CN207884487U - Pfc circuit, electric machine control system and transducer air conditioning - Google Patents
Pfc circuit, electric machine control system and transducer air conditioning Download PDFInfo
- Publication number
- CN207884487U CN207884487U CN201820153520.XU CN201820153520U CN207884487U CN 207884487 U CN207884487 U CN 207884487U CN 201820153520 U CN201820153520 U CN 201820153520U CN 207884487 U CN207884487 U CN 207884487U
- Authority
- CN
- China
- Prior art keywords
- value
- current
- voltage
- bus
- pfc
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn - After Issue
Links
- 238000004378 air conditioning Methods 0.000 title claims abstract description 9
- 238000005070 sampling Methods 0.000 claims abstract description 38
- 230000005611 electricity Effects 0.000 claims description 17
- 230000001939 inductive effect Effects 0.000 claims description 17
- 230000007274 generation of a signal involved in cell-cell signaling Effects 0.000 claims description 7
- 238000001914 filtration Methods 0.000 claims description 5
- 238000001514 detection method Methods 0.000 claims description 4
- 238000007689 inspection Methods 0.000 claims 1
- 239000000203 mixture Substances 0.000 abstract description 3
- 235000013350 formula milk Nutrition 0.000 description 15
- 239000003990 capacitor Substances 0.000 description 14
- 238000010586 diagram Methods 0.000 description 14
- 238000004146 energy storage Methods 0.000 description 7
- 230000002459 sustained effect Effects 0.000 description 5
- 230000009466 transformation Effects 0.000 description 5
- 230000008859 change Effects 0.000 description 4
- 238000000034 method Methods 0.000 description 4
- 238000012546 transfer Methods 0.000 description 4
- 239000004065 semiconductor Substances 0.000 description 3
- 230000003068 static effect Effects 0.000 description 3
- 101100293261 Mus musculus Naa15 gene Proteins 0.000 description 2
- 238000012937 correction Methods 0.000 description 2
- 238000005516 engineering process Methods 0.000 description 2
- 238000011156 evaluation Methods 0.000 description 2
- 230000004907 flux Effects 0.000 description 2
- 230000001360 synchronised effect Effects 0.000 description 2
- 238000012360 testing method Methods 0.000 description 2
- 238000000844 transformation Methods 0.000 description 2
- 238000004804 winding Methods 0.000 description 2
- 241000208340 Araliaceae Species 0.000 description 1
- 235000005035 Panax pseudoginseng ssp. pseudoginseng Nutrition 0.000 description 1
- 235000003140 Panax quinquefolius Nutrition 0.000 description 1
- LEHOTFFKMJEONL-UHFFFAOYSA-N Uric Acid Chemical compound N1C(=O)NC(=O)C2=C1NC(=O)N2 LEHOTFFKMJEONL-UHFFFAOYSA-N 0.000 description 1
- 238000006243 chemical reaction Methods 0.000 description 1
- 230000000295 complement effect Effects 0.000 description 1
- 230000005347 demagnetization Effects 0.000 description 1
- 235000008434 ginseng Nutrition 0.000 description 1
- 230000006698 induction Effects 0.000 description 1
- 230000010354 integration Effects 0.000 description 1
- 239000002184 metal Substances 0.000 description 1
- 229910044991 metal oxide Inorganic materials 0.000 description 1
- 150000004706 metal oxides Chemical class 0.000 description 1
- 230000008569 process Effects 0.000 description 1
- 238000012545 processing Methods 0.000 description 1
- 238000005406 washing Methods 0.000 description 1
Classifications
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B70/00—Technologies for an efficient end-user side electric power management and consumption
- Y02B70/10—Technologies improving the efficiency by using switched-mode power supplies [SMPS], i.e. efficient power electronics conversion e.g. power factor correction or reduction of losses in power supplies or efficient standby modes
Abstract
The utility model provides a kind of pfc circuit, electric machine control system and transducer air conditioning, electric machine control system is by including reactor, rectification part, current detecting part, filter circuit, alternating voltage sampling unit, DC voltage sampling unit and calculation control unit composition, and rectification part is by including that the concatenated rectification unit of two rectifier diodes and two concatenated switch units of switching tube are formed in parallel, full-wave rectifying circuit is constituted with this, calculation control unit includes PFC calculation control units, by the DC bus-bar voltage given value for obtaining motor operation, and according to AC-input voltage value, d-c bus voltage value, DC bus current value and DC bus-bar voltage given value generate the switching tube work of PFC duty cycle of switching signals driving rectification part, to carry out Active PFC to the alternating current of input.The relatively existing pfc circuit of the pfc circuit of the utility model embodiment can effectively improve efficiency, reduce common mode noise, and the reliability of entire electric machine control system is improved with this.
Description
Technical field
The utility model is related to convertible frequency air-conditioner technical field more particularly to pfc circuit, electric machine control system and convertible frequency air-conditioners
Device.
Background technology
In order to cope with household appliances power conservation requirement, convertible frequency air-conditioner is developed rapidly, and active power factor correction is
It is widely used in convertible frequency air-conditioner electric control part.The automatically controlled power factor correction portion of major part convertible frequency air-conditioner uses Boost at present
(boosting) type circuit after electric current flows through rectifier bridge, supplies motor inverter, the electricity of this type after inductance and diode
Control is the disadvantage is that AC-DC (AC-DC) transfer efficiency is relatively low;Or there is a kind of PFC (Active PFC) of no bridge mode
Circuit, although the pfc circuit of this no bridge mode improves AC-DC transfer efficiencies to a certain extent, but there are common-mode noises
Big problem.
The above is only used for auxiliary and understands the technical solution of the utility model, does not represent and recognizes that the above is existing
Technology.
Utility model content
The main purpose of the utility model is to provide a kind of pfc circuit, electric machine control system and transducer air conditioning, purposes
It is to solve the problems, such as in existing pfc circuit that there are transfer efficiency is relatively low or common-mode noise is big.
