Traditional frequency AC motor output cables typically use unshielded cables or laying trough line tube in solid conductors. This wiring method in preventing noise radiation and cause the motor and cable fault these two serious problems. Using continuous welded aluminum armored cable is a solution, however, engineers found that this would lead to high costs, but also need to install this cable in a larger bend radius, very inconvenient to use. Belden VFD Variable Frequency Drive Cables withstand 600 volts, meet UL 1277 TC cable specifications, with excellent shielding characteristics, high durability, flexible, very practical. The cable conductor beyond the requirements of the thick XLPE (cross linked polyethylene) insulation, the insulation on the electrical aspects not only has the advantage of polyethylene, synthetic rubber also has the durability and dielectric strength. The cable conductors have moisture resistance, can be used in a wet environment, without worrying about the conductor insulation problems, leading to a dangerous electrical short or costly downtime. Another 85% coverage tinned copper braid shield, there are entirely consistent with the conductor diameter tinned copper ground wire, and 100% foil shield so that the cable has so far minimal ground resistance and VFD applications, the most efficient shielding effect. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Practical and economical solution Reduce costs (costs only viable alternative to the cheapest 1/3 to 1/2) For a variety of installation environments (see specifications on the second page presentation) Ease of use Absolutely valid double shielded Thicker insulation moisture Reduces the capacitance |
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Wide range of applications | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
230V Allen Bradley 1336 Plus/Plus II A/B Driver Model Belden VFD Cable Type 1336F(S) - AQF05 29500 1336F(S) - AQF10 29500 1336F(S) - AQF15 29500 1336F(S) - AQF20 29500 1336F(S) - AQF30 29500 1336F(S) - AQF50 29500 1336F(S) - A07 29501 1336F(S) - A010 29502 1336F(S) - A015 29503 1336F(S) - A020 29504 1336F(S) - A025 29505 1336F(S) - A030 29505 1336F(S) - A040 29506 1336F(S) - A050 29507 460V Allen Bradley 1336 Plus/Plus II | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
(VFD) Cable | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Specification UL 1277 Type TC Cable Division NEC ARTICLE 340 Open Wiring UL 44 subjects; NEC RHW-2 single Class I & II, Div 2 area CSA AWM I/II A/B; 1kV RW90 single 90 degree C (Wet/Dry), SUN RES, DIR BUR Conductor: Highly flexible, stranded tinned copper wire Insulation: XLPE (black numbered, green is the ground wire) Shield: 100% Beldfoil Foil shield and 85% tin copper clad (TCB) braid shield Sheath: industrial grade PVC (black) Ground: the same size with the conductor, XLPE insulated (green) Flame Test: UL1581 vertical trough IEEE1202 vertical slot 70,000 BTU/HR | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Belden VFD Cable Solutions In order to avoid failure of the motor and cable, Belden has an ultra-conventional thickness of conductor insulation, it has a more suitable electrical performance, and more long-term durability. Thickening of the insulating layer can provide two benefits: 1 reduces the capacitance so as to achieve a more effective and comprehensive power transfer, and improves the life of the motor and the cable. 2 increasing the distance between the conductors, reducing the air gap between the conductors in the electric potential of the accumulation, thus reducing the possibility of corona discharge. Only when all these precautions are exceeded, the thermal insulation of solid will be melted. Conductor failure THHN wire or other thermoplastic insulation on electrical cables can cause overall system failure. PWM on the cable due to the energy of waves which cause the single-core wire on a high potential. High potential cause small air gap between the conductor corona discharge. High temperatures generated by corona discharge melting heat shaping insulation, which could cause cable failure. (See figure below) | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
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