JP5965277B2 - Capacitor device - Google Patents

Description

  The present invention relates to a capacitor device used for a phase advance for adjusting a power factor of a load and a filter for reducing harmonics.

  For example, as disclosed in Patent Document 1, for example, as disclosed in Patent Document 1, a capacitor device is provided between a power source and a load for phase advance for adjusting the power factor of the load or for a filter for reducing harmonics. Yes. Moreover, in order to prevent the deterioration and damage of the apparatus due to overcurrent, providing an overcurrent relay for detecting overcurrent has been conventionally performed as disclosed in, for example, Patent Document 2. FIG. 2 illustrates the capacitor device. In the figure, C is a capacitor, SR is a series reactor, CT is a current transformer, and OCR is an overcurrent relay.

Japanese Patent Laid-Open No. 10-145976 JP 7-255122 A

  By the way, as for a capacitor | condenser apparatus, an installation capacity | capacitance and a reactance value change with the change of a frequency. Therefore, for example, if a capacitor device manufactured assuming use at 60 Hz is used at 50 Hz, the intended power factor improvement effect and high frequency reduction effect cannot be obtained.

  While providing a dedicated capacitor and reactor for each frequency and switching the capacitor and reactor according to the frequency, it is possible to obtain the effect as intended, but in this case, this leads to an increase in the size of the device, It is not realistic because it leads to cost increase.

  In addition, since the current value changes when the frequency changes, it is necessary to readjust the setting of the overcurrent relay as the frequency is switched.However, the operation is complicated and the adjustment may be forgotten. There is also a risk of causing deterioration and damage of the apparatus.

  Accordingly, the present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a capacitor device that can be shared at different frequencies while suppressing the increase in size and cost of the device. Yes.

  In order to solve the above problems, a capacitor device of the present invention is a capacitor device including a capacitor unit 10 connected to a power source that outputs AC power, and a reactor unit 20 connected in series with the capacitor unit 10. The capacitor unit 10 is connected when the AC power frequency is the first frequency and the second frequency, and is connected when the AC power frequency is the first frequency. And connected to the shared capacitor 11 via the first switch 40 that is disconnected when the frequency is the second frequency, and compensates for fluctuations in equipment capacity (phase-advanced capacity) that accompany frequency switching. The capacitor device further includes an overcurrent relay 30 for detecting an overcurrent flowing through the capacitor unit 10 or the reactor unit 20. The overcurrent relay 30 is characterized by being configured so as to switch the number of turns of the winding 31 in response to a first frequency and a second frequency.

  According to the capacitor device of the present invention, since the adjustment capacitor for compensating for the difference in the equipment capacity accompanying the switching of the frequency is provided, the frequency applied to the capacitor device is changed from the first frequency to the second frequency, or Even when the frequency is switched from the second frequency to the first frequency, the reactance value can be kept constant by changing the capacitance of the capacitor portion accordingly, while the reactor portion can be shared. For this reason, a power factor improvement effect and a harmonic reduction effect can be exhibited irrespective of whether the frequency of AC power is the first frequency or the second frequency. In this way, it is not necessary to provide a dedicated capacitor or reactor for each frequency by using the common capacitor and the reactor part and covering the difference in equipment capacity due to frequency switching with the adjustment capacitor. The increase in size and cost can be suppressed.

  In addition, the overcurrent relay is configured to switch the number of turns of the winding in accordance with the frequency, so that the value of the moving magnetic field generated by the winding can be kept constant even if the current value fluctuates due to the switching of the frequency. This eliminates the need to readjust the setting of the operating current value of the overcurrent relay.

It is a circuit diagram showing a capacitor device concerning an embodiment of the present invention. It is a circuit diagram which shows the conventional capacitor | condenser apparatus.

  Next, an embodiment of a capacitor device of the present invention will be described in detail with reference to the drawings. The capacitor device 1 is connected between a power source that outputs three-phase AC power and a load, thereby improving the power factor and reducing harmonics. Specifically, as shown in FIG. 1, a capacitor unit 10 connected to a power supply, a reactor unit 20 connected in series with the capacitor unit 10, and an overcurrent flowing through the capacitor unit 10 and the reactor unit 20 are detected. Even if the applied frequency is switched from 50 Hz (first frequency) to 60 Hz (second frequency) or from 60 Hz to 50 Hz, the same power factor is provided. It is configured to obtain an improvement effect and a harmonic reduction effect. Hereinafter, the components of the capacitor device 1 will be described individually.

