7 C.F.R. § 1755.860
(a) Scope.
(1) This section covers the requirements for filled buried wires intended for direct burial as a subscriber drop and/or distribution wire.
(2) The number of pairs and gauge size of conductors which are used within the RUS program are provided in the following table:
| American Wire Gauge (AWG) | 22 | 24 |
| Pairs | 2 | 2 |
| 3 | 3 |
(b) Conductors and conductor insulation.
(2) The minimum conductor elongation in the final wire must comply with the following limits when tested in accordance with ASTM E 8-91.
| Conductor—AWG | Minimum Elongation—Percent |
|---|---|
| 22 | 20 |
| 24 | 16 |
(4)
(ii) Engineering Information: The sizes of wire used and their nominal diameters shall be as shown in the following table:
| AWG | Nominal Diameter | |
|---|---|---|
| Millimeters (mm) | (Inches (in.)) | |
| 22 | 0.643 | (0.0253) |
| 24 | 0.511 | (0.0201) |
(5) Each conductor must be insulated with either a colored, solid, insulating grade, high density polyethylene or crystalline propylene/ethylene copolymer or with a solid natural primary layer and a colored, solid outer skin using one of the insulating materials listed in paragraphs (b)(5)(i) through (b)(5)(ii) of this section.
(7) A permissible overall performance level of faults in conductor insulation must average not greater than one fault per 12,000 conductor meters (40,000 conductor feet) for each gauge of conductor.
(ii) The voltages for determining compliance with the requirements of this section are as follows:
| AWG | Direct Current Voltages (Kilovolts) |
|---|---|
| 22 | 6.0 |
| 24 | 5.0 |
(10) Colored insulating material removed from or tested on the conductor, from a finished wire, must be capable of meeting the following performance requirements:
| Property | Polyethylene | Crystalline Propylene/Ethylene Copolymer |
|---|---|---|
| Melt Flow Rate | ||
| Percent increase from raw material, Maximum | ||
| <0.5 (Initial Melt Index) | 50 | — |
| 0.5-2.00 (Initial Melt Index) | 25 | — |
| ≤5.0 (Initial Melt Index) | — | 110 |
| Tensile Strength—Minimum | ||
| Megapascals (MPa) | 16.5 | 21.0 |
| (Pounds per Square Inch (psi)) | (2,400) | (3,000) |
| Ultimate Elongation | ||
| Minimum, Percent | 300 | 300 |
| Cold Bend | ||
| Failures, Maximum | 0/10 | 0/10 |
| Shrinkback | ||
| Maximum, mm (in.) | 10 (0.375) | 10 (0.375) |
| Oxygen Induction Time | ||
| Minimum, Minutes | 20 | 20 |
(11) Testing procedures. The procedures for testing the insulation samples for compliance with paragraph (b)(10) of this section must be as follows.
(iv) Shrinkback. Samples of insulation must be tested for four hours in accordance with ASTM D 4565-90a. The temperature for the type of material is listed as follows:
| Material | Temperature |
|---|---|
| Polyethylene | 115 ±1 °C |
| Crystalline propylene/ethylene Copolymer | 130 ±1 °C |
(c) Identification of pairs and twisting of pairs.
(1) The insulation must be colored to identify:
(2) The colors to be used to provide identification of the tip and ring conductor of each pair are shown in the following table:
| Pair No. | Color | |
|---|---|---|
| Tip | Ring | |
| 1 | White | Blue |
| 2 | White | Orange |
| 3 | White | Green |
(9) An alternative method of forming the two pair wire is the use of a star-quad configuration.
(iv) The following color scheme must be used to provide identification of the tip and ring conductor of each pair in the star-quad:
| Pair No. | Color | |
|---|---|---|
| Tip | Ring | |
| 1 | White with blue stripe | Blue |
| 2 | White with orange stripe | Orange |
(d) Forming of the wire core.
(e) Filling compound.
(4) The filling compound must exhibit the following dielectric properties at a temperature of 23 ±3 °C when measured in accordance with ASTM D 150-87 or ASTM D 4872-88.
(f) Core wrap (optional).
(g) Inner jacket.
(h) Flooding compound.
(i) Shield.
(1) A shield must be applied either longitudinally or helically over the inner jacket.
