CN115315034A - Self-adjusting IGBT drive circuit and electromagnetic heating equipment - Google Patents

Abstract

The invention relates to the technical field of electromagnetic heating, and discloses a self-adjusting IGBT driving circuit and electromagnetic heating equipment. The circuit comprises a control circuit, a self-adjusting drive circuit, a sampling circuit and an IGBT tube; the sampling circuit samples the collector voltage of the IGBT tube; the control circuit outputs a control signal to the self-adjusting drive circuit, the self-adjusting drive circuit receiving the control signal outputs weak IGBT drive voltage to the grid electrode of the IGBT tube when the voltage of the collector electrode is larger than or equal to the critical voltage, and outputs strong IGBT drive voltage to the grid electrode of the IGBT tube when the voltage of the collector electrode is smaller than the critical voltage, so that the IGBT tube is started after receiving the weak IGBT drive voltage or the strong IGBT drive voltage. This is disclosed through the voltage level of monitoring collector voltage and according to the big or small automatic control driving voltage size of collector voltage to adapt to different start-up scenarios, avoid the collector voltage of IGBT pipe too high and lead to danger.

Description

Self-adjusting IGBT drive circuit and electromagnetic heating equipment

Technical Field

The invention relates to the technical field of electromagnetic heating, in particular to a self-adjusting IGBT driving circuit and electromagnetic heating equipment.

Background

In the prior art, IH heating products such as an induction cooker, an IH electric cooker, a pressure cooker and the like mostly adopt a single-tube IGBT tube scheme due to cost reasons. Under the states such as high pressure, this scheme is because of input energy is not enough during resonance, leads to the non-zero voltage of IGBT pipe to turn on, and the conduction voltage is high, and the electric current is big in the twinkling of an eye, and IGBT can be overheated, explode the quick-witted damage. When pot detection and power starting are carried out, the collector of the IGBT tube is directly 1.4 times of the commercial power high voltage, the conduction voltage is higher, the instant conduction current is larger, the instant conduction current can reach more than 150A in the high-voltage working state, the IGBT specification range is exceeded, and great explosion risks exist.

Disclosure of Invention

It is an object of the present invention to provide a self-regulating IGBT driver circuit and an electromagnetic heating apparatus, which solve one or more of the technical problems of the prior art and provide at least one of the advantages.

In a first aspect, a self-adjusting IGBT driving circuit is provided, and comprises a control circuit, a self-adjusting driving circuit, a sampling circuit and an IGBT tube;

the control circuit, the self-adjusting driving circuit and the grid electrode of the IGBT tube are sequentially connected, one end of the sampling circuit is connected with the collector electrode of the IGBT tube, and the other end of the sampling circuit is connected with the self-adjusting driving circuit;

the sampling circuit samples the collector voltage of the IGBT tube;

the control circuit outputs a control signal to the self-regulation driving circuit, the self-regulation driving circuit receiving the control signal outputs weak IGBT driving voltage to the grid electrode of the IGBT tube when the voltage of the collector electrode is greater than or equal to the critical voltage, and outputs strong IGBT driving voltage to the grid electrode of the IGBT tube when the voltage of the collector electrode is less than the critical voltage, so that the IGBT tube is started after receiving the weak IGBT driving voltage or the strong IGBT driving voltage;

the critical voltage is greater than or equal to the critical voltage, the weak IGBT driving voltage is smaller than the strong IGBT driving voltage or the voltage rising rate of the weak IGBT driving voltage is smaller than that of the strong IGBT driving voltage.

Further, the self-adjusting driving circuit comprises a self-adjusting module, a level generating module and an output module;

the self-adjusting module is connected with the sampling circuit, the output module is connected with the grid of the IGBT tube, and the input end of the level generating module is connected with the control circuit and the self-adjusting module;

the control circuit outputs a control signal to the input end of the level generation module, and the level generation module controls the output module to drive the IGBT tube;

when the voltage of a collector is greater than or equal to the critical voltage, the self-regulating module triggers the level generation module to be in a weak level conversion state, so that the output module outputs weak IGBT driving voltage to a grid electrode of the IGBT tube;

when the voltage of the collector is smaller than the critical voltage, the self-regulating module triggers the level generation module to be in a high-level conversion state, so that the output module outputs high-capacity IGBT driving voltage to the grid electrode of the IGBT tube.

