rud 5488 e

Date Edition Status Prepared by Updated by Approved by

Nov 2014 A Superseded Robert

Vanhentenrijk

Odette Bruyninckx Steven Theys

Nov 2014 B Superseded Robert

Vanhentenrijk


May 20, 2016 C Superseded Robert

Vanhentenrijk


Jan 27, 2021 D Superseded Daniel Daems Odette Bruyninckx

July 5, 2021 E Active Daniel Daems Odette Bruyninckx

Performance Specification

FIST-EDSA2 closure for stationary use at underground locations according to ETSI EN 300 019-2-8.


FIST-EDSA2 closure for stationary use at underground

locations according to ETSI EN 300 019-2-8.

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Performance specifications of FIST- EDSA2 closure for stationary use at underground locations according to ETSI EN 300 019-2-8.

Content

1 Scope 2

2 Product description 3

3 Product requirements 4

3.1 General requirements 4

3.2 Material requirements 5

3.3 Test sample construction 6

3.4 Sealing pass/fail criteria 10

3.5 Sealing performance requirements

11

3.6 Optical pass/fail criteria 14

3.7 Optical performance requirements 15

4 Quality assurance provisions 16

4.1 Responsibility for quality 16

4.2 Qualification conformance 16

4.3 Manufacturing follow-up 16

5 References 17




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1 Scope

This document describes the functional performance requirements, together with the test

descriptions and severities of the optical fiber closures FIST-EDSA2 for use in FTTH-networks.

The described tests and severities are selected to cover outdoor subterranean applications and

are selected to cover ETSI EN 300 019-2-8 T8.1 Stationary use at underground locations.

The test methods are conforming international test methods of the IEC 60068 and IEC 61300

series.

Quality assurance provisions and a list of norms complete the document.

The document is intended for use:

− by CommScope for internal qualification and re-qualification purposes

− by other organizations to:

o provide information on product performance

o act as a guide for test programs

o analyze and compare product performance in, for example, tender

situations

− by CommScope customers worldwide, except in countries where a customized

document has been prepared.




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2 Product description

The FIST-EDSA2 closure is a cold applied closure system housing. The closure body consists

of two parts (dome and base), sealed with H-seal between dome and base. The drop ports are

sealed with gel.

FIST-EDSA2 closure enables fast and easy installations of cables and microducts. The drop sealing block allows a fast, wrap around, modular installation and provides cable

retention, water blocking and sealing in one go.

The FIST-EDSA2 is typically used in the drop part of the access network. It is the last

enclosure in the outside plant from which up to 48 customers can be provisioned through direct

buried drop cables or microducts.

All fiber cable elements are routed in such a way that no transmission degradation is seen after

accessing these cable elements. The nominal bend radius of the fibers after installation is

30 mm throughout the whole closure system as described in IEC 61756-1.

The closure accommodates 6 cable ports. One oval (main cable), four rectangular (drop

cables) and one round port. The oval port allows the installation of blown fiber tubes 14/10 or

cables with diameter 2 x 4 mm up to 2 x 16 mm.

The rectangular ports can accept blown fiber tubes from 8 mm and cables from 5 up to 8 mm.

Each gel block can accept 12 drop cables or tubes.

The round cable port is suitable for the multi-out gel seals FIST-RSKG and can be used for

cables with diameters from 0 mm up to 14 mm.

Unused cable ports shall be closed with plugs.

Intrusion protection: IP 68 (2 meters) according to IEC 60529

Operating temperature range: -20 °C to +60 °C




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3 Product requirements

3.1 General requirements

The product shall be capable of meeting the functional requirements as specified on the

following pages when installed in accordance with the applicable installation instructions and

tested according to the methods of test described in this document.

The components of the kits shall be free of defects that would adversely affect product

performance.

Access compartments shall have no sharp edges that could damage installers or cables. All

device materials that are likely to come into contact with personnel shall be non-toxic and shall

not be a potential environmental hazard.

Metal parts shall be resistant to the corrosive influences they may encounter in normal use.

A color change due to passivation is allowed.

