CN109889074A - Drive control circuit and household appliance - Google Patents

Abstract

The present invention provides a kind of drive control circuit and household appliances, wherein, drive control circuit includes: filter inductance, the filter inductance is configured as filtering out the harmonic signal in the power supply signal, filter inductance is set in the alternating current circuit of rectification module prime, and/or in the two buss lines of rectification module rear class；Voltage absorption compensation branch, with inverter parallel, voltage absorption compensation branch includes concatenated capacitive element and switching device, switching device is configured as control capacitive element and carries out charge or discharge, wherein, the capacitive element electric discharge carries out voltage compensation to the inverter, and the inverter is configured as driving load running.Technical solution provided by the invention, efficiently reduces load current peak, solves the caused beat frequency noise problem when the alternating voltage of input is too low.

Description

Drive control circuit and household appliance

Technical field

The present invention relates to Drive Control Technique fields, set in particular to a kind of drive control circuit and a kind of household electrical appliances It is standby.

Background technique

In general, the power factor of passive PFC (Power Factor Correction, PFC) circuit It is very low, and the capacitor very big using capacity is needed, cause passive PFC circuit cost very high.

And for the circuit methods of general no electrolytic capacitor, there is following disadvantage:

The first, DC bus-bar voltage fluctuation is big, causes load current fluctuations big, and load current peak is high, it is therefore desirable to needle Overcurrent protection to power module setting high gauge, leads to cost increase；

The second, it is present in the periodic phenomena that the identical busbar voltage of supply frequency is insufficient, can not contribute, causes to clap The problems such as frequency noise.

Therefore, a kind of drive control circuit that can solve above-mentioned technical problem is needed at present.

Summary of the invention

The present invention is directed to solve at least one of the technical problems existing in the prior art or related technologies.

For this purpose, the first aspect of the present invention proposes a kind of drive control circuit.

The second aspect of the present invention proposes a kind of household appliance.

In view of this, the first aspect of the present invention provides a kind of drive control circuit, comprising: filter inductance, the filter Wave inductance is configured as filtering out the harmonic signal in the power supply signal, and filter inductance is set to the alternating current circuit of rectification module prime In, and/or in the two buss lines of the rectification module rear class；Voltage absorption compensation branch, with inverter parallel, the electricity Pressure absorption compensation branch includes concatenated capacitive element and switching device, and the switching device is configured as controlling the capacitive member Part carries out charge or discharge, wherein the capacitive element electric discharge carries out voltage compensation to the inverter, and the inverter is matched It is set to driving load running.

In the technical scheme, drive control circuit is provided with filter inductance, for filtering out the power supply of network system input Harmonic signal in signal, meanwhile, drive control circuit is additionally provided with capacitive element and switching device.Switching device and capacitive member Part series connection, and control capacitive element charge or discharge.When power supply signal is higher, switching device controls capacitive element charging.When When power supply signal is lower, switching device controls capacitive element electric discharge, to carry out voltage compensation to inverter.

Technical solution provided by the invention is applied, if detecting that power supply signal is too low, is controlled by switching device Capacitive element electric discharge, to realize that the voltage compensation to inverter, the capacitor that wherein capacitive element need not select capacity very big can drop The cost of low-voltage compensation circuit, avoids system power from fluctuating, to solve caused when the alternating voltage of input is too low Beat frequency noise problem.

Specifically, it is the electrolytic capacitor of 10uF to 2000uF that capacitance range, which can be used, in capacitive element, without selecting capacitance Bigger capacitor is, it can be achieved that preferable cost control, controller change according to collected ac voltage size driving switch pipe Become switching mode, to control electrolytic capacitor charge or discharge, has both two aspects for reducing load current peak and voltage compensation Effect.

In addition, the drive control circuit in above-mentioned technical proposal provided by the invention can also have following supplementary technology special Sign:

In the above-mentioned technical solutions, further, the inverter access is described between high voltage bus and low-voltage bus bar One end of switching device is connected to the high voltage bus, and one end of the capacitive element is connected to the low-voltage bus bar, the mother Line route includes the high voltage bus and the low-voltage bus bar.

In the technical scheme, inverter access is between high voltage bus and low-voltage bus bar, by the direct current signal on bus It is converted into the AC signal of driving load running.One end of switch element is connected to high voltage bus, and an end of capacitive element is connected to low Bus is pressed, to realize the control to capacitive element charging, electric discharge.

In any of the above-described technical solution, further, drive control circuit further include: controller, the controller connect It is connected to the switching device, to regulate and control the on state of the switching device；Wherein, if the power supply signal is greater than or equal to the One power supply signal threshold value, then the controller triggers the switching device and is connected in the first pattern, to control the capacitive element It charges, in addition, if the controller detects the power supply signal less than the second power supply signal threshold value, the controller It triggers the switching device to be connected in a second mode, be discharged with controlling the capacitive element.

In the technical scheme, controller is according to the conduction mode of the size control switch device of power supply signal.Specifically, When ac voltage signal is more than first voltage threshold value, illustrate that alternating voltage is higher, controller control switch device is at this time with the One mode conducting, to reduce load current amplitude for capacitive element charging；When ac voltage signal is less than second voltage threshold value When, illustrate that alternating voltage is too low at this time, controller control switch device is connected in a second mode at this time, so that capacitive element is put Electricity carries out power compensation to inverter.

Wherein, the first power supply signal threshold value and the second power supply signal threshold value can take same numerical value or different numerical value, and the One power supply signal threshold value and the second power supply signal threshold value are mainly determined by the power of the power and inverter that load.

Wherein, power supply signal can be the alternating voltage of input rectifying module, be also possible to the direct current of rectification module output Voltage.

