Communications Infrastructure Standards

STANDARDS FOR THE INSTALLATION OF COMMUNICATIONS
INFRASTRUCTURE AT CHARLES STURT UNIVERSITY
Release 8.7 – February 2015
Table Of contents
1.
GENERAL ......................................................................................................................... 4
1.1
Introduction ................................................................................................................. 4
1.2
Standards ..................................................................................................................... 4
1.2.1
Introduction .......................................................................................................... 4
1.2.2
Quality Standards ................................................................................................. 4
1.2.3
IEEE Standards .................................................................................................... 5
1.2.4
Australian Standards ............................................................................................ 5
1.2.5
EIA Standards ...................................................................................................... 5
1.3 Other General Requirements........................................................................................... 6
2
1.3.1
Sealing.................................................................................................................. 6
1.3.2
Painting and corrosion ......................................................................................... 6
1.3.3
Mechanical ........................................................................................................... 6
1.3.4
Cable troughing .................................................................................................... 6
QUALITY OF MATERIALS AND WORKMANSHIP ................................................... 8
2.1
Warranty ...................................................................................................................... 8
2.2
Acceptance Testing ..................................................................................................... 8
2.3
Compliance with standards ......................................................................................... 8
2.4
TCA 1 .......................................................................................................................... 8
2.5
Guarantee of materials ................................................................................................ 8
3
DESCRIPTION OF SYSTEM ........................................................................................... 9
4
SYSTEM DETAILS ....................................................................................................... 10
4.1
Work Station Subsystem ........................................................................................... 10
4.1.1
Materials ............................................................................................................ 10
4.1.2
Installation requirements .................................................................................... 10
4.2
Horizontal Subsystem ............................................................................................... 11
4.2.1
Outlets ............................................................................................................... 11
4.2.2
Internal horizontal cabling Installation Requirements ....................................... 13
4.2.3
Communication Room ....................................................................................... 16
4.2.4
Rack Requirements ............................................................................................ 19
4.2.5
Rack Layout ....................................................................................................... 20
4.2.6
Termination requirements .................................................................................. 21
4.3
Campus Subsystem ................................................................................................... 24
4.3.1
Excavation.......................................................................................................... 24
4.3.2
Conduits/Ducts................................................................................................... 24
4.3.3
Laying ................................................................................................................ 25
4.3.4
Pits...................................................................................................................... 26
4.3.4.1
Pits - General .................................................................................................. 26
4.3.4.2
Documentation and Labelling ........................................................................ 26
4.3.5
Identification and Marking of cables in pits ...................................................... 27
4.3.6
Earthing .............................................................................................................. 27
4.3.7
Optical Fibre Cables .......................................................................................... 28
4.4
Active Equipment Installation ................................................................................... 29
4.5
Outlet Patching .......................................................................................................... 29
APPENDIX A .......................................................................................................................... 30
APPENDIX B .......................................................................................................................... 35
APPENDIX C .......................................................................................................................... 38
APPENDIX D .......................................................................................................................... 39
1.
GENERAL
1.1
Introduction
These technical requirements set out the minimum technical and functional parameters to be
met by the communication/telephone infrastructure, to meet the needs of CSU.
1.2
Standards
1.2.1 Introduction
All work covered in the Scope of Works and the Technical Requirements shall be
implemented and completed in strict compliance with regulations of statutory bodies, and the
applicable standards and codes. In general, standards and codes shall be those issued or
endorsed by the Standards Association of Australia and ACMA, at the time. Alternative
comparable standards and codes which can be demonstrated to be equivalent or of a more
demanding standard may be considered as alternatives.
Unless otherwise stated, the equipment and installation standards shall conform in every way
to the requirements of the latest issue of appropriate ACMA Specifications (or an agreed
equivalent), or to relevant Australian or International Standards if there is no ACMA
Specification.
ACMA specifications (and /or agreed equivalent) shall be complied with due to the potential
indirect connection or equipment to the Public Switched Telephone Network.
1.2.2 Quality Standards
The contractor shall be required before commencement of work to supply proof of being a
ACMA accredited Registered Cabler under the provision of the Telecommunications Cabling
Provider Rules 2000
The contractor shall be required before commencement of work to supply proof of being an
accredited Registered Panduit Certified Installer. A copy of the PCI Contractor Regristration
certificate shall be submitted in the proposal – example shown of the PCI certificate
1.2.3 IEEE Standards
The cabling materials and practices shall result in a structured
cabling system that meets or exceeds the latest edition at the time of all relevant
communications standards including but not limited to the following:
IEEE 802.3
IEEE 802.3
IEEE 802.3u
IEEE
802.3ab
CSMA/CD Access Method Physical Layer Specifications
Supp 1 Twisted Pair Media Attachment unit (MAU) and Baseband
Medium Type 10 Base T (Section 14 of IEEE 802.3)
CSMA/CD Access Method Physical Layer Specifications for 100 Mbps
Ethernet
CSMA/CD Access Method Physical Layer Specifications for 1000 Mbps
Ethernet
1.2.4 Australian Standards
The cabling materials and practices shall comply with the latest edition
at the time of all relevant Australian Cabling Standards including but not limited to the
following;
AS 3000
AS 3080
AS 3084
AS 3260
AS 3548
AS/ACIF
S009:2006
AS/ACIF
S008:2006
SAA Wiring Rules (latest edition)
Integrated communications cabling systems for commercial premises
(latest edition)
Telecommunications Installations - Telecommunications pathways and
spaces for commercial buildings (latest edition)
Safety of Information Technology Equipment including Electrical
Business
Electrical Interference - limits and methods of Measurements of
Information Technology Equipment
Installation requirements for Customer Cabling
Requirements for Customer Cabling Products
1.2.5 EIA Standards
The cabling materials and practices shall comply with the latest edition
at the time of all relevant Australian Cabling Standards including but not limited to the
