KR940012843A - Parallel power factor improvement method and device - Google Patents

Abstract

The present invention can be applied to any load, and provides a modular general-purpose parallel power factor improvement method having a practical value without considering the characteristics or size of the load. The apparatus of the present invention includes a main control wiring board, several sub-power factor wiring boards, and an energy storage device installed in the sub power factor wiring board and directly in parallel with the load. Under the influence of the load, the power current equivalent to the load current is in phase with the power supply voltage and replaced with a sine wave current whose amplitude varies with the size of the load, thereby providing a power factor adjusting current to improve the power factor, and By correcting the power supply current and power supply voltage in the same phase, the magnitude of the amplitude is also exactly equal to the size of the load.

Description

Parallel power factor improvement method and device

As this is a public information case, the full text was not included.

1 is a simplified diagram of the present invention,

2 is an electric circuit diagram of the present invention,

3 is an automatic control loop diagram of the present invention,

4 is an embodiment in a state in which the present invention is parallel.

Claims (10)

In the modular general-purpose parallel power factor improvement method applicable to any load, a signal synchronized with the power supply voltage Vi is obtained, and the signal is a unit in phase where the central control unit (CPU) 36 is equal to the power supply voltage Vi. Based on the generation of sinusoidal wave (I sin wt), the pulse width control level (direct current level) that varies according to the magnitude of the load is obtained, multiplied by the unit sinusoid of? Generates a reference sine wave that varies according to the magnitude, detects the waveform change and magnitude of the power supply current, compares it with the reference sine wave of ㈏, obtains a differential signal, and adjusts the pulse width in response to the differential signal of 차동 를 By controlling the switching switch of the energy accumulator 80 in parallel with the load by the control pulse of ㈑ 축적 to accumulate or release the appropriate energy in the energy accumulator 80 By generating a power factor adjusting current (I pfc) which ensures a waveform of the power supply current, and forcibly converts the power supply current into a current waveform that is completely equivalent to the reference sine wave. Modular Generalized Parallel Power Factor Correction. 2. The modular general-purpose parallel according to claim 1, wherein the step of claim 1 is a phase detection method to obtain a synchronization signal of a power supply voltage from a transmission line between a power supply and a load. Power factor improvement method. The method of claim 1, wherein the step of claim 1 is achieved by one voltage feedback control loop, and the control variable of the loop is a negative feedback signal proportional to the engine accumulation capacitor in the energy storage device 80. Compared to the reference variable (direct current reference voltage) of the modular general-purpose parallel power factor improvement method that can be applied to any load, characterized in that it is possible to obtain a pulse width control level that varies with the size of the load. The method of claim 1, wherein the step ㈐ is achieved by one current feedback control loop, and the control variable of the loop is a power supply current capable of detecting a waveform change and magnitude by a current transformer, and the reference variable is a reference sine wave of the step ,, Modular general-purpose parallel power factor improvement that can be applied to any load, characterized in that the control variable is obtained by comparing the control variable with the reference variable in a negative feedback manner, and the power factor adjustment current described in step 가 is generated. Way. The method according to claim 1, wherein the energy storage device 80 of the stepper is a booster circuit which can be directly parallel to the load, and its inlet end is a controllable bidirectional directional electronic switch. Applicable Modular Universal Parallel Power Factor Correction Method. One main control wiring board 10 and a plurality of sub-power factor wiring boards 90 to be combined with the main control wiring board 10, among which the main control wiring board mainly outputs the reference sine wave to each sub power factor wiring board 90, and The power factor wiring board mainly detects the waveform change and the magnitude of the power current and compares it with the reference sine wave again, and is a standard for controlling the energy storage device 80. Power factor improvement method. 