8650 SDM Product Installation Sheet

3CM03094BAAARJZZA Edition 02 Released 1/32

COVER SHEET

PIS

Title 8650 SDM

SD01 Rack Layout

Product Installation on Site

Classification ATCA-V2

CBG/CTO/TC3

HW R&D

Edition 01 02

Date 2008-12-10 2009-03-05

Change Note

Appraisal Authority(ies)

Company ALCATEL-LUCENT ALCATEL-LUCENT

Function

Name(s) Initial(s)

Originator

Company CITLN CITLN

Department CCHW CCHW

Name(s) Initial(s) PE PE


Originator(s) Pierre Esnault

Approval(s) Project TPM Installation Product Manager B. PARIS P. LOLLIERIC JF. CIVEL

Product Integrity Y. HENRY

ABSTRACT This document defines the specific rules for installing, grounding, powering and external wiring of the 8650 SDM product.

This document is for Alcatel-Lucent internal use only.

REVIEW 01 Creation

02 Add Chinese configuration (xSX extended and 1mF modular)

Rename IX board by RH board


INTERNAL HISTORY

Version Status Date yy/mm/dd

Comments

Ed.01 Released 2008-12-10 Creation.

Ed.02 Proposal 01 2009-02-19 Add Chinese configuration (xSX extended and 1mF modular)

Rename IX board by RH board


ATCA-V2

8650 SDM

SD01 Rack Layout

Product Installation on Site


TABLE OF CONTENTS

REFERENCE LIST ..................................................................................................................................... 7

PREFACE .................................................................................................................................................. 8

1 GENERIC 9 2 RACK FIXING 9

2.1 Part List 9 2.2 Selection criteria 9 2.3 Survey and engineering questions 9

3 RACK GROUNDING 10 3.1 Part List 10 3.2 Selection criteria 10 3.3 Survey and engineering questions 10

4 RACK POWERING 11 4.1 Part List 12 4.2 Selection criteria 13 4.3 Survey and engineering questions 14

5 WIRING 15 5.1 Part List 15 5.2 Selection criteria 16

5.2.1 Serial Links......................................................................................................... 16 5.2.2 Ethernet Links.................................................................................................... 16 5.2.3 E1 Links .............................................................................................................. 18 5.2.4 Alarm Links ........................................................................................................ 24

5.3 How rout the External Cords 26 5.3.1 E1 Cords ............................................................................................................. 26 5.3.2 Other Cords........................................................................................................ 26

5.4 Survey and engineering questions 27 6 CABLING PARTS 28

6.1 Part List 28 6.2 Selection criteria 28 6.3 Survey and engineering questions 28

A. CONSUMPTION: .............................................................................................................................. 29

B. WIRING: .......................................................................................................................................... 31

GLOSSARY.............................................................................................................................................. 32


List of figures Figure 1: wiring schematic of the JSXPDUE1 connection to the customer power plant.........................................11 Figure 2: All cases to connect the rack to the customer power plant ......................................................................12 Figure 3 : Example of copper GE links from S/R.....................................................................................................17 Figure 4 : 120 ohms case .........................................................................................................................................19 Figure 5 : 75 ohms case ...........................................................................................................................................20 Figure 6 : 100 ohms case .........................................................................................................................................21 Figure 7 : Example of E1 links to customer DDF on one couple of RT board........................................................22 Figure 8 : Example of E1 links to customer DDF on one couple of RT board........................................................23 Figure 9 JBALARM (side view)...............................................................................................................................24 Figure 10 SCSI26 alarms connector pin-out ...........................................................................................................25 Figure 11 cabling way front view, example..............................................................................................................26 Figure 12. -48V Distribution in the rack ...................................................................................................................30

List of Tables Table 1 Part list of fixing kits....................................................................................................................................9 Table 2 seismic and non seismic rack fixing .............................................................................................................9 Table 3 Part list of grounding elements..................................................................................................................10 Table 4 drums ..........................................................................................................................................................10 Table 5 Part list of powering elements...................................................................................................................12 Table 6 cables..........................................................................................................................................................12 Table 7 Part list of wiring elements........................................................................................................................15 Table 8. GE link between OS6850 and External networks, in all config.............................................................16 Table 9. Number of E1/T1 links vs. configuration. ...............................................................................................18 Table 10 E1/T1 link from AB/M03 RT stations to External DDF ...........................................................................19 Table 11 E1/T1 link from AB/M03 RT stations to External DDF ...........................................................................19 Table 12 Alarm link between Alarm board and external signal lamp panel........................................................24 Table 13 Part list of cabling parts...........................................................................................................................28 Table 14 Length of 16 and 35 mm² external cords ...............................................................................................29 Table 15 Length of all external cords .....................................................................................................................29 Table 16 JLCAT6 length table ................................................................................................................................31 Table 17 ALETHC length table ................................................................................................................................31 Table 18 JLDAW length table .................................................................................................................................31 Table 19 DLANM120 length table ...........................................................................................................................31


