JP5231614B2 - Induction melting furnace controller - Google Patents

Description

  The present invention relates to a control device for an induction melting furnace that melts a material to be melted stored in the furnace by the heat of a heating coil.

  Conventionally, a voltage type inverter using a switching element is used in a control device of this type of induction melting furnace, and this inverter is operated in a resonance state synchronized with a load resonance frequency. In such a device, the inverter output frequency is adjusted by detecting the phase difference between the output voltage and the output current of the voltage type inverter so that the resonance state can be maintained even when the load resonance frequency changes depending on the state of the material to be melted. It has become.

For example, the following method is known as a control method using the switching element. When the phase difference γ between the output current and the output voltage of the inverter is detected and it is determined that the detected phase difference γ exceeds the phase difference lower limit γ _B , that is, when the load resonance frequency approaches a state where adjustment becomes difficult, In this method, the V / f converter is operated and the output frequency of the inverter is once increased to the maximum frequency for adjustment (Patent Document 1, [0026], [0027], FIGS. 10 and 11).

JP 2004-071444 A

However, in such a conventional control method, control is performed to raise the frequency to the highest frequency every time the phase difference γ exceeds the phase difference lower limit γ _B , so that the resonance state, that is, the state where the power factor is highest is temporarily left. Therefore, it has been difficult to stably heat and dissolve the material to be dissolved while maintaining a high power factor.

  In view of the above circumstances, an object of the present invention is to provide a control device for an induction melting furnace capable of controlling electric power while maintaining a high power factor.

The control apparatus for the induction melting furnace of the first invention is a control apparatus for the induction melting furnace that melts the material to be melted stored in the furnace by the heat of the heating coil,
A high-frequency power generator that generates high-frequency power to be supplied to the heating coil;
A phase difference detector for detecting a phase difference between the voltage and current of the high-frequency power;
A control signal generation unit that generates a control signal of the high-frequency power generation unit so as to generate the high-frequency power according to the phase difference detected by the phase difference detection unit;
The control signal generator (1) changes the control signal so that the phase difference is reduced from a startup frequency preset for the high-frequency power generator, and maintains the predetermined phase difference. (2) When the phase difference reaches a preset threshold value , a correction signal is added to the first control signal to keep the phase difference constant while following the change in the phase difference. generates a second control signal that be greater by a value, (3) said phase when a phase difference is equal to or higher than a preset threshold, characterized by generating the first control signal to maintain a predetermined said phase difference And

  According to the induction melting control apparatus of the first aspect of the invention, since the high frequency power generated by the high frequency power generation unit is supplied to the heating coil, Joule heat is generated in the heating coil, and the material to be melted can be heated and melted. it can.

  The control signal generation unit generates a control signal for controlling the high-frequency power generation unit, and generates high-frequency power corresponding to the phase difference detected by the phase difference detection unit at that time. For this reason, the control signal can be adjusted by changing the phase difference.

  Here, when the phase difference between the voltage and the current of the high-frequency power is zero, the power factor becomes 1 at the maximum. The control signal generation unit generates the control signal so that the power factor is close to 1.

  When the control device is activated, the control signal generation unit generates a control signal so that the phase difference becomes smaller from a preset activation frequency, that is, the power factor approaches 1.

  Further, when the phase difference becomes a preset threshold value, that is, when the power factor decreases and the control of the high frequency power shifts to the unstable region, the control signal generation unit changes the power factor from 1. A control signal for increasing the phase difference by a certain value is generated so as not to leave as much as possible. This is because, unlike the method of starting from the starting frequency again when the phase difference becomes a threshold value, the power factor does not greatly decrease.

  Therefore, the induction melting control apparatus of the first invention can heat and melt the material to be melted while maintaining a high power factor.

  A control device for an induction melting furnace according to a second invention is the control device for an induction melting furnace according to the first invention, wherein the high-frequency power generation unit includes a forward converter that converts AC power into DC power, An inverter that converts the DC power into the high-frequency power by configuring a bridge circuit using two switching elements, and the inverse converter is configured to control the first and second by a control signal of the high-frequency power generator. The DC power is converted into the high-frequency power by alternately operating switching elements.

  According to the control apparatus for an induction melting furnace of the second invention, the high-frequency power generation unit is largely composed of a forward converter and an inverse converter. The forward converter converts AC power (50 Hz or 60 Hz) into DC power.

  Next, the reverse converter converts the DC power generated by the forward converter again into AC power in order to generate electric power to be supplied to the heating coil. Here, the inverse converter has first and second switching elements, and constitutes a bridge circuit.