In any of the above-described technical solution, further, the switching device includes: power tube, with the capacitive element Series connection, the control terminal of the power tube are connected to the instruction output end of the controller, and described instruction output end is to the control End output control instruction, the control instruction are configured as controlling the power tube on or off；Reverse-biased freewheeling diode, institute The both ends for stating reverse-biased freewheeling diode are respectively connected to drain electrode and the source electrode of the power tube, wherein if the power tube is connected, Then the capacitive element is through the power tube to the load discharge, if the power tube ends, the capacitive element is through institute It states reverse-biased freewheeling diode charging or is failure to actuate.

In the technical scheme, switching device includes power tube and reverse-biased freewheeling diode, power tube and capacitive element string Connection, the instruction output end of controller are connected to the control terminal of power tube, and to send control instruction to power tube, power tube is according to control System instruction change on state (on or off), the both ends of reverse-biased freewheeling diode respectively with the drain electrode of power tube and source electrode phase Connection, when power tube conducting when, capacitive element through power tube to load discharge, to realize voltage compensation, when power tube cut-off when, The voltage signal of input is capacitive element charging through reverse-biased freewheeling diode, to reduce load current peak.At load current peak Value usually for normal water, without reducing load current peak, be failure to actuate by capacitive element.

Wherein, the capacitive element refers to that power supply signal is through reverse-biased two pole of afterflow through the reverse-biased freewheeling diode charging Pipe charges to capacitive element, meanwhile, power supply signal is powered the load of operation, and capacitive element charging process is complete Charging process, i.e., when capacitive element discharges, the discharge voltage of capacitive element is greater than the supply voltage on route, and then realizes electricity Pressure compensation.

Specifically, power tube can it is preferable to use IGBT (Insulated Gate Bipolar Transistor, insulation Grid bipolar junction transistor) type power tube, MOSFET (Metal-Oxide-Semiconductor Field- can also be selected Effect Transistor, metal-oxide semiconductor (MOS) power field effect transistor), reverse-biased freewheeling diode can be independently arranged, It can also be integrally disposed with IGBT or MOSFET.

In any of the above-described technical solution, further, drive control circuit further include: rectification module is set to the appearance Between the input terminal and the filter inductance of property element, the rectification module is configured as the power supply signal being converted to direct current Signal, wherein the direct current signal is configured as charging to the capacitive element, and electricity needed for the offer load running Amount, the inverter are configured as controlling the direct current signal driving load running.

In the technical scheme, rectification module is provided in drive control circuit, rectification module is connected to capacitive element Between input terminal and filter module, the power supply signal of network system input enters rectification module after filter module filters out noise, Rectification module rectifies power supply signal, and by the DC signal output obtained after rectification to capacitive element and loading section, To charge to capacitive element, and provide operation required electricity to load.Direct current signal is converted AC signal by inverter, control System driving load running.

In any of the above-described technical solution, further, if the load includes single-phase load, the inverter includes Corresponding single-phase inversion circuit, the single-phase inversion circuit include: two upper bridge arm power devices and two lower bridge arm power devices Part accesses between the output end of the voltage absorption compensation branch and the input terminal of the load, if the load includes three Phase load, then the inverter includes corresponding three-phase inverting circuit, and the three-phase inverting circuit includes: three upper bridge arm power Device and three lower bridge arm power devices access the output end in the voltage absorption compensation branch and the input terminal of the load Between, wherein the upper bridge arm power device of a phase is connected with the lower bridge arm power device of a corresponding phase Connect, the upper bridge arm power device and the lower bridge arm power device of same phase do not simultaneously turn on.

In the technical scheme, if load includes single-phase load, corresponding single-phase inversion is provided in inverter Circuit, to export corresponding driving signal to single-phase load.Specifically, single-phase load can be monophase machine, be also possible to list Phase inductive load.

Wherein, single-phase inversion circuit includes two upper bridge arm power devices and two lower bridge arm power devices, is connected to appearance Between the deferent segment of property element and the input terminal of load.

If load includes threephase load, corresponding three-phase inverting circuit is provided in inverter, with negative to three-phase It carries and exports corresponding driving signal.Specifically, threephase load can be induction machine, be also possible to permanent magnet synchronous motor.

Wherein, three-phase inverting circuit includes three upper bridge arm power devices and three lower bridge arm power devices, is connected to appearance Between the deferent segment of property element and the input terminal of load.The lower bridge of the upper corresponding phase of bridge arm power device of each phase The series connection of arm power device, the upper bridge arm power device and lower bridge arm power device of same-phase will not simultaneously turn on, and negative to three-phase The load one phase driving signal of output of load, the upper bridge arm power device and lower bridge arm power device alternate conduction of three phases, to The load of threephase load exports three-phase driving signal.

In any of the above-described technical solution, further, between the source electrode and drain electrode of any upper bridge arm power device It is connected to a reverse-biased freewheeling diode, is denoted as the reverse-biased freewheeling diode of bridge arm, the source electrode of any lower bridge arm power device It is connected to a reverse-biased freewheeling diode between drain electrode, is denoted as the reverse-biased freewheeling diode of lower bridge arm.

In the technical scheme, between upper bridge arm power device and the source electrode and drain electrode of lower bridge arm power device between be connected to one A reverse-biased freewheeling diode, the specially upper reverse-biased freewheeling diode of bridge arm and the reverse-biased freewheeling diode of lower bridge arm.

In any of the above-described technical solution, further, any upper bridge arm power device includes metal oxide half Conductor field effect transistor and/or insulated gate bipolar transistor, any lower bridge arm power device includes metal oxide Semiconductor field effect transistor and/or insulated gate bipolar transistor, wherein the collector of the insulated gate bipolar transistor It is connected as the drain electrode, the emitter of the insulated gate bipolar transistor is connected as the source electrode.

In the technical scheme, upper bridge arm power device include Metal Oxide Semiconductor Field Effect Transistor (i.e. MOSFET) and/or insulated gate bipolar transistor (i.e. IGBT), in the case where having used insulated gate bipolar transistor, absolutely The collector of edge grid bipolar junction transistor is connected as the drain electrode, and emitter is connected as the source electrode.Lower bridge arm power device Part includes Metal Oxide Semiconductor Field Effect Transistor (i.e. MOSFET) and/or insulated gate bipolar transistor (i.e. IGBT), In the case where having used insulated gate bipolar transistor, the collector of insulated gate bipolar transistor connects as the drain electrode It connects, emitter is connected as the source electrode.