To achieve the above object, a kind of pfc circuit provided by the utility model, the pfc circuit include reactor, rectification
Portion, current detecting part, filter circuit, alternating voltage sampling unit, DC voltage sampling unit and calculation control unit;The reactor connects
The input terminal of AC power is connect, the reactor and rectification part are connected in ac power supply circuit;The rectification part output end connects
DC bus is connect, the filter circuit is connect by the DC bus with the rectification part;The current detecting part is connected on
On the DC bus;
The rectification part includes the first switch pipe and of the first diode, the second diode and included fly-wheel diode
The L lines of two switching tubes, points of common connection and AC power after first diode and the second Diode series connect;It is described
The N lines of points of common connection and AC power after first switch pipe and the series connection of second switch pipe connect;The first switch pipe and
One end after the series connection of second switch pipe connects first diode cathode, after the first switch pipe and second switch pipe are connected
The other end connect second diode anode, the control terminal of the first switch pipe and second switch pipe is separately connected described
Calculation control unit;Wherein
The current detecting part is used to detect the electric current on the DC bus, and obtains corresponding DC bus current
Value;The filter circuit is used to carry out smothing filtering to the direct current that the rectification part exports to export DC bus-bar voltage;Institute
Alternating voltage sampling unit is stated for detecting AC-input voltage, and obtains corresponding AC-input voltage value;The DC voltage
Sampling unit obtains corresponding d-c bus voltage value for detecting the DC bus-bar voltage;
The calculation control unit includes PFC calculation control units, and the PFC calculation control units are for obtaining the straight of motor operation
Busbar voltage given value is flowed, and according to the AC-input voltage value, the d-c bus voltage value, the DC bus current
Value and the DC bus-bar voltage given value generate PFC duty cycle of switching signals and the switching tube of the rectification part are driven to work,
To carry out Active PFC to the alternating current of the input.
Preferably, the current detecting part is connected between the rectification part and the filter circuit, described in detection
DC bus current determines the current value by the reactor.
Preferably, the current detecting part is connected on the electrode line of the DC bus.
Preferably, the current detecting part is connected in the negative line of the DC bus.
Preferably, the electric machine control system includes phase current sampling portion and inverter;
The phase current sampling portion is used to sample the phase current signal of the motor and is input to the calculation control unit;
The inverter input terminal connects the DC bus, and the inverter output end connects motor;
The calculation control unit further includes motor calculation control unit, and the motor calculation control unit is used for according to the direct current
The rotating speed of target value of bus voltage value, the phase current signal of the motor and the motor, which calculates, generates pulse width signal,
The calculation control unit also generates triangle carrier signal, and is generated according to the triangle carrier signal and the pulse width signal
Pwm control signal is to the inverter, to drive the motor operation.
Preferably, the motor calculation control unit includes:
Location/velocity estimation module is estimated to estimate with the rotor angle for obtaining motor for the rotor-position to motor
Evaluation and motor speed estimated value;
Q axis gives current value computing module, for calculating Q axis according to motor rotating speed of target value, motor speed estimated value and giving
Constant current value;
D axis gives current value computing module, for according to the maximum output voltage of inverter and the output voltage of inverter
Amplitude calculates D axis and gives current value;
Current control module, for giving current value according to the Q axis, the D axis gives current value, the motor speed
It estimated value, the d-c bus voltage value and the phase current values of motor sampling calculate generates the pulse width and believes
Number, and the pwm control signal is generated to the inverter according to the triangle carrier signal and the pulse width signal, with
Drive the motor operation.
Preferably, the PFC calculation control units include that weak magnetic critical voltage value computing module, AC voltage parameter determine mould
Block, weak magnetic critical voltage value clipping module, inductive current given value computing module, inductor current value computing module, PFC switch letters
Number duty ratio computing module and switching signal generation module;Wherein
The weak magnetic critical voltage value computing module, for according to the Q axis given voltage value, the D axis given voltage
Weak magnetic critical voltage value when motor operation is calculated in value and index of modulation Kmax;
The AC voltage parameter determining module, the AC-input voltage value for being acquired according to alternating voltage sampling unit,
Calculate that respectively obtain AC-input voltage polarity mark signal, AC-input voltage virtual value, AC-input voltage absolute
Value and zero passage detection signal;
The weak magnetic critical voltage value clipping module is described straight for being obtained to weak magnetic critical voltage value progress amplitude limit
Flow busbar voltage given value;
The inductive current given value computing module, for female according to the DC bus-bar voltage given value and the direct current
Line voltage value carries out that the inductive current given value is calculated;
The inductor current value computing module, for the inductive current to be calculated according to the DC bus current value
Value;
The PFC switching signals duty ratio computing module, for according to the inductive current given value and inductance electricity
The PFC switching signals duty cycle signals are calculated in flow valuve;
The switching signal generation module, for according to the PFC switching signals duty cycle signals, AC-input voltage pole
Switching signal is calculated to control the first switch pipe or described in property beacon signal and alternating voltage zero-crossing signal
Two switching tubes switch work.
To achieve the above object, the utility model also provides a kind of electric machine control system, including the PFC circuits.
To achieve the above object, the utility model also provides a kind of transducer air conditioning, including the electric machine control system.
Pfc circuit provided by the utility model applied to electric machine control system, by including reactor, rectification part, electric current
Test section, filter circuit, alternating voltage sampling unit, DC voltage sampling unit and calculation control unit composition, and rectification part is by including
The concatenated rectification unit of two rectifier diodes and two concatenated switch units of switching tube are formed in parallel, and it is whole to be constituted all-wave with this
Current circuit, calculation control unit include PFC calculation control units, by obtaining the DC bus-bar voltage given value of motor operation, and root
PFC is generated according to AC-input voltage value, d-c bus voltage value, DC bus current value and DC bus-bar voltage given value to open
The switching tube work for closing duty cycle signals driving rectification part, to carry out Active PFC to the alternating current of input.This practicality is new
The relatively existing pfc circuit of the pfc circuit of type embodiment can effectively improve efficiency, reduce common mode noise, be improved entirely with this
The reliability of electric machine control system.
Description of the drawings
Fig. 1 is the electrical block diagram of the utility model pfc circuit first embodiment;
Fig. 2 is another electrical block diagram of the utility model pfc circuit first embodiment;
Fig. 3 is current loop schematic diagram of the electric current from the reactors of L lines in energy storage in first embodiment;
Fig. 4 is the current loop schematic diagram that electric current charges to electrolytic capacitor from L lines in first embodiment;
Fig. 5 is current loop schematic diagram of the electric current from the reactors of N lines in energy storage in first embodiment;
Fig. 6 is the current loop schematic diagram that electric current charges to electrolytic capacitor from N lines in first embodiment;
Fig. 7 is the sine wave modulation waveform diagram of the pwm signal of the control inverter in first embodiment;
Fig. 8 is the correspondence of the pwm signal and isosceles triangle carrier signal of the control inverter in first embodiment
Schematic diagram;
Fig. 9 is 51 output pwm signal waveform of PFC calculation control units and the friendship of the utility model pfc circuit second embodiment
Galvanic electricity stream waveform diagram;
Figure 10 is the motor calculation control unit high-level schematic functional block diagram of the utility model pfc circuit 3rd embodiment;
Figure 11 be motor D axle inductances and Q axle inductances with electric current change curve;
Figure 12 is the PFC calculation control unit high-level schematic functional block diagrams of the utility model pfc circuit fourth embodiment.