  When the bridge circuit gives a control signal and operates these switching elements alternately, the path of the direct current flowing through the circuit is sequentially switched, so that high-frequency power to be supplied to the heating coil can be generated.

  Therefore, in the induction melting furnace control device of the second invention, the generation of the high-frequency power supplied to the heating coil can be realized with a simple configuration, and the material to be melted can be heated and melted while maintaining a high power factor. .

A control device for an induction melting furnace according to a third invention is the control device for an induction melting furnace according to the first or second invention, wherein the control signal generator includes a mono-multi circuit, and the phase difference is preset. When the threshold value is reached, a second control signal is generated by generating a correction signal that increases the phase difference by a fixed value by an internal signal output from the mono-multi circuit for a fixed time , and adding the correction signal to the first control signal. Is generated.

  According to the control apparatus for an induction melting furnace of the third aspect of the invention, when the phase difference detected by the phase difference detection unit reaches a preset threshold, the mono-multi circuit that is an oscillator outputs an internal signal for a certain period of time. To do.

  At this time, the control signal generation unit generates a control signal that increases the phase difference by a certain value using the internal signal output from the mono-multi circuit as a trigger.

  Therefore, the control apparatus for the induction melting furnace according to the third aspect of the invention operates to increase the phase difference by a certain value only for a certain period of time when the phase difference becomes a threshold value, and thereafter, while maintaining a high power factor. It is possible to heat and dissolve the melting material.

  According to a fourth aspect of the invention, in the induction melting furnace control device according to any one of the first to third aspects of the invention, the high-frequency power generation unit includes an AC voltage detection unit that detects a voltage of the high-frequency power, and the high-frequency power. An alternating current detection unit that detects the current of the voltage, and the phase difference detection unit uses a rising edge width of the voltage detected by the alternating voltage detection unit as an ON signal, and a reset set flip-flop circuit The output voltage signal generated via the signal and the rising and falling edge widths of the current of the high-frequency power detected by the alternating current detection unit are generated as the ON signal via the reset set flip-flop circuit. A phase difference from the output current signal is detected.

  According to the control apparatus for an induction melting furnace of the fourth invention, the phase difference detection unit generates an output current signal as follows from the voltage of the high frequency power detected by the AC voltage detection unit.

  The output voltage signal is not a high-frequency power voltage itself detected by the AC voltage detection unit, but a signal generated via a reset set flip-flop circuit with an edge width of each rising edge of the voltage as an ON signal. .

  The reset set flip-flop circuit stores a rising edge of the voltage input first and a rising edge of the next input voltage, and outputs a pulse having both edge widths as ON signals. Therefore, the output voltage signal can be generated with a simple circuit.

  The phase difference detector generates an output current signal from the high-frequency power current detected by the alternating current detector as follows.

  The output current signal is not a high-frequency power current detected by the AC current detector, but a signal generated via a reset set flip-flop circuit with the rising and falling edge widths of the current as ON signals. It is.

  Also in this case, the reset set flip-flop circuit stores a rising edge and a falling edge of the input current, and outputs a pulse having both edge widths as ON signals. For this reason, an output current signal can be generated with a simple circuit.

  Therefore, in the induction melting furnace control apparatus according to the fourth aspect of the invention, since the phase difference detection unit detects the phase difference between the output voltage signal and the output current signal output in the above processing, the phase difference can be reliably detected with a simple configuration. It is possible to detect and heat and dissolve the material to be dissolved while maintaining a high power factor.

According to a fifth aspect of the invention, in the induction melting furnace control device according to any one of the first to fourth aspects, the high-frequency power generation unit includes a forward converter that converts AC power into DC power, and a reverse converter for converting the DC power to the high-frequency power by a bridge circuit using a second switching element, the first and second switching elements and wherein the Ah Turkey together with the IGBT element To do.

  According to the control apparatus for an induction melting furnace of the fifth invention, since the first and second switching elements are both IGBT elements, the control signal generation unit starts from a preset start frequency when starting the control apparatus. A control signal for reducing the operating frequency of the IGBT element is generated so that the phase difference becomes small, that is, the power factor approaches 1.

  However, when the phase difference detected by the phase difference detection unit becomes a threshold value, the control signal generation unit increases the phase difference by a certain value. At this time, the control signal generation unit generates a control signal for increasing the operating frequency of the IGBT element.

Therefore, the control for an induction melting furnace of the fifth invention, even when using the IGBT element inverter, prevented from becoming difficult to control the operating frequency, the dissolved material while maintaining a high power factor Can be heated and dissolved.

