ....................lSDRW ....................ISDRWA: ..................ISDSGA .:.................ISDSGU ...................LSECM ....................LSECMA ...................LSFHOF ...................I.SFNW....................LWTilJA....................

lkls.e

6868616156.565667656761615656566a515h5142423037373031.40&o514262

LSFPS ....................ISFSCA . . . . . . .. . . . . . . . . . . .LSFSGU ....................I.SMA.....................Lsncos ...................ISIDu ....................LSKDY. ....................L5MHOF ...................LSMMOP ...................EMWW ....................ISMNWA ...................Mm ....................IS4S .....................EMSA....................LSISCA ...................IS4Scs.. .........’........LSMSCU ...................Lam .....................LSnus ....................ISPBTN ..................’..LSPBTMU ...................ISPI .....................LSSHOF .....................ISIRU ....................LSSRWA ...................USSF ....................LSSSGA ...................E&XXI..... ..............ISTUA ...................LSTCJU ...................

1928121630’26318

313131455637375354454550L545343434454540.!+0415137375131323535

--

103


L5TC.7X...................LSTCKX ...................LSTCOP ...................LSTCTA ...................ISTCTU ...................lST~ ...................LSTHOF . . . . . . . . .. . . . . . . . . . .Ismw. . . . . . . . . . . . . . . . . . . .LSTNWA .....................LSTPNW ..............”.....LSTPNWA ..................ISTPS ....................LSTRW ....................IJY3!RWA. ..................ISTSGA ...................LSTSCU ...................L5TTOP ...................lSr-TRS...................LS2TRSA ............’......UTITSA. ..................LSTTSU ...................LSISA ....................EilSAU ...................ISISMA ...................IS1S14U...................LSISUWA ..................Lslsmwu ..................ISlsu ....................ISISUA ...................ISISWA ...................ISlswu ...................L51S50NA .................LSlssomu .................LS1S50KUS ................LS1S75MA .................IS1S75MU .................LS2A .....................IS2AU ....................LS2AUS ...................LS2CS ....................LS2SA ....................L52SJ .....................LS2SJA ...................L52SU ....................LS2SUS ...................E2SWA ...................LS2SUAU ..................


Centinued

E=s=

3s3554,353535,5162’43505032373733335454543535466646f463838 .464638384646&64646464646&647h34347673838

L92SWL ...................IS2SWLA ..................LS2SWU ...............”.....LS2SWUA ..................IS2U .....................LS2UA ....................LS2UW ....................,IJ32UWA...................,U2UWS ...................LS2WA ....>...............LS21JAU...................LS3SA ....................IS3SF ....................LS3SJ ....................LS3SJA .....................L53SU .....................IS3SUS ...................LS3SWA ...................LS3SWU...................L$3SWUS ..................LS3U .....................IS3UA .....................LS4WW8 ...................M4NTJA8 ...................IS4SJ ....................LS4SJA ...................LS5KVTSGA ................M5KVTSCU ................LS6SGA ...................LS6SGU ...................IJ37PS....................LS7SCA ...................U7SGU ...................M8NW6 ...................LS8NWA6 ..................HCSF. ....................KSP . . . . . . . . . . . . . . . . . . . . . .MSFW . . . . . . . . . . . . . . . . . . . . .l’lws . . . . . . . . . . . . . . . . . . . . . .Hxcow . . . . . . . . . . . . . . . . . . . .mm. . . . . . . . . . . . . . . . . . . . .MXCWA ....................Mxo ......................14xs o....................S2S ......................THOF .....................TFUM-6 ...................

&Q,

383838394848.393939 ‘“.393948546344494939394050504545444433333030303030454565707166

.57575763636768 ‘“67

-:.-

.--,--

104


MIL-HDBK-299(sH)3 April 1989

INDSK - Continued

TRF . . . . . . . . . . . . . . . . . . . . . .TRKP . . . . . . . . . . . . . . . . . . . . .TSP ......................TSPA .....................TSS ......................l-lx......................TTKA .....................TTXou ....................‘rfxs.....................TTXSA. ...................TI’X.So....................2TXW.....................TTXWA ....................Tx .......................TxA .......................IKou. ....................TKW ......................TXWA .....................lSWF .....................

