Page 1 of 26 Prepared by: Daniel Daems R&D Department Manager Approved by: P. De Coster Product Manager for the Gel-Sealed Fiber-Optic Closure System (FOSC 450) The FOSC 450 system is a fully mechanical butt-type closure used in the outside plant network when mass splice storage is the main requirement. It is typically used for track joint applications. It is available in 3 different sizes and can be used in any environment (aerial, pedestal, buried or underground). This document describes the performance requirements for the FOSC 450 closure system. Functional testing conforms to the international test methods described in the IEC 61300 series. The tests described and their severities have been selected to cover outside plant applications (underground, buried and aerial). Test methods are included when not described in the norms referenced. Key metric/imperial conversion factors are included in section 3.2. Quality assurance procedures and a list of references complete the document. The document is intended for use: by Tyco Electronics for internal qualification and re-qualification purposes by other organisations to: provide information on product performance act as a guide for test programmes analyse and compare product performance in, for example, tender situations by Tyco Electronics customers worldwide, except in countries where a customised document has been prepared. 1 Product description 2 2 Requirements 3 2.1 General requirements 3 2.2 Functional tightness requirements 4 2.3 Functional optical requirements 7 3 Testing 9 3.1 General 9 3.2 Conversion factors 9 3.3 Test procedures 10 4 Quality assurance provisions 24 4.1 Responsibility for quality 24 4.2 Qualification conformance 24 4.3 Manufacturing follow-up 24 5 References 25
Page 2 of 26 1 Product description The FOSC 450 base and dome are made from an impact resistant thermoplastic. Base to dome sealing is achieved using a clamp and O-ring system. Cable ports are sealed using a wrap-around gel block with a pre-installed gel profile with six ports, each capable of accommodating cables in the 9-25 mm diameter range. This block can be opened and closed repeatedly without the need to remove or replace the gel. The gel block permits the gradual addition of cables without disturbing cables installed earlier. A tray support structure allows the installation of mass splicing trays for single fiber or ribbon fiber. All the splicing trays are hinged at the support so that any fiber can be accessed without: disturbing fiber on other trays, kinking buffer tubes, introducing losses. Storage baskets for uncut fibers are available. Cable strain relief units provide the strength member fixation and cable jacket gripping. The closure is re-enterable and re-usable. Optional extras include an electrical feed-through and a pressure access valve.
Page 3 of 26 2 Requirements 2.1 General requirements The products shall be capable of meeting the functional requirements as specified on the following pages when: installed in accordance with the applicable installation instructions, and evaluated according to the methods of test described in this document. Exposed metal parts shall be resistant to the corrosive influences they may encounter in normal use. The effect of fungus and UV on polymeric materials shall not adversely affect product performance. The effect of fungus shall be determined according to ISO 846. The effect of UV shall be assessed following ASTM G154 Cycle 2. In both cases a suitable material property (e.g. tensile strength or impact strength) shall be measured before and after exposure. The products' components shall withstand storage at temperatures of -30 to 60 C and storage humidity levels up to 93% RH. Dimensions of the parts shall comply with the applicable specification control drawings (SCDs). The components of the FOSC 450 kit shall be free of defects which would adversely affect product performance. The splice closures shall be installable at temperatures between -5 and +45 C. The splice closures shall allow the accommodation of the fibers with a minimum bend radius of 30 mm. The kits shall contain all the necessary components for a complete installation. All kit components that are likely to come into contact with personnel shall be non-toxic and shall not be a potential environmental hazard. Each kit shall have a label with the following information: Supplier's name Product designation and size Batch number Customer reference number
Page 4 of 26 2.2 Functional tightness requirements 1 Performance criteria Method and conditions Intern. Norm/ref Page Requirements Performance criteria references Appearance Examination with the unaided naked eye IEC 61300-3-1 10 No defects which will adversely affect product performance Pressure loss during test Temperature: Internal pressure: Elapsed time: Pressure measurement At test temperature (40 ± 2) kpa <12 hrs Before and after test IEC 61300-2-38 Method B 17 Difference in pressure before and after the test: 2 kpa at the same atmospheric conditions Tightness Test temperature: Internal pressure: Test time: Location: (+23 ± 3) C (40 ± 2) kpa 15 minutes Just beneath surface IEC 61300-2-38 Method A IEC 60068-2-17 Test Qc 21 No continuous emission of bubbles Test Method and conditions Intern. Norm/ref Page Performance criteria to be checked Mechanical tests (tightness evaluation) Axial tension Test pressure: Load/cable: Test time: (40 ± 2) kpa sealed D/45 x 1000 N (max. 1000 N) 1 hr each cable IEC 61300-2-4 10 Pressure loss during test Displacement 3 mm Tightness Flexure Test temperatures: Test pressure: (-15 ± 2) C and (+45 ± 2) C (40 ± 2) kpa sealed 2 IEC 61300-2-37 12 Pressure loss during test Appearance Tightness Force: Force application: No. of cycles: 30 bending or max. 500 N force 400 mm from end of base 5 per cable Impact Test temperatures: Test pressure: Impact tool: Weight: Drop height: (-15 ± 2) C and (+45 ± 2) C (40 ± 2) kpa sealed 2 Steel ball 1 kg 2 m Locations: 0, 90, 180 and 270 Number of impacts: at middle of closure 1 per location IEC 61300-2-12 Method B 13 Pressure loss during test Appearance Tightness 1 All testing is at room temperature unless otherwise stated. RT: room temperature. D is the cable outer diameter in mm. 2 Sealed at test temperature.