The whole block diagram which shows the structure of an induction melting furnace and its control apparatus. The block diagram which shows the internal structure of the control circuit in a control apparatus. FIG. 3 is an explanatory diagram showing the contents of the output voltage signal generation circuit of FIG. 2. FIG. 3 is an explanatory diagram showing the contents of the output current signal generation circuit of FIG. 2. (A) Explanatory drawing which shows the content of the phase difference detection circuit of FIG. 2, (b) Explanatory drawing which shows the content of the phase difference correction circuit. (A) Explanatory drawing which shows operation | movement of the phase difference correction circuit in the case of normal delay power factor, (b) Explanatory drawing which shows operation | movement of the phase difference correction circuit when delay power factor is insufficient. Explanatory drawing which shows the example of the phase difference correction control of an inverter operating frequency.

  With reference to FIG. 1, the control apparatus of the induction melting furnace of this embodiment is demonstrated.

  The induction melting furnace melts the material to be melted stored in the furnace by Joule heat generated in the heating coil. The entire apparatus includes a power source 1, a power receiving unit 2, a power conversion device 4, an induction melting furnace 15, and a controller 18. Details of each component will be described below.

  The power source 1 is a rated AC power source (50 Hz or 60 Hz), and is connected to the power receiving unit 2.

  The power receiving unit 2 performs power communication to the induction melting furnace, shuts down, and shuts off the power when a failure occurs. Inside, a power fuse 2a, a circuit breaker 2b, and a converter transformer 3 are provided.

  The power fuse 2a cuts off the current when a short circuit accident occurs. In addition, the circuit breaker 2b performs an opening / closing operation accompanying energization and stop of the power source.

  The transformer 3 for converters adjusts the input voltage to the power converter device 4 so that the power converter device 4 can output a predetermined voltage. A three-phase commercial power source is input to the primary side of the converter transformer 3. A voltage whose phase is advanced by 30 ° with respect to the primary side is output to the secondary side, and a voltage having the same phase as that of the primary side is output from the tertiary side.

  The power conversion device 4 is a device for generating arbitrary high-frequency power from a commercial power supply of 50 Hz or 60 Hz, and is connected to the converter transformer 3. The power conversion device 4 includes a forward converter unit 4a, an inverse converter unit 4b, a high-frequency matching unit 4c, and a control circuit 11 therein.

  The power conversion device 4 corresponds to the control device of the present invention. Further, the forward converter unit 4a, the inverse converter unit 4b, and the high-frequency matching unit 4c constitute a high-frequency power generation unit of the present invention.

  The forward converter unit 4a is a device that converts alternating current into direct current. Inside, there are provided diode-type forward converters (hereinafter abbreviated as forward converters) 5a and 5b constituting an AC / DC converter, and a DC reactor 6 for smoothing the output voltage ripple.

  The inverse converter unit 4b is a device that converts direct current into alternating current. Inside, IGBT type inverse converters (hereinafter abbreviated as inverse converters) 10a and 10b, which are DC / AC converters, are provided. Hereinafter, the inverse converters 10a and 10b may be collectively referred to as an inverter 10.

  IGBT is an abbreviation for Insulated Gate Bipolar Transistor, and is an insulated gate bipolar transistor. The inverse converters 10a and 10b correspond to first and second switching elements of the present invention, respectively.

  As shown in FIG. 1, the reverse converters 10a and 10b and the high frequency capacitors 12a and 12b described later constitute a half-bridge circuit. By alternately turning on and off the reverse converters 10a and 10b, the high frequency voltage Is generated.

  Further, the inverse converter unit 4b includes therein an output ripple of the forward converters 5a and 5b and a DC capacitor 7 for smoothing voltage fluctuations caused by the operation of the inverse converters 10a and 10b, and a DC voltage by detecting a DC voltage. A DC voltage detector 8 that outputs voltage (a) and a DC current detector 9 that detects DC current and outputs DC current (b) are provided.

  Since the DC voltage (a) and the DC current (b) are used to calculate DC power, both signals are input to the control circuit 11. Details of the control circuit 11 will be described later.

  The high frequency matching unit 4c includes power factor adjusting high frequency capacitors (hereinafter abbreviated as high frequency capacitors) 12a and 12b used for adjusting the power factor. The high frequency capacitors 12a and 12b improve the load power factor because the induction melting furnace 15 has a low power factor. Further, a load resonance frequency is generated from the heating coil 16 in the induction melting furnace 15.

  In general, high-frequency capacitors 12a and 12b having the same capacity are used, but operation is possible even if the capacities are different.

  Further, the high-frequency matching unit 4 c includes an energization current detector 13 that detects an energization current (d) that is output from the inverse converters 10 a and 10 b and flows to the heating coil 16, and a load voltage that is applied to the heating coil 16. A load voltage detector 14 for detecting (e) is provided. The energizing current detector 13 corresponds to an alternating current detector of the present invention, and the load voltage detector 14 corresponds to an alternating voltage detector of the present invention.