“IX14So ....................mow.. ..’................2SWP .....................

EaPs

686871716763635863,63635858616156565667625967

2KA0 . . . . . . . . . . . . . . . . . . . .2K0 . . . . . . . . . . . . . . . . . . . . .2XOIJ . . . . . . . . . . . . . . . . . . . .2KS . . . . . . . . . . . . . . . . . . . . .2KSA . . . . . . . . . . . . . ...’..”..2KSAOU . . . . . . . . . . . . . . . . . .2KSAU . . . . . . . . . . . . . . . . . . .2K2AUA . . . . . . . . . . . . . .. . . .2KS0 . . . . . . . . . . . . . . . . . . . .2KSOV . . . . ... . . . . . . . . . .. . . .2KSX0 . . . . . . . . . . . . . . . . . . .2KSU . . . . . . . . . . . . . . . . . . . .2KSVA ...................3KS .....................3KSA .....................3KSOW .....................3XSV ....................3XSWA ...................5ss .....................7ss .....................7X37 ....................7XWA ....................

Appendix

Cable characteristics, LSTSGA cable ...............................Definitions’.......................................................Derivation of resistance and reactancevalues for cables ................................................Drop factors for IS6SGA cable .....................................Drop factors for Ii3TSGAcable (60-H2) .............................Drop factors for LqTSGA cable (400-Hz) .............................Drop factors for ISTSGA cable (using I and 1~ drop factorvalues) ..........................................................Drop,factors for LSTSGA cable (using watts and vars) ..............Voltage drop equations for ac circuits .......’.....................Voltage drop equations for &circuits ............................

E@

626259626259595962.59635960636360606069675656

.@&

8275

96798381

83’.847778

105 ,,


. .c I

I.1

IIII1I

III

II

iilz,

“1I,.I

IIII

:I

I II I

I

/

STANDARDIZATION DOCUMWT IMPROVEMENT PROPOSAL(sEl?Inmuuiau - Jkwsewe)

. DOCUMENT NUMSER 2 00 CUMENT TITLE MLE C<ti~N-

MIL-HDBK-299(Sli) ELECTRIC sHIPBOARD CABLE. MAME0$SWSWI-IHOORGANIZATION ~~, oFo”oA”12ATm.,”d-,

I o 07”En f8mdfy,,-

●1100LEM AREAS

.“,

. NAME OF SUBU1lTEm b L ~fmt.Ml) - O@mul b. ~,c l~WNE Nwun fkha A=

MAILINCI &09RESS (Slwd, CIti, stsm, ZIP c&) . ~ ~ DATE OP SWMMEIOM fTYMMDDJ

1’


,

I

lNSTRUCf10N5 In & continuing ●ffon to msh our tidardkation documen?s better, tbe DoD pm?tda ti form for use in

ct!bndttiag COmraenw md wggatbm for im> owntenb. AD m of military standsrdkstkn documenb e hvitedtoprovide

ruggatkoru.lhh form IMY b 4etacbe?,folded along tbe fines indiated, taped along the Iooae edge (DO NOT STAPLE), and

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~=ti= IW-=1* On CW=nt -U=* @-fJ mbmitted 00 thh form do I!ot constitute or hllpfy ●Utb0ri21ti0n

to &w -y portion Et tbe referenced docuotent(s)or tosmend contmcttmlreq~nk

I

(Fold EIO,U thb UIU)

(Fold e&IU WI lINJ

.

DEPARTMENT OF THE NAW

COMMANDERNAvAL SEA SYSTEMS COMMAND (SSA 55Z3)DEPARTMENT OF TNE NAVY

111111 FI

WASHINGTON , DC 20362-5101 UN17E0 =ATCS

OFFICIAL SLISINE~●ENALTY FOR ●RIVATE USE E300 B~S~NE:SNoR~PLY MAIL

WASHINGTON D. C.

POSt_AGE WILL 8E PAID EY THE DEPARTMENT OF THE NAVY

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