Specific implementation mode
The embodiments of the present invention are described below in detail, examples of the embodiments are shown in the accompanying drawings, wherein from beginning
Same or similar element or element with the same or similar functions are indicated to same or similar label eventually.Below by ginseng
The embodiment for examining attached drawing description is exemplary, it is intended to for explaining the utility model, and should not be understood as to the utility model
Limitation.
Referring to Fig.1, Fig. 1 is the pfc circuit structural schematic diagram that the utility model first embodiment provides, for the ease of saying
It is bright, illustrate only with the relevant part of the utility model embodiment, details are as follows:
The PFC of the utility model embodiment is applied to electric machine control system, including reactor L, rectification part 4, current detecting
Portion 3, filter circuit 7, alternating voltage sampling unit 2, DC voltage sampling unit 6 and calculation control unit 5;Wherein
The input terminal of reactor L connections AC power 1, reactor L and rectification part 4 are connected in ac power supply circuit.
4 output end of rectification part connects DC bus, and filter circuit 7 is connect by DC bus with rectification part 4;Filter circuit
The 7 direct current progress smothing filterings for export to rectification part 4 to export DC bus-bar voltage, in figure filter circuit 7 mainly by
Electrolytic capacitor EC compositions.
Current detecting part 3 is connected on DC bus, for detecting DC bus current value Idc, current detecting part 3 here
Can be based on the current sampling circuit of series resistance type, then the difference channel by being connect with resistance both ends exports, such sampling
Circuit belongs to the prior art, and details are not described herein.
Alternating voltage sampling unit 2 and DC voltage sampling unit 6 are respectively used to Sample AC input voltage value Uac and direct current
Bus voltage value Udc, here DC voltage sampling unit 6 can based in figure by the first divider resistance R4 and the second divider resistance R5
The circuit of simple pressure sampling circuit in series, alternating voltage sampling unit 2 can be identical as DC voltage sampling unit 6,
It can be based on the voltage sampling circuit of other existing voltage sampling circuits such as transformer device structure type.
Calculation control unit 5 includes PFC calculation control units 51, and PFC calculation control units 51 are used to obtain the direct current of motor operation
Busbar voltage given value Udref, and according to AC-input voltage value Uac, d-c bus voltage value Udc, DC bus current value
Idc and DC bus-bar voltage given value Udref generates the switching tube work of PFC duty cycle of switching signals driving rectification part 4, with
Active PFC is carried out to the alternating current of input.
Specifically, rectification part 4 includes the first rectification unit 41 and second switch unit 42, the first rectification unit 41 includes string
The the first diode D1 and the second diode D3 of connection, second switch unit 42 include first opening for concatenated included fly-wheel diode
Pipe S7 and second switch pipe S8 is closed, the first rectification unit 41 and second switch unit 42 are in parallel, and first switch pipe S7 and second is opened
The control terminal for closing pipe S8 is separately connected calculation control unit 5, the total contact and first of the first diode D1 and the second diode D3
The total contact of switching tube S7 and second switch pipe S8 are separately connected the L lines and N lines of AC power, and being constituted AC power with this returns
Road.
In figure the first diode D1 and the second diode D3 can be common low speed rectifier diode, first switch pipe S7 and
Second switch pipe S8 is metal-oxide-semiconductor (Metal Oxid Semiconductor, metal-oxide semiconductor (MOS)), naturally it is also possible to be it
The power tube of his type such as IGBT pipes (Insulated Gate Bipolar Transistor, insulated gate bipolar transistor),
First diode D1 and the second diode D3 series connection are the cathode of the second diode D3 of anode connection of the first diode D1, and the
Firewire, that is, L lines of points of common connection and AC power after one diode D1 and the second diode D3 series connection connect, the one or two pole
The poles S, that is, source electrode of the cathode connection first switch pipe S7 of pipe D1, the D of the anode connection second switch pipe S8 of the second diode D3
Pole drains, and first switch pipe S7 connect second switch pipe S8's with the poles D that the S8 series connection of second switch pipe is first switch pipe S7
The poles S, and first switch pipe S7 is connect with the concatenated points of common connection of second switch pipe S8 with AC power N lines, fly-wheel diode
The anode and cathode of D5 is separately connected the poles D and the poles S of first switch pipe S7, and sustained diode 6 is integrated in first switch pipe S7
The anode and cathode in portion, sustained diode 6 is separately connected the poles D and the poles S of second switch pipe S8, and sustained diode 6 is integrated in
Inside second switch pipe S8.
Above-mentioned current detecting part 3 is connected on the positive line side of DC bus in Fig. 1, can also be connected on DC bus
Cathode line side, as shown in Fig. 2, its to detect the function of DC bus current value Idc identical as Fig. 1.Current detecting part 3 is specific
It can be connected between rectification part 4 and the filter circuit 7.
Pfc circuit operation principle shown in the present embodiment is as follows:It is helped by reactor L, rectification part 4 and electrolytic capacitor EC groups
Wave current rectifying and wave filtering circuit, as shown in figure 3, when PFC calculation control units 51 control the S7 conductings of first switch pipe, second switch pipe S8
When cut-off, at this time AC power electric current from firewire, that is, L lines through the first diode D1, the poles S of first switch pipe S7 and the poles D,
Reactor L returns to AC power zero curve i.e. N lines and constitutes circuit, realizes the energy storage to reactor L;When PFC calculation control units 51 are controlled
When first switch pipe S7 cut-offs processed, as shown in figure 4, generating induced electromotive force on reactor L, the electric current that electromotive force generates flows through
It is consistent before the current direction of reactor L and the S7 cut-offs of first switch pipe, the electricity that the induced electromotive force of reactor L generates at this time
The first diode D1, current detecting part 3, electrolytic capacitor EC, the sustained diode 6 of second switch pipe S8, reactor L is flowed through to return
Circuit is constituted to charge to electrolytic capacitor EC to AC power zero curve, that is, N lines, and AC power electric current is realized from L with this
Phasing, that is, the Active PFC for the alternating voltage and alternating current that slave rectification part 4 when line starting direction inputs.
And when PFC calculation control units 51 control the S7 cut-offs of first switch pipe, when the S8 conductings of second switch pipe, such as Fig. 5 institutes
Show, at this time AC power electric current from zero curve, that is, N lines through reactor L, the poles S of second switch pipe S8 and the poles D, the second diode
D3 returns to AC power firewire i.e. L lines and constitutes circuit, realizes the energy storage to reactor L;When PFC calculation control units 51 control second
When switching tube S8 cut-offs, as shown in fig. 6, generating induced electromotive force on reactor L, the electric current that electromotive force generates flows through reactor
It is consistent before the current direction of L and the S8 cut-offs of second switch pipe, the electric current warp that the induced electromotive force of reactor L generates at this time
The sustained diode 5 of first switch pipe S7, current detecting part 3, electrolytic capacitor EC, the second diode D3 return to AC power fire
Line, that is, L lines constitutes circuit to charge to electrolytic capacitor EC, with this realize AC power electric current from N line starting directions when
Phasing, that is, Active PFC of the alternating voltage and alternating current that are inputted from rectification part 4.
