CN104601033A - High-voltage pulse type magnetron power source - Google Patents

Abstract

The invention discloses a high-voltage pulse type magnetron power source. The high-voltage pulse type magnetron power source comprises a rectifying and filtering module, a main circuit module, a sampling feedback module and a controlling and driving module, wherein the main circuit module comprises an LLC resonance module, a high-frequency transformer T1 and a high-voltage rectifying module, the input end of the rectifying and filtering module is connected with mains supply, the output end of the rectifying and filtering module is connected with the LLC resonance module, and the LLC resonance module is connected with the high-voltage rectifying module through the high-frequency transformer; the sampling feedback module samples from the output end of the high-voltage rectifying module, the signal output end of the sampling feedback module is connected with the input end of the controlling and driving module, and the output end of the controlling and driving module is connected with the LLC resonance module. The high-voltage pulse type magnetron power source can meet requirements of high-voltage pulse power supply of a magnetron. Output power can be flexibly adjusted by adjusting pulse width, size and weight of the power source can be reduced, service life of the magnetron is prolonged, and potential safety hazards in switching in the high-voltage environment are avoided.

Description

High-tension pulse stamp magnetron power source

Technical field

The present invention relates to impulse type powered by direct current technical field, be specifically related to a kind of high-tension pulse stamp magnetron power source.

Background technology

The advantages such as microwave heating has homogeneous heating, speed is fast, the heat efficiency is high, easy realization controls automatically.Compared with traditional heating technique, microwave heating has great attraction and wide prospects for commercial application undoubtedly.And the core component in microwave power equipment is the Switching Power Supply driving microwave source, its operating efficiency and stability directly affect the overall performance of microwave equipment.

Traditional magnetron drive power supply has two kinds of modes, and one is linear power supply, adopts the voltage-multiplying circuit of Industrial Frequency Transformer, diode, electric capacity composition to produce anode high voltage.This structure utilizes Industrial Frequency Transformer to boost and produces high pressure, but due to frequency lower, so such structural volume is large, heavy, loss is large, serious to harmonic pollution in electric power net, and the output power of power supply is non-adjustable, and power factor is low.Non-adjustable due to power output, the method that microwave oven can only take discontinuity to power is powered to magnetron, changes the average output power of microwave oven, the useful life affecting magnetron that the method for this frequent unlatching, closedown can be serious.

Except the supply power mode of linear power supply, along with development and the innovation of power electronic technology, make switch power technology also at constantly development innovation, because it has small-sized, light weight and high efficiency feature, so also apply Switching Power Supply structure more and more in magnetron power source.But because the normal condition of work of continuous magnetron is not high direct voltage, what the existing Switching Power Supply overwhelming majority exported is all direct voltage, therefore general switch power supply topological structure can add switch at output, is exported by the control voltage that turns on and off of switch.Although though this measure can meet the power reguirements of magnetron substantially, the operating voltage due to magnetron is the voltage of the many volts of 4K, and therefore the switch of output will bear very high voltage stress.This method of supplying power to not only increases components and parts, and under high pressure control switch, there is very large potential safety hazard.

In view of these two kinds of magnetron drive power supplies existing exist above-mentioned defect, design a kind of stable performance, energy-efficient magnetron drive power supply has high scientific research value and commercial value.

Summary of the invention

The present invention is intended to the technical problem solving existing magnetron power source complex structure, unstable properties, the very big potential safety hazard of existence.

For solving the problems of the technologies described above, the present invention adopts following technical scheme:

Design a kind of high-tension pulse stamp magnetron power source, comprise rectification filtering module, main circuit module, sampling feedback module and control driver module, described main circuit module comprises LLC resonance modules, high frequency transformer T1 and high-voltage rectifying module, the input of described rectification filtering module is connected with civil power, output is connected with described LLC resonance modules, and described LLC resonance modules is connected with described high-voltage rectifying module by described high frequency transformer;

Described sampling feedback module samples from the output of described high-voltage rectifying module, and its signal output part is connected with the input of described control driver module, and the output of described control driver module connects described LLC resonance modules;

Corresponding civil power passes through rectification filtering module, be input to described main circuit module, then provide high voltage by described main circuit module to negative electrode, make the waveform exported be impulse type direct voltage by described control driver module, realize high-voltage pulse to export, the magnetron that supply is corresponding.