Further, the self-regulation module comprises a first switch sub-circuit;

the trigger end of the first switch sub-circuit is connected with the sampling circuit, the first end of the first switch sub-circuit is connected with the input end of the level generation module, and the second end of the first switch sub-circuit is grounded;

the trigger end of the first switch sub-circuit receives a sampling signal of the sampling circuit, the first switch sub-circuit is conducted when the collector voltage is larger than or equal to the critical voltage, and the first switch sub-circuit is cut off when the collector voltage is smaller than the critical voltage.

Further, the level generating module comprises a second switch sub-circuit and a third switch sub-circuit;

the trigger end of the second switch sub-circuit is connected with the control circuit, the first end of the second switch sub-circuit is connected with the output module, and the second end of the second switch sub-circuit is grounded;

the trigger end of the third switching sub-circuit is connected with the self-adjusting module, the first end of the third switching sub-circuit is connected with the direct-current voltage, and the second end of the second switching sub-circuit is connected with the output module;

the input end of the output module is connected with direct-current voltage;

when the third switching sub-circuit is switched off, the output module is connected with the direct-current voltage and outputs the weak-capacity IGBT driving voltage, and when the third switching sub-circuit is switched on, the third switching sub-circuit is used as a bypass of the output module, so that the output module is connected with the direct-current voltage and outputs the strong-capacity IGBT driving voltage.

Further, the output module comprises a fourth switch sub-circuit and a fifth switch sub-circuit;

the fourth switch sub-circuit and the fifth switch sub-circuit form a push-pull circuit structure;

the triggering end of the fourth switch sub-circuit is respectively connected with the direct-current voltage and level generation module, the first end of the fourth switch sub-circuit is connected with the direct-current voltage, and the second end of the fourth switch sub-circuit is connected with the grid electrode of the IGBT tube;

the triggering end of the fifth switch sub-circuit is respectively connected with the direct-current voltage and level generation module, the first end of the fifth switch sub-circuit is connected with the grid electrode of the IGBT tube, and the second end of the fifth switch sub-circuit is grounded.

Furthermore, the fourth switch sub-circuit is connected with a first bias sub-circuit, one end of the first bias sub-circuit is connected with the first end of the fourth switch sub-circuit, and the other end of the first bias sub-circuit is connected with the trigger end of the fourth switch sub-circuit;

the fifth switch sub-circuit is connected with a second bias sub-circuit, one end of the second bias sub-circuit is connected with the trigger end of the fifth switch sub-circuit, and the other end of the second bias sub-circuit is connected with the ground.

Further, the sampling circuit comprises a first sampling module and a second sampling module;

one end of the first sampling module is connected with a collector electrode of the IGBT tube, the other end of the first sampling module is respectively connected with one end of the second sampling module and the self-adjusting driving circuit, and the other end of the second sampling module is grounded.

Further, the control circuit and the self-adjusting driving circuit are integrally packaged.

Further, after the IGBT tube receives the weak IGBT driving voltage and is started, the voltage value of the weak IGBT driving voltage output by the self-adjusting driving circuit receiving the control signal is increased, so that the IGBT tube is normally switched on; or is

After the IGBT tube receives the high-capacity IGBT driving voltage and is started, the voltage value of the high-capacity IGBT driving voltage output by the self-adjusting driving circuit receiving the control signal is increased, and the IGBT tube is normally switched on.

Further, after the IGBT tube is started, the self-adjusting driving circuit receiving the control signal maintains and outputs weak-capacity IGBT driving voltage or strong-capacity IGBT driving voltage, so that the IGBT tube is normally switched on.

In a second aspect, there is provided an electromagnetic heating device comprising a self-regulating IGBT drive circuit according to the first aspect.

The invention has the beneficial effects that: through setting up the voltage level of sampling circuit monitoring collector voltage and can open the self-interacting drive circuit of voltage size by the self-interacting, the self-interacting drive circuit is according to the size automatic control starting voltage's of collector voltage size to adapt to different start-up scenes, avoid the collector voltage of IGBT pipe too high and lead to danger.

Drawings

Fig. 1 is one of circuit configuration diagrams of a self-regulating IGBT drive circuit provided by the present invention.

Fig. 2 is a second circuit structure diagram of the self-regulating IGBT driving circuit according to the present invention.