Therefore, PFC calculation control units 51 pass through the alternate conduction of control first switch pipe S7 and second switch pipe S8 respectively
And cut-off, realize the Active PFC function under full-wave rectification pattern.
Further, the electric machine control system cited in the pfc circuit of the utility model embodiment further includes that phase current is adopted
Sample portion 9, phase current sampling portion 9 are used to detect the phase current signal of motor 10, and obtain corresponding phase current values, are input to operation
Control unit 5, such as phase current signal Iu, Iv, Iw in Fig. 1, the current sample that current sample portion 9 can be based on three resistance and single electron
Scheme is realized, belongs to the prior art, details are not described herein.
8 input terminal of inverter connects DC bus, is that inverter 8 provides the DC power supply described in work by rectification busbar,
8 output end of inverter connects motor 10, and calculation control unit 5 further includes motor calculation control unit 52, and motor calculation control unit 52 is used
According to phase current signal Iu, Iv, Iw of d-c bus voltage value Udc, motor and the rotating speed of target value ω ref of motor 10
It calculates and generates pulse width signal, calculation control unit 5 also generates triangle carrier signal, and wide according to triangle carrier signal and pulse
It spends signal and generates pwm control signal to inverter 8, run with driving motor 10.
Specifically, motor calculation control unit 52 passes through simultaneously according to phase current signal Iu, Iv, Iw of the motor 10 of sampling
The rotating speed of target value ω ref for further obtaining d-c bus voltage value Udc and motor 10 finally export six tunnels by calculating
Pwm control signal is to inverter 8, and pwm control signal is macroscopically being based on sine wave modulation principle, as shown in fig. 7, passing through
Lumbar triangle carrier wave S2 is modulated the pwm control signal waveform such as S1 finally obtained wherein all the way using sine voltage signal S3
Shown, the cycle T of PWM is traditionally arranged to be 100us-250us, finally by 8 driving motor 10 of inverter, due to motor around
The inductance characteristic of group finally forms sinusoidal waveform as shown in the dotted portion waveform S4 in Fig. 7 on three windings of motor 10.
Since the frequency of PWM is very high, carries out pulsewidth calculating in motor calculation control unit 52 and ultimately produce PWM control letters
Number when, be actually based on the Principle of Space Voltage Vector PWM (SVPWM) realization, that is, pass through calculate generate pulse width letter
Number, and continuous triangle carrier signal is generated by timer inside motor calculation control unit 52, and by above-mentioned pulse width
The mode final output pwm control signal that signal is compared with triangle carrier signal, pwm control signal share six tunnels, point
Not Kong Zhi inverter 8 S1-S6 six switching tubes work, last inverter 8 exports three-phase driving signal to the realization pair of motor 10
The driving of motor 10 is run.
As shown in figure 8, the triangle carrier signal waveform diagram that the timer inside motor calculation control unit 52 generates is such as
Shown in S6, as shown in Du1, Du2, Du3 in figure, practical Software Create pwm control signal waveform is pulse width signal
This pulse width signal is sent into comparand register, being based on triangular carrier S6 finally by timer produces wherein all the way
Pwm control signal is as shown in S5, and wherein each the triangular carrier cycle corresponds to one of pwm control signal period.Wherein S6
For triangle carrier signal in each triangle be isosceles triangle, the wave crest of each of which isosceles triangle in this isosceles three
The intermediate time of the effective pulse width of pwm control signal in angular carrier cycle is identical, such as first isoceles triangle in figure
The wave crest of shape corresponds to the midpoint b moment position at the a-c moment in effective pulse width, that is, figure of first pwm pulse waveform.It is logical
It crosses different pulse width signals and ultimately generates the different pwm control signal of different effective pulse widths.This PWM of wherein six roads
Control signal is added to six switching tubes of inverter 8 and finally constitutes three 120 ° of space phase mutual deviations when controlling motor 10
Vector finally synthesizes the voltage vector signal changed over time, and this voltage vector signal amplitude is constant, identical according to sine wave
Frequency rotation so that motor 10 this voltage vector signal control under realize operating.
The pfc circuit applied to electric machine control system of the utility model embodiment, by include reactor L, rectification part 4,
Current detecting part 3, filter circuit 7, alternating voltage sampling unit 2, DC voltage sampling unit 6 and calculation control unit 5 form, and whole
Stream portion 4 by including that the concatenated rectification unit of two rectifier diodes and two concatenated switch units of switching tube are formed in parallel, with
This constitutes full-wave rectifying circuit, and calculation control unit includes PFC calculation control units 51, by the DC bus electricity for obtaining motor operation
Press given value Udref, and according to AC-input voltage value Uac, d-c bus voltage value Udc, DC bus current value Idc and
DC bus-bar voltage given value Udref generates the switching tube work of PFC duty cycle of switching signals driving rectification part 4, with to input
Alternating current carry out Active PFC.The relatively existing pfc circuit of the pfc circuit of the utility model embodiment can be carried effectively
High efficiency reduces common mode noise, and the reliability of entire electric machine control system is improved with this.
Further, the second embodiment as pfc circuit provided by the utility model, the PFC based on the utility model
The first embodiment of circuit, in the present embodiment, the current value for passing through reactor by detecting DC bus current Idc determinations
IL, current detecting part 3 is in first switch pipe S7 or the intermediate time progress current sample of second switch pipe S8 closings.
Pfc circuit operation principle is illustrated in first embodiment it is found that controlling first switch pipe in PFC calculation control units 51
When S7 or second switch pipe S8 are opened, energy storage of the AC power electric current to reactor L passes through the electric current I of reactor at this timeL
Without electrolytic capacitor EC, will not charge at this time to electrolytic capacitor EC, therefore there is no electric current to flow through on DC bus, only
PFC calculation control units 51 control first switch pipe S7 or second switch pipe S8 when closing, the induction electric generated on reactor L
The electric current I that gesture generatesLIt can just charge to electrolytic capacitor EC, just there is electric current on DC bus at this time, therefore in order to accurate
Detect the electric current of DC bus, it should detect in first switch pipe S7 or second switch pipe S8 down periods.