The effect of UV-light on the outer polymeric materials shall not adversely affect product

performance or cause a clear colour change.

For polymeric materials, the effect of fungus shall be determined according to IEC 60068-2-10

or ISO 846, measuring a suitable property (e.g. tensile strength at yield and elongation at yield)

both before and after exposure.

The packaged product shall meet the storage performance requirements for temperature

(-25 ºC and +70 ºC) and humidity (+40 °C/93 %RH) in ETSI EN 300 019-2-1 class 1.2

(Weather protected, not temperature-controlled storage locations).

The packaged product shall meet the transportation performance requirements for temperature

(-25 ºC and+70 ºC) and humidity (+40 °C/93%RH) in ETSI EN 300 019-2-2 class T2.2 (Careful

transportation).

Closures are designed to withstand an impact with energy 20 J.

Note: The IEC 61753 optical fiber closure performance specifications do not refer to the IEC

62262 (2002) IK10 test method. The test method IEC 61300-2-12 version 2009 Method B is

used.

By meeting the sealing performance tests in this document this hermetical sealed closure will

meet the IP68 with 2 meter waterhead as described in IEC 60529 (as there is no exchange with

air, dust and water with outer environment).

The closures shall be installable at temperatures between -10 °C and +50 °C.

Each kit shall have a label with the following information:

− Supplier's name

− Product designation

− Batch number




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3.2 Material requirements

Test Method and conditions Acceptance criteria

to be checked

Material tests

UV resistance of

outer polymeric

materials

ISO 4892-3

Alternative method:

ASTM G.154

UV source:

Exposure cycles:

- UV:

- Condensation:

Exposure time:

Lamp type 1A Fluorescent

lamps (UVA 340 nm)

Cycle 1: Alternating UV and

condensation cycle

8 h at (+60 3)°C, light

4 h at (+50 3)°C; dark

Minimum 2160 h

Material tests are done on

molded dumbbells

Visual examination

Reduction in mechanical properties

(tensile strength and elongation at

yield) not more than 20%.

Fungus resistance

(Mould growth)

ISO 846

or IEC 60068-2-10

Strains:

Inoculation

conditions:

Temperature:

Relative humidity:

Duration:

Test Variant 1

Test Severity 1

(29 1)°C

> 90%

28 days

Material tests are done on

molded dumbbells

Visual examination:

When a rating 0 is obtained, the

material is considered fungus

resistant and no further testing is

required.

When a rating of 1 or 2 is obtained,

the effect of mould growth shall be

evaluated by measuring a

representative performance property

(e.g. tensile strength at yield and

elongation at yield for thermoplastic

polymers, a compression set, a Shore

A hardness for elastic materials, or

any other test which checks a

relevant property) both before and

after exposure of the material

samples. The average change in

mechanical characteristics of the

tested material samples shall be less

than 20 %.

A rating of more than 2 is not allowed.

Hydrolysis

resistance of

polymer materials

IEC 61300-2-19

Test temperature1:

Humidity:

Duration:

(+85 ± 2)°C

(85 ± 2) %RH

1 000 h

Visual examination.

After the test the materials shall not

become brittle.

1

Higher test temperatures with shorter test duration are allowed when no phase transition

occurs in the material.




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3.3 Test sample construction

All installations shall be performed according to CommScope standard installation instructions

unless otherwise stated.

For each sealing tests minimum 3 samples shall be made. All test samples shall be installed

with cables. The length of the cables extending the closure shall be sufficient to perform the

tests. The free ends of the cables shall be sealed with a cap. Test samples shall include both

maximum and minimum cable diameters as specified in the applicable installation instructions.

It is not necessary to use all cable ports. Open cable ports shall be sealed with a cap or a plug.

Sealing performance test samples shall be provided with an air pressure test access valve.

Testing is performed at room temperature, (IEC 61300-1 standard laboratory conditions of

+23 °C ± 5 °C unless otherwise specified.

When a test is specified at another ambient temperature, samples shall be preconditioned with

the test pressure for a period of 4 hours at that temperature.