Page 5 of 26 2.2 Functional tightness requirements (continued) 3 Test Method and conditions Intern. Norm/ref Page Performance criteria to be checked Mechanical tests (tightness evaluation) Re-entries Number: Aging between each re-entry: - Temperature range: - Dwell time: - Transition: Test pressure: 10 minimum 1 cycle -30 C/+60 C 4 hrs 2 hrs 0 kpa sealed at RT IEC 61300-2-33 18 Tightness Appearance Static load Test temperatures: Test pressure: Load/surface area Time: Position: (-15 ± 2) C and (+45 ± 2) C (40 ± 2) kpa sealed 4 1000 N/25 cm² 10 min 0 and 90 IEC 61300-2-10 20 Pressure loss during test Appearance Tightness Torsion Test temperatures: Test pressure: Torque Torque application: No. of cycles: Tensile load: (-15 ± 2) C and (+45 ± 2) C (40 ± 2) kpa sealed 4 Max. 50 Nm or max. 90 rotation 400 mm from end of base 5 per cable None IEC 61300-2-5 22 Pressure loss during test Appearance Tightness Vibration Test pressure: Frequency: Amplitude: Cable clamping: Duration: (40 ± 2) kpa regulated IEC 61300-2-1 (10 ± 1) Hz sinusoidal IEC 60068-2-6 3 mm Test Fc 500 mm from end of base 10 days 23 Tightness Appearance Environmental tests (tightness evaluation) Resistance to aggressive media Test pressure at RT: Media: Test time: Drying at 70 C (40 ± 2) kpa sealed ph 2, ph 12 Kerosene (lamp oil) Petroleum jelly Diesel fuel for cars 5 days None IEC 61300-2-34 ISO1998/I 1.005 EN 590 18 Tightness Appearance Resistance to stress cracking Test temperature: Test pressure at RT: Medium: Test time: Drying at 70 C (+50 ± 2) C (40 ± 2) kpa sealed 10% Igepal 5 days None IEC 61300-2-34 19 Tightness Appearance 3 All testing is at room temperature unless otherwise stated. RT: room temperature. 4 Sealed at test temperature.
Page 6 of 26 2.2 Functional tightness requirements (continued) 5 Test Method and conditions Intern. Norm/ref Page Performance criteria to be checked Environmental tests (tightness evaluation) Salt fog Test temperature Test pressure at RT: Medium: Test time: (+35 ± 2) C (40 ± 2) kpa sealed 5% NaCl in water 5 days IEC 61300-2-26 IEC 60068-2-11 Test Ka 19 Appearance Temperature cycling Lowest temperature: Highest temperature: Dwell/transition time: Internal pressure: Number of cycles: (-30 ± 2) C (+60 ± 2) C 4 hrs/2 hrs (40 ± 2) kpa regulated 20 IEC 61300-2-22 IEC 60068-2-14 Test Nb 20 Tightness Appearance Waterhead Column height: Test pressure at RT: Duration: Wetting agent: 5 m water 0 kpa sealed 7 days None IEC 61300-2-23 Method 2 23 No water ingress 5 All testing is at room temperature unless otherwise stated. RT: room temperature.
Page 7 of 26 2.3 Functional optical requirements Performance criteria Method and conditions Intern. Norm/ref Page Requirements Performance criteria references (optical evaluation) Appearance Examination of product with the unaided naked eye IEC 61300-3-1 10 No defects which would adversely affect product performance Change in attenuation Source wavelength: 1310 nm, 1550 nm and 1625 nm 6 IEC 61300-3-3 11 δil 0.2 db per incoming fiber during the test at 1310 and 1550 nm δil 0.5 db per incoming fiber during the test at 1625 nm δil 0.1 db per incoming fiber after the test Notes All optical losses refer 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 contains 10 spliced incoming fibers. Light will sequentially flow through all the incoming fibers. Fiber type used for all test samples: Fiber characteristics Fiber type: Non dispersion shifted (ITU-T G.652) Proofstress test: 0.7 GPa Mode field diameter at 1310 nm: 9.2 µm ± 0.4 µm Mode field diameter at 1550 nm: 10.4 µm ± 0.8 µm Cabled fiber cut off wavelength: 1260 nm 1550 nm loss performance: < 0.1 db for 100 turns on 50 mm mandrel diameter Fiber curl: > 4.0 meter radius Cladding diameter: 125.0 µm ± 1.0 µm Non coloured coating diameter: 245 µm ± 5 µm 6 Cable should be specified for 1625 nm transmission (temperature range, bending diameter). If not the 1625 nm data will only be indicative.