REFERENCE LIST

[1] 8650 SDM ELS (SD01) 3CM03094AAAARJZZA

[2] Fixing GIS 3BW208340001RJZZA

[3] Grounding GIS 3BW208340003RJZZA

[4] Powering GIS (standard solution) 3BW208340007RJZZA

[5] Wiring GIS Add a JLDAW on a JSXPDUEx 3BW208340005RJZZA

[6] General Wiring GIS 3BW208340006RJZZA

[7] Files : KIACC1 3CM03177AA

[8] Files : KIBRAID 3BW13762AA

[9] Files : ZKFIXA 3BW11993AA

[10] Files : ZKFIX19P 3BW11883AA

[11] Files : MASISM1 3CM02941AA

[12] Files : KMISO 3CM02942AA

[13] Files : KI2HL2P2 3BW13774AA

[14] Files : KI2HL6P2 3BW13773AA

[15] Files : KI2HLGD1 3BW13768AA

[16] Standard for cable matrix 3CL000510001ASZZA

[17] Installation Decision Tool (IDT) for 8650 SDM (SD01) 3CM03094CAAAVTZZA


PREFACE

The purpose of this document is to provide useful information for assembling and connecting the SD01 rack layout, for the 8650 SDM product, on customer field.

For each step of the installation (fixing, grounding, powering, wiring processes) one or more Generic installation Sheet will be used.

A specific IDT (Installation Decision Tool) for the 8650 SDM product (SD01) ref. [17]), is available to calculate the kits to be order for an installation.

The description of the SD01 rack layout is made on the ELS document [1].

Symbols in text

This symbol may be found in the text of this document. It has the following meanings.

! CAUTION

CAUTION: Test set off in this manner indicates that failure to follow directions could result in damage to equipment or loss of information

! REMARK

Remark

Conventions

The naming of the devices and the ports is compliant with ELS naming.

The Right of the rack is the Right from the front view. So the right rear Vertical Rail is behind the right front Vertical Rail.

External cord or access: external for the SD01 rack layout.

Internal cord or access: internal for the SD01 rack layout.

All the non validated options are in orange in this document.*

In red: modifications from the previous iteration


1 GENERIC

An accessories kit KIACC1 (3BW13769AA) should be order. It included consumables to install the rack in the customer field.

2 RACK FIXING

The SD01 rack layout could be installed on solid or raised floor, on seismic or non seismic mode.

It is recommended to fix the rack on the floor (mandatory if seismic configuration).

2.1 Part List

The usable kits for this function are: Kits Codes to be order function

ZKFIX19P 3BW11883AA FIXING KIT FOR RACK ON SOLID FLOOR ZKFIXA 3BW11993AA fixation kit

MASISM1 3CM02941AA SEISMIC BASE FOR NRA2XX RACK KMISO 3CM02942AA INSULATING PLATE KIT FOR NRA2XX RACKS

Table 1 Part list of fixing kits

2.2 Selection criteria

For solid floor installation, one ZKFIX19P is always ordered, and for raised floor one ZKFIXA is always ordered. In this last case, on the seismic field, one MASISM1 is ordered. The following table summarizes these different cases:

Seismic Non Seismic Solid floor ZKFIX19P (ZKFIX19P)1 Raised floor MASISM1 + ZKFIXA ZKFIXA

Table 2 seismic and non seismic rack fixing

For IBN customer fields, an insulation kit is foreseen: KMISO.

All these solutions are described in the Fixing GIS document [2].

2.3 Survey and engineering questions

The questions for the site survey and/or engineering are:

1/ seismic installation?

2/ on solid or raised Floor?

3/ IBN or CBN installation?

According to the answers, the different kits will be ordered.

1 It is recommended to fix the rack on the floor , but in this case, it is not mandatory


3 RACK GROUNDING

The 8650 SDM rack, in SD01 rack layout, has been developed for CBN installation mode, but it could be also installed in IBN mode.

3.1 Part List

The usable elements for this function are: Object Ref. ALU Codes function

G/Y Wire 3BK08957BA 100m of 16mm² G/Y wire G/Y Wire 3BK08960BA 100m of 35mm² G/Y wire KIBRAID 3BW13762AA CBN kit

KI2HLGD1 3BW13768AA Two Holes lugs kit Table 3 Part list of grounding elements


For CBN customer fields only, one KIBRAID must be ordered by rack. For IBN customer fields one KMISO will be ordered and mounted under the rack, during rack fixing step (see chapter 2).

One or two KI2HLGD1 kits are to order, as much as the JSXPDUE1 number. This kit contains the two holes lugs to connect the 16 or 35mm² wires to the rack. The main features of these two holes lugs are: standard barrel 90°, ∆=19mm (3/4’) Ø=M6 (1/4’)

In most countries, the 16mm² 1AC017610012 wire is compliant and should be ordered.

! CAUTION

CAUTION: The choice of the safety ground section wire is compliant with IEC60364-5-54. On some customer fields the installation rules are more restricted and in this case, the solution is to order the 35mm² 1AC017610003 wire.

These wires could be ordered per drum. The only drums codified today are: Section (mm²) length ALU code Drum ref.

16 100m 1AC017610012 3BK08957BA 35 100m 1AC017610003 3BK08960BA

Table 4 drums

All these solutions are described in the Grounding GIS document [3].



1/ IBN or CBN installation?

2/ Distance between this rack and the Ground Window Site?

! CAUTION

CAUTION: In this document, the solutions with a distance more than 50m are not taking into account.

3/ Are the local Grounding rules more restricting that IEC 60364-5-54?

According to the answers, the different kits and cable will be ordered.