Unless specified otherwise, internal pressurization is achieved with an air supply within

± 2 kPa of the specified overpressure value. The pressure and temperature shall be recorded

before the start of the test.

Pressure measurements before and after the test shall be carried out with the same pressure

measurement equipment and at the same atmospheric conditions (temperature and pressure).

When a difference is observed in atmospheric conditions after the test the pressure shall be

calculated according to the relationship: p.V/T=cte.

For each optical test minimum 1 sample shall be made. The optical test sample will be built

with 2 closures: one configured as track/spur joint and one configured as distribution joint

(access point for connections to customers). The cable jacket between the 2 closures shall not

be interrupted or removed.

The selected cable or tube must be suitable for the selected temperature range.

Fiber type used for the test samples with a fiber management system based on 30 mm bending

radii of fibers is ITU-T G.652.D, other fiber types will be qualified by similarity (since G.652.D is

the most bend sensitive type).

Fiber characteristics

Fiber type: Dispersion unshifted single mode fiber -matched

cladding (ITU-T G.652.D or IEC 60793-2-50 Type B-

652.D)

Proof stress strain test: ≥1 %

Mode field diameter at 1310 nm: Nominal value from 9.0 µm to 9.2 µm

Tolerance om nominal value 0.4 µm

Cabled fiber cut off wavelength: 1260 nm

Macro bend loss at 1625 nm: < 0.5 dB for 100 turns with radius 30 mm

Cladding diameter: 125.0 µm 1.0 µm

Non colored coating diameter: 245 µm 10 µm

Colored coating diameter 250 µm 15 µm




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ITU-T G.657.A1 fiber type used in closures with a fiber management system based on 20 mm

bending radii of fibers. By meeting the closure requirements with A1 fiber, the closure is

automatically qualified for use with A2 and B3 fibers.

Fiber characteristics

Fiber type: Dispersion unshifted single mode fiber -matched

cladding (ITU-T G.657.A1 or IEC 60793-2-50 Type

B6a1)

Proof stress strain test: ≥1 %

Mode field diameter at 1310 nm: Nominal value between 8.6 µm and 9.2 µm

Tolerance on nominal value: ± 0.4 µm

Cabled fiber cut off wavelength: 1260 nm

Macro bend loss at 1625 nm: < 1 dB for 10 turns on 30 mm mandrel diameter

< 1,5 dB for 1 turn on 20 mm mandrel diameter

Cladding diameter: 125.0 µm 0.7 µm

Non colored coating diameter: 245 µm 10 µm

Colored coating diameter 250 µm 15 µm

The optical test sample is built with two closures: one configured as track/spur joint and one

configured as distribution joint (access point for connections to customers). The selected

cables shall be suitable for the selected temperature range.

Step 1: Both extremities of a looped cable are terminated in the track/spur joint closure (see

Figure 1). The length of the looped cable is chosen to be longer than the "dead zone" of an

optical time domain reflectometer (OTDR). Typically, a cable loop length of 25 m to 50 m is

used, allowing location of the potential causes of optical losses and to distinguish whether a

change in signal is induced by the fibre management system in a single location or distributed

evenly over the whole circuit length.

Figure 1 – Track/spur joint configuration sample

In the track/spur joint closure, the fibres from one cable end are connected to the fibres of the

other cable end in such a way that light will sequentially flow through an optical circuit of

10 random selected incoming fibres from the cable loop. An "incoming fibre" is a part of an

optical circuit containing the fibre entering the closure, spliced to a fibre leaving the closure.

Typically, an optical circuit contains 10 incoming fibres.

The first and the last incomin fibre of this circuit will be spliced to the fibres of a cable for

making external connections to a light source and optical power meter.

When applicable, all relevant fibre separation levels (SE, ME and MR) shall be represented in

the test sample, preferably in separate circuits. As example, additional circuits as indicated by

1, 2 and 3 are shown in

Figure 2.




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Figure 2 – Optical circuits in track/spur joint closure

When the closure also allows a distribution joint configuration, an additional closure shall be

added to the test sample construction as described in step 2.