Preferably, described LLC resonant circuit comprises resistance R2, resistance R3, power MOSFET Q1, Q2, inductance L R1, static exciter inductance L m and electric capacity CR4, wherein, described resistance R2, R3 is parallel to described power MOSFET Q1 respectively, the grid of Q2 and source electrode, described power MOSFET Q1, Q2 connects mutually, receive on input voltage, described inductance L R1, electric capacity CR1, the former limit output that LLC resonant network is connected to described high frequency transformer T1 is jointly formed with static exciter inductance L m, the former limit of described high frequency transformer T1 is input as the output voltage of described LLC resonant circuit.

Described high-voltage rectifying module comprises diode DR1, DR2, electric capacity CR2, CR3, wherein, the negative electrode of described diode DR1 is connected with electric capacity CR2, described diode DR1 anode is connected with the negative electrode of diode DR2, and described diode DR2 anode meets electric capacity CR3, and described electric capacity CR1 and CR2 connects;

Described main circuit module carries out elementary boosting by described high frequency transformer, then provides high voltage through the described high-voltage rectifying module backward negative electrode that again boosts.

Preferably, described control driver module comprises low frequency modulations circuit and drive circuit, and described low frequency modulations circuit comprises 555 timers, diode D1, D2, potentiometer R2, resistance R1, R4, voltage stabilizing chip Z4040-5 and electric capacity C1, C2;

Wherein, 2 pin of described voltage stabilizing chip Z4040-5 are connected with 3 pin, 1 pin accesses VCC by resistance R4,8 pin of NE555 connect 5 volts of voltages, 5 pin to be connected with 1 pin ground connection by described electric capacity C1,6 pin receive the negative electrode of diode D1 i.e. the anode of D2 after being connected with 2 pin, 7 pin connect the anode of D1 and the input of potentiometer R2,10 pin of 3 pin access SG3525,4 pin connect the voltage of 5 volts and 1 pin of Z4040-5, receive the negative electrode of D2 after R1, R2, R3 series connection, after electric capacity C1, C2 series connection, receive the anode of diode D2.

Preferably, described drive circuit comprises control chip SG3525, driving chip IR2110, resistance R4, R5, R7, R8, and electric capacity C2, C3, C5, C6, C7,

Wherein, power supply VCC accesses 15,13 pins of described control chip SG3525, and 11,13 pins of described driving chip IR2110, is respectively described control chip SG3525 and described driving chip IR2110 powers; Shunt capacitance C2 between 5 pins of described control chip SG3525 and GND, 6 pins and GND parallel resistance R4, resistance R5 is sealed between 5 pins and 7 pins, directly be connected between 9 pins with 1 pin, 2 pins connect VSE end, and VSE accesses 16 pins, and 10 pins are connected on the output pin of NE555,8 pins meet GND by electric capacity C3, and 2,12 pins meet GND; Electric capacity C5, C6 are also connected between VCC and GND, 12,13 pins of described driving chip IR2110 are connected on output 11,14 pin of described control chip SG3525 respectively, 13,15 pins of described driving chip IR2110 are received on GND jointly, 3,4,16 pins do not connect, diode D1 is connected between VCC and 7 pin, its Anodic meets VCC, negative electrode connects 7 pins, electric capacity C7 is incorporated between 6 pins and 7 pins, 8 pins give described MOSFET Q1 after sealing in resistance R7, the source electrode of 6 pin access Q1,1 pin exports to described MOSFETQ2 by resistance R8.