In any of the above-described technical solution, further, the power tube includes metal oxide semiconductor field-effect crystalline substance Body pipe and/or insulated gate bipolar transistor, wherein the grid of the Metal Oxide Semiconductor Field Effect Transistor is as institute The instruction output end that control terminal is connected to the controller is stated, the base stage of the insulated gate bipolar transistor is as the control End is connected to the instruction output end of the controller.

In the technical scheme, power tube include Metal Oxide Semiconductor Field Effect Transistor (i.e. MOSFET) and/or Insulated gate bipolar transistor (i.e. IGBT), wherein the grid of MOSFET as control terminal, the instruction output end of controller with The grid of MOSFET is connected, and as control terminal, the instruction output end of controller is connected the MOSFET of IGBT with the base stage of IGBT It connects.

In any of the above-described technical solution, further, the filter inductance is serially connected in the drive control circuit At least one alternating current circuit, the alternating current circuit is for accessing the power supply signal, wherein the sensibility reciprocal value of the inductive element Range is 200uH~25mH.

In the technical scheme, filter inductance is additionally provided with inductive element, and inductive element is connected in series in drive control electricity It is exchanged in road at least one alternating current circuit of survey, inductive element is filter inductance, is filtered out on alternating current circuit by filter inductance The clutter in power supply signal carried.

Optionally, the sensibility reciprocal value range of inductive element is 200uH~25mH.

Optionally, the sensibility reciprocal of inductive element is 500uH.

Optionally, the sensibility reciprocal of inductive element is 5mH.

In any of the above-described technical solution, further, the filter inductance is serially connected with the high voltage bus and/or described Low-voltage bus bar, DC line carrying signal is the direct current signal, wherein the sensibility reciprocal value range of the inductive element is 200uH~25mH.

In the technical scheme, inductive element is connected in series in pressure bus that direct current in drive control circuit is surveyed and/or low It presses on bus, inductive element is filter inductance, is filtered out by filter inductance miscellaneous in the direct current signal carried on DC line Wave.

Optionally, the sensibility reciprocal value range of inductive element is 200uH~25mH.

Optionally, the sensibility reciprocal of inductive element is 500uH.

Optionally, the sensibility reciprocal of inductive element is 5mH.

In any of the above-described technical solution, further, the load of the load includes blower and/or compressor or institute The load for stating load includes induction machine and/or permanent magnet synchronous motor.

In any of the above-described technical solution, further, the capacitive element includes electrolytic capacitor and/or the capacitive Element includes a capacity cell and/or the capacitive element includes the capacity cell of multiple series connection and/or parallel connection.

In any of the above-described technical solution, further, the capacitance value range of the capacitive element be 10uF~ 2000uF。

Optionally, the capacitance of capacitive element is 82uF.

Optionally, the capacitance of capacitive element is 220uF.

Optionally, the capacitance of capacitive element is 470uF.

Optionally, the capacitance of capacitive element is 560uF.

Optionally, the capacitance of capacitive element is 680uF.

Optionally, the capacitance of capacitive element is 820uF.

In any of the above-described technical solution, further, the power supply source of the controller includes isolated power supply or bootstrapping electricity Source, wherein the bootstrap power supply includes bootstrapping power supply circuit, bootstrap diode and bootstrap capacitor in the inverter, described The anode of bootstrap diode is connected to the anode of the bootstrapping power supply circuit, the cathode of the bootstrap diode be connected to it is described from The anode of capacitor is lifted, the anode of the bootstrap capacitor is connected to the feeder ear of the controller.

In the technical scheme, controller is provided with power supply, and specifically, power supply includes isolated power supply or bootstrapping Power supply is connected to the feeder ear of controller by isolated power supply, provides electricity for controller when power supply is isolated power supply Can, when power supply is bootstrap power supply, bootstrap power supply includes concatenated bootstrapping power supply circuit, isolated power supply or bootstrap power supply, The cathode of bootstrapping power supply circuit is connected with the low-voltage bus bar in two buss lines, the anode and bootstrap diode of power supply circuit of booting Anode be connected, while the cathode of bootstrap diode is connected with the anode of bootstrap capacitor, and the cathode of bootstrap capacitor is connected to The feeder ear of controller, to provide electric energy for controller.

In any of the above-described technical solution, further, the voltage absorption compensation branch further include: with the capacitive member The concatenated resistive element of part and/or inductance element, the resistive element are used to adjust the size of current for flowing through the capacitive element, The inductance element is for filtering out the AC noise for flowing through the capacitive element.

In the technical scheme, resistive element and/or inductance element can access between high voltage bus and switching device, It can also access between capacitive element and low-voltage bus bar, can also access between switching device and capacitive element.

In addition, resistive element includes the resistance of a resistance or multiple series connection and/or parallel connection, similarly, inductance element includes One inductance or the inductance of multiple series connection and/or parallel connection.

In any of the above-described technical solution, further, the value range of the resistive element is the Ω of 0.1m Ω~10, institute The value range for stating inductance element is 1uH~10mH.

The second aspect of the present invention provides a kind of household appliance, comprising: load；As described in any of the above-described technical solution Drive control circuit, between network system and load, the drive control circuit is matched for drive control circuit access Control network system is set to the load supplying.

In the technical scheme, household appliance includes the drive control circuit as described in any of the above-described technical solution, because This, which includes whole beneficial effects of the drive control circuit as described in any of the above-described technical solution, again not It repeats again.

In the above-mentioned technical solutions, further, the household appliance includes air conditioner, refrigerator, fan, smoke pumping At least one of machine, dust catcher and host computer.