4 RACK POWERING

The 8650 SDM rack, in SD01 rack layout, has been developed with one or two JSXPDUE1 Power Distribution Units (PDU).

The JSXPDUE1 has been developed to feed one ATCA-V2 chassis, and up to four other small devices as Switch/Routers (S/R) and an alarm board in redundant mode.

In these configurations, two power feeds (0V and -48V), one for A branch and one for B branch, could be requested to the customer for each JSXPDUE1 implemented in the rack. Each power feed should be protected by a dedicated CB on the Customer power plant.

Figure 1: wiring schematic of the JSXPDUE1 connection to the customer power plant

! REMARK

Only black wires references are provided with colored rings.

! CAUTION

CAUTION: The ground of the rack must be connected before to connect the rack to the power plant. See chapter 3.

The nominal voltages are -48 or -60V. (From -40.5V to -72V).

The wires to use are double sheathing 10mm² or 35mm² wires.

B branch

A branch

X1

-48V

0V


4.1 Part List

The following table summarizes the usable elements for this function: Objects Ref. ALU Codes function

KI2HL6P2 kit 3BW13773AA Four 16mm² two holes lugs and colored heat shrinkable tubing KI2HL2P2 kit 3BW13774AA Four 35mm² two holes lugs and colored heat shrinkable tubing Black wire 3BK0895BA 100m of 16mm² (AWG6) double-sheathing wire for building Black wire 3BK08959BA 100m of 35mm² (AWG2) double-sheathing wire for building

Table 5 Part list of powering elements

The Two Holes lugs main features included in the KI2HLxP2 kits are: standard barrel, flat, ∆=16mm (3/4’) Ø=M6 (1/4’)

These wires could be ordered per drum. The only drums codified today are: Section (mm²) length ALU code Drum ref.

16 (AWG6) 100m 1AC017610010 3BK08956BA 35 (AWG2) 100m 1AC017610001 3BK08959BA

Table 6 cables

Figure 2: All cases to connect the rack to the customer power plant

A

B

PDU1

SD01 Customer Power plant

CB

Customer Dependent

A

B

KI2HL2P2 if 35mm² wire, and KI2HL2P6 if 16mm² wire.

PDU2 (optional)

16mm² wire if D ≤ 20m, and 35mm² wire if 20 < D ≤ 45m.

Dr

CB max: 125A if 35mm², 80A if 16mm² Available CB: from (Max consumption x 1.25) to CB max: from 60A to 80A if 16mm² wire, or from 60A to 125A if 35mm² wire To preserve the selectivity: from 90 to 125A Strongly recommended: 80A if 16mm² wire, and 90 or 100A if 35mm² wire.

Consumption : Nominal / Max (worst Cases)

19.5 / 46.1A

19.5 / 46.1A

18.2 / 43.1A

18.2 / 43.1A



To define the material to be ordered, three data must be defined:

• Na The number of ATCAV2 chassis included in the rack.

! REMARK

In the configurations with two ATCAV2 chassis (2D, 2F, 2DF and 2FD distributed configurations and DC Compact configuration) the second JSXPDUE1 (X2) will be connected on the customer power plan only when the second ATCAV2 chassis will be implemented on the rack.

! CAUTION

CAUTION: It is strongly advisable to connect the second JSXPDUE1 to customer power plant when the second ATCAV2 chassis (CD) is not implemented in the rack.

• Dr: distance from rack to customer power plant (meters): from 5 to 45m.

• Ff: Foreseen for the future. If the distance between rack and customer power plant is less than 20m, 16mm² cables are sufficient to feed the JSXPDUE1, but in this case, if the product used new more consuming boards in the future, the power cables will be to replace by 35mm² cables. The choice to install directly 35mm² cables is proposed.

From these two criteria, the number of cable drums and two holes kits could be defined with the following table:

Dr Na = 1 x ATCAV2 chassis 2 x ATCAV2 chassis

Ff= 16 mm² 35mm² 16 or 35mm² 35mm² only

[5-12.5m] 1 x drum 16mm² 1 x drum 35mm² 1 x drum 16mm² 1 x drum 35mm²

]12.5-25m] 1 x drum 16mm² 1 x drum 35mm² 2 x drum 16mm² 2 x drum 35mm²

]25-33m] Not available 2 x drum 35mm² Not available 3 x drum 35mm²

]33-45m] Not available 2 x drum 35mm² Not available 4 x drum 35mm²

Two Holes lugs kits 1 x KI2HL6P2 1 x KI2HL2P2 2 x KI2HL6P2 2 x KI2HL2P2 Table 7 Drums and kits vs. criteria

On the site, each connected access (A and B) must be connected by two cables (-48V and 0V cables, see the Figure 2)

The consumption of each these accesses, in the nominal / worst cases is given by the ELS document [1] and recalled in the Figure 2.

The strongly recommended values to protect these accesses on the customer power plant are:

• 80A if 16mm² wire (in this case the selectivity is not preserved),

• 90 or 100A if 35mm² wire.

! CAUTION

CAUTION: In no case should the circuit breaker protection exceed 125A for a 35mm² cable, and 80A for a 16mm² cable (IEC60364-5-52 installation method E, F).

The Figure 2 summarize all the cases.


! REMARK

How defined if your conf is a Compact or Distributed configuration?