following:
568AIEA/TIA 568A
EIA/TIA TSB 36
EIA/TIA TSB 40
EIA/TIA-492AAAA
Commercial Building Telecommunications Wiring Standards
Cable Specifications for Unshielded Pair Cables
Additional transmission specifications for unshielded twisted pair connecting
hardware
Detail specification for 62.5/125um cladding Class 1A multi code, graded
index, wave guide fibres.
1.3 Other General Requirements
1.3.1 Sealing
The contractor shall:
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effectively seal all openings (made or provided for) in or through building walls,
floors, etc. after cable reticulation;
effectively seal all cable duct openings above ground level, and all cable entries into
trenches in buildings to prevent the ingress of moisture and the entry of rodents;
ensure that all spare conduit and cable entries into equipment are affectively plugged
and sealed to prevent the ingress of moisture; and
ensure that all openings through roofs and external walls are made weatherproof
including the installation of flashing and/or rainhoods to prevent the entry of driving
rain, seepage, etc.
1.3.2 Painting and corrosion
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The contractor shall be responsible for corrosion protection and the painting treatment
of all brackets, supports, cable ladders, weather shields, etc. being supplied and/or
installed by him.
They shall also be responsible for the restoration to the supplier's finish (or approved
matching equivalent) on any damaged paintwork to equipment and accessories.
Other painting and corrosion protection eg. for cubicles, shall be in accordance with
the main painting specification for the particular plant area.
Where no special painting procedure is specified, for panels etc, all metal surfaces
shall be wire brushed (or equivalent) to remove all traces of rust, scale, grease, etc.
and prime coated with one coat of an approved rust inhibiting paint. The finishing
coats, including colour and type of paint, shall be advised by the CSU site
representative.
1.3.3 Mechanical
The contractor shall supply and install approved mechanical protection on all equipment and
wiring:
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which is mounted within 1400mm above an operating floor and access platform;
which is subject to damage during normal plant operation and maintenance;
on which scaffolding and planks may be used for means of access for abnormal
plant maintenance; and
as directed by the CSU site representative.
1.3.4 Cable troughing
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All troughing covers and entries shall be effectively sealed against the entry of dust
and moisture.
Troughing shall be hot dipped galvanised (HDG) of steel construction.
Troughing shall be sized so as to allow at least 30 per cent free cable space for
possible future additions.
2
QUALITY OF MATERIALS AND WORKMANSHIP
2.1
Warranty
All materials shall be new and of high quality suitable for the intended purpose. Materials
shall have a long life (minimum 20 years) under normal conditions of use in the specified
environment.
The contractor will furbish details of any manufacturer certified warranty periods, otherwise
the contractor shall be deemed responsible for the repair of all cable faults internal and
external at no cost to Charles Sturt University in relation to this project for a period twelve
months from the date of completion.
All horizontal cable installations will come with a 25 year Panduit Certified Warranty
2.2
Acceptance Testing
At the completion of all cabling installations, all network cabling is to be scanned with a
Category 6 Scanner. The performance criteria will comply with the latest EIA/TIA 568
Standards including Wire Map/Next/Attenuation, length etc.
Results in an electronic form are to be supplied to the CSU representative.
2.3
Compliance with standards
In addition to anything specified herein, all works and materials shall comply with all
relevant ACMA, Australian, and International Standards. A list of some of the main
applicable standards is contained in Section 1.2 herein. The contractor shall provide all
ACMA/Telstra approval documents.
2.4
TCA 1
In accordance with the ACMA, a completed TCA1 form shall be provided to the CSU
representative at the completion of all new cabling installations as certification that the work
complies with the Wiring Rules standard (AS/ACIF S009). A copy of the form can be found
at the below URL:
http://www.acma.gov.au/webwr/_assets/main/lib310111/t019-telecomms_cabling_advicetca1.pdf
2.5
Guarantee of materials
The contractor shall guarantee the complete installation against faulty materials and failure of
materials (except where due to misuse or maltreatment after installation) for a warranty
period of at least 25 years. The contractor shall supply any manufacturer guarantee(s) against
faulty material and failure of materials. During the guarantee period, the contractor shall
replace with new equipment which fail under normal use, or do not meet the manufacturer
published performance figures at no cost to the University.
3
DESCRIPTION OF SYSTEM
The network infrastructure shall comprise of the following prime components of a structured
Cabling System..
Work Station System
Horizontal Subsystem
Building Backbone Subsystem
Campus Subsystem
The connection between the wall outlet and the
user device
The connection between the Communications
room and workstation outlets. It consists of the
transmission media, the associated terminations
of this media and the housings for the cable and
terminations, eg faceplates and patch panels,
cable tray etc
The connection between communications rooms
within the same building. It consists of the
transmission media, the associated terminations
of this media and the housings for the cable and
terminations, eg faceplates and patch panels,
cable tray, fiberoptic trays etc
This system provides connectivity between
buildings. It consists of the transmission media,
the associated terminations of this media and the
housings for the cable and terminations. It
includes entry to buildings, external conduit and
pit requirements.
4
SYSTEM DETAILS
4.1
Work Station Subsystem
4.1.1 Materials
 All fly leads shall be factory-terminated category 6 UTP with RJ45
connectors.
 Unless otherwise specified these will be provided by DIT and charged back to
the project.
 In general these leads should be no longer than 5m
4.1.2 Installation requirements
 Leads shall not be run along any part of the floor where they pose a safety
hazard to people or equipment.
 No labelling of fly leads is required.
4.2
Horizontal Subsystem
All cabling to non WAP outlets shall be Panduit UTP Category 6 LSZH (part number
PUL6004BUY) unless specifically specified as part of the project and shall not
exceed 90 metres from end to end. A standard data outlet location is to have ONE
cable supplied unless otherwise specified.
eg
All cabling to WAP (Wireless Access point) outlets shall be Panduit UTP Category
6A LSZH part number (PUL6A04BU-CEG) unless specifically specified as part of
the project and shall not exceed 90 metres from end to end. A standard data outlet to
a WAP is to have TWO cables supplied unless otherwise specified.
eg
All UTP outlets shall be electrically and mechanically matched to the Category of
UTP cables to which it connects.
4.2.1
Outlets
4.2.1.1 Materials
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Outlets for NON WAPs (Wireless Access Points) shall be RJ45 category 6, Panduit
Mini-Com Jack module. Part number Mini-Com (CJ688TG**) or better, unless
specifically specified as part of the project.
Outlets for WAPs (wireless Access Points) shall be RJ45 category 6A, Panduit MiniCom Jack module. Part number Mini-Com (CJ6X88TG**) or better, unless
specifically specified as part of the project.
The jack colour should be one consistent with the faceplate colour.
All flush mounting outlets shall be mounted on Clipsal faceplates suitable for flush
mounting in standard wall boxes, skirting trunking, ducts in modular partition systems
and similar. Panduit Clipsal adaptor bezel required to mount Mini-Com Jack module
into Clipsal faceplates (part number CAFPA**-X)
Sockets/connectors and mounting hardware to be used shall be submitted as a sample
for approval by the CSU site representative prior to supply.
Mounting shall be arranged to minimise the risk of damage during removal and
replacement of skirting trunking covers or other associated hardware.
Surface mounted blocks will be Panduit (side exit) blocks of an appropriate colour to
blend with the chosen decor or as per CSU site representative’s requirement.
RJ45 Sockets and small children - RJ 45 Sockets frequented by small children (eg
Pre-school, Child Care Centre) shall be installed out of their reach or provided with
Mechanical protection to prevent finger access. Panduit shutter jacks are acceptable.
(part number CJD688TG**)
** - replace ** with colour of Jack module required – BL Black, WH White, BU Blue,
GR Green etc
4.2.1.2 Installation Requirements
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All outlets to be terminated to S 568A colour code.