Pwm signal waveform such as S7 control first switch pipe S7 that PFC calculation control units 51 as shown in Figure 9 export or the
The on off state of two switching tube S8 switches over, and when carrying out Active PFC to control pfc circuit, current detecting part 3 is right
The acquisition of DC bus current is control first switch pipe S7 or second switch pipe S8 in a pwm control signal period
Be the T2 periods in the period figure of closing intermediate time such as figure in the t1 moment sampled, due to first switch pipe
When the on off state of S7 or second switch pipe S8 switch over, reactor L can carry out the conversion of energy storage and release, above-mentioned
Reactor L energy storage during switching tube is opened, passes through the current value I of reactorLIncrease, and in electricity of above-mentioned switching tube down periods
The induced electromotive force that anti-device L is generated releases to the electrolytic capacitor electric discharge of filtering, passes through the current value I of reactorLReduce,
It passes through the alternating current I of reactor LLIt follows the waveform diagram of the PWM of switching tube as shown in the S8 in figure, is opened in switching tube
T1 devices its electric current increase opened, and its electric current reduces during the t2 that switching tube is closed, therefore select a suitable electric current
Sampled point is important, the problem that otherwise sampling error can be brought big.Due in first switch pipe S7 or second switch pipe S8
When unlatching, pass through the electric current i of reactorLWithout electrolytic capacitor EC, only in first switch pipe S7 or second switch pipe S8
When closing, pass through the electric current i of reactorLJust pass through electrolytic capacitor, i.e., the electric current i of reactor at this timeLFor DC bus current value
Idc, it is tests determined, it is handed over than accurate representative in the electric current that the intermediate time of above-mentioned switching tube down periods samples
Galvanic electricity stream each PWM cycle actual current value, such as I in figureL_ sample is the current value that actual samples obtain, size
Close to the electric current I of reactorLIn the average value of the PWM control signal device variations of entire switching tube, in this, as passing through electricity
The current value I of anti-deviceL, therefore ensure that the accuracy of sampled current value, hereby it is ensured that FC calculation control units 51 control switching tube
Work is accurate, and the accuracy of Active PFC is improved with this.
Further, the 3rd embodiment as pfc circuit provided by the utility model, the PFC based on the utility model
The first embodiment of circuit, as shown in Figure 10, the motor calculation control unit 52 of the electric machine control system of the present embodiment further includes:
Location/velocity estimation module 521 is estimated for the rotor-position to motor to obtain the rotor of motor 10
Angle estimation value θ est and motor speed estimated value ω est;
Q axis gives current value Iqref computing modules 522, for being estimated according to motor rotating speed of target value ω ref, motor speed
Evaluation ω est calculate Q axis and give current value Iqref;
D axis gives current value Idref computing modules 523, for according to the maximum output voltage Vmax of inverter and inversion
The output voltage amplitude V1 of device calculates D axis and gives current value Idref;
Current control module 524 gives current value Idref, motor speed for giving current value Iqref, D axis according to Q axis
Degree estimated value ω est, d-c bus voltage value Udc and phase current values Iu, Iv, Iw for being sampled to motor 10 calculate
Pwm control signal is generated to pulse width signal, and according to above-mentioned triangle carrier signal and pulse width signal to inverter 8,
To drive the motor 10 to run
Specifically, the motor 10 in the utility model embodiment can be the motor of position-sensor-free, location/velocity is estimated
When counting the rotor angle estimated values theta est and motor speed estimated value ω est of the determination motor 10 of module 521, it can be seen by magnetic linkage
Survey method realizes above-mentioned function, specifically, first can be according to the voltage V in two-phase stationary coordinate systemα、VβWith electric current Iα、IβIt calculates
The estimated value of compressor electric motor useful flux in two-phase stationary coordinate system α and β axis direction is counted with specific reference to following formula (1)
It calculates as follows:
Wherein,WithThe respectively estimated value of motor useful flux in α and β axis directions, VαAnd VβRespectively α and β
Voltage in axis direction, IαAnd IβElectric current respectively in α and β axis directions, R are stator resistance, LqJoin for the q axle inductances of motor
Number.
Then, the rotor angle estimated values theta est and motor actual speed of compressor electric motor are calculated according to following formula (2)
Value value ω est:
Wherein, Kp_pllAnd Ki_pllRespectively proportional integration parameter, θerrFor misalignment angle estimated value, ωfFor speed low pass filtered
The bandwidth of wave device.
Specifically, it includes superpositing unit and pi regulator that Q axis, which gives current value computing module 522,.Wherein, superpositing unit is used
It is calculated in the difference of motor rotating speed of target value ω ref and motor speed estimated value ω est, PI adjusters are used for according to above-mentioned
The difference of the motor rotating speed of target value ω ref and motor speed estimated value ω est of superpositing unit output carry out PI and adjust to export Q axis
Given current value Iqref.
Specifically, it includes weak magnetic controller and clipping unit that D axis, which gives current value computing module 523, wherein weak magnetic controls
Device be used to calculate with the output voltage amplitude V1 of inverter 8 the maximum output voltage Vmax of inverter 8 with obtain D axis to
Constant current value initial value Id0, clipping unit be used for D axis give current value initial value Id0 carry out amplitude limiting processing with obtain D axis to
Constant current value Idref.
In the embodiments of the present invention, at the beginning of weak magnetic controller can calculate the given current value of D axis according to following formula (3)
Initial value Id0:
Wherein, Id0Current value initial value, K are given for D axisiFor integral control coefficient, V1
For the output voltage amplitude of inverter, vdFor D shaft voltages, vqFor Q shaft voltages, VmaxFor the maximum output voltage of inverter 8, Vdc
The DC bus-bar voltage exported for rectifier 4.
In the embodiments of the present invention, clipping unit obtains D axis according to following formula (4) and gives current value:
Wherein, Idref is that D axis gives current value, IdemagFor motor demagnetization current limits value.
Specifically, the specific calculating of current control module 524 is as follows:
U, V, W three-phase electricity flow valuve Iu, Iv, Iw are obtained according to being sampled to motor 10, and passes through the static seat of three phase static-two-phase
It marks converting unit and carries out Clark transformation, be based on following formula (5), obtain motor in two-phase stationary coordinate system α and β axis direction
Electric current IαAnd Iβ
Iα=Iu
Further according to rotor angle estimated values thetaestPass through static-two cordic phase rotators converting unit of two-phase to carry out
Park is converted, and actual current value Iq, Id of D axis and Q axis under two-phase rotating coordinate system is calculated by following formula (6).
Id=Iαcosθest+Iβsinθest
Iq=-Iαsinθest+Iβcosθest (6)
Q shaft currents value and D shaft current value meters in current control module 524 are realized above by formula (5) and formula (6)
Calculate calculating of the unit to actual current value Iq, Id of D axis and Q axis.