Fig. 3 is a third circuit configuration diagram of the self-regulating IGBT driver circuit according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the present invention will be further described with reference to the embodiments and the accompanying drawings.

In the description of the present invention, it should be understood that the orientation or positional relationship referred to in the description of the orientation, such as the upper, lower, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, a plurality of the terms are not limited to a definite number, and a plurality of the terms are two or more, and are understood to include the number of the terms greater than, smaller than, larger than, and the like. If the first and second are described for the purpose of distinguishing technical features, they are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated. Additionally, appearing throughout and/or representing three side-by-side scenarios, e.g., A and/or B represents a scenario satisfied by A, a scenario satisfied by B, or a scenario satisfied by both A and B.

In the description of the present invention, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, which may include other elements not expressly listed, in addition to those listed.

As described above, most of the electromagnetic heating schemes in the prior art that use single-tube IGBT tubes are in a high-power or low-power operating state, when the input energy is insufficient during resonance, the IGBT tube is turned on at a non-zero voltage, the conduction voltage is high, the instantaneous conduction current is large, and the IGBT is overheated and damaged by explosion. When pot detection and power starting are carried out, the collector of the IGBT tube is directly 1.4 times of the mains supply high voltage, the conduction voltage is higher, the instant conduction current is larger, and in a high-power working state, the instant conduction current can reach more than 150A and exceeds the specification range of the IGBT, so that great explosion risk exists.

Based on the self-adjusting IGBT driving circuit and the electromagnetic heating equipment, the voltage level of the collector voltage and the driving circuit structure capable of self-adjusting the magnitude of the turn-on voltage are monitored, and the magnitude of the starting voltage is automatically controlled according to the voltage level of the collector voltage, so that different starting situations are adapted, and dangers caused by overhigh collector voltage of an IGBT tube are avoided.

According to a first aspect of the invention, a self-regulating IGBT drive circuit is provided.

As shown in fig. 1, the self-regulating IGBT driving circuit according to the embodiment of the present invention includes a control circuit 100, a self-regulating driving circuit 200, a sampling circuit 300, and an IGBT tube 400.

The control circuit 100, the self-regulation driving circuit 200 and the gate of the IGBT tube 400 are connected in sequence, one end of the sampling circuit 300 is connected with the collector of the IGBT tube 400, and the other end of the sampling circuit 300 is connected with the self-regulation driving circuit 200.

The sampling circuit 300 samples the collector voltage of the IGBT tube 400, the control circuit 100 outputs a control signal to the self-regulation drive circuit 200, the self-regulation drive circuit 200 receiving the control signal outputs a weak IGBT drive voltage to the gate of the IGBT tube 400 when the collector voltage is greater than or equal to a critical voltage, and outputs a strong IGBT drive voltage to the gate of the IGBT tube 400 when the collector voltage is less than the critical voltage, so that the IGBT tube 400 starts after receiving the weak IGBT drive voltage or the strong IGBT drive voltage. The critical voltage is greater than or equal to the critical voltage, the weak IGBT driving voltage is smaller than the strong IGBT driving voltage or the voltage rising rate of the weak IGBT driving voltage is smaller than that of the strong IGBT driving voltage.

The control circuit 100, for example, an MCU (micro controller unit), outputs a control signal to the self-regulation driving circuit 200 when receiving a start instruction, so as to control the self-regulation driving circuit 200 to output a turn-on voltage to the IGBT tube 400, so that the IGBT tube 400 starts and turns on normally. In practical use, the collector of the IGBT 400 is further connected to a resonant circuit, and the resonant circuit is powered on to perform electromagnetic heating after the IGBT 400 is normally turned on.

The sampling circuit 300 is connected to the collector of the IGBT tube 400, the sampling control circuit 100 starts the collector voltage generated at the collector of the IGBT tube 400 at the moment of starting the IGBT tube 400 by the self-regulation drive circuit 200, the sampling circuit 300 transmits a sampling signal to the self-regulation drive circuit 200, and the self-regulation drive circuit 200 receiving the control signal adjusts the starting voltage according to the collector voltage of the IGBT tube 400 corresponding to the sampling signal. Specifically, in the turn-on stage of the IGBT tube 400, when the collector voltage is greater than or equal to the critical voltage, the self-regulation driving circuit 200 receiving the control signal automatically reduces its own driving capability, the self-regulation driving circuit 200 outputs a weak IGBT driving voltage to the gate of the IGBT tube 400, thereby limiting the turn-on current when the IGBT tube 400 is started, when the collector voltage is less than the critical voltage, the self-regulation driving circuit 200 receiving the control signal automatically raises or recovers its own driving capability, the self-regulation driving circuit 200 outputs a strong IGBT driving voltage to the gate of the IGBT tube 400, so that the IGBT tube 400 is started after receiving the weak IGBT driving voltage or the strong IGBT driving voltage, thereby reducing the loss when the IGBT tube 400 is started.

