In the field of power systems, reactive power management is crucial to ensure efficient and reliable operation. The use of capacitors is crucial when compensating capacitive reactive power. However, capacitors are often susceptible to the harmful effects of harmonic currents, closing surge currents and operating process voltages. These factors can lead to capacitor damage and reduced power factor. In order to alleviate these problems, a series reactor must be installed, such as the CKSG series low-voltage series reactor. The function of the reactor is to suppress and absorb harmonics, protect capacitors, reduce the impact of harmonic voltages and currents, improve power quality, and increase system power factor.
The CKSG series of low voltage series reactors play a key role in solving the challenges associated with capacitive reactive power compensation. This reactor protects capacitors from potential damage caused by harmonic currents and closing inrush currents by effectively suppressing and absorbing harmonics. In addition, it can also reduce the impact of harmonic voltages and currents, thereby improving power quality and ensuring reliable operation of the power system.
The installation of CKSG series low-voltage series reactors helps improve the system power factor. By reducing the effects of harmonic currents and voltages, reactors allow capacitors to operate more efficiently, thereby improving the overall power factor. This not only optimizes power system performance but also helps save energy and reduce operating costs.
CKSG series low-voltage series reactor is a key component in the pursuit of excellent power quality and efficient reactive power compensation. Its ability to suppress harmonics, protect capacitors, and improve power factor makes it an indispensable asset in modern power systems. By incorporating this reactor into the system design, operators can ensure the reliability, efficiency and longevity of their power infrastructure while optimizing power quality and performance.
1.The filtering reactor is divided into two types: three-phase and single-phase, both of which are iron core dry type.
2.The iron core adopts high-quality and low loss imported cold-rolled oriented silicon steel sheets, and the core column is divided into uniform small sections by multiple air gaps. The air gaps are separated by epoxy laminated glass cloth plates and bonded with special adhesives to ensure that the reactance air gap does not change during operation.
3.The coil is wound with H-grade or C-grade enameled flat copper wire, arranged tightly and evenly.
4.After assembling the coil and iron core of the reactor into one, it undergoes a process of pre drying,vacuum impregnation, and heat curing. H-grade impregnation paint is used to firmly bond the coil and iron core of the reactor.
5.The clamps and fasteners of the reactor are made of non-magnetic materials to ensure a high quality factor and good filtering effect.
6.The exposed components are all treated with anti-corrosion measures, and the outgoing terminals are made of tinned copper tube terminals.