Page 8 of 26 2.3 Functional optical requirements (continued) 7 Test Method and conditions Intern. Norm/ref Page Performance criteria to be checked Mechanical tests (optical evaluation) Flexure Force: Force application: No. of cycles: 30 bending or max. 500 N force 400 mm from end of base 5 per cable IEC 61300-2-37 12 Appearance Change in attenuation after the test (Residual loss) Installation Installation of looped cable inside closure (EN) None 14 Change in attenuation after the test (Residual loss) Reconfiguration Closure handling: Cable handling Open closure Hinging trays Splicing fibers Close IEC 61300-2-33 17 Change in attenuation after the test (Residual loss) Shock Severity: Duration: Wave form: Number of shocks: Axes: 15 g (150 m/s²) 11 milliseconds half sine 3 up & 3 down 3 mutually perpendicular IEC 61300-2-9 IEC 60068-2-27 Test Ea 19 Appearance Change in attenuation after the test (Residual loss) Torsion Torque: Max. 50 Nm or max. 90 rotation IEC 61300-2-5 22 Torque application: 400 mm from end of base No. of cycles: Tensile load: 5 per cable. None Appearance Change in attenuation after the test (Residual loss) Vibration Sweep range: - crossover frequency: - severity below 9 Hz: - severity above 9 Hz: Axes: Duration: (5-500) Hz at 1 octave/minute 9 Hz 3.5 mm 10 m/s² ( 1 g) 3 mutually perpendicular 10 cycles/axis IEC 61300-2-1 IEC 60068-2-6 Test Fc 23 Appearance Change in attenuation after the test (Residual loss) Environmental tests (optical evaluation) Temperature cycling Lowest temperature: Highest temperature: Dwell/Transition time: Number of cycles: (-30 ± 2) C 8 (+60 ± 2) C 8 4 hrs / 2 hrs 20 IEC 61300-2-22 IEC 60068-2-14 Test Nb 20 Appearance Change in attenuation 7 All testing is at room temperature unless otherwise stated. 8 If this temperature falls outside the range specified for any of the cables being used, the test temperature must be modified accordingly.
Page 9 of 26 3 Testing 3.1 General The construction and configuration of test samples shall be as described in the test plan agreed between Tyco Electronics and the customer. For internal qualification or requalification the number of samples being tested shall be depending on the object and the purpose of the test programme. For the optical tests minimum 1 circuit, containing minimum 10 fusion splices, shall be built in one sample. All installations shall be performed according to Tyco Electronics standard installation instructions and at room temperature, unless otherwise stated. If relevant for the test, samples shall be installed with cables. If it is required to use cables with lower performance capabilities, the test parameters will need to be appropriately modified. Tightness test samples shall be installed over unspliced optical cable. The cable ends shall be capped. 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. For test pressure access, a valve shall be installed in the dome or cable caps. Unless specified otherwise, internal pressurization is achieved with an air supply held to ± 2 kpa of the specified value. Testing is at room temperature 9 unless otherwise specified. When tests are specified at temperatures other than ambient, the samples shall be preconditioned for a period of at least 4 hours at those temperatures. 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, the pressure shall be calculated according to the relationship: p.v/t=cte. 3.2 Conversion factors C = ( F-32)/1.8 F = ( C x 1.8) +32 1 cm² 0.1550 in² 1 kg 2.205 lb 1 kpa 0.1450 psi 1 m 3.281 ft 1 mm 0.03937 in 1 N 0.2248 lb 1 Nm 0.74 lbf. ft 9 Standard laboratory conditions of (+23 ± 3)ºC
Page 10 of 26 3.3 Test procedures 3.3.1 Appearance This test is included to ensure that no obvious defects are present that would affect product performance. Testing shall be performed in accordance with IEC 61300-3-1. The closure system and components shall be inspected for flaws, defects, pinholes, cracks or inclusions visible to the naked eye. 3.3.2 Axial tension This test is designed to simulate cable/closure manipulation. It specifically addresses seal performance. Testing shall be performed in accordance with IEC 61300-2-4. Samples shall be pressurized internally at 40 kpa at room temperature and sealed and measured (page 17) prior to testing. The closure shall be clamped, and a force shall be applied to each of the extending cables individually for a period of one hour. The force per cable shall be calculated according to the equation: D (cable outer diameter in mm)/45mm x 1000 N (maximum 1000 N). After completion of the test, internal pressure shall be checked (page 17) again and specimens shall be subjected to the tightness test described on page 21. After the test the permanent displacement of the cable elements in the cable attachment shall be smaller than 3 mm.