Detailed description of the invention

Above-mentioned and/or additional aspect of the invention and advantage will become from the description of the embodiment in conjunction with the following figures Obviously and it is readily appreciated that, in which:

Fig. 1 shows the schematic diagram of drive control circuit according to an embodiment of the invention；

Fig. 2 shows the schematic diagrames of drive control circuit according to another embodiment of the invention；

Fig. 3 shows the schematic diagram of drive control circuit according to still another embodiment of the invention；

Fig. 4 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Fig. 5 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Fig. 6 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Fig. 7 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Fig. 8 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Fig. 9 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 10 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 11 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 12 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 13 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 14 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 15 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 16 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 17 shows the schematic diagrames of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 18 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 19 shows the schematic diagram of the drive control circuit of still another embodiment in accordance with the present invention；

Figure 20 shows the block diagram of household appliance according to an embodiment of the invention.

Specific embodiment

To better understand the objects, features and advantages of the present invention, with reference to the accompanying drawing and specific real Applying mode, the present invention is further described in detail.It should be noted that in the absence of conflict, the implementation of the application Feature in example and embodiment can be combined with each other.

In the following description, numerous specific details are set forth in order to facilitate a full understanding of the present invention, still, the present invention may be used also To be implemented using other than the one described here other modes, therefore, protection scope of the present invention is not by described below Specific embodiment limitation.

The drive control circuit described according to some embodiments of the invention and household appliance are described referring to Fig. 1 to Figure 19.

As shown in Fig. 1 (load is threephase load) and Fig. 2 (load is single-phase load), in the implementation of first aspect present invention In example, a kind of drive control circuit is provided, comprising: filter inductance L, the filter inductance L are configured as filtering out the power supply Harmonic signal in signal, filter inductance L are set in the alternating current circuit of rectification module prime, and/or are set to the rectification module In the two buss lines of rear class；Voltage absorption compensation branch, with inverter parallel, the voltage absorption compensation branch includes concatenated Capacitive element C₁And switching device, the switching device are configured as controlling the capacitive element C₁Charge or discharge are carried out, In, the capacitive element C₁Electric discharge carries out voltage compensation to the inverter, and the inverter is configured as driving load running.

In this embodiment, drive control circuit is provided with filter inductance L, for filter out network system input for telecommunications Harmonic signal in number, meanwhile, drive control circuit is additionally provided with capacitive element C₁And switching device.Switching device and capacitive member Part C₁Series connection, and control capacitive element C₁Charge or discharge.When power supply signal is higher, switching device controls capacitive element C₁It fills Electricity.When power supply signal is lower, switching device controls capacitive element C₁Electric discharge, to carry out voltage compensation to inverter.

Above-described embodiment provided by the invention controls capacitive by switching device if detecting that power supply signal is too low Element C₁Electric discharge, to realize to the voltage compensation of inverter, wherein capacitive element C₁The capacitor that capacity need not be selected very big can drop The cost of low-voltage compensation circuit, avoids system power from fluctuating, to solve caused when the alternating voltage of input is too low Beat frequency noise problem.

Specifically, capacitive element C₁It is the electrolytic capacitor of 10uF to 2000uF that capacitance range, which can be used, is held without selecting It is worth bigger capacitor, it can be achieved that preferable cost control, controller M is according to collected ac voltage size driving switch pipe Change switching mode, to control electrolytic capacitor charge or discharge, has both two sides for reducing load current peak and voltage compensation Face effect.

In one embodiment of the invention, further, as (load is single-phase by Fig. 1 (load is threephase load), Fig. 2 Load), Fig. 3 (load be threephase load) and Fig. 4 (load is single-phase load) shown, Fig. 5 (loading is threephase load) and Fig. 6 Shown in (load is single-phase load), the inverter access is between high voltage bus and low-voltage bus bar, and the one of the switching device End is connected to the high voltage bus, the capacitive element C₁One end be connected to the low-voltage bus bar, the two buss lines include The high voltage bus and the low-voltage bus bar.

In this embodiment, inverter access turns the direct current signal on bus between high voltage bus and low-voltage bus bar Turn to the AC signal of driving load running.One end of switch element is connected to high voltage bus, capacitive element C₁An end be connected to it is low Bus is pressed, to realize to capacitive element C₁Charging, the control discharged.

In one embodiment of the invention, further, as shown in Fig. 5, Fig. 6, Fig. 7, Fig. 8 and Fig. 9, drive control electricity Road further include: controller M, the controller M are connected to the switching device, to regulate and control the on state of the switching device； Wherein, if the power supply signal is greater than or equal to the first power supply signal threshold value, the controller M trigger the switching device with First mode conducting, to control the capacitive element C₁Charge, in addition, if the controller M detect it is described for telecommunications Number less than the second power supply signal threshold value, then the controller M triggers the switching device and is connected in a second mode, described in control Capacitive element C₁It discharges.

In this embodiment, controller M is according to the conduction mode of the size control switch device of power supply signal.Specifically, When ac voltage signal is more than first voltage threshold value, illustrate that alternating voltage is higher, controller M control switch device is at this time with the One mode conducting, for capacitive element C₁Charging reduces load current amplitude；When ac voltage signal is less than second voltage threshold value When, illustrate that alternating voltage is too low at this time, controller M control switch device is connected in a second mode at this time, so that capacitive element C₁ Electric discharge carries out power compensation to inverter.

Wherein, the first power supply signal threshold value and the second power supply signal threshold value can take same numerical value or different numerical value, and the One power supply signal threshold value and the second power supply signal threshold value are mainly determined by the power of the power and inverter that load.

Wherein, power supply signal can be the alternating voltage of input rectifying module, be also possible to the direct current of rectification module output Voltage.

In one embodiment of the invention, further, as shown in Figure 1, Figure 2 and Figure 3, the switching device includes: Power tube Q, with the capacitive element C₁Series connection, the control terminal of the power tube Q are connected to the instruction output of the controller M End, described instruction output end export control instruction to the control terminal, and the control instruction is configured as controlling the power tube Q On or off；Reverse-biased sustained diode₁, the reverse-biased sustained diode₁Both ends be respectively connected to the power tube Q's Drain electrode and source electrode, wherein if the power tube Q is connected, the capacitive element C₁It is put through the power tube Q to the load Electricity, if the power tube Q ends, the capacitive element C₁Through the reverse-biased sustained diode₁It charges or is failure to actuate.