  The energization current (d) is used for a constant current control ACR described later, and this control protects the inverse converters 10a and 10b from overcurrent. The load voltage (e) is used for voltage constant control AVR described later, and this control protects the high-frequency capacitors 12a and 12b from overvoltage.

  Further, the energization current (d) and the load voltage (e) are input to the control circuit 11 inside the power conversion device 4 to generate control signals for the inverse converters 10a and 10b, that is, the IGBT gate signal (c). Used.

  The induction melting furnace 15 is a device for heating and melting the material to be melted 17. The induction melting furnace 15 includes a heating coil 16 and a material to be melted 17 is accommodated in the furnace. The induction melting furnace 15 generates eddy currents in the material to be melted 17 in the furnace when high frequency power is supplied to the heating coil 16. The material to be melted 17 is heated and melted by Joule heat due to the eddy current and the inherent internal resistance of the material to be melted 17.

  The controller 18 performs operation / stop of the entire apparatus and adjustment of power supply to the material 17 to be melted by a controller control signal (f). In addition, protection is provided to prevent damage and failure of the equipment components.

  Next, the configuration of the control circuit 11 will be described with reference to FIGS.

  First, the internal configuration of the control circuit 11 in the control device will be described with reference to FIG.

  The control circuit 11 in FIG. 2 includes first to third system circuits.

  The circuit of the first system is a circuit that generates a reference frequency mainly used for generating the IGBT gate signal (c), and is a constant voltage control circuit 22, a constant current control circuit 23, and a constant power control circuit. 24, a delay priority circuit 25, and a reference frequency holding circuit 26.

  The circuit of the second system is a circuit that detects a phase difference mainly used for generating the IGBT gate signal (c), and includes an output voltage signal generation circuit 19, an output current signal generation circuit 20, and a phase difference detection circuit. 21a.

  The circuit of the third system is a circuit that generates an IGBT gate signal (c) mainly based on information on the reference frequency and the phase difference, and is a part of the control signal generation unit 30 that includes the phase difference correction circuit 21b and the like. It is.

  First, the first system circuit will be described.

  A constant voltage control circuit (AVR) 22 is a circuit that controls the operating frequency of the inverter 10 when the high-frequency capacitors 12a and 12b are overvoltage.

The load voltage (e) is a voltage applied to the heating coil 16 of the induction melting furnace 15, and is a voltage component of high-frequency power supplied to the heating coil 16 (see FIG. 1). A signal obtained by subtracting the load voltage (e) from the voltage reference V _ref is input to the constant voltage control circuit 22, and the output signal is input to the delay priority circuit 25 described later.

  A constant current control circuit (ACR) 23 is a circuit that controls the operating frequency of the inverter 10 when the inverters 10a and 10b are overcurrent.

The energization current (d) is a current component of the high-frequency power supplied to the heating coil 16 (see FIG. 1). A signal obtained by subtracting the energization current (d) from the current reference I _ref is input to the constant current control circuit 23, and the output signal is input to the delay priority circuit 25 described later.

  A constant power control circuit (APR: Automatic Power Regulator) 24 is a circuit that controls the operating frequency of the inverter 10 so that the output power is constant.

A signal obtained by subtracting the product of the DC voltage (a) and the DC current (b) from the power reference P _ref is input to the constant power control circuit 24, and the output signal is input to the delay priority circuit 25 described later. .

The delay priority circuit 25 constantly detects the output signals of the constant voltage control circuit 22, the constant current control circuit 23, and the constant power control circuit 24, and selects the signal that is most delayed with respect to the reference to the frequency reference _Fref . It is a circuit that adjusts. By this circuit, an inverter frequency reference signal (n1) serving as a reference for operating frequency control of the inverter 10 is generated.

  The reference frequency holding circuit 26 is a circuit for holding the inverter 10 at a reference frequency based on the inverter frequency reference signal (n1). The inverse converters 10a and 10b operate at an operating frequency based on the output signal of this circuit.

  Next, the second system circuit will be described.

  The output voltage signal generation circuit 19 and the output current signal generation circuit 20 are both circuits that generate signals used for phase difference detection. The output voltage signal generation circuit 19 generates an output voltage signal (g) to be described later from the load voltage (e), and outputs this signal to the phase difference detection circuit 21a.

  The output current signal generation circuit 20 generates an output current signal (h) to be described later from the energization current (d) and outputs it to the phase difference detection circuit 21a. The processing contents of the output voltage signal generation circuit 19 and the output current signal generation circuit 20 will be described with reference to FIGS.