• one PDU + 2 CT + 2 RT + 2 DB boards (4xNBRZAN + 2xNBRZAF) : SC compact cfg

• one PDU + 2 CT + 4 RT + 2 DB boards (4xNBRZAN + 4xNBRZAG) : xSC compact cfg

• one PDU + 2 CT + 6 RT + 4 DB boards (6xNBRZAN + 6xNBRZAF): MC2 compact cfg

• two PDU + 4 CT + 8 DB + 12 RT boards (12xNBRZAN + 12xNBRZAF) : DC2 compact cfg

• two PDU + 2 CT + 2 RH + 8 RT boards (4xNBRZAN + 8xNBRZAF): 1F3 distributed cfg

• two PDU + 4 CT + 2 RH + 8 RT boards + 10 DB boards (16xNBRZAN + 8xNBRZAF): 2DF3 or 2FD3 distributed cfg

• two PDU + 4 CT + 4 RH + 4 to 20 RT boards (8xNBRZAN + 16xNBRZAF): 2F3 distributed cfg

• two PDU + 2 CT + 10 DB boards (12xNBRZAN): 1D distributed cfg

• two PDU + 4 CT + 20 DB boards (24xNBRZAN): 2D distributed cfgFrom these

All these solutions are described in the Grounding GIS document [4].



1/ how many ATCAV2 chassis are implemented in the rack?

According to the answer, determine the number of links and kits to order.

2/ distance between the rack and the customer power plant to deduct the Dr length of the cable to fed the rack?

According to the answer, calculate the number of 100m drum to order.

3/ 16 or 35mm² cables between rack and customer power plant?

According to the answers: 35 : 35mm² cables will be ordered 16 : 16 mm² cable are ordered (if Dr ≤20m).

2 For Chinese market the NBRZAF are replaced by NBRZAG 3 For Chinese market the number of NBRZAF is at least 2 up to 8 by step of 2 per FE node


5 WIRING

There are four types of external cords:

• Serial cords for debug and/or installation only,

• Ethernet cords, on copper cable or optical fiber medium

• E1 cords

• Alarm links

5.1 Part List

The following cables could be ordered: Objects Ref. ALU Codes function

JLCAT6 1AB2298300xx CAT6 S-FTP straight cord LSMUD9 1AB360300001 DB9 – mini USB Serial link JLDAW 3BW13065AA Link to external Signal lamp panel DLANM120 3BL02197AA 120 ohms E1 link to DDF KRACG120 3BW12321AA 4 x 8 pairs terminal blocks kit JSIO 1AB066340011 10 pairs Terminal Block LDPETIQ 1AD021320001 Label holders PVTBSYM 1AB227470001 External 120/75 ohms terminal FICHE 1AB025460001 1.6/5.6 male plug COAX1X 3BW12260AA 100m drum coaxial cable

Table 7 Part list of wiring elements

For the lengths vs. codes, see annex B



5.2.1 Serial Links

Two LSMUD9 are always ordered with one rack.

These cords are used on debug and/or installation mode only. These cords could be connected on the serial ports of the ROUZIC or MALBAN boards (ports X09 and X10 from M01 to M14) on the ATCA-V2 side and on DB9 Serial port on an external PC. This link is a 3m link only.

5.2.2 Ethernet Links

For Ethernet, Fast Ethernet (FE) and Giga Ethernet (GE) links, the only cords used are GE compliant cords (≤100m). In standard solution, the provided Ethernet cords are white JLCAT6 (≤90m).

When the JLCAT6 length is customer dependent, to limit the number of codes, only 10, 15, 20, 30 and 40m lengths will be suggested.

All these links are from the S/R accesses or Malban Switches (on ATCAV2 chassis).

The crossover cords are rarely used because many Ethernet accesses are Auto MDI-X., and by default, the straight cords will be preferred. In other case, this data will be provided. When these cords are mandatory, the ALETHC could be used, but this cable is not foreseen in the standard installation solution. The codes vs. lengths for this cord see Annex B.

Two JLCAT6 (10m) are always provided to connect eventually two Malban switches (X01 port) to the External management, in the debug or installation mode. This port is usable after disconnection of the functional link. This functional link must be re-connected in operational mode.

All the other Ethernet links are configuration dependent.

5.2.2.1 External Ethernet Link from the Switch/routers

The OS6850 S/R are mandatory in this rack, then 2x24 ports are available to connect the customer networks. All these port are Auto MDI-X, and then the Straight cords are always available. The wiring is defined for each site but by default four accesses and four links are foreseen.

In the standard installation, four links are provided to fulfill this function. Their length is given by the IDTool.

In the standard installation, these links are copper links only.

FROM TO

Rack Device Port Side Rack Device Port Side Cord

H1 GE C21 1 GE port 2 JLCAT6 (<90m) H2 GE C21 1

customer network #1 GE port 2 JLCAT6 (<90m)

H1 GE C22 1 GE port 2 JLCAT6 (<90m) SD01

H2 GE C22 1

External customer network #2

GE port 2 JLCAT6 (<90m) Table 8. GE link between OS6850 and External networks, in all config.