Outlets shall be firmly attached to the structure. Fixing to loose skirting trunking
covers is not generally acceptable, and requires prior written approval from the CSU
site representative.
Outlets shall be mounted so that the contacts are not at the bottom - to reduce the risk
of contamination of contacts with grit and dust.
Faceplates shall be available in colours which will blend with the chosen decor, or as
per the CSU site representative requirements.
Outlets shall not be mounted where there is a risk of mechanical damage.
If not otherwise specified for this particular job, Outlets shall be mounted at a height
consistent with existing outlets in that area or where no outlets currently exist outlets
shall be mounted at the following standard heights in order of priority as specified:
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Skirting duct
300 mm above floor level
1200 mm above floor level
4.2.1.3 Outlet Identification
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Each Faceplate shall be fitted with a quality indelible label to the approval of the CSU
site representative.
The label shall clearly identify the communications room letter (“A”, “B”, etc) to
which this outlet is terminated at the other end and the outlet number.
The letter is to identify the Comms room not the patch panel, so only ONE letter is to
be used per comms room with a sequential number scheme.
Example; the identification A127 and A128 would refer to sockets 127 and 128 which
would terminate in a rack in Comms room “A” at sockets 127 and 128.
Labels for WAPs (wireless Access Points) are to use a larger font. They are to be
readable from floor level.
4.2.2 Internal horizontal cabling Installation Requirements
4.2.2.1 General
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Each outlet plate (for non WAP installations) shall be cabled with a quantity of ONE
4 pair UTP cable from the designated Distribution Point located in a communications
Closet/IDF Room.
Each outlet plate (WAP installations) shall be cabled with a quantity of TWO 4 pair
UTP cable from the designated Distribution Point located in a communications
Closet/IDF Room.
Cable shall not be installed under residual tension or pressure except as required to
secure to cable tray.
All cable runs shall be continuous between the termination points specified. No
joints, splices, junctions, or similar are permitted, except for the specified
terminations, jumpering, and/or patching at the designated Distribution Point.
In addition to any installation requirements specified in the Specifications referenced
herein, all UTP cable installed under this specification shall be installed so as to
maintain the separation distances from power cables specifies in Australian Standard
AS 3080m Table 1. Cable pathways which do not meet this criteria shall not be used.
Separation of cable to comply with all appropriate ACMA standards.
All cables shall be installed in accordance with the minimum bending radius
specified by the manufacturer.
All cables installed shall be supported. Internal cables shall be securely cable tied to a
dedicated catenary wire support system consisting of seven strand galvanised or zinc
coated steel wire.
Where mechanical protection is required, cables shall be installed in conduit.
All mechanical protection and cable supports shall be free of burrs and sharp edges.
Additional bushing, sleeving, etc. shall be provided as required to ensure adequate
bending radius and to prevent cable damage.
Where cables are run through steel noggings or studs, appropriate grommeting shall
be provided to protect the cables. Cable entry into a wall cavity shall be directly
above or below the physical location of the information outlet location. The cable
entry hole into the cavity should be sufficient to permit free running of all cables and
a minimum of 20% spare capacity for additional cable.
Where three or more cables are grouped together on structures, they shall be laid on
cable ladders. Single and double runs may (with the CSU site representative
approval) be affixed direct to structural members. Single cable runs may also be
installed in conduit for support and/or protection.
Cable entry into a power pole, riser column, duct or cavity wall shall be preceded by a
one metre service loop of approximately 300mm in diameter to allow for minor
moves/changes prior to entry into the pole, column, duct.
Where cables exit from skirting ducts and enter into workstation furniture, flexible
conduit shall be used to reticulate cables and to afford protection.
Cables reticulated via workstation duct shall be run via the appropriate duct and tied
at intervals no greater than 1000mm.
4.2.2.2 Requirements for AV installations
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Installations in Audio/Video lecterns and cabinets will require more outlets. The
exact number should be confirmed by referring to the CSU AV specification for the
installation.
In general however 6 to 8 outlets will be required in such installations.
The outlets should be installed in a position that enables easy access even after the
AV equipment has been installed, eg via side or rear panel.
4.2.2.3 Cable ladders
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Supporting brackets shall be spaced so that the loaded cable ladder deflection does no
exceed 6mm, and generally at a maximum of 3000mm centres for heavy duty cable
ladder.
All steelwork, support brackets, mounting plates, etc. shall be protected.
All edges of, and openings in, the cable ladder shall be protected in an approved
manner to prevent cable damage.
Cable ladders shall be of hot dipped galvanised constructed with steel bolts, nuts,
washers and fittings.
4.2.2.4 In ceiling support
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In general, the in-ceiling cable support structure shall comprise of catenary wire
suitably anchored and supported to the ceiling slab and tensioned by way of
turnbuckles. Catenary wire shall be of seven stranded gal-steel wire. Cabling shall be
secured to catenary systems with Velcro ties at min 300mm centres.
Where catenary wire is impractical, "unicorn saddle" type support structure may be
used at appropriate intervals.
Where the cable loading is excessive for catenary wire or saddle type structures, a
cable tray should be used, mounted to be compliant with ACMA Regulatory
Specifications.
Where any cables traverse electrical power, consideration shall be given to the
appropriate ACMA regulatory requirements and adequate separation be provided.
Where cables traverse a plaster ceiling space, it may be appropriate to use a conduit
either tied to a catenary wire, or suitably saddled to the ceiling slab. A draw wire
should be let in position through the conduit for future cabling additions.
4.2.2.5 In-Floor
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In general, the under-floor cable support structure shall comprise of catenary wire
suitably anchored to the floor and supported by either the fixed raised floor pedestals
or by dedicated stand-offs and tensioned by way of turnbuckle. Catenary wire shall
be seven strand gal-steel wire.
Where catenary wire is impractical, conduit may be used, appropriately saddled.
Consideration should be given to the upgrade requirements of the customer before
using conduit.
Where the cable loading is excessive for catenary wire, cable tray/rack should be
used, mounted and earthed to be compliant with ACMA Regulatory Specifications.
Where any cables traverse electrical power, consideration should be give to the
appropriate ACMA regulatory requirements, and the mandatory segregation
maintained.
All copper circuits shall have a maximum of two points of administration. These may
be on the main cross-connect or at the Telecommunications Closet.
Cable in Suspended (False) Ceilings - Laying cable on top of ceiling tiles or tying
them to hanger rods is expressly prohibited.
4.2.3 Communication Room
4.2.3.1 General
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All buildings shall have at least one communications room provided. The location to
be decided at design time after consultation with the relevant member of the Division
of Information Technology. The specifications laid out below will be strictly adhered
to and any variation from this specification must be authorised by the Division of
Information Technology in writing.
There will be one double 10A and TWO separate 15A GPOs installed, each on its
own circuit (3 Circuits in total)
A 18 Watt fluorescent light or better shall be installed.
The doors will be fitted with ventilation grills in the lower half of the door.
Thermostatically controlled Mechanical ventilation will need to be installed to remove
heat from the cupboard.
A duct system with a minimum diameter of 100 mm is to extend from the cabinet to
the service corridor outside the building with no bends exceeding 60 degrees.
All data and fibre optic cables entering the comms rack are to do so from the top of
the rack.
Fire Pillows shall be placed into all conduits exiting the communication cupboard.
If it is the intention to collocate additional equipment within the coms room additional
room may need to be allocated for this equipment.