Beneficial effect of the present invention is:

1. abandon traditional microwave power supply structure, adopt switch power supply topological structure.The present invention uses high frequency switch power to replace traditional Industrial Frequency Transformer boost type power supply, can be magnetron load and continuously adjustable supply power voltage is provided, while raising delivery efficiency, its volume and weight can be reduced, owing to avoiding frequent starting and the stopping of magnetron, the useful life of magnetron greatly can be extended.

2. adopt resonant network to reduce the wastage.The present invention adopts resonant network to realize the soft start of switch, reduces switching loss, improves the efficiency of power supply.

3. by regulating the pulsewidth of low frequency pulse signal, can regulation output power easily, make microwave equipment more intelligent.

4. control the non-dc output voltage that driver module controls magnetron.The low frequency modulations circuit that the low frequency that the present invention adopts controls to export meets the particular/special requirement of magnetron to output waveform, ensure that the normal work of magnetron.This low frequency modulations circuit utilizes low frequency pulse signal to control the output pulse of high frequency, makes the signal being supplied to drive circuit be intermittent working pulse, thus makes output voltage be the direct voltage of impulse type.This result eliminates the high-voltage switch gear of conventional magnetron pipe power supply output loop, avoids the potential safety hazard of switching under hyperbaric environment.

Accompanying drawing explanation

Fig. 1 is the modular structure schematic diagram of high-tension pulse stamp magnetron power source of the present invention.

Fig. 2 is the electrical block diagram of main circuit module.

Fig. 3 is the structural representation of low frequency modulations circuit.

Fig. 4 is the structural representation of drive circuit.

Wherein, 101 is LLC resonance modules; 102 is high frequency transformer T1; 103 is high-voltage rectifying module.

Embodiment

Below in conjunction with drawings and Examples, the specific embodiment of the present invention is described, but following examples are only used to describe the present invention in detail, and limit the scope of the invention never in any form.

Embodiment 1: a kind of high-tension pulse stamp magnetron power source, comprise rectification filtering module, main circuit module, sampling feedback module and control driver module, main circuit module comprises LLC resonance modules, high frequency transformer T1 and high-voltage rectifying module, the input of rectification filtering module is connected with civil power, output is connected with LLC resonance modules, and LLC resonance modules is connected with high-voltage rectifying module by high frequency transformer.

Sampling feedback module samples from the output of high-voltage rectifying module, and its signal output part is connected with the input controlling driver module, and the output controlling driver module connects LLC resonance modules.

Civil power, first by the rectification filtering module of certain step-up ratio, obtains the direct voltage of 330V, then inputs to main circuit module, alleviates the boost pressure of main circuit module medium/high frequency transformer.Main circuit module obtains the negative voltage of volt more than 2,000 by LLC resonance modules, the voltage being supplied to negative electrode after the boosting of high-voltage rectifying module reaches 4,000 more and lies prostrate, control drive circuit turning on and off by control MOSFET, output waveform is made to be the direct voltage of impulse type, to realize high-voltage pulse output function, ensure the normal work of magnetron.

LLC resonance modules comprises resistance R2, resistance R3, power MOSFET Q1, Q2, inductance L R1, static exciter inductance L m and electric capacity CR4, wherein, resistance R2, R3 are parallel to grid and the source electrode of power MOSFET Q1, Q2 respectively, power MOSFET Q1, Q2 connect mutually, receive on input voltage, inductance L R1, electric capacity CR1, static exciter inductance L m form the former limit output that LLC resonant network is connected to high frequency transformer T1 jointly, and the former limit of high frequency transformer T1 is input as the output voltage of LLC resonance modules.

High-voltage rectifying module comprises diode DR1, DR2, electric capacity CR2, CR3, and wherein, the negative electrode of diode DR1 is connected with electric capacity CR2, and diode DR1 anode is connected with the negative electrode of diode DR2, and diode DR2 anode meets electric capacity CR3, and electric capacity CR1 and CR2 connects;

Main circuit module carries out elementary boosting by high frequency transformer, then provides high voltage through the high-voltage rectifying module backward negative electrode that again boosts.