NRA244AA

43

AB

04

01

JSXPDUE1 X1 JBALARM AL1

03 Deflector (NDDEF1U)

D1

5

40

44

1

ATCA-V2 chassis

Mandatory

S/R (OS6850-24D) H2 S/R (OS6850-24D) H1

C01 C03 C05 C09 C11

C02 C04 C06 C10 C12

C13 C15 C17 C19 C21 C23

C14 C16 C18 C20 C22 C24

C07

C08

M01 M03

M02 M04 C50

Console Port

C49 USB Port

C01 C03 C05 C09 C11

C02 C04 C06 C10 C12

C13 C15 C17 C19 C21 C23

C14 C16 C18 C20 C22 C24

C07

C08

M01 M03

M02 M04 C50

Console Port

C49 USB Port

H2

H1

Customer Networks

Switch#2

Switch#1

Figure 3 : Example of copper GE links from S/R (front view)


5.2.3 E1 Links

5.2.3.1 Number of links vs. Configurations

The number of E1/T1 links is dependent of:

- the number of RT boards

- the type of RT board (NBRZAF or NBRZAG),

The following table gives the number of these links vs. configurations:

Configuration Number of RT

RT Board Number of E1/T1 links Location

1D, 2D 0 NBRZAF 0 - SC 2 NBRZAF 2x4 = 8 AB(M06+M14) xSC 4 NBRZAG 4x8 = 32 AB(M06-M05 + M14-M13) MC 6 NBRZAF 6x4 = 24 AB(M06 to M04 + M14 to M12)

MC for China market 6 NBRZAG 6x8 = 48 AB(M06 to M04 + M14 to M12)

1F, 2DF, 2FD 8 NBRZAF 8x4 = 32 AB(M06 to M03 + M14 to M11) or CD(M06 to M03 + M14 to M11)

1F, 2DF, 2FD for China market

2 to 10 [2] NBRZAF From 2x4=8 to 10x4=40 by step of 8

AB(M06 to M02 + M14 to M10) or CD(M06 to M02 + M14 to M10)

DC 12 NBRZAF 12x4 = 48 AB(M06 to M04 + M14 to M12) and CD(M06 to M04 + M14 to M12)

DC for China market 12 NBRZAG 12x8 = 96 AB(M06 to M04 + M14 to M12) and CD(M06 to M04 + M14 to M12)

2F 16 NBRZAF 16x4 = 64 AB(M06 to M03 + M14 to M11) and CD(M06 to M03 + M14 to M11)

2F for China Market 4 to 20 [2] NBRZAF From 4x4=16 to 20x4 =

80 by step of 16 AB(M06 to M02 + M14 to M10) and CD(M06 to M02 + M14 to M10)

Table 9. Number of E1/T1 links vs. configuration.

Then, the number of E1/T1 links is given by the number of RT stations x 4 (NBRZAF), except in the Chinese Compact configurations x8 (NBRZAG).


Three connection modes are available:

5.2.3.2 120 ohms E1 links

To connect these links to an external wiring system on a DDF, one DLANM120 cord will be ordered per PCM link (≤200m). Their number is configuration dependent (see Table 9). Their length is customer dependent.

DLANM120 Wiring system for DDF (JSIO kit or ¼ of KRACG120)

On customer DDF

Connect to ATCA-V2 chassis

Figure 4 : 120 ohms case

The JSIO is a 10 pair terminal block. One LDPETIQ kit will be ordered by JSIO kit. The KRACG120 is a kit of 4 x 8 pair terminal blocks and labels.

The Base8 kit is strongly recommended.

The following table gives the location of these links in the AB ATCA-V2 chassis, for the RT station in M03 slot, in all configuration, except Chinese compact configurations.

FROM TO Rack Device Port Side Rack Device Port Side

Cord

E1 M03/D02/X01 1 E1 port 2 in & out DLANM120 (≤200m) E1 M03/D02/X02 1 E1 port 2 in & out DLANM120 (≤200m) E1 M03/D02/X03 1 E1 port 2 in & out DLANM120 (≤200m)

SD01 AB

E1 M03/D02/X04 1

External Customer DDF

E1 port 2 in & out DLANM120 (≤200m)

Table 10 E1/T1 link from AB/M03 RT stations to External DDF

The following table gives the location of these links in the AB ATCA-V2 chassis, for the RT station in M03 slot, in the Chinese Compact configurations (xSC, MC and DC for Chinese market).


Cord

E1 M03/D02/X01 1 E1 port 2 in & out DLANM120 (≤200m) E1 M03/D02/X02 1 E1 port 2 in & out DLANM120 (≤200m) E1 M03/D02/X03 1 E1 port 2 in & out DLANM120 (≤200m) E1 M03/D02/X04 1 E1 port 2 in & out DLANM120 (≤200m) E1 M03/D01/X01 1 E1 port 2 in & out DLANM120 (≤200m) E1 M03/D01/X02 1 E1 port 2 in & out DLANM120 (≤200m) E1 M03/D01/X03 1 E1 port 2 in & out DLANM120 (≤200m)

SD01 AB

E1 M03/D01/X04 1

External Customer DDF

E1 port 2 in & out DLANM120 (≤200m)

Table 11 E1/T1 link from AB/M03 RT stations to External DDF

From these tables, the connection from each RT station could be extrapolate

In this case, will be always ordered:

• As much as DLANM120 as PCM links

• One KRACG120 kit for 16 PCM links, or one JSIO for 4 PCM links. In this last case, labels are added.


