JP3873203B2 - Speed control apparatus and method for wound induction machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a speed control device and method for a wound-rotor induction machine using Scherbius method of control using the regenerative inverter chopper secondary power for a wound-rotor induction machine, in particular, a plurality of wound-rotor induction machine The present invention relates to a technology for variable speed control.
[0002]
[Prior art]
As a conventional apparatus, as described in JP-A-6-105598, a control apparatus for a plurality of induction motors using a stationary Serbius apparatus has been proposed. This control device supplies the sum of the output currents of the forward converters connected to the electric motors to the reverse converter, and controls the electric motor by controlling the firing angle of the reverse converter. In this case, the speeds of the plurality of electric motors cannot be controlled independently. In addition, in this Serbius device, the power factor of the inverse converter is poor near the synchronous speed, that is, when the slip is near zero, and on the contrary, at the time of start-up, the slip needs to withstand a large voltage equivalent to 1. There exists a problem that the capacity | capacitance of the transformer connected between an inverter and an inverter and an alternating current power supply system becomes large.
As a technique for solving the problems of the inverse converter and the transformer capacity, there is a method described in, for example, Japanese Patent Application Laid-Open No. 60-91890. This method uses a Serbius method in which the secondary power of the induction machine is controlled using a chopper and a regenerative inverter, and a low-cost device can be realized compared to a conventional Serbius device. For this control, it was necessary to provide a capacitor, an inverse converter, a transformer, and the like for each electric motor.
[0003]
[Problems to be solved by the invention]
In the above prior art, there are problems that the speeds of a plurality of winding type induction motors cannot be controlled independently, and that a plurality of capacitors, inverters and transformers are required.
An object of the present invention, the circumstances in view, the respectively independently control the speed of the plurality of wound-rotor induction motor, yet compact, the speed control apparatus and method for a wound-rotor induction machine that enables cost reduction of the apparatus Is to provide.
[0004]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, a switching element is connected directly or via a reactor between the DC output terminals of the forward converters connected to the secondary side of each of the plurality of winding induction machines, and the plurality of winding inductions In order to control the rotation speed of each machine independently, a speed control that controls on / off of the switching element to control the output current of the forward converter according to the deviation between the rotation speed of the winding induction machine and its command value And a common capacitor is connected to each speed control means via a diode in parallel with the switching element of each speed control means, and the output current of the forward converter is connected to the common capacitor when the operation of the switching element is off. connect to the direction leading to further connect the inverter between the common capacitor terminal, be those for regenerating the secondary power for a wound-rotor induction machine to said AC power source, the speed The switching phase setting means for shifting the phase of the PWM carrier signal of the control means is provided, shifting the switching phases for each switching element.
[0005]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a speed control device for an induction machine according to an embodiment of the present invention, and shows a configuration of a speed control device for a plurality of wound induction motors.
In FIG. 1, 1 is an AC power supply system, 2a to 2c are winding induction motors, and 3a to 3c are forward converters (diode rectifiers) that convert secondary voltages of the winding induction motors 2a to 2c into DC. Reference numerals 6a to 6c denote speed detectors directly connected to the respective winding induction motors 2a to 2c, which detect and output the speeds of the respective winding induction motors. Reference numerals 7a to 7c denote current detectors which detect and output the output currents of the forward converters 3a to 3c. Reference numerals 8a to 8c denote speed control circuits which receive a signal output from the speed detectors 6a to 6c and a signal output from the current detectors 7a to 7c, and based on these signals, a self-extinguishing element (IGBT). A control signal for turning on and off 4a to 4c is calculated and output. Reference numerals 5a to 5c denote backflow prevention diodes, and the output currents of the forward converters 3a to 3c flow to the capacitor 9 when the self-extinguishing elements 4a to 4c are in the off state. Reference numeral 10 denotes an inverter (IGBT inverter) for regenerating the total power of the secondary power of each of the winding induction motors 2a to 2c to the AC power source 1, and 11 is a transformer for the inverter. Reference numeral 12 denotes a current detector that detects and outputs the output current of the inverse converter 10. A voltage detector 13 detects and outputs a DC voltage between the terminals of the capacitor 9. Reference numeral 14 denotes a control device for the inverse converter 10, which receives a signal output from the current detector 12 and a signal output from the voltage detector 13, and outputs a control signal for the inverse converter 10 based on this signal. .
In addition, between the DC output terminals of the forward converter, that is, between the connection points of the forward converters 3a to 3c and the self-extinguishing element (IGBT) 4a to 4c, or the backflow blocking diodes 5a to 5c and the self-extinguishing element (IGBT). You may insert a reactor between the connection points of 4a-4c.