  The phase difference detection circuit 21a is a circuit that detects the phase difference between the output voltage signal (g) and the output current signal (h), and can determine the power factor from the detected phase difference. The phase difference detection circuit 21a corresponds to the phase difference detection unit of the present invention. Details of the processing of the phase difference detection circuit 21a will be described with reference to FIG.

  Next, the circuit of the third system will be described.

  The control signal generation unit 30 includes a phase difference correction circuit 21b, a voltage control oscillation circuit 27, an AND gate 28, and a reset / set / flip / flop circuit 29. An inverter frequency reference signal (n1), which will be described later, Alternatively, the IGBT gate signal (c) is generated based on (n2). The control signal generation unit 30 corresponds to the control signal generation unit of the present invention.

  The phase difference correction circuit 21b is a circuit that outputs a signal for correcting the phase difference when a predetermined phase lag occurs and corrects the inverter reference frequency. Details of the processing of the phase difference correction circuit 21b will be described with reference to FIG.

  The voltage controlled oscillation circuit 27 is an oscillator that can change the operating frequency according to the applied voltage. The voltage controlled oscillation circuit 27 sets the operating frequency of the inverter 10 based on the determined inverter frequency reference signal, and outputs a polarity detection signal, a READ signal, and a RESET signal as signals for controlling the inverse converters 10a and 10b. To do.

  Finally, the output signal of the polarity detection signal and the READ signal calculated by the AND gate 28 and the RESET signal are input to the reset set flip-flop circuit 29, and the IGBT gate signal which is the control signal of the inverse converters 10a and 10b. (C) is output.

  Next, the contents of the output voltage signal generation circuit 19 will be described with reference to FIG.

  The output voltage signal generation circuit 19 generates the output voltage signal (g) of the power converter 4 from the gate signal that is the load voltage (e) detected by the load voltage detector 14 as follows.

  As shown in FIG. 3, in the output voltage signal generation circuit 19, the U-phase gate signal 1 that is the gate signal of the inverse converter 10a is input to the dead time adjustment circuit 19a. The U-phase gate signal 1 is a signal that serves as a reference for the gate signal.

  The U-phase gate signal 1 is adjusted in dead time with reference to the X-phase gate signal 2 which is a gate signal adjusted in dead time. Then, signals other than the U-phase gate signal 1 are removed, and the U-phase gate signal 2 whose dead time is adjusted is taken out.

  Here, the dead time is a pause period set between two operations so that the inverse converters 10a and 10b are not turned on simultaneously. The dead time is adjusted by considering the pulse width in consideration of the dead time. It is because it is necessary to change slightly.

  Similarly, the X-phase gate signal 1 which is the gate signal of the inverse converter 10b is input to the dead time adjustment circuit 19b. The X-phase gate signal 1 is a signal that serves as a reference for the gate signal.

  The X-phase gate signal 1 is adjusted in dead time with reference to the U-phase gate signal 2 which is an output signal adjusted in dead time. Then, signals other than the X-phase gate signal 1 are removed, and an X-phase gate signal 2 whose dead time is adjusted is taken out.

  Next, the extracted U-phase gate signal 2 and X-phase gate signal 2 are input to the reset set flip-flop circuit 19c. Here, the reset set flip-flop circuit 19 c stores the rising edges of the U-phase gate signal 2 and the X-phase gate signal 2.

  Finally, the output voltage signal generation circuit 19 outputs an output voltage signal (with a duty ratio of 50%) having a time region (edge width) defined by each rising edge of the U-phase gate signal 2 and the X-phase gate signal 2 as an ON signal. g).

  Next, the contents of the output current signal generation circuit 20 will be described with reference to FIG.

  The output current signal generation circuit 20 generates the output current signal (h) of the power converter 4 based on the energization current (d) detected by the energization current detector 13 as follows.

  As shown in FIG. 4, in the output current signal generation circuit 20, rising and falling of the energization current (d), which is a sine wave detected by the energization current detector 13, are caused by two binarization circuits 20a and 20b, respectively. To detect.

  The energizing current (d) is converted into rectangular waves by the binarization circuits 20a and 20b, and these rectangular waves are input to the reset / set / flip / flop circuit 20c. Here, the reset set flip-flop circuit 20c stores the rising and falling edges of the energization current (d).

  Finally, the output current signal generation circuit 20 generates an output current signal (h) having a duty ratio of 50% with the time region (pulse width) from the rising edge to the falling edge of the energization current as the ON signal. .

  Next, the signal processing contents of the phase difference correction circuit will be described with reference to FIG.