It should be noted that the threshold voltage is a preset value, and parameters can be adjusted according to actual needs, and the self-regulation driving circuit 200 outputs weak-capability IGBT driving voltage or strong-capability IGBT driving voltage to the gate of the IGBT tube 400, and after the IGBT tube 400 is started, the IGBT tube 400 is normally turned on.

In some embodiments, after the IGBT tube 400 receives the weak IGBT driving voltage and starts up, the voltage value of the weak IGBT driving voltage output by the self-regulation driving circuit 200 that receives the control signal increases, so that the IGBT tube 400 is normally turned on; or after the IGBT tube 400 receives the high-capability IGBT driving voltage and starts up, the voltage value of the high-capability IGBT driving voltage output by the self-regulation driving circuit 200 that receives the control signal increases, so that the IGBT tube 400 is normally turned on.

In some embodiments, after the IGBT 400 is started, the self-regulating driving circuit 200 receiving the control signal maintains to output the weak IGBT driving voltage or the strong IGBT driving voltage, so that the IGBT 400 is normally turned on.

As shown in fig. 2 and 3, a specific structure of the self-regulating IGBT driving circuit according to the present invention will be described.

In one embodiment, the self-adjusting drive circuit 200 includes a self-adjusting module 210, a level generation module 220, and an output module 230.

The self-adjusting module 210 is connected to the sampling circuit 300, the output module 230 is connected to the gate of the IGBT 400, and the input terminal of the level generating module 220 is connected to the control circuit 100 and the self-adjusting module 210.

The self-adjusting module 210 adjusts the driving capability of the output module 230 through the level generation module 220.

Specifically, the level generating module 220 has two switching modes, namely a weak level switching state and a strong level switching state, the level generating module 220 in the weak level switching state controls the output module 230 to output the weak IGBT driving voltage, the level generating module 220 in the strong level switching state controls the output module 230 to output the strong IGBT driving voltage, and the self-adjusting module 210 receives the sampling signal of the sampling circuit 300 and controls the level generating module 220 to enter the weak level switching state or the strong level switching state according to the sampling signal.

The control circuit 100 outputs a control signal to the input terminal of the level generating module 220, and the level generating module 220 controls the output module 230 to drive the IGBT tube 400.

Specifically, the control signal output by the control circuit 100 is a PPG signal, the control signal triggers the level generation module 220 to start, and under the adjustment action of the self-adjustment module 210, the level generation module 220 enters a weak level conversion state or a strong level conversion state. When the collector voltage is greater than or equal to the threshold voltage, the self-regulating module 210 triggers the input terminal of the level generating module 220 and makes the level generating module 220 in a weak level conversion state, so that the output module 230 outputs the weak IGBT driving voltage to the gate of the IGBT transistor 400. When the collector voltage is less than the threshold voltage, the self-regulating module 210 triggers the input terminal of the level generating module 220 and makes the level generating module 220 in a strong level conversion state, so that the output module 230 outputs a strong IGBT driving voltage to the gate of the IGBT transistor 400.

In one embodiment, the self-regulation module 210 includes a first switch subcircuit 211.

The trigger terminal of the first switch sub-circuit 211 is connected to the sampling circuit 300, the first terminal of the first switch sub-circuit 211 is connected to the input terminal of the level generating module 220, and the second terminal of the first switch sub-circuit 211 is grounded.

Specifically, the first switch sub-circuit 211 includes a first triode Q1 and a first resistor R1, a base of the first triode Q1 is connected to the sampling circuit 300 through the first resistor R1, a collector of the first triode Q1 is connected to an input terminal of the level generating module 220, and an emitter of the first triode Q1 is grounded. The first triode Q1 is an NPN type triode.