[0006]
Next, the operation of this embodiment will be described. First, the operation of the speed control portion of each induction motor will be described with reference to FIG. FIG. 2 is a block diagram of a speed control circuit of the winding induction motor 2a in FIG. 1, 2a to 8a and 9 to 14 are the same as those in FIG.
In FIG. 2, 21 is a speed command generator, which outputs a speed command. A speed controller 22 receives the speed command output from the speed command generator 21 and the speed detection value output from the speed detector 6a, and calculates and outputs a current command signal based on this signal. A current controller 23 receives a current command signal output from the speed controller 22 and a current detection signal output from the current detector 7a, and outputs a voltage command signal based on this signal. A PWM controller 24 receives a voltage command signal and a PWM carrier signal output from the current controller 23, compares the voltage command with the PWM carrier signal based on this signal, and turns on / off the self-extinguishing element 4a. Output a control signal.
The rotational speed of the winding induction motor 2a is detected by the speed detector 6a, and is input to the speed controller 22 together with the speed command signal from the speed command generator 21, whereby the rotational speed is controlled to match the speed command. Is done. A current control loop is provided inside the speed control loop as shown in FIG. 2, and the output current of the forward converter 3a is detected by the current detector 7a and is output from the speed controller 22 as a current command signal. At the same time, it is input to the current controller 23, whereby the output current of the forward converter 3a is controlled to match the current command value. A voltage command signal is input from the current controller 23 to the PWM controller 24, where the output voltage of the forward converter 3a is controlled by on / off control of the self-extinguishing element 4a by PWM control, and the forward converter 3a. To control the output current. Since the direct current is controlled in this way, the secondary current and torque of the winding induction motor 2a are controlled to be proportional to the current command, and therefore the rotation speed is controlled following the speed command.
[0007]
Next, the regenerative operation of the secondary power of the winding induction motor will be described. 3A shows the voltage command and PWM carrier signal during speed control, FIG. 3B shows the on / off signal of the self-extinguishing element 4a, FIG. 3C shows the output current signal of the forward converter 3a, and FIG. A current flowing through 5a and a voltage waveform of the capacitor 9 are shown in (e). When the voltage command is larger than the carrier signal, the PWM pulse signal is turned on and the self-extinguishing element 4a is turned on. During this time, the DC output current of the forward converter 3a in FIG. 2 flows through the self-extinguishing element 4a, and at this time, the current flowing through the diode 5a becomes zero. Conversely, when the voltage command is smaller than the carrier signal, the PWM pulse signal is turned off, the self-extinguishing element 4a is turned off, and at this time, a direct current flows through the diode 5a. At this time, the output current of the forward converter 3a increases when the self-extinguishing element 4a is on as shown in FIG. 3C and decreases when it is off. In this way, the output current is controlled according to the voltage command signal. Also, the current of the diode 5a charges the capacitor 9 and increases its voltage. As a result, the secondary power of the winding induction motor 2a is regenerated on the AC power supply side by the operation of the control device 14 of the inverter 10. Here, the circuit composed of the self-extinguishing element 4a, the diode 5a, and the capacitor 9 has an action of converting the secondary power of the winding induction motor 2a whose secondary voltage changes due to slipping into a constant voltage. At this time, the electric power transmitted to the inverter 10 side becomes equal to the secondary electric power of the winding induction motor 2a. The above is the description of the prior art.
Next, this embodiment will be described. By the way, since the speed control part can be controlled independently of the inverter that performs the regenerative operation, the speeds of the plurality of induction motors shown in FIG. 1 can be controlled independently. That is, in the present embodiment, the speed control circuit 8a is configured as 8b and 8c for the plurality of induction machines 2a, 2b, and 2c, and is connected to the common capacitor 9 via the diodes 5a, 5b, and 5c. Connecting. As a result, the secondary power of each of the electric motors 2a, 2b, 2c is accumulated in the capacitor 9 via the diodes 5a, 5b, 5c, and is further regenerated to the AC power supply side by one inverse converter 10.
According to this embodiment, the number of capacitors, inverters and transformers is reduced to 1 / n (n: the number of electric motors) compared to the case where a plurality of conventional devices shown in FIG. 2 are provided. The apparatus can be realized at a low cost, and the speed of each electric motor can be controlled independently.
[0008]
FIG. 4 shows another embodiment of the present invention. 1 is different from FIG. 1 in that a carrier phase setting unit 15 for shifting the phase of the PWM carrier signal of FIG. 3A of each speed control circuit 8a, 8b, 8c is provided. According to this embodiment, compared with FIG. 1, the capacity of the capacitor 9 can be reduced and the cost can be reduced.