(3) General requirements for application of the shielding material are as follows:
(4) The following materials are acceptable for use as wire shielding:
| Standard Wire | Gopher Resistant Wire |
|---|---|
| Copper Alloy 220 (Bronze) | Copper-Clad Stainless Steel |
| (0.1016 ±0.0076 mm) | 0.1270 ±0.0127 mm |
| (0.0040 ±0.0003 in.) | (0.0050 ±0.0005 in.) |
| Copper Alloy 220 (Bronze) | Copper Alloy 664 |
| 0.1270 ±0.0127 mm | 0.1397 ±0.0127 mm |
| (0.0050 ±0.0005 in.) | (0.0055 ±0.0005 in.)Copper-Clad Alloy Steel0.1270 ±0.0127(0.0050 ±0.0005 in.) |
(i) The copper-clad steels and copper alloy 664 shielding tapes must be capable of meeting the following performance requirements prior to application to the wire:
| Property | Requirement |
|---|---|
| Tensile Strength | |
| Minimum, MPa (psi) | 379 (55,000) |
| Tensile Yield | |
| Minimum, MPa (psi) | 241 (35,000) |
| Elongation | |
| Minimum, percent in 50 mm (2 in.) | 15 |
(j) Outer jacket.
(3) The raw material used for the outer jacket must be one of the five types listed in paragraphs (j)(3)(i) through (j)(3)(v) of this section. The raw material must contain an antioxidant to provide long term stabilization and the materials must contain a 2.60 ±0.25 percent concentration of furnace black to provide ultraviolet shielding. Both the antioxidant and furnace black must be compounded into the material by the raw material supplier.
(4) The outer jacketing material removed from or tested on the wire must be capable of meeting the following performance requirements:
| Property | LLDHMW, Ethylene Copolymer | LDHMW Polyethylene | HD or MD Polyethylene |
|---|---|---|---|
| Melt Flow Rate Percent increase from raw material Maximum | 50 | 50 | |
| <0.41 (Initial Melt Index) | 100 | — | — |
| 0.41-2.00 (Initial Melt Index) | 50 | — | — |
| Tensile Strength Minimum, MPa (psi) | 12.0 (1,700) | 12.0 (1,700) | 16.5 (2,400) |
| Ultimate Elongation Percent, Minimum | 400 | 400 | 300 |
| Shrinkback Percent of Length, Maximum | 5 | 5 | 5 |
| Impact Failures, Maximum | 2/10 | 2/10 | 2/10 |
(5) Testing procedures. The procedures for testing the jacket samples for compliance with paragraph (j)(4) of this section must be as follows:
(7) Eccentricity. The eccentricity of the jacket must not exceed 43 percent when calculated using the formula as follows:

(k) Sheath slitting cord (optional).
(l) Identification marker and length marker.
(m) Electrical requirements—(1) Mutual capacitance and conductance.
(4) Far-end crosstalk loss.
(i) The output-to-outputfar-end crosstalk loss (FEXT) between any pair combination of a completed wire when measured in accordance with ASTM D 4566-90 at a test frequency of 150 kHz must not be less than 58 decibel/ kilometer (dB/km) (63 decibel/1000 ft). If the loss Ko at a frequency Fo for length Lo is known, then Kx can be determined for any other frequency Fx or length Lx by:

(5) Attenuation. The attenuation of any individual pair on any reel of wire must not exceed the following limits when measured at or corrected to a temperature of 20 ±1 °C and a test frequency of 150 kHz. The test must be conducted in accordance with ASTM D 4566-90.
| Conductor AWG | Individual Pair Attenuation dB/km (decibel/mile (dB/mile)) | |
|---|---|---|
| Maximum | Minimum | |
| 22 | 6.8 (11.0) | 5.0 (8.1) |
| 24 | 8.7 (14.0) | 6.6 (10.7) |
(7) High voltage test.
(i) In each length of completed wire, the insulation between conductors when tested in accordance with ASTM D 4566-90 must withstand for 3 seconds a direct current (dc) potential whose value is not less than:
(8) Conductor resistance. The dc resistance of any conductor must be measured in the completed wire in accordance with ASTM D 4566-90 and must not exceed the following values when measured at or corrected to a temperature of 20 ±1 °C.
| AWG | Maximum Resistance | |
|---|---|---|
| ohms/kilometer | (ohms/1000 ft) | |
| 22 | 57.1 | (17.4) |
| 24 | 90.2 | (27.5) |
(9) Resistance unbalance.
(4) Water penetration test.
(o) Acceptance testing and extent of testing.
(2) For initial acceptance, the manufacturer must submit:
(5) Tests on 100 percent of completed wire.