Step 2: In the middle of the looped cable, the cable jacket is removed over a distance (window

cut) according to the installation instructions. The bundles of uncut loose tubes are inserted

and stored inside the distribution joint closure (see Figure 3 and

Figure 4). If fibres can be stored in different separation levels (SC, SE, SR, ME and MR), each

of these options shall be executed in separate circuits.

Figure 3 – Distribution joint configuration sample




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Figure 4 – Optical circuits in the distribution joint closure

Typically, the following separate circuits will be made as shown in

Figure 4:

Circuit 1: uncut looped fibres in uncut loose tube (stored in loose tube basket);

Circuit 2: uncut looped fibres stored in SC or SR trays, two uncut looped fibres shall be broken

in the middle and the fibre ends are spliced to the fibres of a looped drop cable with minimum 2

fibres; the remaining non-active fibres in circuit 2 are stored in SC/SR trays located between 2

active SC/SR trays. These non-active fibres will be accessed again during the

intervention/reconfiguration test;

Circuit 3: fibres stored in SE, ME or MR trays, spliced to fibres of a looped drop cable with

minimum 12 fibres.

The non-active fibres from the remaining loose tubes in the looped cables are installed in the

closure and the fibres are stored randomly in the fibre management system in between the live

fibre circuits.




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3.4 Sealing pass/fail criteria2

Pass/fail criteria Method and conditions Requirements

Sealing performance criteria

Pressure loss

during test

IEC 61300-2-38

Method B

Internal pressure:

Temperature:

Elapsed time:

(20 2) kPa

As specified

<12 h

Difference in pressure before & after

the test

2 kPa at the same atmospheric

conditions

Sealing

IEC 61300-2-38

Method A

Internal pressure:

Test temperature:

Test time:

Depth:

(20 2) kPa

(23 5) °C

15 minutes

Just below water surface

After immersion in water the closure

shall be turned and moved around to

remove all trapped air.

No continuous emission or visual

growing of bubbles is allowed

Visual

examination

IEC 61300-3-1

Examination of product

with naked eye.

Inspection with the naked

eye for flaws, defects, cracks

or impurities that could

impair functionality.

No defects which would adversely

affect product performance

2

All testing is at room temperature (23 ± 5) °C unless otherwise stated.




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3.5 Sealing performance requirements 3

Test Method and conditions Pass/fail criteria to be checked

Mechanical tests (sealing performance)

Assembly/

Disassembly

(Re-entries)

IEC 61300-2-33

Number re-entries:

Temperature ageing

cycle between

re-entries:

Dwell time:

Transitions:

Test pressure between

each re-entry:

5 times

At least one temperature

cycle -20 °C/+60 °C

4 h

1°C/minute

20 kPa overpressure

regulated

Visual examination

Sealing after each re-entry

Cable retention

IEC 61300-2-4

Test temperatures:

Test pressure:

Load/cable (N):

Point of application:

Duration:

(-10 2)°C and (+40 2)°C

(20 2) kPa overpressure

sealed off at test temperature

10 x ØCable (mm)

10 N for tubes and cables

without strength member or

aramid yarns attachment

The greater of 400 mm or 50

x cable diameter measured

from closure

15 min per cable and per test

temperature

Visual examination

Max. cable displacement 3 mm

Pressure loss during test Sealing

after test

Crush resistance

(Static load)

IEC 61300-2-10

Test temperatures:

Test pressure:

Load:

Surface:

Duration:

Position:

(-10 2)°C and (+40 2)°C


sealed off

1000 N

25 cm²

10 min per test temperature

At closure midpoint

Visual examination


after test

Soil compression

test

No standard

reference available

for this test

procedure

Test temperature:

Test pressure:

Load:

Plate:

Depth in sand:

Duration:

Position load:

(+23 5) °C


sealed off

125 kN on plate

50 cm x 50 cm

0.3 m

10 min

Above closure midpoint

Visual examination

Pressure loss during test

Sealing after test

3





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3.5 Functional sealing requirements (continued) 4


Mechanical tests (sealing performance)

Cable bending

IEC 61300-2-37

Test temperatures:

Test pressure:

Bending angle:

Force application:

No. of cycles

Duration:

(-10 2)°C and (+40 2)°C



From 0º to -30° to +30° to 0º

(= 1 cycle) in random selected

directions

400 mm away from closure

seal

5 per cable and per test

temperature

5 minutes in each extreme

position

Visual examination


(after test)

Cable torsion

IEC 61300-2-5

Test temperature:

Test pressure:

Torsion angle:

Torque application:

No. of cycles:

Duration:

(-10 2)°C and (+40 2)°C



From 0º to - 90° to +90° to 0º

(= 1 cycle)

400 mm from closure seal

5 per cable and per test

temperature

5 minutes in each extreme

position

Visual examination


(after test)

Impact

IEC 61300-2-12

Method B

Test temperatures:

Test pressure:

Impact tool:

Weight:

Drop height:

Location:

Number of impacts:

(-10 2)°C and (+40 2)°C



Steel ball

1 kg

2 m

At closure midpoint - top

1 impact per test temperature

Visual examination


after test

Vibration

IEC 61300-2-1

Test pressure:

Frequency:

Cycle:

Amplitude:

Cable clamping:

Duration:


regulated

(10 1) Hz

Sinusoidal

3 mm

500 mm from end of seal

10 days

Visual examination

Sealing after test

4





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3.5 Functional sealing requirements (continued)5


Environmental tests (sealing performance)

Change of

temperature

IEC 61300-2-22

Lowest temperature:

Highest temperature:

Dwell time:

Transition:

Internal pressure:

Number of cycles:

(-20 2) °C

(+60 2) °C

4 h

1 °C/minute

20 kPa overpressure regulated

20

Visual examination

Sealing after test

Resistance to

Aggressive media

IEC 61300-2-34

Test pressure:

Media:

Duration:

Drying time at 70°C


regulated

pH 2, pH 12

Kerosene (lamp oil)

Petroleum jelly

Diesel fuel for cars

7 days

None

Visual examination

Sealing after test

Resistance to

stress cracking

IEC 61300-2-34

Test temperature:

Test pressure:

Medium:

Duration:

Drying time at 70°C

(+50 2) °C


regulated

10% Igepal

7 days

None

Visual examination

Sealing after test

Salt fog

IEC 61300-2-26

Test temperature:

Medium:

Duration:

(+35 2)°C

5% NaCl in water

5 days

Visual examination. No signs of

corrosion. A color change due to

passivation is allowed for the

metals.

Water immersion

IEC 61300-2-23

Method 2

Water height:

Test pressure:

Duration:

Wetting agent:

2 m water

Without overpressure sealed off

at room temperature

5 days

None

Visual examination

No water ingress

5





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3.6 Optical pass/fail criteria 6

Pass/fail criteria Method and conditions Requirements

Optical performance criteria references

Change in

attenuation

IEC 61300-3-3

Source wavelength: 1310 nm , 1550 nm and

1625 nm

For G.652.D fiber

@1310 and 1550 nm:

0.2 dB during test

0.1 dB after test

@ 1625 nm:

0.5 dB during test

0.1 dB after test IL

For G.657 fiber

All wavelengths:

0.2 dB during test

0.1 dB after test

Transient loss

IEC 61300-3-28

Source wavelength:

Detector bandwidth:

1550 nm and 1625 nm

0-1500 Hz

For ITU-T G.652.D fibers

@ 1550 nm

IL 0.5 dB during test

@ 1625 nm

1 dB during test

@ 1550 nm and 1625 nm (=residual loss)

0.1 dB after test

For ITU-T G.657 fibers

All wavelengths

0.5 dB during test

L 0.1 dB after test (=residual loss)

Visual

examination

IEC 61300-3-1

Examination of

product with naked

eye.

Inspection with the

naked eye for flaws,

defects, cracks or

impurities that could

impair functionality.

No defects which would adversely affect

product performance

Notes

All indicated optical losses are referred to the initial optical signal at the start of the test.