Further, current control module 524 can calculate Q axis given voltage values and the given electricity of D axis according to following formula (7)
Pressure value:
Wherein, Vq is Q axis given voltage values, and Vd is D axis given voltage values, and Iqref is that Q axis gives current value, Idref is
D axis gives current value, and Iq is Q shaft currents, and Id is D shaft currents, and Kpd and Kid are respectively the control proportional gain of D shaft currents and product
It is respectively the control proportional gain of Q shaft currents and storage gain to divide gain, Kpq and Kiq, and ω is motor speed, and Ke is that motor 10 is anti-
The coefficient of potential, Ld and Lq are respectively D axis and Q axle inductances, the two parameters can be provided by motor manufacturer, specifically can basis
The motor D axis and Q axis that motor manufacturer provides with taking rated value therein in the change curve of electric current,Indicate the integrals of x (τ) in time.
Further, in order to further accurately obtain D axle inductance Ld and Q axle inductance Lq, current control module 524 is also
For:The phase current values of motor operation are obtained, and transfer the first phase current values to prestore and the second phase current values are corresponding
First Q axle inductances, the 2nd Q axle inductances value and the first D axle inductances, the 2nd D axle inductance values, according to phase current values and the first phase
Current value and the second phase current values, the first Q axle inductances, the 2nd Q axle inductances value and the first D axle inductances, the 2nd D axle inductance value meters
Calculate Q axle inductances and D axle inductance values.Specifically, the phase current signal Iu of motor 10 by obtaining 9 acquisition of current sample portion,
Iv, Iw, wherein these three phase current sizes are identical, only need to use one of them.The motor D axis that motor manufacturer provides
With the change curve of electric current as shown in Figure 11, wherein i is winding current, that is, phase current values of motor for inductance and Q axle inductances, this
When can be prestored by above-mentioned curve graph the first phase current values i1 and the corresponding first Q axle inductance values of the second phase current values i2
Lq1, the 2nd Q axle inductance value Lq2 and the first D axle inductance values Ld1, the 2nd D axle inductance value Ld2, and currently detected phase electricity
The corresponding D axle inductances value Ld and Q axle inductance values Lq of stream i can be calculated according to mathematic interpolation formula below:
Ld=Ld1+ (Ld2-Ld1) * (i-i1)/(i2-i1)
Lq=Lq1+ (Lq2-Lq1) * (i-i1)/(i2-i1)
Pass through corresponding D axle inductances Ld and Q the axis electricity of the phase current of the relatively accurate settled front motor 10 really of above-mentioned formula energy
Feel Lq values.
It, can be according to angle of rotor of motor estimated value after getting Q axis given voltage value Vq and D axis given voltage values Vd
θestPark inverse transformations are carried out by two-phase rotation-two-phase static coordinate converting unit to Vq and Vd, obtain what fixed coordinates were fastened
Voltage value V α and V β, specific transformation for mula (8) are as follows:
Wherein, θ is 10 rotor angle of motor, can use above-mentioned rotor angle estimated values theta est herein.
Further, can according to voltage value V α and the V β that fixed coordinates are fastened by two-phase it is static-three phase static coordinate turn
It changes unit and carries out Clark inverse transformations, obtain three-phase voltage Vu, Vv and Vw, specific transformation for mula (9) is as follows:
Vu=Vα
Then duty ratio computing unit can carry out duty ratio according to DC bus-bar voltage Udc and three-phase voltage Vu, Vv and Vw
It calculates, obtains duty cycle control signal, i.e. three-phase duty ratio Du, Dv and Dw, specific formula for calculation (10) is as follows:
Du=(Vu+0.5Vdc)/Vdc
Dv=(Vv+0.5Vdc)/Vdc
Dw=(Vw+0.5Vdc)/Vdc (10)
Wherein, Udc is DC bus-bar voltage.
Here three-phase duty cycle signals contain three road pulse width signals, such as a wherein phase duty ratio Du in Fig. 8
In different moments corresponding Du1, Du2, Du3 duty cycle signals, finally generated again by the timer inside calculation control unit
Triangle carrier signal generates corresponding three road pwm control signal to the upper bridge arm three-way switch pipe of inverter 8, and the three of lower bridge arm
Road controls signal and the three complementary road pwm control signals that are corresponding to it, therefore three-phase duty cycle signals here are practical contains
Six road pwm control signals, finally according to the corresponding six roads pwm control signal of three-phase duty ratio Du, Dv, Dw to the six of inverter 4
Way switch pipe is controlled, to realize that the driving to motor 10 is run.
Further, the fourth embodiment as pfc circuit provided by the utility model, the PFC based on the utility model
The 3rd embodiment of circuit, as shown in figure 12, in the present embodiment, PFC calculation control units 51 include weak magnetic critical voltage value Us
Computing module 511, AC voltage parameter determining module 512, weak magnetic critical voltage value Us clipping modules 513, inductive current are given
Value ILref computing modules 514, inductor current value ILIt computing module 516, PFC switching signal duty ratios computing module 515 and opens
OFF signal generation module 517;
Weak magnetic critical voltage value Us computing modules 511 are used for Q axis given voltage value Vq, D axis given voltage value Vd and tune
Weak magnetic critical voltage value Us when motor operation is calculated in COEFFICIENT K max processed.
AC voltage parameter determining module 512, the AC-input voltage value for being acquired according to alternating voltage sampling unit 2
Uac carries out calculating and respectively obtains AC-input voltage polarity mark signal, AC-input voltage virtual value Urms, exchange input
Absolute value of voltage | Uac | and zero passage detection signal, since AC-input voltage value Uac is the voltage value that sine wave changes,
It is not difficult to obtain above-mentioned parameter value by analyzing and calculating its real-time voltage value in a sine wave period.
Weak magnetic critical voltage value Us clipping modules 513 obtain direct current mother for carrying out amplitude limit to weak magnetic critical voltage value Us
Line voltage given value Udref.
Inductive current given value ILrefComputing module 514, for according to DC bus-bar voltage given value Udref and direct current
Bus voltage value Udc carries out that inductive current given value I is calculatedLref;
Inductor current value ILComputing module 516, for inductor current value I to be calculated according to DC bus current value IdcL;
PFC switching signal duty ratios computing module 515, for according to inductive current given value ILrefWith inductor current value IL
PFC switching signal duty cycle signals are calculated;
Switching signal generation module 517, for according to PFC switching signals duty cycle signals, AC-input voltage polarity mark
Know signal and switching signal is calculated to control first switch pipe S7 or second switch pipe S8 in alternating voltage zero-crossing signal
Switch work.
