Abstract
The dielectric recovery process has decisive effects on the current interruption process in vacuum circuit breakers, which has attracted the special attention of researchers. In commercial vacuum interrupters, ions and electrons of the residual plasma between the contact gap are separated and then fly to the electrodes under the effect of the transient recovery voltage after current zero. During this period, the post-arc current forms. During the formation of the post-arc current, ions also enter the post-arc anode due to their thermal motion. Therefore, the number of net electrons, which form the post-arc current, is only part of the total electrons between the contact gap at current zero. During the post-arc sheath expansion process, almost all electrons in the contact gap will enter the post-arc anode under the effects of the transient recovery voltage. If the proportion of ions and electrons, which enter the post-arc anode, can be obtained, the total number of electrons and consequently the residual plasma density between the contact gap could be estimated from the integration of the post-arc current. In this paper, the influences on the absorption of charged particles by the post-arc anode of some factors, e.g., rising rate of transient recovery voltage and metal vapor, have been simulated and discussed with a one-dimensional particle in cell-Monte Carlo collision model.
Highlights
Nowadays, vacuum circuit breakers (VCBs) have been widely used in the electric power system due to their excellent breaking capability in the current interruption process.1 The whole current interruption process can be divided into two main stages: the arcing phase and the post-arc dielectric recovery process
We found that the rising rate of transient recovery voltage and metal vapor density has obvious influences on the proportion β
The transient recovery voltage (TRV), which is generated by the external circuit, has obvious effects on the post-arc sheath expansion process
Summary
Vacuum circuit breakers (VCBs) have been widely used in the electric power system due to their excellent breaking capability in the current interruption process. The whole current interruption process can be divided into two main stages: the arcing phase and the post-arc dielectric recovery process. Because only a few electrons could enter the post-arc cathode under the effect of the transient recovery voltage, it is possible to estimate the total electrons at current zero if the proportion of ions to electrons absorbed by the post-arc anode is known. The proportion of ions to electrons absorbed by the post-arc anode (this is abbreviated to β below) is useful for the estimation of the residual plasma density and benefits the further study of the postarc dielectric recovery process in vacuum circuit breakers. There have been few discussions about the charged particles absorbed by the post-arc anode in VCBs. Sarrailh and co-workers have studied the influence of the residual plasma density and transient recovery voltage on the percentage of ion current absorbed by the post-arc anode during the post-arc sheath expansion process with the hybrid Maxwell−Boltzmann model. We found that the rising rate of transient recovery voltage and metal vapor density has obvious influences on the proportion β
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