An “incoming fiber” is defined as a part of an optical circuit containing the fiber entering the product, spliced to a fiber leaving the

product. One optical circuit can contain many “incoming fibers”. Light will sequentially flow through all the “incoming fibers”. A

circuit contains typically 10 incoming fibers.

6





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3.7 Optical performance requirements

Test Method and conditions Pass/fail criteria to be

checked

Mechanical tests (optical)

Cable bending

IEC 61300-2-37

Bending angle:

Force application:

No. of cycles:

Duration:

From 0º to -30° to +30° to 0º (= 1

cycle) in random selected directions


5 per cable

5 minutes in each extreme position

Visual examination

Transient loss

Reconfiguration

IEC 61300-2-33

All manipulations that will normally occur during an intervention

after initial installation. These are typically:

1.Moving closure to working location. Handling of cables

attached to node;

2.Open closure;

3.Gaining access to previously installed fibres in the fiber

management system by hinging the trays in between the

extreme positions;

4.Adding/installing drop cables;

5 Adding splicing trays or modules

6.Cut one or more uncut fibres and splice them to other fibres;

7. Close and secure fiber management system

8. Close closure;

9. Move closure to storage location. Handling of cables

Visual examination

Transient loss

Shock

IEC 61300-2-9

Severity:

Duration:

Wave form:

Number of shocks:

Axes:

15 g

11 milliseconds

Half sine

3 up and 3 down per axis

3 mutually perpendicular

Visual examination

Transient loss

Vibration

IEC 61300-2-1

Sweep range:

Freq. change:

Crossover freq.:

- below 9 Hz:

- above 9 Hz:

Axes:

Duration:

5 Hz to 500 Hz to 5 Hz

1 octave/minute

9 Hz

Amplitude 3.5 mm

10 m/s² ( 1 g)

3 mutually perpendicular

10 cycles/axis

Visual examination

Transient loss

Cable torsion

IEC 61300-2-5

Torsion angle:

Torque application:

Tensile load:

No. of cycles:

Duration:

From 0º to - 90° to +90° to 0º (= 1

cycle)


None

5 per cable.

5 minutes in each extreme position

Visual examination

Transient loss

Change of

Temperature

IEC 61300-2-22

Lowest temperature:

Highest temperature:

Dwell time:

Transition time:

Number of cycles:

(-20 2) °C

(+60 2 ) °C

4 h

1 °C/minute

10 with first 5 cycles cable out of

climatic chamber, then 5 cycles

with cable in the climatic chamber.

Visual examination

Change in attenuation




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4 Quality assurance provisions

Quality provisions are based upon the philosophy of TQM (Total Quality Management) with a

system approved to ISO 9001.

4.1 Responsibility for quality

Unless otherwise stated in the customer order, it shall be CommScope' responsibility to assure

qualification and lot conformance to this specification. CommScope may utilize its own or other

testing and inspection facilities acceptable to the customer.

4.2 Qualification conformance

For the purposes of internal qualification, the program shall consist of examinations and tests

to determine conformance with the requirements of this specification.

It shall be performed once, on introduction of the product.

Subsequent design changes shall be partially or fully re-qualified depending upon their area of

impact in the context of product functionality.

Regular requalification testing shall be performed as defined by the Quality Department.

4.3 Manufacturing follow-up

CommScope products target Six Sigma levels of performance by the integration of capable

processes from the development throughout the entire supply chain. The goal is to reduce

variability to achieve zero defects for products and services. Systems used are based on

preventive and statistical techniques during development and manufacturing.

This also includes suppliers of materials, components or systems. Dedicated procedures for

supplier selection, development and follow-up are implemented to ensure conformance to TQM

and specification requirements.

Best demonstrated practices are identified and implemented throughout the company, with a

continuing challenge to identify opportunities for innovation and improvement.




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5 References

Reference * Title

ETSI EN 300-019-

series

Equipment engineering (EE); environmental conditions and

environmental tests for telecommunications equipment;

ETSI EN 300-019-2-1

(2014)

Part 2-1: Specification of environmental tests-Storage

ETSI EN 300-019-2-2

(2013)

Part 2-2: Specification of environmental tests-Transportation

ETSI EN 300-019-2-8

(1990)

Part 2-8: Stationary use at underground locations

IEC 60068-2-10 (2005)

+ AMD1 (2018)

Environmental testing - Part 2-10: Tests - Test J and guidance: Mould

growth

IEC 60529 (1989)

+AMD1:1999

+AMD2:2013

Degrees of protection provided by enclosures (IP code).