Specifically, weak magnetic critical voltage value Us clipping modules 513 are calculated based on following equation (11):
Wherein Vd is D axis given voltage values, and Vq is Q axis given voltage values, the two parameters are in above-mentioned 3rd embodiment
The current control module 524 of motor calculation control unit 52 be calculated based on formula (7), Kmax is the index of modulation, i.e. inversion
The ratio between device maximum output voltage and busbar voltage.If the case where considering linear modulation,
Further, weak magnetic critical voltage value Us is passed through amplitude limit [U by weak magnetic critical voltage value Us clipping modules 513dc_min,
Udc_max] after obtain the command value Udref of DC bus-bar voltage, wherein Udc_minIt is determined according to input voltage, usually takes Udc_min
=Uac_max+U0,Uac_maxFor the maximum value of alternating voltage, U0For constant, recommendation takes 5V-10V.Udc_maxAccording to system pressure resistance and protect
Certain surplus is stayed to determine, Udc_max=Urate-U1,UrateFor device pressure voltage, IPM module pressure resistances can used in the present embodiment
It is taken as 500V, i.e. Urate=500V, U1To retain pressure-resistant surplus, recommend 50V-100V, U in the present embodiment1It can be taken as 100V.
Further, inductive current given value ILrefInductive current given value I is calculated in computing module 514LrefWhen, first
DC bus-bar voltage given value Udref and d-c bus voltage value Udc are made the difference, and carry out PI controls, is multiplied by supply voltage
Absolute value | Uac |, multiplied by with the 1/U reciprocal of supply voltage virtual value square2Rms obtains the command value I of inductive currentLref。
Further, inductor current value ILInductor current value I is calculated in computing module 516LWhen, pass through DC bus electricity
Inductor current value I is calculated in flow valuve IdcL, in second embodiment it is found that DC bus current value Idc is first switch pipe
The inductor current value I that S7 or second switch pipe S8 down periods pass through reactor LL, therefore with DC bus current value Idc be
Inductor current value I can be representedL。
Further, when PFC switching signal duty cycle signals are calculated in PFC switching signals duty ratio computing module 515,
According to inductive current given value ILrefWith the actual value I of inductive currentLIt makes the difference, and carries out PI control acquisition PFC switching signals and account for
Sky ratio D.
Further, switching signal generation module 517 is finally according to PFC switching signal duty cycle signals D exchange input electricity
Polarity mark signal and alternating voltage zero-crossing signal is pressed finally to determine output to first switch pipe S7 or second switch pipe S8
The pwm control signal for switching work, to control pfc circuit work.
The PFC calculation control units 51 of the present embodiment calculate generate control switching tube work switching signal during, by
The pwm control signal for generating control inverter is being calculated finally to obtain the operation of motor 10 in introducing motor calculation control unit 52
Relevant parameter such as Q axis given voltage value Vq and D axis given voltage value Vd with obtain weak magnetic control parameter value, therefore its transport
Control process introduces the real-time parameter during motor 10 controls so that the control of pfc circuit can monitor motor 10 in real time
Loading condition and change, therefore control it is more accurate.
The utility model also provides a kind of electric machine control system, and electric machine control system can be used for driving permanent magnet synchronous motor
Operation can be applicable in the household appliance of the sampling permanent magnet synchronous motor work such as air conditioner or washing machine, the utility model
Electric machine control system includes the pfc circuit of above-mentioned the utility model embodiment, and can effectively improve entire electric machine control system can
By property.
The utility model also provides a kind of transducer air conditioning, and transducer air conditioning includes indoor unit part and outdoor machine part,
Wherein outdoor controller and/or indoor machine controller may include the electric machine control system described in the utility model embodiment,
To control indoor fan either outdoor fan or outdoor compressor operation, the reliable of entire transducer air conditioning can be effectively promoted
Property.
In the description of this specification, the description meaning of reference term " first embodiment ", " second embodiment ", " example " etc.
Refer at least one implementation that specific method, device or feature described in conjunction with this embodiment or example are contained in the utility model
In example or example.In the present specification, schematic expression of the above terms are necessarily directed to identical embodiment or show
Example.Moreover, specific features, method, apparatus or the feature of description can be in any one or more of the embodiments or examples to close
Suitable mode combines.In addition, without conflicting with each other, those skilled in the art can will be described in this specification
The feature of different embodiments or examples and different embodiments or examples is combined.
It these are only the preferred embodiment of the utility model, it does not limit the scope of the patent of the present invention, every
Equivalent structure or equivalent flow shift made based on the specification and figures of the utility model, is applied directly or indirectly in
Other related technical areas are equally included in the patent within the scope of the utility model.
Claims (9)
1. a kind of pfc circuit, the pfc circuit is applied to electric machine control system, which is characterized in that the pfc circuit includes electricity
Anti- device, rectification part, current detecting part, filter circuit, alternating voltage sampling unit, DC voltage sampling unit and calculation control unit;Institute
The input terminal of reactor connection AC power is stated, the reactor and rectification part are connected in ac power supply circuit;The rectification
Portion's output end connects DC bus, and the filter circuit is connect by the DC bus with the rectification part;The electric current inspection
Survey portion is connected on the DC bus;
The rectification part includes that the first switch pipe of the first diode, the second diode and included fly-wheel diode and second open
The L lines of Guan Guan, points of common connection and AC power after first diode and the second Diode series connect;Described first
The N lines of points of common connection and AC power after switching tube and the series connection of second switch pipe connect;The first switch pipe and second
One end after switching tube series connection connects first diode cathode, another after the first switch pipe and the series connection of second switch pipe
The control terminal of one end connection second diode anode, the first switch pipe and second switch pipe is separately connected the operation
Control unit;Wherein
The current detecting part is used to detect the electric current on the DC bus, and obtains corresponding DC bus current value;Institute
It states direct current of the filter circuit for being exported to the rectification part and carries out smothing filtering to export DC bus-bar voltage;The exchange
Voltage sample portion obtains corresponding AC-input voltage value for detecting AC-input voltage;The DC voltage sampling unit
For detecting the DC bus-bar voltage, and obtain corresponding d-c bus voltage value;
The calculation control unit includes PFC calculation control units, and the direct current that the PFC calculation control units are used to obtain motor operation is female
Line voltage given value, and according to the AC-input voltage value, the d-c bus voltage value, the DC bus current value with
And the DC bus-bar voltage given value generates PFC duty cycle of switching signals and the switching tube of the rectification part is driven to work, with right
The alternating current of the input carries out Active PFC.
2. pfc circuit as described in claim 1, which is characterized in that the current detecting part is connected on the rectification part and institute
Between stating filter circuit, pass through the current value of the reactor by detecting the DC bus current determination.
3. pfc circuit as claimed in claim 2, which is characterized in that the current detecting part is connected on the DC bus
On electrode line.
4. pfc circuit as claimed in claim 2, which is characterized in that the current detecting part is connected on the DC bus
In negative line.
5. pfc circuit as described in claim 1, which is characterized in that the electric machine control system include phase current sampling portion and
Inverter;
The phase current sampling portion is used to sample the phase current signal of the motor and is input to the calculation control unit;
The inverter input terminal connects the DC bus, and the inverter output end connects motor;
The calculation control unit further includes motor calculation control unit, and the motor calculation control unit is used for according to the DC bus
The rotating speed of target value of voltage value, the phase current signal of the motor and the motor, which calculates, generates pulse width signal, described
Calculation control unit also generates triangle carrier signal, and generates PWM according to the triangle carrier signal and the pulse width signal
Signal is controlled to the inverter, to drive the motor operation.