Page 11 of 26 3.3.3 Change in attenuation This is the criterion test for optical measurements during and after the test. The value quoted assumes the use of a stable qualified splice/protector, well installed. Testing shall be performed in accordance with IEC 61300-3-3. This is defined as a measured attenuation which is exhibited by stable transmission measurements taken before, during and after a test. The optical power shall be monitored using an optical source and a detector operating at 1310 nm, 1550 nm and 1625 nm. The preferred test set-up is shown below: Temperature Transducer Climatic Test Chamber Switch 1 Switch 2 and 3 Detector Source Test sample OTDR Reference IEEE 488 Interface bus Controller Source: 1310 nm ± 20 nm, 1550 nm ± 20 nm and 1625 ± 25 nm. Switch: Repeatability better than 0.04 db. The in- and outgoing fibers of each circuit are spliced onto the connection fibers of the equipment. Splices shall be made using good-quality fusion splices. During and after the test the optical power in each circuit shall be measured with the light source and detector at all specified wavelengths. A change of more than 0.2 db at 1310 nm and 1550 nm per incoming fiber during the test from the initial value constitutes a failure. A change of more than 0.5 db at 1625 nm per incoming fiber during the test from the initial value constitutes a failure. A change of more than 0.1 db at 1310 mm, 1550 nm and 1625 nm per incoming fiber after the test from the initial value constitutes a failure. Note: The above mentioned loss criteria are per incoming fiber. Since one circuit can contain several incoming fibers, it is possible that the total circuit generates higher losses. In this case the loss contribution per incoming fiber needs to be checked. This can be done by OTDR or by reducing the number of incoming fibers per circuit.
Page 12 of 26 3.3.4 Flexure (tightness evaluation) This test simulates cable/closure manipulation and focuses on cable seal performance. Testing shall be performed in accordance with IEC 61300-2-37. Testing shall be done at -15 C and +45 C. Samples shall be conditioned at -15 C or +45 C whilst pressurized internally at 40 kpa regulated. After conditioning, the pressure supply shall be disconnected in such a way that an internal pressure of 40 kpa remains inside the closure. The internal pressure shall be measured and recorded (see page 17). The closure system shall be clamped on a smooth, flat, horizontal surface. Each cable shall be clamped in turn at 400 mm from the end of the base. Cables shall be bent individually to an angle of 30 (or a maximum force application of 500 N) each side of neutral in the same plane. Each bending operation shall be held for 5 minutes. A cable shall then be returned to its original position and the procedure repeated in the opposite direction. The procedure shall be repeated with each cable protruding from the closure system. After 5 cycles on each cable, internal pressure loss shall be checked (page 17) and samples shall be conditioned at room temperature. After conditioning, specimens shall be examined with the unaided eye for damage that would impair product functionality (appearance, page 10). After visual inspection, the samples shall be subjected to the tightness test as described on page 21. 3.3.5 Flexure (optical evaluation) This test simulates cable/closure manipulation and focuses on optical system performance. Movement of the cable can cause fiber movement in the cable to organizer transition inside the closure. Testing shall be performed in accordance with IEC 61300-2-37. The optical test sample shall be built as described on page 14. The active circuit of the test sample shall be connected to the optical test equipment as described on page 11. The closure system shall be clamped on a smooth, flat, horizontal surface. Each cable shall be clamped in turn at 400 mm from the end of the base. Cables shall be bent individually to an angle of 30 (or a maximum force application of 500 N) each side of neutral in the same plane. Each bending operation shall be held for 5 minutes. A cable shall then be returned to its original position and the procedure repeated in the opposite direction. The procedure shall be repeated with each cable protruding from the closure system. The change in attenuation after the test (Residual loss) shall be checked as described on page 11. After completion of the test specimens shall be examined with the unaided eye for damage that would impair product functionality (appearance, page 10).
Page 13 of 26 3.3.6 Impact This test is included to cover the effect of falling objects (by accident), e.g. tools, etc. on the closure. Testing shall be performed in accordance with IEC 61300-2-12, Method B. Testing shall be done at -15 C and +45 C. Samples shall be conditioned at -15 C or +45 C whilst pressurized internally at 40 kpa regulated. After conditioning, the pressure supply shall be disconnected in such a way that an internal pressure of 40 kpa remains inside the closure. The internal pressure shall be measured and recorded (see page 17). A sample shall be placed on a smooth, flat, horizontal surface with its longitudinal axis parallel to it. A steel ball weighing 1 kg shall be suspended at a height of 2 meter above the centre of the test specimen then allowed to fall under the influence of gravity. The test shall be repeated by rotating the closure along its major axis over 90, 180 and 270. After the test, internal pressure loss shall be checked (page 17) and samples shall be conditioned at room temperature. After conditioning, specimens shall be examined with the unaided eye for damage that would impair product functionality (appearance, page 10). After visual inspection, the samples shall be subjected to the tightness test as described on page 21.
Page 14 of 26 3.3.7 Installation of closure (optical evaluation) Checks the influence on the optical performance of a fiber optic channel when a window cut is made and installed in an EN. Sample #1: Single fiber application An optical sample is prepared as follows: The extremities of a looped cable (loose tube SZ construction, 12 fibers/tube, minimum 96 fibers) are brought into a track joint closure (TJ). TJ Fibers spliced in FOSC trays In Fiber Tubes Drop cable Looped Cable Out Note: In order to allow OTDR measurements the minimum recommended length for the cable loop is 50 meter. In the TJ the fibers from one loose tube are spliced to the fibers of the same loose tube at the other cable end in such a way that light will sequentially flow through 10 selected fibers. All fibers from one loose tube are to be stored inside FOSC trays. Splices shall be made using good-quality fusion splices. The fibers of a drop cable are spliced to the above-mentioned circuit to make external connections to a light source and an optical power meter. The remaining dark fibers of the other tubes are routed towards other trays and stored inside. The active circuit of the test sample is connected to the test equipment as described on page 11 and the optical power is recorded. The equipment should not be disconnected during the following installation test. In the middle of the cable loop a window cut shall be made. The uncut looped tubes are brought into the external node (EN) closure. The uncut loose tubes are stored in the loose tube storage area.