In this embodiment, switching device includes power tube Q and reverse-biased sustained diode₁, power tube Q and capacitive element C₁ Series connection, the instruction output end of controller M are connected to the control terminal of power tube Q, to send control instruction, power tube Q to power tube Q Change on state (on or off) according to control instruction, reverse-biased sustained diode₁The both ends leakage with power tube Q respectively Pole is connected with source electrode, when power tube Q conducting, capacitive element C₁Through power tube Q to load discharge, to realize voltage compensation, When power tube Q cut-off, the voltage signal of input is through reverse-biased sustained diode₁For capacitive element C₁Charging, to reduce load electricity Stream peak value.Load current peak be normal water usually, without reducing load current peak, capacitive element C₁It is failure to actuate.

Wherein, the capacitive element C₁Through the reverse-biased sustained diode₁Charging refers to that power supply signal is through reverse-biased afterflow two Pole pipe D₁To capacitive element C₁It charges, meanwhile, power supply signal is powered the load of operation, capacitive element C₁It charged Journey is complete charging process, i.e. capacitive element C₁When electric discharge, capacitive element C₁Discharge voltage be greater than route on power supply electricity Pressure, and then realize voltage compensation.

Specifically, power tube Q can it is preferable to use IGBT (Insulated Gate Bipolar Transistor, insulation Grid bipolar junction transistor) type power tube Q, MOSFET (Metal-Oxide-Semiconductor Field- can also be selected Effect Transistor, metal-oxide semiconductor (MOS) power field effect transistor), reverse-biased sustained diode₁It can independently set It sets, it can also be integrally disposed with IGBT or MOSFET.

In one embodiment of the invention, further, as shown in Figure 1, Figure 2 and Figure 3, drive control circuit is also wrapped Include: rectification module is set to the capacitive element C₁Input terminal and the filter inductance between, the rectification module is configured as The power supply signal is converted into direct current signal, wherein the direct current signal is configured as to the capacitive element C₁Charging, with And electricity needed for providing the load running, the inverter are configured as controlling the direct current signal driving load fortune Row.

In this embodiment, rectification module is provided in drive control circuit, rectification module is connected to capacitive element C₁'s Between input terminal and filter module, the power supply signal of network system input enters rectification module after filter module filters out noise, Rectification module rectifies power supply signal, and by the DC signal output obtained after rectification to capacitive element C₁And load portion Point, with to capacitive element C₁Charging, and provide operation required electricity to load.Direct current signal is converted exchange letter by inverter Number, control driving load running.

In one embodiment of the invention, further, as shown in Fig. 5, Fig. 6, Figure 10 and Figure 11, if the load is wrapped Single-phase load is included, then the inverter includes corresponding single-phase inversion circuit, and the single-phase inversion circuit includes: two upper bridge arms Power device and two lower bridge arm power devices, access in the voltage absorption compensation branch output end and the load it is defeated Enter between end, if the load includes threephase load, the inverter includes corresponding three-phase inverting circuit, three contrary Power transformation road includes: three upper bridge arm power devices and three lower bridge arm power devices, is accessed in the voltage absorption compensation branch Output end and the load input terminal between, wherein the upper bridge arm power device phase corresponding with one of a phase The lower bridge arm power device series connection of position connects, the upper bridge arm power device and the lower bridge arm power device of same phase Part does not simultaneously turn on.

In this embodiment, if load includes single-phase load, corresponding single-phase inversion electricity is provided in inverter Road, to export corresponding driving signal to single-phase load.Specifically, single-phase load can be monophase machine, be also possible to single-phase Inductive load.

Wherein, single-phase inversion circuit includes two upper bridge arm power devices and two lower bridge arm power devices, is connected to appearance Property element C₁Deferent segment and load input terminal between.

If load includes threephase load, corresponding three-phase inverting circuit is provided in inverter, with negative to three-phase It carries and exports corresponding driving signal.Specifically, threephase load can be induction machine, be also possible to permanent magnet synchronous motor.

Wherein, three-phase inverting circuit includes three upper bridge arm power devices and three lower bridge arm power devices, is connected to appearance Between the deferent segment of property element and the input terminal of load.The lower bridge of the upper corresponding phase of bridge arm power device of each phase The series connection of arm power device, the upper bridge arm power device and lower bridge arm power device of same-phase will not simultaneously turn on, and negative to three-phase The load one phase driving signal of output of load, the upper bridge arm power device and lower bridge arm power device alternate conduction of three phases, to The load of threephase load exports three-phase driving signal.

In one embodiment of the invention, further, as shown in Fig. 7, Fig. 8, Fig. 9, Figure 11, Figure 12 and Figure 13, appoint It is connected to a reverse-biased freewheeling diode between the source electrode and drain electrode of the one upper bridge arm power device, is denoted as the reverse-biased afterflow of bridge arm Diode is connected to a reverse-biased freewheeling diode between the source electrode and drain electrode of any lower bridge arm power device, is denoted as lower bridge The reverse-biased freewheeling diode of arm.

In this embodiment, between upper bridge arm power device and the source electrode and drain electrode of lower bridge arm power device between be connected to one Reverse-biased freewheeling diode, the specially upper reverse-biased freewheeling diode of bridge arm and the reverse-biased freewheeling diode of lower bridge arm.

In one embodiment of the invention, further, any upper bridge arm power device includes metal oxide Semiconductor field effect transistor and/or insulated gate bipolar transistor, any lower bridge arm power device include metal oxidation Object semiconductor field effect transistor and/or insulated gate bipolar transistor, wherein the current collection of the insulated gate bipolar transistor Pole is connected as the drain electrode, and the emitter of the insulated gate bipolar transistor is connected as the source electrode.