  The phase difference detection circuit 21a shown in FIG. 5A receives the output voltage signal (g) generated by the output voltage signal generation circuit 19 and the output current signal (h) generated by the output current signal generation circuit 20. Then, a phase advance signal (i) and a phase delay signal (j) are output as phase difference information. The phase difference detection circuit 21a includes a plurality of NAND gates 32, and a part of the output signal is fed back for use as the next input.

  Here, both the output voltage signal (g) and the output current signal (h) are rectangular waves, and the deviation between both waveforms is the phase difference. FIG. 5A shows a circuit in which the pulse of the phase advance signal (i) or the phase delay signal (j) changes when either the phase advance or the phase lag occurs. reference). There is no case where the pulses of the phase advance signal (i) and the phase delay signal (j) change simultaneously.

  The relationship between the phase difference and the power factor is “power factor 1” when the phase difference is zero. Further, when the phase of the output current signal (h) is delayed with respect to the output voltage signal (g), it is in a “delay power factor” state, and the phase of the output current signal (h) with respect to the output voltage signal (g). When the is advanced, it is in the state of “advanced power factor”.

  The phase difference correction circuit 21b shown in FIG. 5B determines the phase difference between the two input signals (i) and (j), and generates the phase difference correction signal (m) when the phase difference is smaller than a predetermined value. The inverter frequency reference signal (n1) is changed to (n2). Details of the phase difference correction circuit 21b will be described below.

  First, a phase advance signal (i) and a phase delay signal (j) output from the phase difference detection circuit 21a are input as input signals. The phase advance signal (i) is input to the AND gate 34 via the NOT gate 33 while the phase delay signal (j) is not changed. The first mono-multi circuit (MM) 35a sets the phase difference level based on the internal signal (k1) constantly output from the AND gate 34, and generates an internal signal (k2) for phase difference confirmation.

  Here, the mono-multi circuit is a monostable multi-vibrator, and is an oscillator that generates one pulse by an external control signal.

  Next, the internal signal (k1) and the internal signal (k2) are input to the NAND gate 36, and the internal signal (k3) by NAND operation is output. The internal signal (k3) is output at a low level until a predetermined phase delay state (detailed in the description of FIG. 6). At this time, the internal signal (k4) output from the second mono-multi circuit (MM) 35b is also at the low level, and the phase difference correction signal (m) that is an analog voltage signal set in the analog switch (ASW) 37 in advance. ) Is not output to the adder 38.

  Therefore, (n1) is output as the final inverter frequency reference signal. Here, the inverter frequency reference signal is a reference signal of the operating frequency of the inverters 10a and 10b. In the normal delay power factor state, the operating frequency is kept near the load resonance frequency by continuously outputting this signal. To do.

  On the other hand, when the power factor changes in the advancing direction and the phase difference becomes insufficient below a predetermined value, the internal signal (k3) becomes a pulse including a high level.

  When the pulse-like internal signal (k3) is output, the second mono-multi circuit 35b outputs the internal signal (k4) to the analog switch 37 for a certain period of time, and the analog switch 37 outputs a preset phase difference correction signal. (M) is output to the adder 38. The second mono multi circuit 35b corresponds to the mono multi circuit of the present invention.

  The inverter frequency reference signal (n1) generated by the delay priority circuit 25 (see FIG. 2) is changed from (n1) to (n2) by adding the phase difference correction signal (m) by the adder 38. . In this case, (n2) is output as the final inverter frequency reference signal, but the relationship is (n2) = (n1) + (m).

  The phase difference correction signal (m) is a signal in which an analog voltage value is set, and is set to 0.5 (v), for example. If the inverter frequency reference signal (n1) is 3.0 (v), the voltage signal corresponding to the inverter frequency reference signal (n2) is 3.5 (v).

  Thereafter, when the operating frequency of the inverters 10a and 10b changes and a predetermined delay power factor or more is secured, the inverter frequency reference signal returns from (n2) to (n1).

  In other words, the phase difference correction circuit 21b generates the phase difference correction signal (m) to increase the inverter operating frequency by a certain value in order to avoid the power factor from changing in the advance direction. After that, it gradually approaches the load resonance frequency. Thus, the operating frequency of the inverter can always be kept near the load resonance frequency in the delay power factor region.

  Next, the operation of the phase difference correction circuit 21b will be described with reference to FIG.

  FIG. 6A is a diagram showing the operation of the phase difference correction circuit 21b in the case of a normal delay power factor. In FIG. 6A, since the phase of the output current signal (h) is delayed with respect to the output voltage signal (g), the phase delay signal (j) is changed by the phase difference.