The trigger terminal of the first switch sub-circuit 211 receives the sampling signal of the sampling circuit 300, the first switch sub-circuit 211 is turned on when the collector voltage is greater than or equal to the threshold voltage, and the first switch sub-circuit 211 is turned off when the collector voltage is less than the threshold voltage.

When the first switch sub-circuit 211 is turned on, the input terminal of the level generating module 220 is connected to ground, and the level of the input terminal of the level generating module 220 is lowered, and when the first switch sub-circuit 211 is turned off, the level of the input terminal of the level generating module 220 maintains the original state. After the level generating module 220 is powered on, the input end of the level generating module 220 is in a high level state, which may be implemented by connecting an external dc voltage Vcc or configuring a level generating sub-circuit inside the level generating module 220, the input end of the level generating module 220 is in a low level state when the first switch sub-circuit 211 is turned on, and is in a high level state when the first switch sub-circuit 211 is turned off, the level generating module 220 is switched to a weak level conversion state when the input end of the level generating module 220 is in the low level state, and the level generating module 220 is switched to a strong level conversion state when the input end of the level generating module 220 is in the high level state.

In one embodiment, the level generating module 220 includes a second switching sub-circuit 221 and a third switching sub-circuit 222.

The trigger terminal of the second switch sub-circuit 221 is connected to the control circuit 100, the first terminal of the second switch sub-circuit 221 is connected to the output module 230, the second terminal of the second switch sub-circuit 221 is grounded, the trigger terminal of the third switch sub-circuit 222 is connected to the self-regulation module 210, the first terminal of the third switch sub-circuit 222 is connected to the dc voltage Vcc, and the second terminal of the second switch sub-circuit 221 is connected to the output module 230.

Specifically, the second switch sub-circuit 221 includes a second triode Q2 and a second resistor R2, a base of the second triode Q2 is connected to the control circuit 100 through the second resistor R2, a collector of the second triode Q2 is connected to the output module 230, and an emitter of the second triode Q2 is grounded; the third switching sub-circuit 222 includes a third transistor Q3 and a third resistor R3, wherein a base of the third transistor Q3 is connected to the self-regulation module 210 through the third resistor R3, a collector of the third transistor Q3 is connected to the dc voltage Vcc, and an emitter of the third transistor Q3 is connected to the output module 230. The trigger terminal of the second switch sub-circuit 221 is used as the input terminal of the level generating module 220, the trigger terminal of the third switch sub-circuit 222 is used as the input terminal of the level generating module 220, and the second triode Q2 and the third triode Q3 are NPN triodes.

In some embodiments, a diode may be used instead of the third resistor R3, a cathode of the diode is connected to the base of the third transistor Q3, and an anode of the diode is connected to the self-adjusting module 210.

The input terminal of the output module 230 is connected to the dc voltage Vcc. When the third switching sub-circuit 222 is turned off, the output module 230 is connected to the dc voltage Vcc and outputs the weak IGBT driving voltage, and when the third switching sub-circuit 222 is turned on, the third switching sub-circuit 222 serves as a bypass of the output module 230, so that the output module 230 is connected to the dc voltage Vcc and outputs the strong IGBT driving voltage.

The control circuit 100 outputs a control signal to the trigger terminal of the second switch sub-circuit 221 to control the second switch sub-circuit 221 to be turned on or off, and during the turning-on and turning-off process of the second switch sub-circuit 221, the level state of the input terminal of the output module 230 changes, and the turn-on voltage output by the output module 230 changes, so that the output condition of the output module 230 is controlled by the second switch sub-circuit 221. For example, when the control circuit 100 controls the second switch sub-circuit 221 to turn on and pull down the level of the input terminal of the output module 230, the output module 230 does not output the turn-on voltage, and when the second switch sub-circuit 221 is turned off and makes the input terminal of the output module 230 at a high level, the output module 230 outputs the turn-on voltage.

The self-adjusting module 210 controls the third switch sub-circuit 222 to be turned on or off according to the received sampling signal, when the third switch sub-circuit 222 is turned off and the second switch sub-circuit 221 is turned off, the input terminal of the output module 230 is in a high level state after receiving the dc voltage Vcc, and when the third switch sub-circuit 222 is turned on and the second switch sub-circuit 221 is turned off, the input terminal of the output module 230 is in a high level state, and the output module 230 outputs different start voltages according to the level state of the input terminal thereof, because the bypass of the third switch sub-circuit 222 exists, the level of the input terminal of the output module 230 is further increased after receiving the dc voltage Vcc. For example, the output module 230 may output the weak IGBT driving voltage according to a level state of its own input terminal when the third switching sub-circuit 222 is turned off, and output the strong IGBT driving voltage according to a level state of its own input terminal when the third switching sub-circuit 222 is turned on.