5.2.3.3 75 ohms E1 links

To connect these links to an external on the DDF, via two, three or four 120/75 ohms terminal blocks (1AB227470001), a DLANM120 cord will be ordered per PCM link (≤200m). This terminal block provides the coaxial plugs for 12 PCM links. It will be installing as near possible as the rack.

From the Terminal block, up to 96 x 1.6/5.6 plugs (1AB025460001) could be ordered (2 per PCM link).

Zero, one or two 100m drums of coaxial cable (3BW12260AA) could be also ordered. Their number is configuration and customer dependent (see Table 9). Their length is customer dependent.

1.6/5.6 plugs (1AB025460001) + coaxial cable (100m drum = 3BW12260AA)

DLANM120 120/75ohms terminals installed on the customer DDF (1AB227470001)

Connect to external device

Connect to ATCAV2 chassis


As the DLANM120 length is customer dependent, to limit the number of codes, only 30, 50 and 80m lengths will be suggested.

The wiring of the DLANM120 to the DDF is the same of the 120 ohms case. A preferentially repartition on the 75/120 ohms terminal is given by the GIS [6].

In this case, will be always ordered:

• As much as DLANM120 as PCM links

• One 120/75 ohms adaptor for 12 PCM links

Could be ordered:

• One or two 100m drum coaxial cable

• Up to 96 x 1.6/5.6 plugs.


5.2.3.4 100 ohms T1 links

To connect these links to an external wiring system on a DDF, one JLCAT6 cord will be ordered per PCM link (≤90m). Their number is configuration dependent (see Table 9). Their length is customer dependent.

JLCAT6 or specific T1 cord

Wiring system for DDF (TBD)

On customer DDF

Connect to ATCAV2 chassis


! REMARK

The IDTool can define all the kits to order in the two first cases, but it is not foreseen to define the elements to order in the last case (T1 links).

! REMARK

The E1/T1 accesses are on the front of the SS7 AMC card.


NRA244AA

43

AB

04

01



D1

5

40

44

1

ATCA-V2 chassis

Mandatory

S/R (OS6850-24D) H2 S/R (OS6850-24D) H1

Custom

er DDF

M15

M16

M20

NBRZAN NBMASW1

D01

D02

X01 X02

X03 X04

X07

X08

X09

X10

X05 X06 X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X01

X02

X01

X02

M0

D01

D02

X01 X02

X03 X04

X07

X08

X09

X10

X05 X06 X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

M02 M01 M03 M04 M05 M06 M07 M10 M09 M11 M12 M13 M14 M08 M18

M17

NBRZAF NBRZAF NBRZAN

D02

X04 X03 X02

X01 D02

X04 X03 X02

X01 D02

X04 X03 X02

X01 D02

X04 X03 X02

X01 D02

X04 X03 X02

X01 D02

X04 X03 X02

X01 D02

X04 X03 X02

X01 D02

X04 X03 X02

X01

Figure 7 : Example of E1 links to customer DDF on one couple of RT board (rear view) with one AMC

The previous figure gives an example of E1 links from AB chassis to customer DDF for one couple of RT boards. It could be extrapolated for the other boards & in the CD chassis. See GIS [6] for the wiring on the DDF.


NRA244AA

43

AB

04

01



D1

5

40

44

1

ATCA-V2 chassis

Mandatory

S/R (OS6850-24D) H2 S/R (OS6850-24D) H1

Custom

er DDF

M15

M16

M20

NBRZAN NBMASW1

D01

D02

X01 X02

X03 X04

X07

X08

X09

X10

X05 X06 X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X01

X02

X01

X02

M0

D01

D02

X01 X02

X03 X04

X07

X08

X09

X10

X05 X06 X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D01

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D02

X01 X02

X03 X04

X07

X09

X10

X05 X06

D02

X01 X02

X03 X04

X07

X09

X10

M02 M01 M03 M04 M05 M06 M07 M10 M09 M11 M12 M13 M14 M08 M18

M17

NBRZAG NBRZAG NBRZAN

D02

X04 X03 X02

X01 D02

X04 X03 X02

X01 D02

X04 X03 X02

X01 D02

X04 X03 X02

X01

D02 D02

X04 X03 X02

X01 D02 D02

X04 X03 X02

X01 D02 D02

X04 X03 X02

X01 D02 D02

X04 X03 X02

X01

Figure 8 : Example of E1 links to customer DDF on one couple of RT board (rear view) in xSC conf


5.2.4 Alarm Links

When the customer requests this function, a JLDAW cord should be used. One by JSXPDUE1 is required. In this case, the following link is:


Cord

AL1 Alarm X01 1 External Signal lamp panel TBD on the site 2 JLDAW (≤60m) SD01 AL2 Alarm X021 1 External Signal lamp panel TBD on the site 2 JLDAW (≤60m)

Table 12 Alarm link between Alarm board and external signal lamp panel

As the JLDAW length is customer dependent, to limit the number of codes, only 20 and 40m lengths will be suggested.

The Alarm board (JBALARM – AL1) is plugged on the side of the JSXPDUE1 (X1 and/or X2) PDUs on the top of the rack. A specific GIS [5] how to install this cord on the customer field. For memory this external cord will be routed mainly on the Rear Area - Left –RAL- and Rear Area – Right –RAR- (see [6]).