  Here, when an output pulse (High level) is generated in the phase delay signal (j), the other phase advance signal (i) is always at the Low level. Since the phase advance signal (i) is inverted to become a high level signal and is input to the AND gate 34 (see FIG. 5B), when the output pulse of the phase delay signal (j) is generated (high level). The internal signal (k1) is at a high level.

  The internal signal (k2) is a signal output from the first mono-multi circuit 35a that sets the phase difference level based on the internal signal (k1) when there is a phase difference.

  Next, the high level pulse width of the internal signal (k1) is compared with the low level pulse width of the internal signal (k2). If the phase difference is not less than a predetermined value, the internal signal (k3) is output at the low level. It becomes.

  In this case, as described above, the internal signal (k4) output from the second mono-multi circuit 35b is also at the low level, and the analog switch 36 does not operate. That is, (n1) is finally output as the inverter frequency reference signal.

  On the other hand, FIG. 6B shows the operation of the phase difference correction circuit 21b when the delay power factor is insufficient. In FIG. 6B, the phase difference between the output current signal (h) and the output voltage signal (g) is smaller than that in FIG.

  In this case, when the high level pulse width of the internal signal (k1) and the low level pulse width of the internal signal (k2) are compared, it is determined that the phase difference is equal to or less than a predetermined value, and the internal signal (k3) is at the high level. Output. Therefore, the internal signal (k4) output from the second mono-multi circuit 35b is also a high level output.

  At this time, the analog switch 37 is operated for a predetermined time by the internal signal (k4), and a signal for adding the phase difference correction signal (m) is output. When the phase difference correction signal (m) is added to the inverter frequency reference signal (n1) by the adder, (n2) is finally output as the inverter frequency reference signal.

  As described above, when the delay power factor is insufficient, that is, when the phase difference becomes equal to or smaller than the predetermined value, the phase difference correction circuit 21b operates to recover the phase difference.

  Next, an example of phase difference correction control by the control signal generation circuit 30 will be described with reference to FIG.

  Since AC power is supplied to a circuit (see FIG. 1) constituted by the high frequency capacitors 12a and 12b and the heating coil 16, this circuit exhibits resonance characteristics as shown in FIG. The horizontal axis represents frequency and the vertical axis represents resonance magnification.

  The center portion of the resonance curve is the resonance frequency f1, and the resonance frequency f1 varies between 50 and 105% with the rated frequency being 100% depending on the state of the material 17 to be melted.

  At the resonance frequency f1, the power factor is 1, and the output current signal (h) and the output voltage signal (g) have no phase difference. The right side of the resonance curve is a state of “delayed power factor” in which the phase of the output current signal (h) is delayed with respect to the output voltage signal (g). Usually, the operating frequency f2 of the inverter is set to the delay power factor. Control within the range (output adjustment range).

  On the other hand, the left side of the resonance curve is a “leading power factor” state, which is a range in which it is difficult to adjust the operating frequency. Further, in the frequency control of the present embodiment, at the time of startup, the startup frequency is set to the maximum frequency f2 ′, and gradually approaches the resonance frequency f1 and is held at the operating frequency f2 within the delay power factor range (FIG. 7). (Dotted arrow (1)).

  Here, the phase difference is always detected, and even when the resonance frequency f1 changes, the operating frequency f2 is controlled to follow the resonance frequency f1 according to the change. Normally, since the width of change of the resonance frequency f1 is small, the control is based on the inverter frequency reference signal (n1) that is not corrected.

  However, when the width of change of the resonance frequency f1 is large, the phase difference may reach the lowest limit value (phase difference threshold) when the operating frequency f2 is followed. In this case, in order to recover the phase difference by increasing the phase difference to a certain value, the phase difference correction circuit 21b is operated to switch to control by the inverter frequency reference signal (n2).

  In the control by the inverter frequency reference signal (n2), after temporarily increasing the operating frequency f2 (dotted line arrow (2) in FIG. 7), it gradually approaches the resonance frequency f1 and again within the range of the delay power factor. Hold (dotted arrow (3) in FIG. 7). At this time, the temporary increase in the operating frequency f2 is limited to about 20% of the total output adjustment range (the range of the delay power factor) at the maximum.

  Therefore, the width of the frequency that changes for phase difference adjustment is narrow, and sudden output fluctuations do not occur. That is, it is possible to control the power of the induction melting furnace 15 while always maintaining a high power factor.

  As described above, the control apparatus for the induction melting furnace of the present embodiment uses an IGBT element as an inverse converter, but may be an apparatus using a thyristor element instead. In this case, since the range of the advance power factor becomes the output adjustable range, when the phase difference reaches the lowest limit value, the operating frequency f2 is temporarily lowered and then gradually brought closer to the resonance frequency f1. It becomes control.