In one embodiment, the output module 230 includes a fourth switch sub-circuit 231 and a fifth switch sub-circuit 232.

The fourth switch subcircuit 231 and the fifth switch subcircuit 232 form a push-pull circuit structure, the trigger end of the fourth switch subcircuit 231 is connected with the direct-current voltage Vcc and the level generation module 220 respectively, the first end of the fourth switch subcircuit 231 is connected with the direct-current voltage Vcc, the second end of the fourth switch subcircuit 231 is connected with the grid electrode of the IGBT tube 400, the trigger end of the fifth switch subcircuit 232 is connected with the direct-current voltage Vcc and the level generation module 220 respectively, the first end of the fifth switch subcircuit 232 is connected with the grid electrode of the IGBT tube 400, and the second end of the fifth switch subcircuit 232 is grounded.

Specifically, the fourth switch sub-circuit 231 includes a fourth triode Q4, the fifth switch sub-circuit 232 includes a fifth triode Q5, the fourth triode Q4 is an NPN-type triode, the fifth triode Q5 is a PNP-type triode, the base of the fourth triode Q4 is connected to the dc voltage Vcc and the level generating module 220, the collector of the fourth triode Q4 is connected to the dc voltage Vcc, the emitter of the fourth triode Q4 is connected to the gate of the IGBT tube 400, the base of the fifth triode Q5 is connected to the dc voltage Vcc and the level generating module 220, the emitter of the fifth triode Q5 is connected to the gate of the IGBT tube 400, and the collector of the fifth triode Q5 is grounded.

After the first level trigger terminal of the level generating module 220 is connected to the control signal, when the level generating module 220 outputs a high level, the fourth switch sub-circuit 231 is turned on and the fifth switch sub-circuit 232 is turned off, the output module 230 outputs a turn-on voltage to the gate of the IGBT tube 400, when the level generating module 220 outputs a low level, the fourth switch sub-circuit 231 is turned off and the fifth switch sub-circuit 232 is turned on, and the output module 230 does not output a turn-on voltage to the gate of the IGBT tube 400.

In combination with the above embodiment, when the level generating module 220 is in a weak level converting state, i.e. the third switch sub-circuit 222 is turned off and the second switch sub-circuit 221 is turned off, the fourth switch sub-circuit 231 is turned on and the fifth switch sub-circuit 232 is turned off, the fourth switch sub-circuit 231 converts the dc voltage Vcc into a weak IGBT driving voltage and outputs the weak IGBT driving voltage to the gate of the IGBT tube 400, and when the level generating module 220 is in a strong level converting state, i.e. the third switch sub-circuit 222 is turned on and the second switch sub-circuit 221 is turned off, the fourth switch sub-circuit 231 is turned on and the fifth switch sub-circuit 232 is turned off, due to the bypass of the third switch sub-circuit 222, the trigger terminal level of the fourth switch sub-circuit 231 is increased, and the fourth switch sub-circuit 231 converts the dc voltage Vcc into a strong IGBT driving voltage and outputs the strong IGBT driving voltage to the gate of the IGBT tube 400.

Furthermore, the fourth switch sub-circuit 231 is connected to the first bias sub-circuit 233, one end of the first bias sub-circuit 233 is connected to the first end of the fourth switch sub-circuit 231, the other end of the first bias sub-circuit 233 is connected to the trigger end of the fourth switch sub-circuit 231, the fifth switch sub-circuit 232 is connected to the second bias sub-circuit 234, one end of the second bias sub-circuit 234 is connected to the trigger end of the fifth switch sub-circuit 232, and the other end of the second bias sub-circuit 234 is connected to ground.

More specifically, the first bias sub-circuit 233 comprises a fourth resistor R4, one end of the fourth resistor R4 is connected to the collector of the fourth transistor Q4, and the other end of the fourth resistor R4 is connected to the base of the fourth transistor Q4; the second bias sub-circuit 234 includes a fifth resistor R5 and a first capacitor C1, one end of the fifth resistor R5 is connected to the base of the fifth transistor Q5, the other end of the fifth resistor R5 is connected to one end of the first capacitor C1, and the other end of the first capacitor C1 is grounded.