(6) Capability tests. Tests on a quality assurance basis must be made as frequently as is required for each manufacturer to determine and maintain compliance with:
(p) Summary of records of electrical and physical tests.
(q) Manufacturing irregularities.
(r) Preparation for shipment.
(6) Each reel must be stenciled or labeled on either one or both sides with the name of the manufacturer, year of manufacture, actual shipping length, an inner and outer end sequential length marking, description of the wire, reel number and the RUS wire designation:
Wire Designation BFW Wire Construction Pair Count Conductor Gauge N = Copper Alloy 220 (Bronze) Shield Y = Gopher Resistant Shields Example: BFWY 3-24 Buried Filled Wire, Gopher Resistant Shield, 3 pair, 24 AWG
(7) Both ends of the filled buried wire, manufactured to the requirements of this section, must be equipped with end caps which are acceptable to RUS.
(The information and recordkeeping requirements of this section have been approved by the Office of Management and Budget under the control number 0572-0059)
Appendix A to § 1755.860—Qualification Test Methods (I) The test procedures described in this appendix are for qualification of initial designs and major modifications of accepted designs. Included in (V) of this appendix are suggested formats that may be used in submitting test results to RUS. (II) Sample Selection and Preparation. (1) All testing must be performed on lengths removed sequentially from the same 3 pair, 22 gauge jacketed wire. This wire must not have been exposed to temperatures in excess of 38 °C since its initial cool down after sheathing. The lengths specified are minimum lengths and if desirable from a laboratory testing standpoint longer lengths may be used. (a) Length A shall be 10 ±0.2 meters (33 ±0.5 feet) long and must be maintained at 23 ±3 °C. One length is required. (b) Length B shall be 12 ±0.2 meters (40 ±0.5 feet) long. Prepare the test sample by removing the inner and outer jacket, shield, and core wrap, if present, for a sufficient distance on both ends to allow the insulated conductors to be flared out. Remove sufficient conductor insulation so that appropriate electrical test connections can be made at both ends. Coil the specimen with a diameter of 15 to 20 times its sheath diameter. Three lengths are required. (c) Length C shall be one meter (3 feet) long. Four lengths are required. (d) Length D shall be 300 millimeters (1 foot) long. Four lengths are required. (e) Length E shall be 600 millimeters (2 feet) long. Four lengths are required. (f) Length F shall be 3 meters (10 feet) long and must be maintained at 23 ±3 °C for the duration of the test. Two lengths are required. (2) Data Reference Temperature. Unless otherwise specified, all measurements shall be made at 23 ±3 °C. (III) Environmental Tests—(1) Heat Aging Test—(a) Test Samples. Place one sample each of lengths B, C, D, and E in an oven or environmental chamber. The ends of sample B must exit from the chamber or oven for electrical tests. Securely seal the oven exit holes. (b) Sequence of Tests. After conditioning the samples are to be subjected to the following tests: (i) Water Immersion Test outlined in (III)(2) of this appendix; (ii) Water Penetration Test outlined in (III)(3) of this appendix; . (iii) Insulation Compression Test outlined in (III)(4) of this appendix; and (iv) Jacket Slip Strength Test outlined in (III)(5) of this appendix. (c) Initial Measurements. (i) For sample B, measure the open circuit capacitance and conductance for each pair at 1 and 150 kilohertz and the attenuation at 150 kilohertz after conditioning the sample at the data reference temperature for 24 hours. Calculate the average and standard deviation for the data of the 3 pairs on a per kilometer (per mile) basis. (ii) The attenuation at 150 kilohertz may be calculated from open circuit admittance (Yoc) and short circuit impedance (Zsc) or may be obtained by direct measurement of attenuation. (iii) Record on suggested formats attached in (V) of this appendix or on other easily readable formats. (d) Heat Conditioning. (i) Immediately after completing the initial measurements, condition the sample for 14 days at a temperature of 65 ±2 °C. (ii) At the end of this period note any exudation of filling compound. Measure and calculate the parameters given in (III)(1)(c) of this appendix. Record on suggested formats attached in (V) of this appendix or on other easily readable formats. (iii) Cut away and discard a one meter (3 foot) section from each end of length B. (e) Overall Electrical Deviation. (i) Calculate the percent change in all average parameters between the final parameters after conditioning with the initial parameters in (III)(1)(c) of this appendix. (ii) The stability of the electrical parameters after completion of this test must be within the following