IEC 60793-2-50 (2018) Optical fibers - Part 2-50: Product specifications - Sectional specification

for class B single-mode fibers

IEC 60950-1 (2013) Information technology equipment - Safety - Part 1: General

requirements

IEC 61300-series Fiber-optic interconnecting devices and passive components.

IEC 61300-1 (2016) General and guidance

IEC 61300-2-series Part 2: basic test and measurement procedures:

IEC 61300-2-1 (2009) Vibration (sinusoidal).

IEC 61300-2-4 (2019)

+ AMD1 (2019)

Fiber/cable retention.

IEC 61300-2-5 (2009) Torsion

IEC 61300-2-9 (2010) Shock.

IEC 61300-2-10 (2012) Crush

IEC 61300-2-11 (2012) Axial compression

IEC 61300-2-12 (2009) Impact

IEC 61300-2-22 (2007) Change of temperature.

IEC 61300-2-23 (2010) Water Immersion

IEC 61300-2-26 (2006) Salt mist

IEC 61300-2-33 (2012) Assembly and disassembly of closures.

IEC 61300-2-34 (2009) Resistance to Solvents and Contaminating Fluids.

IEC 61300-2-37 (2006) Cable Bending for Closures.

IEC 61300-2-38 (2006) Sealing for Pressurized Closures of Fiber Optic Devices

IEC 61300-3-series Part 3: examination and measurements.

IEC 61300-3-1 (2005) Visual examination.

IEC 61300-3-3 (2009) Monitoring change in attenuation and in return loss (multiple paths).

IEC 61300-3-28 (2012) Transient loss.

IEC 61753-1 (2018) +

COR1 (2019)

Fibre optic interconnecting devices and passive components

Performance standard - Part 1: General and guidance

IEC 61756-1 (2019) Fibre optic interconnecting devices and passive components - Interface

standard for fibre management systems - Part 1: General and guidance

ISO 846 (2019) Resistance of Synthetic Polymeric Materials to Fungi and Bacteria.

ISO 1998/1 (1998) Petroleum Industry - Vocabulary - Part 1.

ISO 9001 Quality Management Systems - Requirements.

ITU-T G.652 (2016) Characteristics of single-mode fiber optic cable.

ITU-T.G.657 (2016) Characteristics of a bending loss insensitive single mode optical fiber

and cable for the access network

The documents listed here shall form a part of this specification.




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The non-dated versions, in effect at the date of issue of this specification, shall apply.

Other equivalent national standards may be used as substitutes for international ones.

* Copies of the documents referred to may be obtained from

ASTM American Society for Testing and Materials www.astm.org

DIN Deutsches Institut für Normung www.din.de

EN European Committee for Electrotechnical Standardization www.cenelec.org

ETS European Telecommunications Standards Institute www.etsi.org

IEC International Electrotechnical Commission www.iec.ch

ISO International Standards Organisation www.iso.ch

ITU International Telecommunications Union www.itu.int

UL Underwriters Laboratories lnc. www.ul.com

http://www.astm.org/

http://www.cenelec.org/

http://www.etsi.org/

http://www.iec.ch/

http://www.iso.ch/

http://www.itu.int/

http://www.ul.com/




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www..CommScope.com

Diestsesteenweg 692 B-3010 Kessel-Lo

Belgium

Visit our website or contact your local CommScope representative for more information.

© 2016 CommScope, Inc. All rights reserved.

All trademarks identified by ® or ™ are registered trademarks or trademarks, respectively, of CommScope, Inc. OptiTap is a registered trademark of Corning Cable Systems Solutions. This document is for planning purposes only and is not intended to modify or supplement any specifications or warranties rela ting to CommScope products or services.

http://www.commscope.com/

rud 5488 e

Documents