In the actual parallel use of cables, there are many single-core cables in parallel. During the actual parallel use of single-core PE Cables, due to the influence of the laying method, the actual current carrying capacity may not meet the actual load needs, and it may appear in actual use. Overload phenomenon. In fact, when 6 cables are laid in the air and laid side by side with no gap, the actual reflow can only reach about 60% of the theoretical carrying capacity. If the load of the cable is added to the theoretical selection, it is not laid according to the actual installation. Correct the situation. It is very likely that the cable will be in a full-load operation state during the actual power-on process, causing the cable to generate heat during power-on operation. Therefore, in the process of parallel laying of cables, the actual current carrying capacity is not simply a relationship of “1+1=2”. It is very likely that “1+1=1.5” or even “1+1=1” will appear, causing the cable Severe heating occurred during actual operation. Now we give a simple example, such as a three-phase asynchronous motor load with a capacity of 570KW and a rated current of about 1140A. Two YJV-0.6/1KV-1*300 cables are used for power supply in parallel, and the given value is calculated according to the theoretical design. , YJV-0.6/1KV-1*300 single cable is laid in the air, the theoretical calculation current carrying capacity is about 750A, and the theoretical parallel current carrying capacity of two cables can reach about 1500A, which can fully meet the actual use needs of the equipment. We now assume that there are 32 cables that are all concentrated on a bridge, stacked side by side and laid out randomly, and the above two YJV-0.6/1KV-1*300 power supply in parallel are also located in it. After consulting related materials, it is found that when 6 cables are stacked in the air without gaps, the actual current carrying capacity of the cables will drop to 60% of the theoretically calculated value. Then the actual current carrying capacity of the original cable is 1500×60%=900A, and the actual carrying capacity allocated to each cable is about 450A, which is nearly 300A different from the theoretically calculated carrying capacity of 750A, so that the cable will have serious overload and heat during actual use. phenomenon.
And the number of Copper cables actually laid is far more than 6, so the actual cable reflow may be smaller than 900A. How to solve this problem, some people have proposed to connect another YJV-0.6/1KV-1*120 cable in parallel to reduce the current distributed by the other two cables. Now we theoretically assume and calculate that after the three cables are connected in parallel, the load current In the actual distribution situation, assuming that the length of 3 cables used in parallel is 1 km, the laying temperature is all calculated at 20°C. Moreover, it is assumed that the conductor resistances of two YJV-0.6/1KV-1*300 cables connected in parallel for 1 km are exactly the same. In fact, due to manufacturing process problems, it is impossible to achieve complete consistency, and there is still a slight difference in conductor resistance. In the actual calculation process, we ignore the above influence. The maximum DC resistance of copper conductor at 20℃ is 0.0601Ω/km for 300mm2 copper core, 0.153Ω/km for 120 mm2, and the actual distribution calculation of 1140A current
The distribution current of the 120 mm2 cross-section is (0.0601*0.0601/0.153*0.0601+0.153*0.0601+0.0601*0.0601)=187A, and the current distributed on the remaining 300 mm2 cross-section is 953A, and each 300 mm2 cable actually flows The load current is about 477A. In this case, the actual power on of the cable still has an overload phenomenon. The actual disaster flow of the cable 120 in this case is 435*60%=261A, which still has a large margin, but the current distribution law does not distribute the current to the 120 cross-section cable. In fact, The original problem remains unresolved. And our assumption is that there are only 6 cables, which does not meet our established requirements. Imagine adding another cable with a cross-section of 300 mm2. The actual current-carrying capacity distribution law is 1140*1/3=380A. Therefore, in the actual parallel cable process, the cross-section of the cable must be calculated strictly before proceeding. Use in parallel, otherwise the problem may not be solved by adding cables in time. The best case is to use cables with the same specifications and ensure the same length, so as to ensure that the current distribution is basically even. In fact, it is very difficult to re-install and rework the on-site cable after all on-site installation is completed. Therefore, the formal design, laying and installation of the cable in the early stage is very important, and the method adopted in the later stage is often only a remedial measure, and it is difficult to solve the problem fundamentally.
In addition, there are some problems in the parallel use of multi-core cables. For armored cables, the main core A, B, and C of each cable should be staggered in parallel for parallel use of armored cables. All wires of armored multi-core cables cannot be used in parallel. The new parallel connection is used as a single-core cable on one phase. If this is done, an eddy current effect will be generated in the armored steel strip of the cable, which will cause the cable to heat up and cause thermal breakdown. Although this is a very simple principle of electricity, in the process of the author’s many visits to users, sometimes users have asked similar questions and practices. In the three-phase four-wire unbalanced lighting load, the wiring and distribution method of our load should ensure that the load is distributed as evenly as possible, and the three-phase current is balanced as much as possible, otherwise it may be caused by the serious imbalance of the three-phase current. Alternating induced current is generated in the shaped steel strip, which causes heating of the cable.
The parallel use of cables should also pay attention to the tightness of the lugs at the end of each line, because the load capacity of parallel cables is generally relatively large, and the conductor resistance per kilometer is below 0. If it is once at any end of the line Loose wire noses and poor contact will double the conductor resistance of the line, causing uneven current distribution and even bypassing. This will cause individual cables connected in parallel to generate heat and cause malfunctions.
At the same time, the conductor resistances of the actual lines of the cables may not be completely consistent. Therefore, the current distribution of the cables of the same model and specifications cannot be absolutely evenly distributed, and there may be some differences in the actual current distribution process.
Therefore, during the actual parallel use of multiple single-core cables, corrections should be made according to their actual laying conditions, otherwise it may cause heat generation during the parallel use of the cables, which will affect the normal use of the cables.