Figure 9 JBALARM (side view)

This board provides 4 accesses: P01 for the power, X01 for the alarm loops, X02 and X03 for the ATCA-V2 interface.

In this case: as much as JLDAW as PDU in the rack are proposed.


Figure 10 SCSI26 alarms connector pin-out


5.3 How rout the External Cords

5.3.1 E1 Cords

These cords are routed from the front of the ATCA-V2 chassis. They could be routed to the top or to the bottom of the rack, following the generic methods given in the Wiring GIS [6]. For memory these external cords will be routed mainly on the Rear Area - Left –RAL- and Rear Area – Right –RAR- (see [6]).

With the AMC boards, the wiring is more complex. The suggested solution to wire all these cables is use two accessories:

• A KMFT1 horizontal side-to-side cable tray on the top of the rack (provided with the rack. See ELS [1])

• and MPGC1 & MPGC2 horizontal front to rear cable trays (provided with the rack. See ELS [1]).

Figure 11 cabling way front view, example

5.3.2 Other Cords

The generic methods to rout these cords on the rack are given in the Wiring GIS [6], but in this product, 1. Because the number of these links from the ATCA-V2 chassis is small, no specific rules are given. 2. From the S/R, the external Ethernet links will be routed to the bottom of the rack:

- If the output is in the bottom, these links could be output directly, - If the output is in the top, these links will creep along the Rear Right Vertical Rail (RRVR) to the top of the rack (see the Wiring GIS [6]).

KMFT1

Rear of the rack1

Front of the rack1

MPGC1 & MPGC2

Cables from boards

Cables from AMC

Front uprights used as vertical

cable trays




1/ Distance between the rack and the Ethernet customer network?

According to the answers, will be defined the length of the different Ethernet cords.

2/ How many RT boards are provided?

3/ Is What is the RT type? NBRZAF or NBRZAG?

4/ Distance between the rack and the customer DDF?

5/ 75 or 120 ohms site?

According to the answer, will be defined if E1/T1 links will be delivery and the length of the different E1/T1 cords.

6/ Is Terminal blocks provided? base8 or base10?

According to the answer, will be defined if 120 ohms terminal blocks will be delivery.

7/ Is 120/75 ohms adaptor provided?

8/ Is 100m drum of coaxial cable provided? How?

9/ Is 1.6/5.6 coaxial plug provided?

According to the answer, will be defined if 75 ohms adaptor and accessories will or could be delivery.

10/ how many PDU will be connected to an external signal lamp panel?

11/ Have you need a link to a signal lamp panel?

12/ if yes, what is the distance?

According to the answers, will be defined the number and the length of a JLDAW cord to order.


6 CABLING PARTS

On the SD01 rack layout installation sites, some other elements could be useful. Two of they could be defined from this chapter:

• The wiring systems for DDF

• The cable trays

6.1 Part List

The usable kits for this function are: Kits Codes to be order function

CABLO CAF54/200/8000 1AD147470001 Cable tray LxWxD=8000x200x54 CABLO BOULON 1AD147490001 Screw and nuts for 24m of CABLO CAF54 kits

Table 13 Part list of cabling parts


For a customer site, cable trays could be ordered. Up to three CABLO CAF54 kits for one CABLO BOULON kit will be ordered.



1/ How many cable tray are you need in the customer field?

According to the answers, the different kits will be ordered.


A. CONSUMPTION:

The section of the cable and the lugs to use, depend on the voltage drop and length of the cable.

Recall for memory: Consumption in the worst case, for small configuration ≤ 30.9A and for medium configurations ≤ 46.1A (the reference values are given in the ELS document [1]).

The following table gives the maximum distance between the rack and the customer power plan (for a 1.7V loss max) for 16 and 35mm² wires:

Consumption Upstream protection

<16A ≤30.9A ≤46.1A mm² AWG

10-80A 59,3 m 30,7 m 20,6 m 16 4 10-125A 129,6 m 67,1 m 45,0 m 35 2

Table 14 Length of 16 and 35 mm² external cords

Other wire diameters are usable if the correspondent lugs are finding and checked in the JSXPDUE1. In this case, the limitations are given by the following table:

Consumption Upstream protection

<16A ≤30.9A ≤46.1A mm² AWG

10-63A 37,0 m 19,1 m 12,9 m 10 8 10-80A 59,3 m 30,7 m 20,6 m 16 4 10-100A 92,6 m 47,9 m 32,1 m 25 3 10-125A 129,6 m 67,1 m 45,0 m 35 2

Table 15 Length of all external cords

! CAUTION

CAUTION: In this case, the maximum protections values could must be compliant with EN60950-1 and EN60364-5-54 or other safety local rules, for a loss of 1.7V max in the wires on one access (0V and -48V)..

! CAUTION

CAUTION: If 35mm² Section is not installed on a power access, all evolution on the rack should be completed by a check of the suitability of the wire Section and upstream customer protection.

! CAUTION

CAUTION: The choice of a wire section is also dependent on the loss in the wire. For a Cross Section, the maximum distance between source and JSXPDUEx is given by the following function: Lmax (m) = 2400 * s (area wire in mm²) / P (power in W) for 1.7V loss between A interface (PDU) and Source.


