CN106533283B - The control device and air conditioner of permanent magnet synchronous motor - Google Patents
The control device and air conditioner of permanent magnet synchronous motor Download PDFInfo
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- CN106533283B CN106533283B CN201611103994.5A CN201611103994A CN106533283B CN 106533283 B CN106533283 B CN 106533283B CN 201611103994 A CN201611103994 A CN 201611103994A CN 106533283 B CN106533283 B CN 106533283B
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Abstract
The invention discloses a kind of control device of permanent magnet synchronous motor and air conditioners, wherein, control device includes: AC-DC conversion module, PFC boost module, DC link section and direct exchange mold changing block, and the output end of direct exchange mold changing block is connected with permanent magnet synchronous motor;For acquiring the current sampling module of the phase current of permanent magnet synchronous motor;The temperature detecting module being inlaid on the radiator of direct exchange mold changing block, for detecting the temperature of radiator;The controller being connected respectively with temperature detecting module, current sampling module, DC link section and direct exchange mold changing block controls permanent magnet synchronous motor for changing the mold block according to temperature and phase current control direct exchange to change the mold block by direct exchange.The control device can guarantee to adjust the speed reliability, and the fan-out capability utilization rate of direct exchange mold changing block is high.
Description
Technical field
The present invention relates to frequency control fields, and in particular to a kind of control device and a kind of air-conditioning of permanent magnet synchronous motor
Device.
Background technique
With the promotion that consumer requires electronic product energy saving, more efficient permanent magnet synchronous motor has obtained more next
More it is widely applied.
Conventional passive PFC (Power Factor Correction) scheme frequency-variable controller and conventional active PFC scheme become
Frequency controller changes the mold block by direct exchange and realizes that direct current-three-phase alternating current inversion converts.Direct exchange changes the mold block as frequency conversion
The core component of controller, fan-out capability are limited by itself junction temperature, as shown in Figure 1, when direct exchange mold changing agllutination temperature is lower than
At 80 degrees Celsius, it is 20 amperes that direct exchange mold changing block, which allows to export current peak, when direct exchange mold changing agllutination temperature is greater than 80
When degree Celsius less than 140 degrees Celsius, direct exchange mold changing block allows to export current peak and linearly reduces, when direct exchange changes the mold block
Direct exchange mold changing block allows the current peak exported to be 12 amperes when junction temperature is 140 degrees Celsius.
In use, real-time change when direct exchange changes the mold block, temperature is also real-time change to frequency-variable controller,
How to realize that the control of fan-out capability automated intelligent is one of frequency-variable controller core technology.And current frequency-variable controller is mostly
Rule of thumb with actual test situation, determine the fan-out capability of frequency-variable controller, in order to ensure reliability would generally the volume of dropping make
With without making full use of direct exchange to change the mold the fan-out capability of block.
Summary of the invention
The present invention is directed to solve one of the technical problem in above-mentioned technology at least to a certain extent.
For this purpose, the first purpose of this invention is to propose a kind of control device of permanent magnet synchronous motor.The device can
Guarantee the reliability of speed regulation, and can make full use of the fan-out capability of direct exchange mold changing block.
Second object of the present invention is to propose a kind of air conditioner.
In order to achieve the above objectives, first aspect present invention embodiment proposes a kind of control device of permanent magnet synchronous motor,
It include: AC-DC conversion module, PFC boost module, DC link section and direct exchange mold changing block, wherein the AC-DC conversion
The input terminal of module is connected with AC power source, and the output end of the AC-DC conversion module passes through the PFC boost module and institute
The capacitor for stating DC link section is connected in parallel, and exports DC voltage, described in the input terminal input of the direct exchange mold changing block
The output end of DC voltage, the direct exchange mold changing block is connected with permanent magnet synchronous motor;Current sampling module, for acquiring
State the phase current of permanent magnet synchronous motor;Temperature detecting module, the temperature detecting module are inlaid in the direct exchange mold changing block
Radiator on, the temperature detecting module is used to detect the temperature of the radiator;Controller, the controller respectively with institute
It states temperature detecting module, the current sampling module, the DC link section to be connected with direct exchange mold changing block, the control
The maximum current that device allows to export for the mold changing block of the direct exchange according to the temperature computation, and according to the maximum current
The direct exchange is controlled with the phase current and changes the mold block, controls the permanent magnet synchronous electric to change the mold block by the direct exchange
Machine.
The control device of the permanent magnet synchronous motor of the embodiment of the present invention detects direct exchange mold changing by temperature detecting module
The temperature of the radiator of block acquires the phase current of permanent magnet synchronous motor by current acquisition module, and by controller according to scattered
The temperature of hot device obtains the maximum current for the output that direct exchange mold changing block allows, and then according to the phase of permanent magnet synchronous motor electricity
The maximum current for the output that stream, direct exchange mold changing block allow controls direct exchange and changes the mold block, to realize to permanent magnet synchronous motor
Control, thus can not only guarantee speed regulation reliability, and improve to direct exchange mold changing block fan-out capability utilization
Rate.