Page 15 of 26 TJ Fibers spliced in FOSC trays EN Looped tubes In Fiber Tubes Drop cable Looped Cable Out After the installation of the EN node, the optical power is measured again and compared with the initial value. The change in insertion loss after the test (Residual loss) shall meet the requirements as described on page 11.
Page 16 of 26 Sample #2: 12 FO Ribbon fiber application The extremities of a looped ribbon cable (central core construction, 144 fibers minimum, 12 FO ribbons) are brought into a track joint closure (TJ). In the TJ the ribbons are spliced to the ribbons at the other cable end in such a way that light will sequentially flow through 4 ribbons. All spliced ribbons are to be stored on the tray. Splices shall be made using good-quality fusion splices with heatshrink splice protectors. The ribbons of a drop cable (minimum 4 ribbons) are spliced to the above mentioned circuit to make external connections to a light source and an optical power meter. In total 5 ribbon splices are made on this circuit. One optical ribbon circuit, containing 10 fiber splices, is built. TJ Ribbons spliced in FOSC trays In 1 Out 1 Fibers Ribbons Drop cable Ribbon Cable Loop Note: In order to allow OTDR measurements the minimum recommended length for the cable loop is 50 meter. The remaining dark ribbons are routed towards FOSC trays and stored inside the trays. The position of these trays is randomly chosen, but mixed with the active ribbons of the above mentioned circuits. All circuits of the test sample are connected to the test equipment as described on page 11 and the optical power is recorded for each circuit. The equipment should not be disconnected during the following installation of the external node closure (EN). In the middle of the cable loop a window cut shall be made. The uncut looped ribbons are brought into the EN closure. The uncut ribbon loops are stored in the storage basket. TJ Ribbons spliced in FOSC trays EN Looped ribbons In 1 Out 1 Fibers Ribbons Drop cable Ribbon Cable Loop After the installation of the EN node, the optical power of the circuit is measured and compared with the initial value. The change in attenuation after the test (Residual loss) shall meet the requirements as described on page 11.
Page 17 of 26 3.3.8 Pressure loss during test This is the criterion test for the tightness of a product during the test. The value quoted assumes the difference between 2 pressure measurements made within 12 hours. Testing shall be performed in accordance with IEC 61300-2-38, Method B with pressure losses being calculated from measurements taken before and after a test with: the feeder line removed, using the same pressure measurement equipment, and at equal atmospheric conditions (temperature and pressure). The pressure test equipment shall have a resolution of 0.1 kpa. The maximum time between the 2 measurements shall be 12 hrs (to minimize the changes in atmospheric conditions). A pressure loss of more than 2 kpa will constitute a failure. 3.3.9 Reconfiguration This is the criterion test to check the influence on the optical signal transmission of active circuits after doing typical handling operations that could be performed by the crafts personnel on the product. Testing shall be in accordance with IEC 61300-2-33. The optical test samples shall be built as described on page 14. The active circuit will be connected to optical test equipment as described on page 11. Test procedure The cables are coiled up with the minimum allowed bending diameter of the cable. The following sequence is carried out on the track joint (TJ) closure: Unroll enough cable length from the cable loop to bring the closure to the working area. Rotate the closure in such a way that a torsion of -90 and +90 is created in the cables. Move the closure in such a way that the cables are bent over -30 and +30 at the cable ports of the closure. Mount the closure on an installation table and open the closure. Hinge the trays 5 times from one extreme position towards the other extreme position. Select 2 non-active fibers or ribbons located on the same tray as the active fibers and splice them. Store the spliced fibers in the tray. Close the closure. Coil up the cable respecting the minimum allowed bending diameter of the cable. The optical signal shall be measured after the test. The change in attenuation after the test (Residual loss) shall be checked as described on page 11.
Page 18 of 26 3.3.10 Re-entry This is the criterion test to check the tightness performance of a closure which will be reentered several times during its lifetime. Testing shall be performed in accordance with IEC 61300-2-33. Samples shall be subjected to a tightness test as described on page 21. The test samples shall be sealed off with zero overpressure at room temperature prior to placing in an environmental testing chamber. Samples shall be supported in racks during testing in such a way that they are thermally isolated. There shall be free circulation of air both between specimens and between the specimens and the chamber surfaces. They shall be subjected to minimum 1 cycle defined as follows : Time Temperature or range 4 hrs +20 C 1 hr +20 C to +60 C 4 hrs +60 C 2 hrs +60 C to -30 C 4 hrs -30 C 1 hr -30 C to +20 C 4 hrs +20 C After this cycle, samples shall again be subjected to a tightness test as described on page 21. The closures are opened and resealed. In total 10 re-entries will be carried out on each test sample. After testing, samples shall be examined with the naked eye for signs of defects and subjected to the tightness test described on page 21. 3.3.11 Resistance to aggressive media This test checks the effect of accidental short-term exposure of external parts to various chemicals. The test also simulates possible soil-contamination. Testing shall be according to IEC 61300-2-34. Samples shall be pressurized internally at 40 kpa at room temperature and sealed prior to testing. They shall then be submerged for 5 days in one of the chemicals listed below: ph 2 solution of hydrochloric acid ph 12 solution of sodium hydroxide Kerosene (lamp oil), ISO 1998/I 1.005 Diesel fuel for cars, EN 590. Resistance to petroleum jelly shall be tested by smearing samples with petroleum jelly which has been heated just enough (approximately 70 C) to allow it to be evenly smeared. After testing, undried samples shall be examined with the naked eye for signs of corrosion (appearance, page 10) and subjected to the tightness test described on page 21.