7. The main control wiring board (10) according to claim 6, wherein the main control wiring board (10) includes a DC power generator (20), a control device (30), a triangular perth generator (40), and a relay controller (50). ) Is a self-regulating regulated power switch (RCC circuit), and the DC input power obtained from the transmission path between the power supply and the load mainly by the rectifier (D) and the low wave capacitor is required for each part of the present invention. Switching to a power source, the input terminal can be paralleled with an energy storage capacitor, and sends a feedback signal proportional to the DC bus voltage from the energy storage capacitor to the controller 30, and the power controller 30 is mainly one The DC reference potential is generated by the DC reference voltage generator 31, and this DC reference potential is compared with the bus voltage feedback signal at the input terminal of the DC power generator 20 in the voltage feedback controller 63. Is proportional to the error amplifier 62 Amplification at the low pulse width control level and output to the DC-AC converter 33, and the power controller 30 centers the synchronization signal of the power supply voltage from the transmission line by one transformer 35 combined with a phase detector. The central control unit generates a unit sine wave of the same phase as the power supply voltage and inputs the DC alternating current to the control unit 36 according to the sine wave generation program of the storage unit 37 based on the synchronization signal. The sinusoidal sinusoidal wave and the pulse width control level are mutually multiplied by the DC alternating current converter 33 to output a reference sine wave of one power supply voltage and the same phase from the DC alternating current converter 33, and the reference sine wave also Generated by low pass and correction by the low pass filter 61, and the generated clean sinusoidal wave is output from the control device 30 to the current feedback controller 63 of the sub-power factor wiring board 90, and a triangular pulse generator. 40 It generates mainly high frequency triangular pulses, sends them to the energy accumulation control device 70 and uses them for pulse width modulation, and the relay relay controller 50 is controlled by the central control device 36. In this case, when the operation of the DC power generator 20 and the control device 30 becomes normal and when the energy storage capacitor and the low wave capacitor in the energy storage device are charged to an appropriate level, the command of the central controller 36 is performed. According to the present invention, the control signal is generated and the relay switch installed at the front end of the energy storage device 80 is operated so that the entire negative power factor wiring board 90 is provided with a step of preventing overcurrent. Modular universal parallel power factor improvement method. In the modular general-purpose parallel power factor improving device applicable to any load described in claim 6, the sub-power factor wiring board is mainly a current transformer (CT) which detects a power current and outputs the detected signal to a low-pass filter. The signal is compared with the reference sine wave generated by the control device 30 in the current feedback controller 65 in a low-frequency pass through the circuit 61 and then in a negative feedback manner, and the comparison result is obtained by the error amplifier 62. A power supply current detector 60 which is amplified proportionally to a differential signal and inputted to the comparator 71 of the energy storage control body 70, and a triangular pulse generator 40 when the differential signal is input to the comparator 71; The pulse width modulates the differential signal by the high-frequency triangular pulse sent from the pulse width), and outputs the control pulse relative to the differential signal from the comparator 71, and the control pulse is again the dead time generator 72 and the gate driver ( 73 is processed by the energy storage device 80 and is output to the energy storage device 80 to control the opening and closing of the switching transistor of the energy storage device, and the gate driver 73 of the energy storage control device 70; It is a kind of boosting circuit controlled by the control circuit, which is mainly composed of four bridge-shaped switching transistors, and is an electronic switch for controlling the entrance and exit of energy, and the energy accumulator 80 which boosts and accumulates energy by the choke coil 83 and the energy condenser. Modular universal parallel power factor improvement method comprising the. In the modular general-purpose parallel power factor improving device applicable to any of the loads described in claims 6 and 8, the sub-power factor wiring board 90 is modularized, and in some cases, directly with the load. Modular universal parallel power factor improvement device, characterized in that it can be extended in a parallel manner, it can be controlled by the same main control wiring board (10). In the modular general-purpose parallel power factor improving device applicable to any of the loads described in claims 6 and 8, the sub-power factor wiring board 90 is parallel to more than the actual load due to the redundancy, so that the reliability of the system can be applied. Modular universal parallel power factor improving device that can be applied to any load, characterized in that to increase the. ※ Note: The disclosure is based on the initial application.