In this embodiment, upper bridge arm power device includes Metal Oxide Semiconductor Field Effect Transistor (i.e. MOSFET) And/or insulated gate bipolar transistor (i.e. IGBT), in the case where having used insulated gate bipolar transistor, insulated gate bipolar The collector of transistor npn npn is connected as the drain electrode, and emitter is connected as the source electrode.Lower bridge arm power device includes gold Belong to oxide semiconductor field effect transistor (i.e. MOSFET) and/or insulated gate bipolar transistor (i.e. IGBT), is using In the case where insulated gate bipolar transistor, the collector of insulated gate bipolar transistor is connected as the drain electrode, emitter It is connected as the source electrode.

In one embodiment of the invention, further, the power tube Q includes metal oxide semiconductor field-effect Transistor and/or insulated gate bipolar transistor, wherein the grid conduct of the Metal Oxide Semiconductor Field Effect Transistor The control terminal is connected to the instruction output end of the controller M, described in the base stage of the insulated gate bipolar transistor is used as Control terminal is connected to the instruction output end of the controller M.

In this embodiment, power tube Q include Metal Oxide Semiconductor Field Effect Transistor (i.e. MOSFET) and/or absolutely Edge grid bipolar junction transistor (i.e. IGBT), wherein the grid of MOSFET as control terminal, the instruction output end of controller M with The grid of MOSFET is connected, and as control terminal, the instruction output end of controller M is connected the MOSFET of IGBT with the base stage of IGBT It connects.

In one embodiment of the invention, further, the filter inductance is serially connected in the drive control circuit At least one alternating current circuit, the alternating current circuit is for accessing the power supply signal, wherein the sensibility reciprocal of the inductive element takes Value range is 200uH~25mH.

In this embodiment, filter inductance is additionally provided with inductive element, and inductive element is connected in series in drive control circuit On at least one alternating current circuit (as depicted in figs. 1 and 2, shown in Fig. 7 and Fig. 8) that middle exchange is surveyed, inductive element is filter inductance, The clutter in the power supply signal carried on alternating current circuit is filtered out by filter inductance.

Optionally, the sensibility reciprocal value range of inductive element is 200uH~25mH.

Optionally, the sensibility reciprocal of inductive element is 500uH.

Optionally, the sensibility reciprocal of inductive element is 5mH.

In one embodiment of the invention, further, the filter inductance is serially connected with described high voltage bus (such as Fig. 5 With shown in Fig. 6, shown in Figure 13 and Figure 14) and/or the low-voltage bus bar (as shown in Figure 3 and Figure 4, shown in Figure 15 and Figure 16), institute State DC line carrying signal be the direct current signal, wherein the sensibility reciprocal value range of the inductive element be 200uH~ 25mH。

In this embodiment, inductive element is connected in series in the pressure bus and/or low pressure that direct current is surveyed in drive control circuit On bus, inductive element is filter inductance, and the clutter in the direct current signal carried on DC line is filtered out by filter inductance.

Optionally, the sensibility reciprocal value range of inductive element is 200uH~25mH.

Optionally, the sensibility reciprocal of inductive element is 500uH.

Optionally, the sensibility reciprocal of inductive element is 5mH.

In one embodiment of the invention, further, the load of the load includes blower and/or compressor, or The load of the load includes induction machine and/or permanent magnet synchronous motor.

In one embodiment of the invention, further, the capacitive element C₁Including electrolytic capacitor and/or described Capacitive element C₁It include the capacity cell of multiple series connection and/or parallel connection including a capacity cell and/or the capacitive element.

In one embodiment of the invention, further, the capacitive element C₁Capacitance value range be 10uF~ 2000uF。

Optionally, capacitive element C₁Capacitance be 82uF.

Optionally, capacitive element C₁Capacitance be 220uF.

Optionally, capacitive element C₁Capacitance be 470uF.

Optionally, capacitive element C₁Capacitance be 560uF.

Optionally, capacitive element C₁Capacitance be 680uF.

Optionally, capacitive element C₁Capacitance be 820uF.

In one embodiment of the invention, further, the power supply source of the controller M includes isolated power supply or bootstrapping Power supply, wherein the bootstrap power supply includes bootstrapping power supply circuit, bootstrap diode D in the inverter₂With bootstrap capacitor C₂, The bootstrap diode D₂Anode be connected to it is described bootstrapping power supply circuit anode, the bootstrap diode D₂Cathode connection To the bootstrap capacitor C₂Anode, the bootstrap capacitor C₂Anode be connected to the feeder ear of the controller M.

In this embodiment, controller M is provided with power supply, and specifically, power supply includes isolated power supply or bootstrapping Power supply is connected to the feeder ear of controller M by isolated power supply, provides electricity for controller M when power supply is isolated power supply Can, when power supply is bootstrap power supply, bootstrap power supply includes concatenated bootstrapping power supply circuit, isolated power supply or bootstrap power supply, The cathode of bootstrapping power supply circuit is connected with the low-voltage bus bar in two buss lines, the anode and bootstrap diode of power supply circuit of booting D₂Anode be connected, while bootstrap diode D₂Cathode and bootstrap capacitor C₂Anode be connected, bootstrap capacitor C₂Cathode It is connected to the feeder ear of controller M, to provide electric energy for controller M.

Optionally, it as shown in Fig. 7, Fig. 8, Fig. 9, Figure 10 and Figure 11, loads as threephase load, switching power supply includes control Device M and power supply processed, wherein power supply is bootstrap power supply.

Wherein, optionally, as shown in figure 9, bootstrap diode D₂It is set as one.

Wherein, optionally, as shown in Figure 10, bootstrap diode D₂It is set as two.

Wherein, optionally, as shown in figure 11, bootstrap diode D₂It is set as three.

Multiple bootstrap diode D₂The reliability of drive control circuit can be improved.

Optionally, as shown in figure 12, it loading as threephase load, switching power supply includes controller M and power supply, Middle power supply is isolated power supply.