Page 19 of 26 3.3.12 Resistance to stress cracking This test checks the possibility of stress cracking in a detergent solution. Testing shall be according to IEC 61300-2-34. Samples shall be pressurized internally at 40 kpa at room temperature and sealed prior to testing. Test closure systems shall be submerged for 5 days in a 10% solution of Igepal maintained at 50 C. After testing, undried samples shall be examined with the naked eye for cracks (appearance, page 10) and subjected to the tightness test described on page 21. 3.3.13 Salt fog This checks the corrosion resistance of the selected metallic materials on the outside of the closure. It will also show whether the closure can be re-entered after exposure to a corrosive medium. Testing shall be according to IEC 60068-2-11 Test Ka. Samples shall be pressurized internally at 40 kpa at room temperature and sealed prior to testing. Test closure systems shall be placed in the salt fog chamber for 5 days. A 5% NaCl in water solution will be vaporised onto the sample at a temperature of +35 C. The closure shall be opened (dome/base and gel block), and the metal parts shall be examined with the naked eye for signs of corrosion (appearance, page 10). 3.3.14 Shock (optical evaluation) This checks the optical effect of sudden, sharp movements on fiber and splice storage. Testing shall be according to IEC 61300-2-9 and IEC 60068-2-27 Test Ea. The optical test samples shall be built as described on page 14. The active circuit shall be connected to optical test equipment as described on page 11. The cables extending from the test specimens shall be clamped so that they remain parallel to each other during testing. Samples shall be strapped onto a vibration bank and subjected to 3 shocks in each direction (up and down) for 3 mutually perpendicular axes. Shocks shall have a half-sine waveform and an acceleration of 150 m/s² and a duration of 11 ms. The change in attenuation after the test (Residual loss) shall be checked as described on page 11. After completion of the test specimens shall be examined with the unaided eye for damage that would impair product functionality (appearance, page 10).
Page 20 of 26 3.3.15 Static load This test simulates the effect of a person accidentally standing on the closure. Testing shall be performed in accordance with IEC 61300-2-10. Testing shall be done at -15 C and +45 C. Samples shall be conditioned at -15 C or +45 C while pressurized internally at 40 kpa regulated. After conditioning, the pressure supply shall be disconnected in such a way that an internal pressure of 40 kpa remains inside the closure. The internal pressure shall be measured and recorded (see page 17). A static load of 1000N shall be placed at the centre of the closure using a circular compression die of 25 cm² surface area for a period of 10 minutes. The test shall be repeated after rotating the closure over 90 along its major axis. After the test, internal pressure loss shall be checked (page 17) and samples shall be conditioned at room temperature. After conditioning, specimens shall be examined with the unaided eye for damage that would impair product functionality (appearance, page 10). After visual inspection, the samples shall be subjected to the tightness test as described on page 21. 3.3.16 Temperature cycling (tightness evaluation) This is an accelerated ageing test designed to highlight possible material incompatibility. It is also a lifetime simulation of seal integrity. The temperature range selected covers both indoor and outdoor closure applications but may be modified to accommodate cable specifications as necessary. Testing shall be according to IEC 61300-2-22 (and IEC 60068-2-14, Test Nb). For mechanical evaluation (using tightness as the criterion test) installed closure systems shall be pressurized internally at 40 kpa regulated. Samples shall be supported in racks during testing in such a way that they are thermally isolated. There shall be free circulation of air both between specimens and between the specimens and the chamber surfaces. They shall be subjected to 20 cycles defined as follows: Time Temperature or range 2 hr -30 C to +60 C 4 hr +60 C 2 hr +60 C to -30 C 4 hr -30 C After testing, specimens shall be examined with the naked eye (appearance, page 10), and then subjected to the tightness test described on page 21.