In one embodiment, the sampling circuit 300 includes a first sampling module 310 and a second sampling module 320.

One end of the first sampling module 310 is connected to the collector of the IGBT 400, the other end of the first sampling module 310 is connected to one end of the second sampling module 320 and the self-regulation driving circuit 200, and the other end of the second sampling module 320 is grounded.

Specifically, the first sampling module 310 includes a sixth resistor R6, the second sampling module 320 includes a seventh resistor R7, one end of the sixth resistor R6 is connected to the collector of the IGBT tube 400, the other end of the sixth resistor R6 is connected to one end of the seventh resistor R7 and the self-regulation driving circuit 200, respectively, and the other end of the seventh resistor R7 is grounded. The self-regulation driving circuit 200 obtains a voltage between the sixth resistor R6 and the seventh resistor R7 as a sampling signal of the sampling circuit 300, thereby outputting a weak IGBT driving voltage or a strong IGBT driving voltage according to the obtained sampling signal.

In some other embodiments, the first sampling module 310 and the second sampling module 320 may also be formed by at least two resistors connected in series.

In some embodiments, the control circuit 100 and the self-adjusting driving circuit 200 are integrally packaged and integrated in a single control chip.

The invention provides a self-adjusting IGBT driving circuit, wherein the voltage level of collector voltage is monitored by a sampling circuit 300, and the self-adjusting driving circuit 200 can self-adjust the magnitude of turn-on voltage, and the self-adjusting driving circuit 200 automatically controls the magnitude of starting voltage according to the magnitude of the collector voltage so as to adapt to different starting situations and avoid danger caused by overhigh collector voltage of an IGBT tube 400.

According to a second aspect of the present invention, an electromagnetic heating apparatus is provided.

The electromagnetic heating device comprises the self-regulating IGBT driving circuit of the first aspect, and the electromagnetic heating device of the embodiment adopts all the technical solutions of all the embodiments, and at least has all the beneficial effects brought by the technical solutions of the embodiments.

The electromagnetic heating equipment can be household electromagnetic heating products such as an electromagnetic oven, an electromagnetic rice cooker or an electromagnetic pressure cooker.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (11)

1. A self-adjusting IGBT drive circuit is characterized by comprising a control circuit, a self-adjusting drive circuit, a sampling circuit and an IGBT tube;

the control circuit, the self-adjusting driving circuit and the grid electrode of the IGBT tube are sequentially connected, one end of the sampling circuit is connected with the collector electrode of the IGBT tube, and the other end of the sampling circuit is connected with the self-adjusting driving circuit;

the sampling circuit samples the collector voltage of the IGBT tube;

the control circuit outputs a control signal to the self-adjusting drive circuit, the self-adjusting drive circuit receiving the control signal outputs weak IGBT drive voltage to the grid electrode of the IGBT tube when the collector voltage is greater than or equal to the critical voltage, and outputs strong IGBT drive voltage to the grid electrode of the IGBT tube when the collector voltage is less than the critical voltage, so that the IGBT tube is started after receiving the weak IGBT drive voltage or the strong IGBT drive voltage;

the weak IGBT driving voltage is smaller than the strong IGBT driving voltage or the voltage rising rate of the weak IGBT driving voltage is smaller than that of the strong IGBT driving voltage.

2. The self-regulating IGBT driver circuit of claim 1, wherein the self-regulating driver circuit comprises a self-regulating module, a level generation module, and an output module;

the self-adjusting module is connected with the sampling circuit, the output module is connected with the grid of the IGBT tube, and the input end of the level generating module is connected with the control circuit and the self-adjusting module;

the control circuit outputs a control signal to the input end of the level generation module, and the level generation module controls the output module to drive the IGBT tube;

when the collector voltage is greater than or equal to the critical voltage, the self-adjusting module triggers the level generation module to be in a weak level conversion state, so that the output module outputs weak-capacity IGBT driving voltage to the grid electrode of the IGBT tube;

when the collector voltage is smaller than the critical voltage, the self-adjusting module triggers the level generation module to be in a strong level conversion state, so that the output module outputs strong IGBT driving voltage to the grid electrode of the IGBT tube.