prescribed limits: (A) Capacitance. The average mutual capacitance must be within 5 percent of its original value; (B) The change in average mutual capacitance must be less than 5 percent over the frequency range of 1 to 150 kilohertz; (C) Conductance. The average mutual conductance must not exceed 2 micromhos/kilometer (3.3 micromhos/mile) at a frequency of 1 kilohertz; and (D) Attenuation. The attenuation must not have increased by more than 5 percent over its original value. (2) Water Immersion Electrical Test—(a) Test Sample Selection. The 10 meter (33 foot) section of length B must be tested. (b) Test Sample Preparation. Prepare the sample by removing the inner and outer jacket, shield, and core wrap, if present, for a sufficient distance to allow one end to be accessed for test connections. Cut out a series of 2.5 millimeter by 13 millimeter (0.1 inch by 0.5 inch) rectangular slots along the test sample, at 300 millimeter (1 foot) intervals progressing successively 90 degrees around the circumference of the wire. Assure that the wire core is exposed at each slot by slitting the inner jacket and core wrap if present. Place the prepared sample in a dry vessel which when filled will maintain a one meter (3 foot) head of water over 6 meters (20 feet) of uncoiled wire. Extend and fasten the ends of the wire so they will be above the water line and the pairs are rigidly held for the duration of the test. (c) Capacitance and Conductance Testing. Measure the initial values of mutual capacitance and conductance of all pairs in each wire at a frequency of 1 kilohertz before filling the vessel with water. Be sure the wire shield is grounded to the test equipment. Fill the vessel until there is a one meter (3 foot) head of water on the wires. (i) Remeasure the mutual capacitance and conductance after the wires have been submerged for 24 hours and again after 30 days. (ii) Record each sample separately on the suggested formats attached in (V) of this appendix or on other easily readable formats. (d) Overall Electrical Deviation. (i) Calculate the percent change in all average parameters between the final parameters after conditioning with the initial parameters in (III)(2)(c) of this appendix. (ii) The stability of the electrical parameters after of the test must be within the following prescribed limits: (A) Capacitance. The average mutual capacitance must be within 5 percent of its original value; and (B) Conductance. The average mutual conductance must not exceed 2 micromhos/kilometer (3.3 micromhos/mile) at a frequency of 1 kilohertz. (3) Water Penetration Testing. (a) A watertight closure must be placed over the jacket of length C. The closure must not be placed over the jacket so tightly that the flow of water through preexisting voids or air spaces is restricted. The other end of the sample must remain open. (b) Test per Option A or Option B. (i) Option A. Weigh the sample and closure prior to testing. Fill the closure with water and place under a continuous pressure of 10 ±0.7 kilopascals (1.5 ±0.1 pounds per square inch gauge) for one hour. Collect the water leakage from the end of the test sample during the test and weigh to the nearest 0.1 gram. Immediately after the one hour test, seal the ends of the wire with a thin layer of grease and remove all visible water from the closure, being careful not to remove water that penetrated into the core during the test. Reweigh the sample and determine the weight of water that penetrated into the core. The weight of water that penetrated into the core must not exceed 1 gram. (ii) Option B. Fill the closure with a 0.2 gram sodium fluorscein per liter water solution and apply a continuous pressure of 10 ±0.7 kilopascals (1.5 ±0.1 pounds per square inch gauge) for one hour. Catch and weigh any water that leaks from the end of the wire during the one hour period. If no water leaks from the sample, carefully remove the water from the closure. Then carefully remove the outer jacket, shield, inner jacket and core wrap, if present, one at a time, examining with an ultraviolet light source for water penetration. After removal of the inner jacket and core wrap, if present, carefully dissect the core and examine for water penetration within the core. Where water penetration is observed, measure the penetration distance. The distance of water penetration into the core must not exceed 127 millimeters (5.0 inches). (4) Insulation Compression Test. (a) Test Sample D. Remove inner and outer jacket, shield, and core wrap, if present, being careful not to damage the conductor insulation. Remove one pair from the core and carefully separate, wipe off core filler and straighten the insulated conductors. Retwist the two insulated conductors together under sufficient tension to form 10 evenly spaced 360 degree twists in a length of 100 millimeters (4 inches). (b) Sample