Page 21 of 26 3.3.17 Temperature cycling (optical evaluation) This is a lifetime simulation of optical performance. The temperature range selected covers both indoor and outdoor closure applications but may need to be modified (to less severe extremes) to accommodate cable specifications as necessary. The optical test samples shall be built as described on page 14. The active circuit will be connected to optical test equipment as described on page 11. Temperature cycling test shall be according to IEC 61300-2-22. Samples for optical evaluation are closed but not pressurized. Samples shall be supported in racks during testing in such a way that they are thermally isolated, and there shall be free circulation of air both between specimens and between the specimens and the chamber surfaces. They shall be subjected to 20 cycles defined as follows: Time Temperature or range 2 hr -30 C to +60 C 4 hr +60 C 2 hr +60 C to -30 C 4 hr -30 C The change in attenuation during and after the test is checked for each circuit as described on page 11. After completion of the test, specimens shall be examined with the unaided eye for damage that would impair product functionality. 3.3.18 Tightness This is the criterion test to check the integrity of the seals both after installation and after mechanical or environmental testing. Testing shall be performed in accordance with IEC 61300-2-38, Method A (and IEC 60068-2-17 Test Qc). The tightness of installed closures shall be checked by pressurizing to 40 kpa for a period of 15 minutes while immersed just below the surface of a water bath at room temperature. A sample shall be considered tight if there is no continuous stream of air bubbles escaping from it.
Page 22 of 26 3.3.19 Torsion (tightness evaluation) This test simulates cable/closure manipulation and focuses on the performance of the seals of the product. Testing shall be performed in accordance with IEC 61300-2-5. Testing shall be done at -15 C and +45 C. Samples shall be conditioned at -15 C or +45 C while pressurized internally at 40 kpa regulated. After conditioning, the pressure supply will be disconnected in such a way that an internal pressure of 40 kpa remains inside the closure. The internal pressure shall be measured and recorded (see page 17). Each extending cable shall in turn be clamped rigidly at a distance of 400 mm from the closure base. The closure system shall be axially rotated, with the degree of turn restricted to whichever of the following limits is reached first: a torque of 50 Nm a rotation angle of 90 degrees No tensile load is to be applied. It shall be retained in that position for a period of 5 minutes, then be returned to its original position and the procedure repeated in the opposite direction. After 5 cycles on each cable, internal pressure loss shall be checked (page 17) and samples shall be conditioned at room temperature. After conditioning, specimens shall be examined with the unaided eye for damage that would impair product functionality (appearance, page 10). After visual inspection, the samples shall be subjected to the tightness test as described on page 21. 3.3.20 Torsion (optical evaluation) This test simulates cable/closure manipulation and focuses on optical system performance. Torsion of the cable can cause fiber movement in the cable to organizer transition inside the closure. Testing shall be performed in accordance with IEC 61300-2-5. The optical test samples shall be built as described on page 14. The active circuit will be connected to the optical test equipment as described on page 11. The closure systems shall be clamped on a smooth, flat, horizontal surface. Each extending cable shall in turn be clamped rigidly at a distance of 400 mm from the closure end. The closure system shall be axially rotated, with the degree of turn restricted to whichever of the following limits is reached first: a torque of 50 Nm a rotation angle of 90 degrees No tensile load is to be applied. It shall be retained in that position for a period of 5 minutes, then be returned to its original position and the procedure shall be repeated in the opposite direction. This will be repeated for each cable, in total 5 cycles per cable. The change in attenuation after the test (Residual loss) shall be checked as described on page 11. After completion of the test specimens shall be examined with the unaided eye for damage that would impair product functionality (page 10).
Page 23 of 26 3.3.21 Vibration (tightness evaluation) This test simulates cable movement in the ports and tests the performance of the seals. The conditions relate to vibration caused by passing traffic. Testing shall be in accordance with IEC 61300-2-1 (and IEC 60068-2-6, Test Fc). Samples shall be pressurized internally at 40 kpa regulated. The closure shall be mounted horizontally on a vibration bank, the cables shall be clamped at a distance of 500 mm from the closure end. The closure shall be subjected to a vibration test with the following parameters: Parameter Frequency: Cycle: Amplitude: Duration: Value (10 ± 1) Hz Sinusoidal 3 mm 10 days After testing, specimens shall be examined with the naked eye (appearance page 10) and then subjected to the tightness test described on page 21. 3.3.22 Vibration (optical evaluation) This vibration test highlights possible problems caused by resonance effects. The effect on fiber and splice storage is checked. The conditions relate to vibration caused by passing traffic. Testing shall be in accordance with IEC 61300-2-1. The optical test samples shall be built as described on page 14. The active circuit will be connected to optical test equipment as described on page 11. The closure shall be mounted on a vibration bank and shall be subjected to a sweep range of 5-500 Hz at 1 octave/minute with the following parameters: Parameter Value Crossover frequency: 9 Hz Amplitude below 9 Hz: 3.5 mm Acceleration above 9 Hz: 10 m/s² (~ 1 g) The test shall be repeated for each of 3 mutually perpendicular axes, 10 cycles per axis. The change in attenuation after the test (Residual loss) shall be checked as described on page 11. After completion of the test specimens shall be examined with the unaided eye for damage that would impair product functionality (page 10). 3.3.23 Waterhead This test is included to ensure that no obvious defects are present that would affect product performance when the product is immersed in water. Testing shall be according to IEC 61300-2-23, Method 2. The sample shall be sealed without any overpressure at room temperature. The sample is then placed in a sealed water tank, with no wetting agent added. The water pressure inside the tank is brought to an equivalent of a 5-meter water column. After 7 days of immersion the sample is checked for any water ingress.