3. The self-regulating IGBT drive circuit according to claim 2, wherein the self-regulating module comprises a first switching sub-circuit;

the trigger end of the first switch sub-circuit is connected with the sampling circuit, the first end of the first switch sub-circuit is connected with the input end of the level generation module, and the second end of the first switch sub-circuit is grounded;

the trigger end of the first switch sub-circuit receives a sampling signal of the sampling circuit, the first switch sub-circuit is switched on when the collector voltage is greater than or equal to the critical voltage, and the first switch sub-circuit is switched off when the collector voltage is less than the critical voltage.

4. The self-regulating IGBT driver circuit of claim 2, wherein the level generation module comprises a second switching sub-circuit and a third switching sub-circuit;

the trigger end of the second switch sub-circuit is connected with the control circuit, the first end of the second switch sub-circuit is connected with the output module, and the second end of the second switch sub-circuit is grounded;

the trigger end of the third switching sub-circuit is connected with a self-adjusting module, the first end of the third switching sub-circuit is connected with a direct-current voltage, and the second end of the second switching sub-circuit is connected with an output module;

the input end of the output module is connected with direct-current voltage;

when the third switching sub-circuit is switched off, the output module is connected with direct current voltage and outputs weak IGBT driving voltage, and when the third switching sub-circuit is switched on, the third switching sub-circuit is used as a bypass of the output module, so that the output module is connected with the direct current voltage and outputs the strong IGBT driving voltage.

5. The self-regulating IGBT drive circuit of claim 2, wherein the output module comprises a fourth switching sub-circuit and a fifth switching sub-circuit;

the fourth switch sub-circuit and the fifth switch sub-circuit form a push-pull circuit structure;

the triggering end of the fourth switch sub-circuit is respectively connected with the direct-current voltage and level generation module, the first end of the fourth switch sub-circuit is connected with the direct-current voltage, and the second end of the fourth switch sub-circuit is connected with the grid electrode of the IGBT tube;

the trigger end of the fifth switch sub-circuit is respectively connected with the direct-current voltage and level generation module, the first end of the fifth switch sub-circuit is connected with the grid of the IGBT tube, and the second end of the fifth switch sub-circuit is grounded.

6. The self-regulating IGBT drive circuit of claim 5,

the fourth switch sub-circuit is connected with a first bias sub-circuit, one end of the first bias sub-circuit is connected with the first end of the fourth switch sub-circuit, and the other end of the first bias sub-circuit is connected with the trigger end of the fourth switch sub-circuit;

the fifth switch sub-circuit is connected with a second bias sub-circuit, one end of the second bias sub-circuit is connected with a trigger end of the fifth switch sub-circuit, and the other end of the second bias sub-circuit is connected with the ground.

7. The self-regulating IGBT drive circuit of claim 1, wherein the sampling circuit comprises a first sampling module and a second sampling module;

the IGBT self-adjusting circuit comprises a first sampling module, a second sampling module, a self-adjusting driving circuit and a self-adjusting driving circuit, wherein one end of the first sampling module is connected with a collector electrode of the IGBT, the other end of the first sampling module is connected with one end of the second sampling module and the self-adjusting driving circuit respectively, and the other end of the second sampling module is grounded.

8. The self-regulating IGBT driver circuit according to claim 1, wherein the control circuit and the self-regulating driver circuit are integrally packaged.

9. The self-regulating IGBT driving circuit according to any one of claims 1 to 8, characterized in that after the IGBT tube receives weak IGBT driving voltage and starts up, the voltage value of the weak IGBT driving voltage output by the self-regulating IGBT driving circuit receiving control signals is increased, so that the IGBT tube is normally switched on; or is

After the IGBT tube receives the high-capacity IGBT driving voltage and is started, the voltage value of the high-capacity IGBT driving voltage output by the self-adjusting driving circuit receiving the control signal is increased, and the IGBT tube is normally switched on.

10. The self-regulating IGBT driving circuit according to any one of claims 1 to 8, wherein after the IGBT tube is started, the self-regulating IGBT driving circuit receiving the control signal keeps outputting a weak IGBT driving voltage or a strong IGBT driving voltage, so that the IGBT tube is normally switched on.

11. An electromagnetic heating device, characterized by comprising a self-regulating IGBT drive circuit according to any of claims 1 to 10.

Images