Testing. Center the mid 50 millimeters (2 inches) of the twisted pair between two smooth rigid parallel metal plates measuring 50 millimeters (2 inches) in length or diameter. Apply a 1.5 volt direct current potential between the conductors, using a light or buzzer to indicate electrical contact between the conductors. Apply a constant load of 67 newtons (15 pound-force) on the sample for one minute and monitor for evidence of contact between the conductors. Record results on suggested formats attached in (V) of this appendix or on other easily readable formats. (5) Jacket Slip Strength Test—(a) Sample Selection. Test sample E from (III)(1)(a) of this appendix. (b) Sample Preparation. Prepare test sample in accordance with the procedures specified in ASTM D 4565-90a. (c) Sample Conditioning and Testing. Remove the sample from the tensile tester prior to testing and condition for one hour at 50 ±2 °C. Test immediately in accordance with the procedure specified in ASTM D 4565-90a. A minimum outer jacket slip strength of 67 newtons (15 pound-force) is required. Record the load attained. (6) Humidity Exposure. (a) Repeat steps (III)(1)(a) through (III)(1)(c)(iii) of this appendix for separate set of samples B, C, D and E which have not been subjected to prior environmental conditioning. (b) Immediately after completing the measurements, expose the test sample to 100 temperature cyclings. Relative humidity within the chamber must be maintained at 90 ±2 percent. One cycle consists of beginning at a stabilized chamber and test sample temperature of 52 ±1 °C, increasing the temperature to 57 ±1 °C, allowing the chamber and test samples to stabilize at this level, then dropping the temperature back to 52 ±1 °C. (c) Repeat steps (III)(1)(d)(ii) through (III)(5)(c) of this appendix. (7) Temperature Cycling. (a) Repeat steps (III)(1)(a) through (III)(1)(c)(iii) of this appendix for separate set of samples B, C, D and E which have not been subjected to prior environmental conditioning. (b) Immediately after completing the measurements, subject the test sample to 10 cycles of temperature between −40 °C and + 60 °C. The test sample must be held at each temperature extreme for a minimum of 1 1/2 hours during each cycle of temperature. The air within the temperature cycling chamber must be circulated throughout the duration of the cycling. (c) Repeat steps (III)(1)(d)(ii) through (III)(5)(c) of this appendix. (IV) Control Sample—(1) Test Samples. A separate set of lengths for samples A, C, D, and E must have been maintained at 23 ±3 °C for at least 48 hours before the testing. (2) Repeat steps (III)(2) through (III)(5)(c) of this appendix except use length A instead of length B. (3) Surge Test. (a) One length of sample F must be used to measure the breakdown between conductors while the other length of F must be used to measure core to shield breakdown. (b) The samples must be capable of withstanding, without damage, a single surge voltage of 20 kilovolts peak between conductors, and 35 kilovolts peak between conductors and the shield as hereinafter described. The surge voltage must be developed from a capacitor discharge through a forming resistor connected in parallel with the dielectric of the test sample. The surge generator constants must be such as to produce a surge of 1.5 × 40 microseconds wave shape. (c) The shape of the generated wave must be determined at a reduced voltage by connecting an oscilloscope across the forming resistor with the wire sample connected in parallel with the forming resistor. The capacitor bank is charged to the test voltage and then discharged through the forming resistor and test sample. The test sample will be considered to have passed the test if there is no distinct change in the wave shape obtained with the initial reduced voltage compared to that obtained after the application of the test voltage. (V) The following suggested formats may be used in submitting the test results to RUS:
| PAIR NUMBER | CAPACITANCE | CONDUCTANCE | ||
|---|---|---|---|---|
| nF/km | (nF/mile) | micromhos/km | (micromhos/mile) | |
| Initial | Final | Initial | Final | |
| 1 | ________ | ________ | ________ | ________ |
| 2 | ________ | ________ | ________ | ________ |
| 3 | ________ | ________ | ________ | ________ |
| Average x | ________ | ________ | ________ | ________ |
| Overall Percent Difference in Average x Capacitance:____________________________ Conductance: ____________________________ |
| PAIR NUMBER | CAPACITANCE | CONDUCTANCE | ATTENUATION | |||
|---|---|---|---|---|---|---|
| nF/km | (nF/mile) | micromhos/km | (micromhos/mile) | dB/km | (dB/mile) | |
| Initial | Final | Initial | Final | Initial | Final | |
| 1 | ______ | ______ | ______ | ______ | ______ | ______ |
| 2 | ______ | ______ | ______ | ______ | ______ | ______ |
| 3 | ______ | ______ | ______ | ______ | ______ | ______ |