Page 24 of 26 4 Quality assurance provisions Quality provisions are based upon the philosophy of TQM (Total Quality Management) with a system approved to EN ISO 9001 by Lloyds Register Quality Assurance. 4.1 Responsibility for quality Unless otherwise stated in the purchase order, it shall be the supplier's responsibility to assure qualification and lot conformance to this specification. The supplier may utilize his own or other testing and inspection facilities acceptable to the buyer. 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. For qualification testing to this specification for individual customers, the tests and sample quantities shall be as agreed between Tyco Electronics and the customer. Regular requalification testing shall be performed as defined by the Quality Department (Procedure K3014/001). 4.3 Manufacturing follow-up 4.3.1 Kessel-Lo Components Manufacturing in Kessel-Lo, Belgium, is an integral part of the overall Quality System of the Division 10. Customers are encouraged to audit not only manufacturing, but also other departments. Statistically based in-process control is practiced on all production lines where appropriate, and is conducted on all parameters that govern end-product functionality and performance. The frequency of such control and follow-up is evaluated during capability studies on new equipment and shop floor implementation of the results is determined by the Quality Department. In addition, the information is documented and controlled in the computerized manufacturing specification system. 4.3.2 Sourced Components All suppliers of materials, components or systems manufactured outside the Tyco Electronics facilities are included in the Vendor evaluation/follow-up system defined in TEL 2006/2. As a consequence of this, Tyco Electronics audits relevant suppliers on a regular basis in order to ensure conformance to TQM and specification requirements. Suppliers who do not reach the minimum level of approval are given help to improve their systems. If a supplier has not yet reached this minimum level, but is making adequate progress, outgoing controls at the supplier or incoming controls will be considered, as appropriate, by Tyco Electronics. 10 As managed by the Telecom Outside Plant Business Systems Manual TEL1001 and Quality Procedures TEL 20XX and TEL K30XX.
Page 25 of 26 5 References Reference * Title ASTM G154 Standard Practice for Operating Light- and Water-exposure Apparatus (Fluorescent UV-condensation Type) for Exposure of Non-metallic Materials. EN 590 Automotive Fuels - Diesel - Requirements and Methods of Test. IEC 60068- Basic Environmental Testing Procedures: 2-6 Test Fc: Vibration (Sinusoidal). 2-11 Test Ka: Salt Fog. 2-14 Test Nb: Change of Temperature with specified Rate of Change. 2-17 Test Qc: Sealing Tests - Gas Leakage (Bubble Test). 2-27 Test Ea: Shock Test. IEC 61300- Fiber Optic interconnecting devices and passive components. Part 2: Basic test and measurement procedures: 2-1 Vibration (Sinusoidal). 2-4 Fiber/Cable Retention. 2-5 Torsion/Twist. 2-9 Shock. 2-10 Crush Resistance. 2-12 Impact. 2-22 Change of Temperature. 2-23 Sealing for Non-pressurized Closures of Fiber Optic Devices. 2-26 Salt Mist. 2-33 Assembly and Dissembly of Closures. 2-34 Resistance to Solvents and Contaminating Fluids. 2-37 Cable Bending for Closures. 2-38 Sealing for Pressurized Closures of Fiber Optic Devices. Part 3: Examination and measurements 3-1 Visual Examination 3-3 Monitoring Change In Attenuation And In Return Loss (Multiple Paths). ISO 1998/I Petroleum Industry - Vocabulary - Part 1. ISO 846 Resistance of Synthetic Polymeric Materials to Fungi and Bacteria. ISO 9001 Quality Management Systems - Requirements. ITU-T G.652 Characteristics of Single-Mode Fibre Optic Cable. TEL 1001 Telecom Outside Plant Business Management System Manual. TEL 2006/2 Vendor Programme. TEL K3014/001 Requalification The documents lists here shall form a part of this specification. The version in effect at the date of issue of this specification shall apply, unless otherwise indicated. Other equivalent national standards may be used as substitutes for international ones. * Copies of the documents referred to may be obtained from ASTM European Committee for Standardisation International Electrotechnical Commission International Standards Organisation International Telecommunications Union TEL XXXX www.astm.org www.cenorm.be www.iec.ch www.iso.ch www.itu.int tcomosp@tycoelectronics.com
Page 26 of 26 Tyco Electronics Raychem NV Telecom Outside Plant Diestsesteenweg 692 B-3010 Kessel-Lo, Belgium www.tycoelectronics.com All of this information, including illustrations, is believed to be reliable. Users, however, should independently evaluate the suitability of each product for their application. Tyco Electronics makes no warranties as to the accuracy or completeness of the information and disclaims any liability regarding its use. Tyco Electronics only obligations are those in the Standard Terms and Conditions of Sale for this product and in no case will Tyco Electronics be liable for any incidental, indirect or consequential damages arising from the sale, resale, use or misuse of the product. Tyco Electronics Specifications are subject to change without notice. In addition, Tyco Electronics reserves the right to make changes in materials or processing, without notification to the Buyer, which do not affect compliance with any applicable specification. Tyco, Raychem and FOSC are trademarks. Copyright Tyco Electronics 2001