1 power supply,
2 Power receiving unit,
2a Power fuse,
2b circuit breaker,
3 Transformer transformers,
4 Power converter (control device),
4a Forward converter unit (forward converter, high frequency power generator),
4b Inverter unit (inverter, high frequency power generator),
4c high frequency matching unit (high frequency power generation unit),
5a, 5b Diode forward converter,
6 DC reactor,
7 DC capacitor,
8 DC voltage detector,
9 DC current detector,
10 Inverter,
10a, 10b IGBT inverter (first and second switching elements),
11 Control circuit,
12a, 12b High-frequency capacitors for power factor adjustment,
13 Energizing current detector (AC current detector),
14 Load voltage detector (AC voltage detector),
15 induction melting furnace,
16 heating coil,
17 Materials to be dissolved,
18 controller,
19 output voltage signal generation circuit,
19a, 19b dead time adjustment circuit,
19c, 20c, 29 reset set flip-flop circuit,
20 output current signal generation circuit,
20a, 20b binarization circuit,
21a phase difference detection circuit (phase difference detection unit),
21b phase difference correction circuit,
22 voltage constant control circuit (AVR),
23 constant current control circuit (ACR),
24 constant power control circuit (APR),
25 delay priority circuit,
26 Reference frequency holding circuit,
27 voltage controlled oscillator circuit,
28, 34 AND gate,
30 control signal generation circuit (control signal generation unit),
32, 36 NAND gate,
33 NOT gate,
35a, 35b Mono-multi circuit (MM),
37 Analog switch (ASW),
38 adder,
(A) DC voltage,
(B) DC current,
(C) IGBT gate signal,
(D) energizing current,
(E) load voltage,
(F) Controller control signal,
(G) output voltage signal,
(H) Output current signal,
(I) phase advance signal;
(J) a phase lag signal;
(K1) to (k4) internal signals,
(M) Phase difference correction signal,
(N1), (n2) Inverter frequency reference signal.

Claims (5)

A control device for an induction melting furnace for melting a material to be melted stored in the furnace by the heat of a heating coil,
A high-frequency power generator that generates high-frequency power to be supplied to the heating coil;
A phase difference detector for detecting a phase difference between the voltage and current of the high-frequency power;
A control signal generation unit that generates a control signal of the high-frequency power generation unit so as to generate the high-frequency power according to the phase difference detected by the phase difference detection unit;
The control signal generator (1) changes the control signal so that the phase difference is reduced from a startup frequency preset for the high-frequency power generator, and maintains the predetermined phase difference. (2) When the phase difference reaches a preset threshold value , a correction signal is added to the first control signal to keep the phase difference constant while following the change in the phase difference. generates a second control signal that be greater by a value, (3) said phase when a phase difference is equal to or higher than a preset threshold, characterized by generating the first control signal to maintain a predetermined said phase difference Induction melting furnace control device. In the induction melting furnace control device according to claim 1,
The high-frequency power generation unit
A forward converter that converts AC power into DC power;
An inverter that converts the DC power into the high-frequency power by configuring a bridge circuit using the first and second switching elements;
The inverse converter converts the DC power into the high-frequency power by alternately operating the first and second switching elements according to a control signal of the high-frequency power generation unit. Control device. In the induction melting furnace control device according to claim 1 or 2,
The control signal generation unit includes a mono-multi circuit, and when the phase difference reaches a preset threshold value, a correction for increasing the phase difference by a certain value by an internal signal output from the mono-multi circuit for a certain period of time A control device for an induction melting furnace that generates a signal and generates a second control signal obtained by adding the correction signal to the first control signal. In the induction melting furnace control device according to any one of claims 1 to 3,
The high-frequency power generation unit
An AC voltage detector for detecting the voltage of the high-frequency power;
An AC current detector that detects the current of the high-frequency power, and
The phase difference detector is
An output voltage signal generated through a reset / set / flip / flop circuit with an edge width of each rising edge of the voltage detected by the AC voltage detection unit as an ON signal,
Using the rising and falling edge widths of the high-frequency power detected by the AC current detection unit as ON signals, the phase difference from the output current signal generated via the reset / set / flip / flop circuit is detected. A control apparatus for an induction melting furnace, characterized in that: In the induction melting furnace control device according to any one of claims 1 to 4,
The high-frequency power generation unit
A forward converter that converts AC power into DC power;
An inverter that converts the DC power into the high-frequency power by configuring a bridge circuit using the first and second switching elements;
The control apparatus for an induction melting furnace, wherein both the first and second switching elements are IGBT elements.

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