4.2.3.2 Building Refurbishments
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It is a requirement that any outlets removed during building refurbishment will result
in the cable for those outlets being removed entirely including from the rack patch
panel.
Removal of old cables may require the consolidation of remaining patch panel ports
to optimise remaining rack space.
Consultation with an authorised member of DIT must be carried out to determine final
rack layout or if a new rack is required.
4.2.3.3 Size
1 Rack Installation
 Minimum of 3000 mm Wide, 2000 mm deep extending from floor to standard ceiling
height, with double doors (lockable) – Doorway is to have a clearance of at least
2170mm to allow the rack which is 2159mm high to be able to enter the room
 The rack is to have a minimum clearance of 400mm from the Left wall and 50mm
from the rear of the rack to the rear wall.
 See below diagram for required orientation.
3000mm
1070mm
2000mm
50mm
400mm
800mm
1500mm
2 Rack Installation
 For installations of 2 Racks. Be it 2 Communications Racks or 1 Communications
Rack and another for another purpose eg AV
 Minimum of 3000 mm Wide, 2000 mm deep extending from floor to standard ceiling
height, with double doors (lockable) – Doorway is to have a clearance of at least
2170mm to allow the rack which is 2159mm high to be able to enter the room
 Rack 1 is to have a minimum clearance of 400mm from the Left wall and 50mm from
the rear of the rack to the rear wall.
 Rack 1 is to be the first Rack to be used for Communications equipment
 Rack 2 is to have a minimum clearance of 400mm from the right wall and 50mm from
the rear of the rack to the rear wall.
 See below diagram for required orientation.
3000mm
Rack1
800mm
1070mm
400mm
50mm
1070mm
2000mm
50mm
Rack 2
400mm
800mm
1500mm
For student cottages and smaller installations a small closet size may be acceptable
provided that written authorisation is obtained from authorised staff of the Division of
Information Technology prior to tendering.
4.2.4 Rack Requirements
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A DIT representative should be consulted on the rack to be installed prior to
installation commencing.
Unless otherwise specified the following Panduit Rack equipment is to be used for all
communications rack deployments
Rack is to be earthed appropriately.
Part
Panduit
N8519BQ
Panduit
SN85SDB
Panduit
N51SPS
Rack
Technologies
9004-15AMP
Description
N-Type Series, 800mm(W), 45RU, 1070mm(D), No Side Panels,
Black, No Doors, Cage Nut Rails
Qty
1
Split front doors work on both the N and S style cabinets. Rear doors
are not required as rack back will be against the wall.
1
45 RU 1070mm Depth Net-Access™ N-Type Cabinet Side Panel.
2
Rack Technologies 10 Way Vertical Power Rail –or similar
One to be installed on each side of the rack
2
4.2.5 Rack Layout
Generic rack layout with vertical cable management
Unless otherwise specified this is the rack layout to be used for ALL installations
4.2.6 Termination requirements
4.2.6.1 Telephony Trunk Cables
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All new Communications Cabinets shall have a Telephony trunk cable from
MDF/IDF to patch panel provided.
All cable will be ACMA approved.
The telephony Trunk will be a minimum of a 10 pair cable, a larger cable may be
required dependant on building requirements. The size of the trunk cable to be
confirmed by a staff member from the Division of Information Technology prior to
installation.
All Telephony trunk cables shall be terminated onto unloaded Category 6 RJ45
Panduit ANGLED patch panel (part number UICMPPA24BLY).
The Panduit RJ45 Mini-Com Jack modules used in the termination shall be GREEN
in colour (part number CJ688TGGR).
4.2.6.2 Data Cables
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All horizontal cable runs shall be terminated onto an unloaded Category 6 RJ45
Panduit ANGLED patch panel (part number UICMPPA24BLY)..
The Panduit RJ45 Mini- Com Jack modules used in the termination of NON WAP
(Wireless Access Point) cable runs shall be CAT 6 and BLACK in colour
(CJ688TGBL).
The Panduit RJ45 Mini- Com Jack modules used in the termination of WAP
(Wireless Access Point) cable runs shall be CAT 6A and BLACK in colour
(CJ6X88TGBL).
The sheath of these cables is not to be stripped to a length exceeding 13 mm for
termination purposes.
A Minimum length of 3 metres of data cable shall be left wound and secured in the
side of the communications rack before termination onto patch panels.
4.2.6.3 Fibre optic Cables
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All cable is to be Single Mode of type OS2 (ITU G.652d), Optimised for 1310-nm
wavelength. Cable is to be Prysmian External Underground Loosetube Optical Cable
part numbers as shown below
5422528 F12SLTN
12 core
5422559 F24SLTN
24 core
5422573 F48SLTN
48 core
5424126 F96SLTN
96 core
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Unless otherwise specified ALL optic cable will 12 core with only 6 cores to be
terminated.
All cable to be Loose Tube, Waterproof (Gel Filled)
All cable is to contain a Solid Strength Member through centre of cable
All cable is to be outside grade. Riser grade cable is NOT to be used.
Optical fibre cables shall be clearly marked as such to distinguish them from other
cables. Such marking may include tracer marking on the sheath and/or distinctive
sheath colours.
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Installations into older racks without vertical cable management
Total Cores to be
installed
Panduit 19” rack mount Fibre Tray
Part number to use
Panduit Patch panel to be used on
front of tray
Up to 48
49 to 96
FMT1
FMT2
UICMPP24BLY
UICMPP24BLY * 2
Installations in racks with vertical cable management
Total Cores to be
installed
Panduit 19” rack mount Fibre Tray
Part number to use
Panduit Patch panel to be used on
front of tray
Up to 48
49 to 96
FMT1A
FMT2A
UICMPPA24BLY
UICMPPA24BLY * 2
All terminations to use the following
o Splicing is to be done in a Panduit Fibre optic splice module part number
FOSMF. This will hold 24 fusion splices, multiples will be required for core
counts above 24.
o Fibre Adapter Mini-com LC Jacks to be used are Panduit part no.
CMDSLCZBU (Blue adapter with Blue Module)
o All cable terminations shall use Pre terminated & Polished fusion spliced LC
pigtails. Panduit Part Number F9B10-NM1Y.
All unterminated fibre cores are to be allocated a port on the patch panel and a
Panduit blanking module (Blue) part number CMBBU (comes in a 100 pack
CMBBU-C) is to be installed for each unterminated core. Eg a standard 12 core
installation will only have 6 cores terminated. The 6 cores will take up 3 patch panel
ports, the remaining 6 cores are to be allocated the next 3 patch panel ports where the
3 blue blanking modules are to be installed.
All remaining empty patch panel ports are to have a Panduit blanking module (Black)
part number CMBBL (comes in a various packs eg CMBBL-X) installed. Eg a
standard 12 core installation will occupy 6 patch panel ports (3 with terminated fibre
and 3 with Blue blanking modules). The remaining 18 ports would be filled with
Black blanking modules.
A minimum length of 3 metres of sheathed optic fibre shall be left wound in the
communication cupboard before stripping of jacket for termination into enclosure.
Each new optic fibre cable installation has a set of documentation requirements.
These are outlined in Appendix D
4.2.7 Labelling
4.2.7.1 Telephony Trunk Cables
 Cable terminations at the patch panel will be labelled sequentially starting from 1
 If the far end of the cable terminates on an MDF/IDF Frame the Patch panel will have
a label indicating the building and frame position at the far end on which the cable is
terminated. Eg Bld 4, A50 – 100.
 The Patch Panel will also have a label identifying the cable. This will be the same
label as used to identify the cable in each pit along the cable run.
o See Identification and Marking of cables in pits in section 4.3.5
4.2.7.2 Data Cables
 Cable terminations at the patch panel will be labelled with a unique letter identifying
the comms room and a sequential number starting from 1. These will correspond to
labels used to identify the outlets. Eg if the corresponding outlet is labelled A124
then the port in the rack in communications room A shall be labelled 124.
4.2.7.3 Fiberoptic Cables
 The fibre tray is to have a label clearly indicating near and far end building numbers,
communications rooms and the size of cable. This will be the same label as used to
identify the cable in each pit along the cable run.
o See Identification and Marking of cables in pits in section 4.3.5
 Each termination is to be labelled, starting from 1 for each cable run and labels are to
correspond at each end of the cable. If there are multiple cables connecting the same
buildings and racks continue labelling each termination from the last number used for
the already installed fibre. Eg if there is already a 12 core cable installed between
building 3 and building 4 and a new 12 core cable is being installed, the new 12 core
installation labelling will start from 13.
4.3
Campus Subsystem
Installation Requirements
4.3.1 Excavation