  As illustrated in FIG. 1, the capacitor unit 10 includes a shared capacitor 11 and an adjustment capacitor 15.

  As shown in FIG. 1, the shared capacitor 11 is Δ-connected to a capacitor 12 provided for each phase, a discharge resistor 13 is provided in parallel with each capacitor 12, and two of the three phases In addition, the fuse 14 is interposed.

  Also in the adjustment capacitor 15, as shown in FIG. 1, capacitors 16 provided for each phase are Δ-connected, and a discharge resistor 17 is provided in parallel with each capacitor 16, and further three-phase The two phases are configured by passing fuses 18. The adjustment capacitor 15 is connected in parallel to the shared capacitor 11 via the first switch 40.

  The capacity of the adjusting capacitor 15 is the equipment capacity when the AC power frequency is 50 Hz and the AC power frequency is 60 Hz when the adjusting capacitor 15 is disconnected. It is made equal to the difference (fluctuation) generated between the equipment capacity of the system. Specifically, when the equipment capacity of the apparatus when the frequency of AC power is 60 Hz is 1, the equipment capacity of the apparatus when the frequency of AC power is 50 Hz is 1 / 1.2 (50 / 60), the capacity that can compensate for this difference, that is, 0.2 / 1.2 (1-50 / 60) is the capacity of the adjustment capacitor 15 at 50 Hz.

  The first switching device 40 interposed between the shared capacitor 11 and the adjusting capacitor 15 switches between connection and disconnection of the three phases simultaneously by interlocking the circuit breakers 41 provided for each phase. It is configured to be able to. This first switcher 40 is switched by a switching signal from the outside of the apparatus so that it is connected when the frequency of AC power is 50 Hz and is disconnected when the frequency of AC power is 60 Hz. Made. Therefore, when the frequency of the AC power is 60 Hz, only the shared capacitor 11 functions, and when the frequency of the AC power is 50 Hz, the adjustment capacitor 15 functions in addition to the shared capacitor 11, and the reactance value is 50 Hz. And when it is 60 Hz. The switching of the first switching device 40 is preferably performed by, for example, providing a frequency meter separately and switching by a switching signal automatically input based on the measurement result of the frequency meter. You can go.

  As shown in FIG. 1, the reactor unit 20 is provided so as to be interposed between the power source and the capacitor unit 10. Specifically, the reactor unit 20 includes a reactor 21 provided in each phase, and these reactors 21 are connected in series with the capacitors 12 and 16, respectively. In the reactor unit 20 as well, the reactance value fluctuates by switching the frequency. However, as described above, the capacitance of the capacitor unit 10 is adjusted according to the frequency, so that the reactance value of the apparatus is maintained. The reactor unit 20 can be shared by 50 Hz and 60 Hz.

  As described above, the capacitor device 1 having the above-described configuration includes the adjustment capacitor 15 that compensates for the fluctuation in the equipment capacity of the device that accompanies the switching of the frequency, so that the frequency applied to the capacitor device 1 is changed from 60 Hz to 50 Hz. Or even when switched from 50 Hz to 60 Hz, the reactance value of the device can be kept the same. Moreover, the reactor part 20 can be shared and the same power factor improvement effect and harmonic reduction effect can be exhibited when the frequency of AC power is 60 Hz and when it is 50 Hz. In addition, since the shared capacitor 11 and the reactor unit 20 are regularly used, and the adjustment capacitor 15 covers the fluctuation of the equipment capacity that accompanies the frequency switching, there is no need to provide a dedicated capacitor or reactor for each frequency. Therefore, it is possible to suppress the increase in size and cost of the apparatus, and it is also possible to reduce the environmental load.

  Moreover, in the capacitor | condenser apparatus 1 of this invention, as shown in FIG. 1, the overcurrent relay (static type) 30 is provided through the current transformer 50 between the reactor part 20 and the power supply. This overcurrent relay 30 is a through type formed by penetrating the winding 31 and the iron core 32. By passing a secondary current from the current transformer 50 to the winding 31, the overcurrent relay 30 passes through a rectifying / smoothing circuit and a determination circuit (not shown). A signal indicating an overcurrent is issued. The overcurrent signal activates a circuit breaker (not shown) to disconnect the power supply and the device, thereby preventing deterioration and damage of the device due to overcurrent.