| Average x | ______ | ______ | ______ | ______ | ______ | ______ |
| Overall Percent Difference in Average x Capacitance:______________________ Conductance: ______________________ Attenuation:______________________ |
| PAIR NUMBER | CAPACITANCE | CONDUCTANCE | ||||
|---|---|---|---|---|---|---|
| nF/km | (nF/mile) | micromhos/km | (micromhos/mile) | |||
| Initial | 24 hours | Final | Initial | 24 hours | Final | |
| 1 | ______ | ______ | ______ | ______ | ______ | ______ |
| 2 | ______ | ______ | ______ | ______ | ______ | ______ |
| 3 | ______ | ______ | ______ | ______ | ______ | ______ |
| Average x | ______ | ______ | ______ | ______ | ______ | ______ |
| Overall Percent Difference in Average x Capacitance:____________________________ Conductance: ____________________________ |
| Option A | Option B | |||
|---|---|---|---|---|
| End Leakage grams | Weight Gain grams | End Leakage grams | Penetration mm (in.) | |
| Control | __________ | __________ | __________ | __________ |
| Heat Age | __________ | __________ | __________ | __________ |
| Humidity Exposure | __________ | __________ | __________ | __________ |
| Temperature Cycling | __________ | __________ | __________ | __________ |
| Failures | |
|---|---|
| Control | ________________ |
| Heat Age | ________________ |
| Humidity Exposure | ________________ |
| Temperature Cycling | ________________ |
| Load in newtons (pound-force) | |
|---|---|
| Control | ________________ |
| Heat Age | ________________ |
| Humidity Exposure | ________________ |
| Temperature Cycling | ________________ |
| Heat Age | ________________ |
| Humidity Exposure | ________________ |
| Temperature Cycle | ________________ |
| Conductor to Conductor | ________________ |
| Shield to Conductors | ________________ |
Appendix B to § 1755.860—Sheath Slitting Cord Qualification (I) The test procedures described in this appendix are for qualification of initial and subsequent changes in sheath slitting cords. (II) Sample Selection. All testing must be performed on two 1.2 meters (4 feet) lengths of wire removed sequentially from the same 3 pair, 22 gauge jacketed wire. This wire must not have been exposed to temperatures in excess of 38 °C since its initial cool down after sheathing. (III) Test Procedure. (1) Using a suitable tool, expose enough of sheath slitting cord to permit grasping with needle nose pliers. (2) The prepared test specimens must be maintained at a temperature of 23 ±1 °C for at least 4 hours immediately prior to and during the test. (3) Wrap the sheath slitting cord around the plier jaws to ensure a good grip. (4) Grasp and hold the wire in a convenient position while gently and firmly pulling the sheath slitting cord longitudinally in the direction away from the wire end. The angle of pull may vary to any convenient and functional degree. A small starting notch is permissible. (5) The sheath slitting cord is considered acceptable if the cord can slit the jacket and/or shield for a continuous length of 0.6 meter (2 feet) without breaking the cord.
Appendix C to § 1755.860—Thermal Reel Wrap Qualification (I) The test procedures described in this appendix are for qualification of initial and subsequent changes in thermal reel wraps. (II) Sample Selection. All testing must be performed on two 450 millimeter (18 inch) lengths of wire removed sequentially from the same 3 pair, 22 gauge jacketed wire. This wire must not have been exposed to temperatures in excess of 38 °C since its initial cool down after sheathing. (III) Test Procedure. (1) Place the two samples on an insulating material such as wood, etc. (2) Tape thermocouples to the jackets of each sample to measure the jacket temperature. (3) Cover one sample with the thermal reel wrap. (4) Expose the samples to a radiant heat source capable of heating the uncovered jacket sample to a minimum of 71 °C. A 600 watt photoflood lamp or an equivalent lamp having the light spectrum approximately that of the sun shall be used. (5) The height of the lamp above the jacket shall be 380 millimeters (15 inches) or a height that produces the 71 °C jacket temperature on the unwrapped sample. (6) After the samples have stabilized at the temperature, the jacket temperatures of the samples must be recorded after one hour of exposure to the heat source. (7) Compute the temperature difference between the jackets. (8) For the thermal reel wrap to be acceptable to RUS, the temperature differences between the jacket with the thermal reel wrap and the jacket without the reel wrap must be greater than or equal to 17 °C.
Note: Quality assurance testing at a jaw separation speed of 500 mm/min (20 in./min) is permissible. Failures at this rate must be retested at the 50 mm/min (2 in./min) rate to determine section compliance.
[58 FR 61004, Nov. 19, 1993, as amended at 60 FR 1711, Jan. 5, 1995; 69 FR 18803, Apr. 9, 2004]