Control driver module and comprise low frequency modulations circuit and drive circuit, low frequency modulations circuit comprises 555 timers, diode D1, D2, potentiometer R2, resistance R1, R4, voltage stabilizing chip Z4040-5 and electric capacity C1, C2; Drive circuit comprises control chip SG3525, driving chip IR2110, resistance R4, R5, R7, R8, and electric capacity C2, C3, C5, C6, C7.

In low frequency modulations circuit, 2 pin of voltage stabilizing chip Z4040-5 are connected with 3 pin, 1 pin accesses VCC by resistance R4,8 pin of NE555 connect 5 volts of voltages, 5 pin to be connected with 1 pin ground connection by electric capacity C1,6 pin receive the negative electrode of diode D1 i.e. the anode of D2 after being connected with 2 pin, 7 pin connect the anode of D1 and the input of potentiometer R2,10 pin of 3 pin access SG3525,4 pin connect the voltage of 5 volts and 1 pin of Z4040-5, receive the negative electrode of D2 after R1, R2, R3 series connection, after electric capacity C1, C2 series connection, receive the anode of diode D2;

In drive circuit, 15,13 pins of power supply VCC access control chip SG3525, and 11 of driving chip IR2110,13 pins, be respectively control chip SG3525 and driving chip IR2110 powers; Shunt capacitance C2 between 5 pins of control chip SG3525 and GND, 6 pins and GND parallel resistance R4, resistance R5 is sealed between 5 pins and 7 pins, directly be connected between 9 pins with 1 pin, 2 pins connect VSE end, and VSE accesses 16 pins, and 10 pins are connected on the output pin of NE555,8 pins meet GND by electric capacity C3, and 2,12 pins meet GND; Electric capacity C5, C6 are also connected between VCC and GND, 12,13 pins of driving chip IR2110 are connected on output 11,14 pin of control chip SG3525 respectively, 13,15 pins of driving chip IR2110 are received on GND jointly, 3,4,16 pins do not connect, diode D1 is connected between VCC and 7 pin, its Anodic meets VCC, negative electrode connects 7 pins, electric capacity C7 is incorporated between 6 pins and 7 pins, 8 pins give MOSFET Q1 after sealing in resistance R7, the source electrode of 6 pin access Q1,1 pin exports to MOSFET Q2 by resistance R8.

Wherein, adopt 555 timers and voltage control chip SG3525 chip to provide modulation signal, control switch pipe open situation, make output circuit be pulse signal, ensure the normal work of magnetron.555 timers provide the square wave of mS level, control the square wave of the uS level that 3525 produce.Low frequency pulse signal due to 555 timers is low to moderate mS level, so can control 3525 outputs, adopt driving chip IR2110 to provide drive current to two of half-bridge switching tubes, the output waveform making circuit final is the pulse voltage of the many volts of 4K.

Components and parts involved in the embodiment above if no special instructions, are conventional components and parts.In conjunction with the accompanying drawings and embodiments the present invention is described in detail above, but, person of ordinary skill in the field can understand, under the prerequisite not departing from present inventive concept, each design parameter in above-described embodiment can also be changed, form multiple specific embodiment, be common excursion of the present invention, describe in detail no longer one by one at this.

Claims (4)

1. a high-tension pulse stamp magnetron power source, comprises rectification filtering module, main circuit module, sampling feedback module and controls driver module, it is characterized in that,

Described main circuit module comprises LLC resonance modules, high frequency transformer T1 and high-voltage rectifying module, the input of described rectification filtering module is connected with civil power, output is connected with described LLC resonance modules, and described LLC resonance modules is connected with described high-voltage rectifying module by described high frequency transformer;

Described sampling feedback module samples from the output of described high-voltage rectifying module, and its signal output part is connected with the input of described control driver module, and the output of described control driver module connects described LLC resonance modules;

Corresponding civil power passes through rectification filtering module, be input to described main circuit module, then provide high voltage by described main circuit module to negative electrode, make the waveform exported be impulse type direct voltage by described control driver module, realize high-voltage pulse to export, the magnetron that supply is corresponding.