The contractor shall be responsible for all excavation, cable protection, backfill,
surface restoration and the installation of cable markers.
All excavation and backfill works shall be carried out with the use of hand tools. The
use of mechanical or power assisted tools shall be permitted only when specifically
stated in the contract documents or authorised in writing by the CSU site
representative.
Before proceeding with any excavation work, the contractor shall ascertain details of
any underground services in the area.
Where excavations are required near footings, foundations, concrete floors etc, the
contractor shall ensure that the earthworks does not interfere with these items and
backfill is well consolidated.
Unless otherwise agreed by the CSU site representative, the contractor shall arrange
the installation so that all trenches are excavated and backfilled on the same day.
The contractor shall ensure that the specified safety barriers, work authorities,
warning notices, shoring, etc. are attended to.
On completion of excavations, contractors shall supply to the University, diagrams
indicating the actual locations of the excavation works. Measurements to fixed points
shall be included so as to clearly identify the precise conduit or cable locations. This
shall include GPS location points
Under boring requires the supply of bore plans.
4.3.2 Conduits/Ducts






Intermediate wiring joints are not permitted in conduit or wiring ducts ,unless directed
by a CSU Representative..
Inspection type tees, elbows, bands, etc. are permitted with approval by the CSU site
representative.
All conduit ends shall be reamed or filed free of burrs and conduit threads entering
junction boxes or fittings shall be at least 10mm long.
Conduit shall be used as mechanical protection where required, and shall be left open
at each end.
Draw wires shall be provided in all conduits after installation.
Underground conduit must be white or have white strip and marked
COMMUNICATIONS.
4.3.3 Laying