6. pfc circuit as claimed in claim 5, which is characterized in that the motor calculation control unit includes:
Location/velocity estimation module is estimated for the rotor-position to motor to obtain the rotor angle estimated value of motor
With motor speed estimated value;
Q axis gives current value computing module, for calculating the given electricity of Q axis according to motor rotating speed of target value, motor speed estimated value
Flow valuve;
D axis gives current value computing module, for according to the maximum output voltage of inverter and the output voltage amplitude of inverter
It calculates D axis and gives current value;
Current control module, for giving current value according to the Q axis, the D axis gives current value, the motor speed is estimated
It value, the d-c bus voltage value and the phase current values of motor sampling calculate generates the pulse width signal, and
The pwm control signal is generated to the inverter, with driving according to the triangle carrier signal and the pulse width signal
The motor operation.
7. pfc circuit as claimed in claim 6, which is characterized in that the PFC calculation control units include weak magnetic threshold voltage
Computing module, AC voltage parameter determining module, weak magnetic critical voltage value clipping module, inductive current given value computing module,
Inductor current value computing module, PFC switching signal duty ratio computing modules and switching signal generation module;Wherein,
The weak magnetic critical voltage value computing module, for according to the Q axis given voltage value, the D axis given voltage value with
And the weak magnetic critical voltage values of index of modulation Kmax when being calculated motor operation;
The AC voltage parameter determining module, the AC-input voltage value for being acquired according to alternating voltage sampling unit carry out
Calculating respectively obtain AC-input voltage polarity mark signal, AC-input voltage virtual value, AC-input voltage absolute value and
Zero passage detection signal;
The weak magnetic critical voltage value clipping module obtains the direct current mother for carrying out amplitude limit to the weak magnetic critical voltage value
Line voltage given value;
The inductive current given value computing module, for according to the DC bus-bar voltage given value and DC bus electricity
Pressure value carries out that the inductive current given value is calculated;
The inductor current value computing module, for the inductor current value to be calculated according to the DC bus current value;
The PFC switching signals duty ratio computing module, for according to the inductive current given value and the inductor current value
The PFC switching signals duty cycle signals are calculated;
The switching signal generation module, for according to the PFC switching signals duty cycle signals, AC-input voltage polarity mark
Show that switching signal is calculated to control the first switch pipe or described second open in signal and alternating voltage zero-crossing signal
It closes pipe and switchs work.
8. a kind of electric machine control system, which is characterized in that including pfc circuit as described in any one of claim 1 to 7.
9. a kind of transducer air conditioning, which is characterized in that including electric machine control system as claimed in claim 8.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201820153520.XU CN207884487U (en) | 2018-01-29 | 2018-01-29 | Pfc circuit, electric machine control system and transducer air conditioning |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201820153520.XU CN207884487U (en) | 2018-01-29 | 2018-01-29 | Pfc circuit, electric machine control system and transducer air conditioning |
Publications (1)
Publication Number | Publication Date |
---|---|
CN207884487U true CN207884487U (en) | 2018-09-18 |
Family
ID=63509116
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201820153520.XU Withdrawn - After Issue CN207884487U (en) | 2018-01-29 | 2018-01-29 | Pfc circuit, electric machine control system and transducer air conditioning |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN207884487U (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108123593A (en) * | 2018-01-29 | 2018-06-05 | 广东美的制冷设备有限公司 | Pfc circuit, electric machine control system and transducer air conditioning |
-
2018
- 2018-01-29 CN CN201820153520.XU patent/CN207884487U/en not_active Withdrawn - After Issue
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108123593A (en) * | 2018-01-29 | 2018-06-05 | 广东美的制冷设备有限公司 | Pfc circuit, electric machine control system and transducer air conditioning |
CN108123593B (en) * | 2018-01-29 | 2023-11-28 | 广东美的制冷设备有限公司 | PFC circuit, motor control system and variable frequency air conditioner |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN108054913B (en) | PFC circuit, motor control system and variable frequency air conditioner | |
CN108023473B (en) | PFC circuit, motor control system and variable frequency air conditioner | |
CN108199576B (en) | PFC circuit, motor control system and variable frequency air conditioner | |
CN107681929B (en) | Motor control system and variable frequency air conditioner | |
CN101025156B (en) | DC frequency-changeable compressor driving apparatus and method | |
CN108123593A (en) | Pfc circuit, electric machine control system and transducer air conditioning | |
CN105119536B (en) | A kind of motor driver topology and its control method | |
CN101674046A (en) | Electric current reconstructing and over-modulating device of air conditioning frequency converter and method thereof | |
CN207427006U (en) | Electric machine control system, transducer air conditioning | |
CN111130333B (en) | Control method, control device, PFC circuit, motor driving device and air conditioner | |
CN109713949A (en) | A kind of suppressing method and system of torque pulsation of brushless DC motor | |
CN106788048A (en) | Brushless DC motor control system and control method based on no electrolytic capacitor inverter | |
CN109525152A (en) | Motor drive control method, device and circuit | |
CN110299882B (en) | Three-vector model prediction control method for hybrid power supply type open winding permanent magnet synchronous motor | |
CN113238170B (en) | Inverter open-circuit fault on-line diagnosis method for motor control | |
CN108054914A (en) | Pfc circuit, electric machine control system and transducer air conditioning | |
CN108023474B (en) | PFC circuit, motor control system and variable frequency air conditioner | |
CN109004883A (en) | A kind of busbar voltage low-pressure area control method of small capacitances motor driven systems | |
CN111030442A (en) | Control method, control device, PFC circuit, motor driving device and air conditioner | |
CN207884488U (en) | Pfc circuit, electric machine control system and transducer air conditioning | |
CN209488475U (en) | Motor control assembly and electrical equipment based on FOC | |
CN207884487U (en) | Pfc circuit, electric machine control system and transducer air conditioning | |
CN207884485U (en) | Pfc circuit, electric machine control system and transducer air conditioning | |
CN208112505U (en) | Pfc circuit, electric machine control system and transducer air conditioning | |
CN207884486U (en) | Pfc circuit, electric machine control system and transducer air conditioning |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant | ||
AV01 | Patent right actively abandoned |
Granted publication date: 20180918 Effective date of abandoning: 20231128 |
|
AV01 | Patent right actively abandoned |
Granted publication date: 20180918 Effective date of abandoning: 20231128 |
|
AV01 | Patent right actively abandoned | ||
AV01 | Patent right actively abandoned |