2. high-tension pulse stamp magnetron power source according to claim 1, it is characterized in that, described LLC resonant circuit comprises resistance R2, resistance R3, power MOSFET Q1, Q2, inductance L R1, static exciter inductance L m and electric capacity CR4, wherein, described resistance R2, R3 is parallel to described power MOSFET Q1 respectively, the grid of Q2 and source electrode, described power MOSFET Q1, Q2 connects mutually, receive on input voltage, described inductance L R1, electric capacity CR1, the former limit output that LLC resonant network is connected to described high frequency transformer T1 is jointly formed with static exciter inductance L m, the former limit of described high frequency transformer T1 is input as the output voltage of described LLC resonant circuit,

Described high-voltage rectifying module comprises diode DR1, DR2, electric capacity CR2, CR3, wherein, the negative electrode of described diode DR1 is connected with electric capacity CR2, described diode DR1 anode is connected with the negative electrode of diode DR2, and described diode DR2 anode meets electric capacity CR3, and described electric capacity CR1 and CR2 connects;

Described main circuit module carries out elementary boosting by described high frequency transformer, then provides high voltage through the described high-voltage rectifying module backward negative electrode that again boosts.

3. high-tension pulse stamp magnetron power source according to claim 2, it is characterized in that, described control driver module comprises low frequency modulations circuit and drive circuit, and described low frequency modulations circuit comprises 555 timers, diode D1, D2, potentiometer R2, resistance R1, R4, voltage stabilizing chip Z4040-5 and electric capacity C1, C2;

Wherein, 2 pin of described voltage stabilizing chip Z4040-5 are connected with 3 pin, 1 pin accesses VCC by resistance R4,8 pin of NE555 connect 5 volts of voltages, 5 pin to be connected with 1 pin ground connection by described electric capacity C1,6 pin receive the negative electrode of diode D1 i.e. the anode of D2 after being connected with 2 pin, 7 pin connect the anode of D1 and the input of potentiometer R2,10 pin of 3 pin access SG3525,4 pin connect the voltage of 5 volts and 1 pin of Z4040-5, receive the negative electrode of D2 after R1, R2, R3 series connection, after electric capacity C1, C2 series connection, receive the anode of diode D2.

4. high-tension pulse stamp magnetron power source according to claim 3, is characterized in that, described drive circuit comprises control chip SG3525, driving chip IR2110, resistance R4, R5, R7, R8, and electric capacity C2, C3, C5, C6, C7,

Wherein, power supply VCC accesses 15,13 pins of described control chip SG3525, and 11,13 pins of described driving chip IR2110, is respectively described control chip SG3525 and described driving chip IR2110 powers; Shunt capacitance C2 between 5 pins of described control chip SG3525 and GND, 6 pins and GND parallel resistance R4, resistance R5 is sealed between 5 pins and 7 pins, directly be connected between 9 pins with 1 pin, 2 pins connect VSE end, and VSE accesses 16 pins, and 10 pins are connected on the output pin of NE555,8 pins meet GND by electric capacity C3, and 2,12 pins meet GND; Electric capacity C5, C6 are also connected between VCC and GND, 12,13 pins of described driving chip IR2110 are connected on output 11,14 pin of described control chip SG3525 respectively, 13,15 pins of described driving chip IR2110 are received on GND jointly, 3,4,16 pins do not connect, diode D1 is connected between VCC and 7 pin, its Anodic meets VCC, negative electrode connects 7 pins, electric capacity C7 is incorporated between 6 pins and 7 pins, 8 pins give described MOSFET Q1 after sealing in resistance R7, the source electrode of 6 pin access Q1,1 pin exports to described MOSFETQ2 by resistance R8.