Cables under roadways shall be laid in ducts. These ducts shall project approximately
300mm beyond the kerb lines and unless specified otherwise, shall be supplied and
installed by the contractor. Ducts shall be white, heavy duty, rigid UPVC conduit in
accordance with AS 2053, or heavy duty, fibrous cement conduit in accordance with
AS 2053.
All conduits shall be laid at a minimum cover depth of 350mm, with minimum cover
of 75mm round the conduit. The trench shall be backfilled and consolidated to
finished ground level.
A white detectable marker tape (trace wire imbedded) complying with AS 2648, part
1 shall be laid continuously along the route of the cable approximately 100mm above
conduits. . The type of white marker tape shall have a metal tracer wire within.
Unless specified elsewhere, a communications pit shall be installed approximately
every forty (40) metres of the conduit run.
For direct Buried runs - Marker poles, consisting of yellow power coated 1 ½ inch
galvanised steel poles with caps, are to be used to mark conduit runs. The marker
poles are to be buried 500mm deep, directly beside the conduit, and should extend
approximately 1000 mm above ground surface. Poles should be used to indicate
changes in direction in the conduit, or indicate conduit location between pits further
than 100 meters apart. Straight runs of conduit, no further than 100 meters between
two pits do not require marker poles.
Cable shall not be installed under residual tension or pressure except as required to
secure to cable tray.
All cable runs shall be continuous between the termination points specified. No
joints, splices, junctions, or similar are permitted, except for the specified
terminations, jumpering, and/or patching at the designated TDS Distribution Frames.
In addition to any installation requirements specified in the Specifications referenced
herein, all UTP cable installed under this specification shall be installed so as to
maintain the separation distances from power cables specified in Australian Standard
AS 3080, Table 1, Cable pathways which do not meet this criteria, shall not be used.
All cables shall be installed in accordance with the minimum bending radius specified
by the manufacturer.
All cables installed must be supported. External cables shall be securely tied to cable
tray at no more than 300mm separation. Multicore cables shall be indoor grade and
shall be supported along the entire length.
Where mechanical protection is required, cable shall be installed in conduit.
All mechanical protection and cable supports shall be free of burrs and sharp edges.
Additional bushing, sleeving, etc. shall be provided as required to ensure adequate
bending radius and to prevent cable damage.
Where three or more cables are grouped together on structures, they shall be laid on
cable ladders. Single and double runs may (with the superintendents approval) be
affixed direct to structural members. Single cable runs may also be installed in
conduit for support and/or protection.
4.3.4 Pits
4.3.4.1 Pits - General





In ground pit should be of suitable construction for that locality (Plastic pits are
unsuitable at Thurgoona) with an allowance to cater for dual 100mm conduits from 2
sides only (ie, a total of four 100mm conduits).
The pit should have a suitable cover of metal construction and be clearly labelled
“COMMUNICATIONS”
All Conduit entry points into a pit need to be fitted with pit bushes.
Entry is to be from end of pits only.
Use only large radius bends.
4.3.4.2 Documentation and Labelling
4.3.4.2.1 New Pits
 As part of any new pit installation it is a CSU requirement that the installation be fully
documented
 (See Appendix C for Documentation Requirements)
4.3.4.2.1 Existing Pits
 When working on installations which go through existing pit infrastructure, it is a
CSU requirement that the existing pit documentation be updated. Eg new conduit
added into pit.
 If the pit is currently undocumented (ie No label and Number) then it is the
responsibility of the contractor to document the existing pit as part of the undertaken
works.

(See Appendix C for Documentation Requirements)
4.3.5 Identification and Marking of cables in pits
4.3.5.1 Phone Cable
 At each pit in a cable run a plastic cable label shall be cable tied to the cable. It will
identify the building number of the buildings at each end of the cable and the pairs in
the cable as well as the cable type (P = Phone)
o Eg a phone cable running between building 229 Communications Room ‘a’
and building 227 Communications Room ‘a’, labels would be “227a –
229a(P1-50)”
 In instances where a cable already exists between buildings, the new cable will
identify the pairs starting from one number higher than the last pair number used in
the existing cable.
o Eg and additional 50 pair cable is added between building 229 comms room
‘a’ and building 227 comms room ‘a’, labels would be “227a – 229a(P51100)”
 Labels should start with the final building and end with the fibre distribution point the
cable has been run to. In the above example building 229 is the fibre distribution
point and so it appears as the second building in the label
4.3.5.2 Optic Fibre Cable
 At each pit in a cable run a plastic cable label shall be cable tied to the cable. It will
identify the building number of the buildings at each end of the cable and the cores in
the cable as well as the cable type (SMF = Single Mode Fibre optic)
o Eg an optic fibre cable running between building 229 Communications Room
‘a’ and building 227 Communications Room ‘a’ labels would be “227a –
229a(SMF1-12)”.
 In instances where a cable already exists between buildings, the new cable will
identify the cores starting from one number higher than the last core number used in
the existing cable.
o Eg and additional 12 core cable is added between building 229 comms room
“a” and building 227 comms room “a”, labels would be “227a – 229a(SMF13
- 24)”
 Labels should start with the final building and end with the fibre distribution point the
cable has been run to. In the above example building 229 is the fibre distribution
point and so it appears as the second building in the label and 227 as the first.
4.3.6 Earthing




All distribution frames, cable trays and catenary wires shall be connected to the
building protective earth as specified for each case in ACMA TS 009.
Sizing of earthing conductors shall be as per ACMA TS 009
All earthing of Communication/Telephone cables will comply with ACMA earthing
requirements.
Cable strength members and sheaths, shall be connected to the building protection
earth with, ACMA - TS 009 and AS000.
4.3.7 Optical Fibre Cables

See requirements under Communications room - Section 4.2.6.3
4.4
Active Equipment Installation
4.4.1 Initial switch installation (For Building Commissioning)





The contractor will be required to install ALL switches for use in building
commissioning into the communications rack
The switches shall be installed in accordance with the installation instructions in
Appendix A
The switches will be supplied and configured by a representative of the Division of
Information technology
Switch installation is only to commence upon the communications rack and room fit
out completion (Flooring down, dust free, cable tests completed)
Photos of the communications Rack are to be provided before and after installation to
a representative of the Division of Information Technology
4.4.2 Wireless Access Point installation




4.5
The contractor will be required to install all wireless access points (Radios) into the
building.
The Wireless Access Points shall be installed in accordance with the installation
instructions in Appendix B
The Wireless Access Points will be supplied and configured by a representative of the
Division of Information technology
To prevent the possibility of damage, Wireless Access Point installations are only to
commence upon the installation area being suitably finished (Painting complete,
clean)
Outlet Patching
4.5.1 Patching of newly installed outlets into active switching equipment

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

The contractor will be required to patch outlets in the communications rack to active
switching equipment based on a list supplied by the project in conjunction with DIT
The contractor is to supply the patch cables
The patch cables are to be of an appropriate length to facilitate tidy cable management
practices.
The patch cables are to be of correct specification to match the outlet they are being
patched into and certified for use at those speeds or greater.
Cables are to be patched in a neat and tidy manner utilising available cable
management.
All field outlets NOT patched to active equipment are to have Panduit port blockers
part number (PSL-DCJB) red in colour, installed into them (This is to be done on the
user outlet end not in the communications rack patch panel). Note the port blockers
are available in bulk packs of 100 part number (PSL-DCJB-C)
Cable patching will be inspected as part of the final rack audit to ensure quality of
work
APPENDIX A
Switch installation Instructions
Parts List – (Supplied by DIT representative)
Part
CISCO switch – These switches will have the mounting brackets already
attached
Power cord for the CISCO switches
0.5m Switch stacking cables
0.5 Stack power cable
Single Mode SFP optical module
2m Single mode SC – LC fibre Patch cable
Quantity
Varies
1 per switch
1 per switch
1 per switch
1
1
Switch installation
Observe these general precautions:


Be careful lifting the switch as it is heavy
Installation may require 2 persons during the switch mounting process
Step 1
Step 2
Step 3
Step 4
Step 5
Fit 4 cage nuts to the rack to support a 1RU device
Attach an ESD-preventive wrist strap to your wrist and to a bare metal surface
Lift switch into mounting position
Screw switch into rack as shown below
Install 1RU Panduit cable management (CMPHF1 with the cover CMPH1C) above
the first switch and under every switch including the first
Step 6
Repeat steps 1 to 6 for each switch to be installed
Switch stack cables
Once all switches have been installed the stacking cables need to be installed at the rear of
each switch
Step 1 Remove the dust covers from the StackWise cables and StackWise ports, and store
them for future use.
Step 2 Connect the cable to the StackWise port on the switch rear panel. Align the connector
and connect the StackWisecable to the StackWise port on the switch rear panel and
finger-tighten the screws (clockwise direction). Make
sure the Cisco logo is on the top side of the connector as shown in the figure.
Step 3 Connect the other end of the cable to the port on the other switch and finger-tighten
the screws. Avoid over tightening the screws
Switch 1 links to switch 2, switch 2 to switch 3 etc. The last switch is to link back to switch 1
See diagram below for correction connection ports.
1 Cisco log
2 Connector screw
3 Connector screw
Connecting Stack power cables
Step 1 Remove the dust covers from the StackPower cable connectors.
Step 2 Connect the end of the cable with a green band to either StackPower port on the first
switch. Align the connector correctly, and insert it into a StackPower port on the
switch rear panel.
Step 3 Connect the end of the cable with the yellow band to another Catalyst 3850 switch (to
configure StackPower power sharing).
Step 4 Hand-tighten the captive screws to secure the StackPower cable connectors in place.
Switch 1 links to switch 2, switch 2 to switch 3 etc.
SFP Optic Module Installation
SFP to be installed in the first switch
Observe these general precautions:
Warning Class 1 laser product.



Step 1
Step 2
Step 3
Step 4
Step 5
Do not remove the dust plugs from the SFP modules or the rubber caps from the fibreoptic cable until you are ready to connect the cable. The plugs and caps protect the
module ports and cables from contamination and ambient light.
Removing and installing an SFP module can shorten its useful life. Do not remove
and insert any SFP module more often than necessary.
To prevent ESD damage, follow your normal board and component handling
procedures when connecting cables to the switch and other devices.
Attach an ESD-preventive wrist strap to your wrist and to a bare metal surface
Find the send (TX) and receive (RX) markings that identify the top side of the SFP
module.
On some SFP modules, the send and receive (TX and RX) markings might
be replaced by arrows that show the direction of the connection, either send
or receive (TX or RX).
If the SFP module has a bale-clasp latch, move it to the open, unlocked position.
Align the module in front of the slot opening (position G1), and push until you feel
the connector snap into place as shown below
If the module has a bale-clasp latch, close it to lock the SFP module in place
Power the switches
Step 1
Step 2
Step 3
Connect the power cord to the switchs ensuring it has been fed through the cable
minder
Plug the power cords into the power rail
Wait for the switches to boot (6-7 min)
Optical Patch Cable Installation
Observe these general precautions:
Warning Class 1 laser product.