Looking at the waveform in FIG. 3, the ripple current component is included in the input current to the capacitor 9, so that the required capacitor capacity increases. As shown in FIG. 1, when a plurality of winding induction motors are controlled independently, the input current flowing from the forward converters 3a, 3b, 3c to the capacitor 9 when the same carrier signal is used. Since these are synchronized, each ripple component is added, the ripple amount increases, and as a result, the capacitor capacity increases. On the other hand, in FIG. 4, the carrier phase is shifted by the setting device 15, for example, 360 degrees / n (n: the number of motors), so that the forward converters 3 a, 3 b, 3 c to the diodes 5 a, 5 b , 5c, the timing of the current ripple flowing through the capacitor 9 is shifted, and as a result, the ripple component of the input current flowing through the capacitor 9 can be smoothed, and the capacitance of the capacitor can be reduced.
[0009]
【The invention's effect】
As described above, according to the present invention, the speed of each induction motor is controlled by each speed control circuit for a plurality of induction motors, and the secondary power generated in each circuit is converted by one inverter. Since the circuit configuration regenerates on the power supply side, the speed control of each motor can be performed independently in a plurality of induction motor drive systems, and the number of system components such as capacitors, inverters and transformers Can be reduced, and downsizing and cost reduction can be achieved.
Further, in each speed control circuit, the ripple component can be reduced by shifting the switching phase of the self-extinguishing element in each circuit so as to cancel the ripple component generated from each circuit. Can be reduced.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a speed controller for an induction machine showing an embodiment of the present invention. FIG. 2 is a circuit diagram showing a speed controller of the present invention. FIG. 3 is a waveform diagram of a secondary current according to the present invention. 4] Configuration diagram of another embodiment of the present invention [Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... AC power supply system, 2a-2c ... Winding type induction motor, 3a-3c ... Forward converter, 4a-4c ... Self-extinguishing element, 5a-5c ... Diode, 6a-6c ... Speed detector, 7a-7c DESCRIPTION OF SYMBOLS ... Current detector, 8a-8c ... Speed control circuit, 9 ... Capacitor, 10 ... Inverter, 11 ... Inverter transformer. DESCRIPTION OF SYMBOLS 12 ... Current detector, 13 ... Voltage detector 14 ... Inverter control device, 21 ... Speed command generator, 22 ... Speed controller, 23 ... Current controller, 24 ... PWM controller

Claims (2)

A winding that performs speed control while regenerating secondary power of the winding type induction machine to the AC power source by connecting the secondary side of the plurality of winding type induction machines to an AC power source through a forward converter and an inverse converter. In the linear induction machine speed control device,
A switching element is connected directly or via a reactor between the DC output terminals of each of the forward converters connected to the secondary side of each of the plurality of winding induction machines, and the rotational speed of the plurality of winding induction machines In order to control each independently, a speed control means for on / off controlling the switching element to control the output current of the forward converter according to the deviation between the rotational speed of the winding induction machine and its command value. Provided,
A common capacitor is connected to each speed control means via a diode in parallel with the switching element of the speed control means, and the output current of the forward converter is changed to the common when the operation of the switching element is off. Connecting in a direction leading to a capacitor, further connecting the inverse converter between terminals of the common capacitor, and regenerating secondary power of the wire wound induction machine to the AC power source ,
A speed control device for a winding induction machine, characterized in that switching phase setting means for shifting the phase of the PWM carrier signal of each speed control means is provided, and the switching phase is shifted for each of the switching elements. The secondary side of a plurality of wound induction machines is connected to an AC power supply via a forward converter and an inverse converter, and the speed is controlled while regenerating secondary power of the wound induction machine to the AC power supply. In the linear induction machine speed control method,
A switching element is connected directly or via a reactor between the DC output terminals of each of the forward converters connected to the secondary side of each of the plurality of winding induction machines, and the speed of the plurality of winding induction machines A speed control means for controlling the switching element, and a common capacitor is connected in parallel to the switching element via a diode,
The switching element is turned on / off to control the output current of the forward converter according to the deviation between the rotational speed of the wire wound induction machine and its command value by the speed control means, and when the operation of the switching element is turned off An output current of the forward converter is caused to flow through the common capacitor through the diode, and the rotational speeds of the plurality of winding induction machines are independently controlled, and further connected between terminals of the common capacitor. Regenerating secondary power of the wire wound induction machine from the inverse converter to the AC power source ,
A speed control method for a winding induction machine, characterized in that a switching phase is shifted with respect to each switching element by a switching phase setting means for shifting the phase of a PWM carrier signal provided in each speed control means.

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