  By the way, as shown in FIG. 1, the winding 31 is formed by making 6 rotations (6 turns) around the iron core 32. In addition, a bypass path 33 that bypasses the lowest one turn is formed at the fifth turn from the top in the figure. The bypass path 33 is connected to a second switch 60 provided between the current transformer 50 and the winding 31.

  The second switch 60 is a lap contact switch in which, when the two switches 61 are interlocked so that one of the paths is connected, the other path is disconnected. Thus, when the frequency of the AC power is 50 Hz, the number of turns of the winding 31 is 5 turns, and when the frequency of the AC power is 60 Hz, the number of turns of the winding 31 is changed to 6 turns. It is done. This configuration is for dealing with fluctuations in current value caused by frequency switching. More specifically, if the current value when the frequency of the AC power is 60 Hz is 1, the current value when the frequency of the AC power is 50 Hz is 1.2 (60/50). As a result, the iron core The value of the current flowing to the 32 side is also 1.2 times. Therefore, the number of turns of the winding 31 at 50 Hz is 1 / 1.2 (50/60) times that at 60 Hz, and the current value flowing through the rectifying and smoothing circuit is kept constant.

  With this configuration, even if the frequency of the AC power is switched from 60 Hz to 50 Hz or from 50 Hz to 60 Hz, the value of the current flowing through the overcurrent relay 30 can be kept constant. Therefore, it is not necessary to replace the current transformer 50 according to the current value or readjust the setting of the operating current value and the like of the overcurrent relay 30. Note that the switching of the second switching device 60 can be performed by a switching signal used for switching of the adjustment capacitor 15 in addition to the manual switching. In this case, forgetting to switch can be prevented, leading to suppression of malfunction, deterioration and damage of the apparatus.

  Although specific embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the present invention. For example, in the above embodiment, the first frequency is 50 Hz and the second frequency is 60 Hz, but the first frequency is 60 Hz and the second frequency is 50 Hz, that is, for adjustment when the frequency is 60 Hz. The capacitor 15 may be connected and disconnected at 50 Hz. In this case, the capacitance of the capacitor unit 10 can be adjusted by connecting the shared capacitor 11 and the adjustment capacitor 15 in series.

  In the above embodiment, the number of turns of the winding 31 at 60 Hz is 6 turns and the number of turns of the winding 31 at 50 Hz is 5 turns, but the relationship of 60 Hz: 50 Hz = 6: 5 is maintained. However, the number of turns may be changed as appropriate. Further, in the above embodiment, the three-phase circuit is used, but the same effect can be obtained even with a single-phase circuit. Further, the position of the current transformer 50 is not limited to between the power source and the reactor unit 20, but may be other parts, and the number of the current transformers 50 can be changed as appropriate. Further, the connection method of the capacitors 12 and 16 is not limited to the Δ connection, and various known methods such as a Y connection and a V connection may be used.

1 ·· Capacitor device 10 ·· Capacitor part 11 ·· Shared capacitor 15 ·· Adjustment capacitor 20 ·· Reactor part 30 ·· Overcurrent relay 31 ·· Winding 40 ··· Selector

Claims (1)

  A capacitor device including a capacitor unit (10) connected to a power source that outputs AC power and a reactor unit (20) connected in series with the capacitor unit (10), wherein the capacitor unit (10) A shared capacitor (11) that is connected when the frequency of the AC power is the first frequency and the second frequency, and a connection state when the frequency of the AC power is the first frequency; An adjustment capacitor (which is connected to the shared capacitor (11) via the first switch (40) which is disconnected when the frequency is 2, and compensates for the fluctuation of the equipment capacity due to the frequency switching ( 15), and the capacitor device further includes an overcurrent relay (30) for detecting an overcurrent flowing through the capacitor unit (10) or the reactor unit (20). (30), the capacitor apparatus characterized by being configured to switch the number of turns of the first frequency and the second winding in response to the frequency (31).