Do not remove the dust plugs from the caps from the fibre-optic cable until you are
ready to connect the cable. The caps protect the module ports and cables from
contamination and ambient light.
To prevent ESD damage, follow your normal board and component handling
procedures when connecting cables to the switch and other devices.
Do not look directly into the end of a cable attached to either the SFP module or the
fibre patch tray
Step 1
Step 2
Step 3
Step 4
Step 5
Step 6
Step 7
Step 8
Step 9
Step 10
Remove the caps from the SC end of the fibre patch cable.
Remove the caps from the appropriate ports on the fibre patch tray, for new
installations these will most likely be ports 1 and 2
Connect the fibre patch cable to the appropriate fibre patch tray ports
Run the patch cable through the cable management system appropriately
Remove the rubber plugs from the SFP fibre module
Remove the caps from the LC end of the fibre patch cable and connect it to the
SFP module
Connect the fibre patch cable to the SFP module
Retain all caps and plugs, these are to be left in a small ziplock bag
The bag is to be cable tied to the left mounting rail, just beneath the fibre tray
Confirm the green light is lit for fibre slot G1. If not then reverse the patch cable
connectors on the SC end. If you still fail to get connectivity please contact a
representative from the Division of Information Technology.
APPENDIX B
Wireless Access Point installation Instructions
Mounting the Access Point
There are 3 mounting options for the AP7131 and AP7131N access points used at CSU
Option 1
Option 2
Wall mounting
Ceiling mount under a suspended T-Bar
Choose one of the mounting options based on the data point location and the instructions
given when supplied the access points
Option 1 Integrated Antenna Model Wall Mount Instructions
Wall mounting requires hanging the AP6522 along its width or length using the two slots on
the bottom of the unit.
The AP6522 can be mounted on to any plaster, wood, or cement wall surface using customer
supplied screw hardware (M3.5 x 0.6 x 20 mm- or equivalent).
Wall Mount Hardware
• Two wide-shoulder Phillips pan head self-tapping screws (customer supplied)
• Two wall anchors (customer supplied)
• Security cable (optional)
NOTE The following screws are recommended: (ANSI Standard) #6-18 X
0.875in. Type A or AB Self-Tapping Screw, or (ANSI Standard Metric)
M3.5 X 0.6 X 20mm Type D Self-Tapping Screw.
Wall Mount Procedure
1. Orient the case on the wall by its width or length.
CAUTION To ensure proper operation of an AP6522 access point, ensure it is
mounted in the correct orientation as shown above.
2. Mark two points (for drill holes) 4.08 inches (103.7 mm) apart on a horizontal line.
3. At each point, drill a hole in the wall, insert an anchor, screw into the anchor the wall
mounting screw and stop when there is 1mm between the screw head and the wall.
NOTE When pre-drilling a hole the recommended hole size is 2.8mm (0.11in.).
4. If required, install and attach a Kensington security cable (customer supplied) to the
unit’s lock port.
5. Attach an Ethernet cable from the access point to the installed data outlet.
6. 6. Place the middle of each of the case’s mount slots over the screw heads.
7. 7. Slide the case down along the mounting surface to hang the mount slots on the
screw heads.
8. 8. Verify the unit has power by observing that the LEDs are lit or flashing.
CAUTION If not using a 802.3af capable controller to power the AP6522, ensure
only the AP6522’s designated power supply (PWRS-14000-148R) is
used to supply power to the access point. Using an incorrectly rated
power supply could damage the unit and void the product warranty.
Do not actually connect to the power source until the cabling portion
of the installation is complete.
Suspended Ceiling T-Bar Mount
Ceiling mount requires holding the AP6522 access point up against a T-bar of a suspended
ceiling grid and twisting the case onto the T-bar.
Suspended Ceiling T-Bar Mount Procedure
1. If required, install and attach a Kensington security cable (customer supplied) to the
unit’s lock port.
2. Attach an Ethernet cable from the access point to the installed data outlet.
1. Align the bottom of the T-bar with the back of the case.
2. Orient the case by its length, and the length of the T-bar.
3. Rotate the case 45 degrees clockwise, or about 10 o’clock.
4. Push the back of the case onto the bottom of the T-bar.
5. Rotate the case 45 degrees counter-clockwise. The clips click as they fasten to the
T-bar.
6. Verify the unit has power by observing the LEDs.
CAUTION If not using a 802.3af capable controller to power the AP6522, ensure
only the AP6522’s designated power supply (PWRS-14000-148R) is
used to supply power to the access point. Using an incorrectly rated
power supply could damage the unit and void the product warranty.
Do not actually connect to the power source until the cabling portion
of the installation is complete.
APPENDIX C
CSU Communications Pit Infrastructure Documentation Requirements
These requirements apply to both new installations and work being carried out on existing pit installations
Steps
1.
2.
3.
4.
5.
6.
7.
8.
9.
Locate Pit
Attach CSU Pit Number Label if none present
Take Photograph (A) of pit cover with Labels attached
Step back a few meters. Take Photograph (B). Photo is to include the pit and surrounding
building or landmark to help identify pits location and orientation.
Open pit
Take photograph (C) of the inside of the pit from the top down
Fill in pit audit sheet( see attached examples)
7.1.1 Sketch drawing of the inside of the pit in the space provided
7.1.2 Indicate north orientation
7.1.3 Draw each conduit and its conduit number.
7.1.4 In the Materials section indicate if it is possible if the pit contains asbestos
7.1.5 Include any other relevant info eg. broken into conduits
Use the Sketch to produce a diagram of the pit in .vsd (visio) format
Any observation or comments other than the above.
Required outputs
A visit to each pit is to produce the following outputs
 A CSU Pit Number attached to the Pit
 A completed Pit Audit Sheet – in .xls (Excel) format as supplied.
 A diagram of the pit layout in .vsd (Visio) format as supplied
o Files to have the name of the Pit ID – eg WW105.xls and WW105.vsd
 3 Photographs files
Photo
Description
File Name
A
B
Pit lid Showing the Label
Perspective showing pit and nearby building or landmark
Pit number + Letter Photo identifier eg BA017A
Pit number + Letter Photo identifier eg BA017B
C
Top down Photo of Pit
Pit number + Letter Photo identifier eg BA017C
CSU Pit Number – CCXXX - eg WW005
Where CC = Campus Identifier
WW = Wagga Wagga
BA = Bathurst
OR = Orange
DU = Dubbo
AL = Albury
CA = Canberra
Where XXX is the sequential Pit number
CSU Pit Labels
Pit labels are to be stainless steel
100mm*70 Approx
With CSU COMMS and the PIT number Laser etched
into the plate as shown in the following example
Labels can be screwed where appropriate and/or
attached with Liquid Nails
Note: Labels are to be securely attached to pit lids. Contractors should contact DIT
representative for Label info and numbering.
APPENDIX D
Documentation required for the
\installation of new fibre optic cable at CSU
For Each fibre run



Complete a copy of the CSU Fibre Optic cable installation record
FibreInstallRecord.doc
Fill in the fibre run details in the FibreInstallRecord.xls file
Conduct OTDR and Insertion loss tests. An electronic copy of the test results shall
be provided to the relevant IT staff member prior to project sign off.
Instructions for filling in FibreInstallRecord.xls
The supplied FibreInstallRecord.xls contains sample data to give an idea of how to enter the
data. Be sure to remove the sample data before submitting the file.
If you are installing multiple fibre runs a separate FibreInstallRecord.xls is not required, just
add the data for each run on a new row as in the example data.
Use one row per fibre cable run
In column A enter the Cable Label
In column B enter the numbers of cores run
In column C enter the cores terminated
In column D enter the installation date
In column E enter the company name of the installer
In column F enter the first building of the run (this is the remote building not the fibre
distribution point
From column G enter the first pit in the sequence
Continuing entering pit numbers in column H, I , J etc until all the pits have been recorded
After the final pit has been entered, record the final destination building (fibre distribution
point)
DOCUMENTATION VARIATION TABLE
Rev
Date
Modification
8.0
05-08-2011
Major release version – Please review entire document.
8.1
08-09-2011
Addition of section 4.4
Addition of Appendix A
Addition of Appendix B
Modifications to section 1.2.2
Modifications to section 4.2.3.1
Modifications to section 4.2.4
Modifications to section 4.2.5
Modifications to section 4.2.6.3
8.2
21-09-2011
Modifications to section 1.2
8.3
23-10-2013
Modifications to section 1.2
Modifications to section 2.1
Modifications to section 2.5
Modifications to section 4.2
Modifications to section 4.2.1.1
Modifications to section 4.2.4
Modifications to section 4.2.6.1
Modifications to section 4.2.6.2
Modifications to section 4.2.6.3
Modifications to section 4.3.4
Addition of section 4.3.4.2
Modifications to Appendix B
Addition of Appendix C
8.4
93-04-2014
8.5
8.6
17/09/2014
07/11/2014
8.7
10/02/2015
Modifications to section 4.2
Modifications to section 4.2.1.1
Modifications to section 4.2.1.3
Modifications to section 4.2.2.1
Modifications to section 4.2.6.2
Modifications to section 4.2.6.3
Modifications to section 4.2.7.2
Modification to section 4.2.6.3
Extensive Modification to section 4.2.6.3
Modification to section 4.2.5
Modification to section 4.4.1
Added Appendix D
Added Section 4.5
4.3.5.1 Phone Cable
4.3.5.2 Optic Fibre Cable
Modifications to Appendix A
Modifications to Appendix C
Modifications to Appendix D

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