Optionally, it as shown in Figure 13, Figure 15, loads as threephase load, switching power supply includes controller M and power supply electricity Source, wherein power supply is bootstrap power supply.

Optionally, it as shown in Figure 14 and Figure 16, Figure 17, Figure 18, loads as single-phase load, switching power supply includes control Device M and power supply, wherein power supply is bootstrap power supply.

Wherein, optionally, as shown in figure 17, bootstrap diode D₂It is set as one.

Wherein, optionally, as shown in figure 18, bootstrap diode D₂It is set as two.

Two bootstrap diode D₂The reliability of drive control circuit can be improved.

Optionally, as shown in figure 19, it loading as single-phase load, switching power supply includes controller M and power supply, Middle power supply is isolated power supply.

In one embodiment of the invention, the drive control circuit 100 of single-phase load is specifically comprising filter inductance, filtering Capacitor, rectification circuit, power switch tube, power diode, electrolytic capacitor, single-phase inversion circuit and single-phase load.Single phase ac Voltage source is converted to DC voltage after filter inductance and filter capacitor filtering, then after rectified circuit；Power switch tube and function Rate diodes in parallel, the emitter (or source electrode) of power switch tube, the cathode of power diode are connect with DC voltage anode, The collector (or drain electrode) of power switch tube, the anode of power diode are connect with electrolytic capacitor anode, electrolytic capacitor cathode It is connect with DC voltage negative terminal；DC voltage is powered to single-phase inversion circuit, drives single-phase load.

Preferably, the single-phase inversion circuit can be made of 4 IGBT or be made of 4 MOSFET, have simultaneously Inverse parallel freewheeling diode.

Preferably, the single-phase load, can be monophase machine, be also possible to single-phase inductive load.

As shown in Figure 1, Figure 2, shown in Fig. 3, Fig. 4, Fig. 5 and Fig. 6, in any of the above-described technical solution, further, the voltage Absorption compensation branch further include: with the capacitive element C₁Concatenated resistive element and/or inductance component L₀, the resistive element The capacitive element C is flowed through for adjusting₁Size of current, the inductance component L₀The capacitive element C is flowed through for filtering out₁ AC noise.

In the technical scheme, resistive element and/or inductance component L₀Can access in high voltage bus and switching device it Between, it can also access in capacitive element C₁Between low-voltage bus bar, it can also access in switching device and capacitive element C₁Between.

In addition, resistive element includes the resistance of a resistance or multiple series connection and/or parallel connection, similarly, inductance component L₀Packet Include the inductance an of inductance or multiple series connection and/or parallel connection.

In any of the above-described technical solution, further, the value range of the resistive element is the Ω of 0.1m Ω~10, institute State inductance component L₀Value range be 1uH~10mH.

As shown in figure 20, embodiment according to the present invention provides a kind of household appliance 300, comprising: load 200；As above Drive control circuit 100 described in any embodiment is stated, the access of drive control circuit 100 is in network system and load Between, the drive control circuit 100 is configured as control network system to 200 power supply of load.

In this embodiment, household appliance includes the drive control circuit 100 as described in above-mentioned any embodiment, because This, which includes whole beneficial effects of the drive control circuit 100 as described in above-mentioned any embodiment, again not It repeats again.

In one embodiment of the invention, further, the household appliance includes air conditioner, refrigerator, fan, pumping At least one of kitchen ventilator, dust catcher and host computer.

In description of the invention, term " multiple " then refers to two or more, unless otherwise restricted clearly, term The orientation or positional relationship of the instructions such as "upper", "lower" is to be merely for convenience of retouching based on orientation or positional relationship described in attached drawing It states the present invention and simplifies description, rather than the device or element of indication or suggestion meaning must have a particular orientation, with specific Orientation construction and operation, therefore be not considered as limiting the invention；Term " connection ", " installation ", " fixation " etc. should all It is interpreted broadly, for example, " connection " may be fixed connection or may be dismantle connection, or integral connection；It can be straight Connect it is connected, can also be indirectly connected through an intermediary.It for the ordinary skill in the art, can be according to specific feelings Condition understands the concrete meaning of above-mentioned term in the present invention.

In the description of the present invention, the description meaning of term " one embodiment ", " some embodiments ", " specific embodiment " etc. Refer to that particular features, structures, materials, or characteristics described in conjunction with this embodiment or example are contained at least one implementation of the invention In example or example.In the present invention, schematic expression of the above terms are not necessarily referring to identical embodiment or example.And And the particular features, structures, materials, or characteristics of description can be in any one or more of the embodiments or examples with suitable Mode combines.

The foregoing is only a preferred embodiment of the present invention, is not intended to restrict the invention, for the skill of this field For art personnel, the invention may be variously modified and varied.All within the spirits and principles of the present invention, made any to repair Change, equivalent replacement, improvement etc., should all be included in the protection scope of the present invention.

Claims (19)

1. a kind of drive control circuit characterized by comprising

Filter inductance, the filter inductance are configured as filtering out the harmonic signal in the power supply signal, and filter inductance is set to whole In the alternating current circuit of flow module prime, and/or in the two buss lines of the rectification module rear class；

Voltage absorption compensation branch, with inverter parallel, the voltage absorption compensation branch includes concatenated capacitive element and opens Device is closed, the switching device is configured as controlling the capacitive element progress charge or discharge,

Wherein, the capacitive element electric discharge carries out voltage compensation to the inverter, and the inverter is configured as driving load Operation.

2. drive control circuit according to claim 1, which is characterized in that

Between high voltage bus and low-voltage bus bar, it is female that one end of the switching device is connected to the high pressure for the inverter access Line, one end of the capacitive element are connected to the low-voltage bus bar.