P01

M48V-A1 M48V-A2 VRTN-A2

M48V-B1 VRTN-B1

M48V-B2 VRTN-B2

P02 P03 P04 P01 P02 P03 P04

VRTN-A1

M05

-48V 0V GND

P01

JSXPDUE1

B3 B2 B1 P

93

P9

0

P95

P87

P8

9

P84

P

85

P8

1

P51-P52

AB

CD

H2

H1

AL1

X1 B5 B4

P83

A3 A2 A1

P43

P4

0

P45

P37

P3

9

P34

P

35

P3

1

P01-P02

A5 A4

P33

10A

10A

10A

10A

75A

10A

10A

10A

10A

75A

B

A

JSXPDUE1

B3 B2 B1

P93

P9

0

P95

P87

P8

9

P84

P

85

P8

1

P51-P52

AL2

X2 B5 B4

P83

A3 A2 A1

P43

P4

0

P45

P37

P3

9

P34

P

35

P31

P01-P02

A5 A4

P33

10A

10A

10A

10A

75A

10A

10A

10A

10A

75A

B

A

Acc

ess

es t

o c

ust

om

er p

lant

Figure 12. -48V Distribution in the rack

For further details on the power wiring, see ELS [1] and MWR (link in the ELS).


B. WIRING:

Copper:

JLCAT6 code Length JLCAT6 code Length JLCAT6 code Length 1AB229830011 0m50 1AB229830006 5m 1AB229830016 40m 1AB229830001 1m 1AB229830007 10m 1AB229830010 45m 1AB229830002 1m50 1AB229830008 15m 1AB229830017 50m 1AB229830003 2m 1AB229830009 20m 1AB229830018 60m 1AB229830004 2m50 1AB229830012 25m 1AB229830019 70m 1AB229830005 3m 1AB229830014 30m 1AB229830020 80m 1AB229830022 3m50 1AB229830015 36m 1AB229830021 90m

Table 16 JLCAT6 length table

ALETHC ALETHC code Length code Length

3BW01805AD 0m15 3BW01805HA 20m 3BW01805AL 0m50 3BW01805JA 30m 3BW01805BA 1m 3BW01805JL 40m 3BW01805CA 2m 3BW01805KA 50m 3BW01805CL 2m50 3BW01805KH 60m 3BW01805DA 3m 3BW01805KR 70m 3BW01805EL 5m 3BW01805LA 80m 3BW01805GA 10m 3BW01805LF 90m 3BW01805GL 15m 3BW01805LL 100m

Table 17 ALETHC length table

JLDAW JLDAW code Length code Length

3BW13065FA 6m 3BW13065JL 40m 3BW13065GE 12m 3BW13065KA 50m 3BW13065HA 20m 3BW13065KH 60m 3BW13065JA 30m 3BW13065LA 80m

Table 18 JLDAW length table

DLANM120 DLANM120 DLANM120 DLANM120 code Length code Length code Length code Length

3BL02197FA 6m 3BL02197JA 30m 3BL02197KA 50m 3BL02197LS 110m 3BL02197GA 10m 3BL02197JC 32m 3BL02197KE 56m 3BL02197MA 120m 3BL02197GE 12m 3BL02197JE 34m 3BL02197KJ 62m 3BL02197MC 130m 3BL02197GJ 14m 3BL02197JG 36m 3BL02197KN 68m 3BL02197ME 140m 3BL02197GN 16m 3BL02197JJ 38m 3BL02197KT 74m 3BL02197MG 150m 3BL02197GT 18m 3BL02197JL 40m 3BL02197LA 80m 3BL02197MJ 160m 3BL02197HJ 24m 3BL02197JN 42m 3BL02197LD 86m 3BL02197ML 170m 3BL02197HN 26m 3BL02197JR 44m 3BL02197LG 92m 3BL02197MN 180m 3BL02197HT 28m 3BL02197JT 46m 3BL02197LK 98m 3BL02197MR 190m 3BL02197JW 48 3BL02197LN 104m 3BL02197MT 200m

Table 19 DLANM120 length table


GLOSSARY

1D Stand Alone DataBase distributed Configuration 1F Stand Alone Front End distributed Configuration 2D Dual DataBase distributed Configuration 2F Dual Front End distributed Configuration 2DF Dual distributed Configuration (1 DataBase then 1 Front End) 2FD Dual distributed Configuration (1 Front End then 1 DataBase) AC Alternating Current AMC Advanced Mezzanine Card Auto-MDIX Crossed or Straight cord could be used equally on this port Auto-sensing The Ethernet port recognizes speed of the links: 10/100 or 1000 CB Circuit Breaker CBN Common Bounding Network DB Database DC Double Compact Configuration DC Direct Current DDF Digital Distribution Frame ELS Equipment Layout Specification EMC Electro Magnetic Compatibility ETSI European Telecommunications Standards Institute FE Front End FE Fast Ethernet GE Gigabit Ethernet IBN Isolated Bounding Network IP Internet Protocol LAN Local Area Network MC Medium Compact configuration MOE Matériel d'Origine Exterieure (installation kit) NMC Network Management Center MWR Mounting and Wiring Rules OAM Operation and Maintenance OMC-CN Operation and Maintenance Center-Core Network PCM Pulse Code Modulation RRVR Rear Right Vertical Rail SC Small Compact configuration SS7 Signaling System Nº7 STM Synchronous Transfer Mode TDM Time Division Multiplex

END OF DOCUMENT

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8650 SDM Product Installation Sheet