3. drive control circuit according to claim 1, which is characterized in that

Controller, the controller are connected to the switching device, to regulate and control the on state of the switching device；

Wherein, if the power supply signal is greater than or equal to the first power supply signal threshold value, the controller triggers the derailing switch Part is connected in the first pattern, is charged with controlling the capacitive element,

In addition, if the controller detects the power supply signal less than the second power supply signal threshold value, the controller triggering The switching device is connected in a second mode, is discharged with controlling the capacitive element.

4. drive control circuit according to claim 3, which is characterized in that the switching device includes:

Power tube is connected with the capacitive element, and the control terminal of the power tube is connected to the instruction output end of the controller, Described instruction output end exports control instruction to the control terminal, and the control instruction is configured as controlling the power tube conducting Or cut-off；

The both ends of reverse-biased freewheeling diode, the reverse-biased freewheeling diode are respectively connected to drain electrode and the source electrode of the power tube,

Wherein, if the power tube be connected, the capacitive element through the power tube to the load discharge, if the power Pipe cut-off, then the capacitive element charges or is failure to actuate through the reverse-biased freewheeling diode.

5. drive control circuit according to claim 1, which is characterized in that further include:

The rectification module, between the input terminal and the network system of the capacitive element, the rectification module is matched It is set to and the power supply signal is converted into direct current signal,

Wherein, the direct current signal is configured as charging to the capacitive element, and electricity needed for the offer load running Amount, the inverter are configured as controlling the direct current signal driving load running.

6. drive control circuit according to claim 4, which is characterized in that

If the load includes single-phase load, the inverter includes corresponding single-phase inversion circuit, the single-phase inversion electricity Road includes:

Two upper bridge arm power devices and two lower bridge arm power devices are accessed in the output end of the voltage absorption compensation branch Between the input terminal of the load,

If the load includes threephase load, the inverter includes corresponding three-phase inverting circuit, the three-phase inversion electricity Road includes:

Three upper bridge arm power devices and three lower bridge arm power devices are accessed in the output end of the voltage absorption compensation branch Between the input terminal of the load,

Wherein, the upper bridge arm power device with the lower bridge arm power device of a corresponding phase of a phase are connected phase It connects, the upper bridge arm power device and the lower bridge arm power device of same phase do not simultaneously turn on.

7. drive control circuit according to claim 6, which is characterized in that

It is connected to a reverse-biased freewheeling diode between the source electrode and drain electrode of any upper bridge arm power device, it is anti-to be denoted as bridge arm Inclined freewheeling diode,

It is connected to a reverse-biased freewheeling diode between the source electrode and drain electrode of any lower bridge arm power device, it is anti-to be denoted as lower bridge arm Inclined freewheeling diode.

8. drive control circuit according to claim 6, which is characterized in that

Any upper bridge arm power device includes that Metal Oxide Semiconductor Field Effect Transistor and/or insulated gate bipolar are brilliant Body pipe,

Any lower bridge arm power device includes that Metal Oxide Semiconductor Field Effect Transistor and/or insulated gate bipolar are brilliant Body pipe,

Wherein, the collector of the insulated gate bipolar transistor is connected as the drain electrode, the insulated gate bipolar crystal The emitter of pipe is connected as the source electrode.

9. drive control circuit according to claim 6, which is characterized in that

The power tube includes Metal Oxide Semiconductor Field Effect Transistor and/or insulated gate bipolar transistor,

Wherein, the grid of the Metal Oxide Semiconductor Field Effect Transistor is connected to the controller as the control terminal Instruction output end, the base stage of the insulated gate bipolar transistor is connected to the instruction of the controller as the control terminal Output end.

10. drive control circuit according to any one of claim 1 to 9, which is characterized in that

The filter inductance is serially connected with the alternating current circuit, and the alternating current circuit is used to access the power supply signal,

Wherein, the sensibility reciprocal value range of the inductive element is 200uH~25mH.

11. drive control circuit according to any one of claim 1 to 9, which is characterized in that

The filter inductance is serially connected with the high voltage bus and/or the low-voltage bus bar, and the DC line carrying signal is institute Direct current signal is stated,

Wherein, the sensibility reciprocal value range of the inductive element is 200uH~25mH.

12. drive control circuit according to any one of claim 1 to 9, which is characterized in that

The load of the load includes blower and/or compressor,

Or the load of the load includes induction machine and/or permanent magnet synchronous motor.

13. drive control circuit according to any one of claim 1 to 9, which is characterized in that

The capacitive element includes electrolytic capacitor and/or the capacitive element includes a capacity cell and/or the capacitive Element includes the capacity cell of multiple series connection and/or parallel connection.

14. drive control circuit according to any one of claim 1 to 9, which is characterized in that

The capacitance value range of the capacitive element is 10uF~2000uF.

15. drive control circuit according to any one of claim 1 to 9, which is characterized in that

The power supply source of the controller includes isolated power supply or bootstrap power supply,

Wherein, the bootstrap power supply includes bootstrapping power supply circuit, bootstrap diode and the bootstrap capacitor in the inverter, described The anode of bootstrap diode is connected to the anode of the bootstrapping power supply circuit, the cathode of the bootstrap diode be connected to it is described from The anode of capacitor is lifted, the anode of the bootstrap capacitor is connected to the feeder ear of the controller.

16. according to claim 1 to drive control circuit described in 9, which is characterized in that the voltage absorption compensation branch also wraps It includes:

With the concatenated resistive element of the capacitive element and/or inductance element, the resistive element flows through the appearance for adjusting Property element size of current, the inductance element is for filtering out the AC noise for flowing through the capacitive element.

17. according to claim 1 to drive control circuit described in 9, which is characterized in that

The value range of the resistive element is the Ω of 0.1m Ω~10, and the value range of the inductance element is 1uH~10mH.

18. a kind of household appliance characterized by comprising

Load；

Drive control circuit as described in any one of claims 1 to 17, the drive control circuit access is in network system Between load, the drive control circuit is configured as control network system to the load supplying.

19. household appliance according to claim 18, which is characterized in that

The household appliance includes at least one of air conditioner, refrigerator, fan, smoke exhaust ventilator, dust catcher and host computer.