In addition, the control device of permanent magnet synchronous motor according to the above embodiment of the present invention can also have it is following additional
Technical characteristic:
According to one embodiment of present invention, the current sampling module includes: the first sampling resistor and the second sampling electricity
Resistance, first sampling resistor and the second sampling tube resistor change the mold two lower bridge arm strings of block with the direct exchange respectively
Connection connection, first sampling resistor and second sampling resistor acquire the permanent magnetism in each PWM carrier cycle T respectively
The corresponding biphase current I of synchronous motoru、Iv;Wherein, the controller is used for according to the biphase current Iu、IvCalculate third phase
Electric current Iw。
According to one embodiment of present invention, the current sampling module includes: third sampling resistor, the third sampling
One end of resistance is connected with the negative input end of direct exchange mold changing block, the other end ground connection of the third sampling resistor, institute
State the three-phase current I of third sampling resistor permanent magnet synchronous motor described in acquisition time in each PWM carrier cycle Tu、Iv、Iw。
According to one embodiment of present invention, the current sampling module includes: separate current sensor, the electric current every
It is connected from sensor with the output end of direct exchange mold changing block, the separate current sensor is in each PWM carrier cycle T
The three-phase current I of the interior acquisition permanent magnet synchronous motoru、Iv、Iw。
According to one embodiment of present invention, the boost module includes: capacitor;First inductance, first inductance
One end is connected with one end of the capacitor, and forms first node;First diode, the anode of the first diode with it is described
The other end of first inductance is connected, and the cathode of the first diode is connected with the other end of the capacitor, and forms the second section
Point;Wherein, the first node is connected with the positive output end of the AC-DC conversion module, the second node and the straight friendship
The positive input terminal for flowing conversion module is connected.
According to one embodiment of present invention, the boost module includes: the second inductance, one end of second inductance with
The positive output end of the AC-DC conversion module is connected;Second diode, the anode of second diode and second electricity
The other end of sense is connected, and the cathode of second diode is connected with the positive input terminal of direct exchange mold changing block;Parallel connection is even
The switching tube and third diode connect, the anode of the third diode and the source grounding of the switching tube, the third
The cathode of diode is connected with the anode of second diode with the drain electrode of the switching tube.
According to one embodiment of present invention, the controller is according to the temperature T0Calculate the direct exchange mold changing block
Allow the maximum current I exportedMAXWhen, the controller is specifically used for: calculating the direct exchange by following formula and changes the mold block
Junction temperature Tj:
Tj=T0+ 2.5 DEG C,
Wherein, T0For the temperature of the radiator, TjThe junction temperature of block is changed the mold for the direct exchange;And according to described straight
Exchange the junction temperature T of conversion modulejCalculating the direct exchange mold changing block with predetermined current-temperature relation allows described in output most
High current IMAX。
According to one embodiment of present invention, the controller is also used to: calculating the three-phase current Iu、IvAnd IwIt is exhausted
To the maximum value I in valuemax, and when timing time reaches the PWM carrier cycle T, judge ImaxWhether institute is greater than or equal to
State maximum current IMAX。
According to one embodiment of present invention, the controller is used for: in ImaxMore than or equal to the maximum current IMAX
When, the resultant current threshold limit value of the d axis, q axis that control the permanent magnet synchronous motor reduces the first preset value, in ImaxLess than institute
State maximum current IMAXWhen, control the d axis, the resultant current threshold limit value of the q axis increases by first preset value;Judgement
The resultant current threshold limit value of the d axis, the q axis after increasing or reducing whether exceed preset range [Idqmin,
Idqmax];And the resultant current threshold limit value of the d axis, the q axis after increasing or reducing exceeds the preset range
When [Idqmin, Idqmax], control the d axis, the resultant current threshold limit value of the q axis takes boundary value Idqmax or
Idqmin。
According to one embodiment of present invention, the controller is specifically used for: according to the d axis, the synthesis electricity of the q axis
Stream threshold limit value obtains q axis and gives constant current IqrefConstant current I is given with d axisdref, and constant current I is given according to the q axisqref, the d
Axis gives constant current IdrefThe direct exchange mold changing block is controlled, controls the permanent-magnet synchronous to change the mold block by the direct exchange
Motor, whereinIn the preset range [Idqmin, Idqmax].
According to one embodiment of present invention, the controller is also used to: in ImaxMore than or equal to the maximum current
IMAXWhen, the given rotating speed for controlling the permanent magnet synchronous motor reduces the second preset value.
According to one embodiment of present invention, the controller is specifically used for: after reducing by second preset value
Given rotating speed controls the direct exchange and changes the mold block, controls the permanent magnet synchronous motor to change the mold block by the direct exchange.
Wherein, second preset value is 1Hz.
Further, the invention proposes a kind of air conditioners comprising the control device of above-mentioned permanent magnet synchronous motor.
The air conditioner of the embodiment of the present invention is detected by the temperature detecting module of the control device of above-mentioned permanent magnet synchronous motor
Direct exchange changes the mold the temperature of the radiator of block, and the phase current of permanent magnet synchronous motor is acquired by current acquisition module, and passes through
Controller obtains the maximum current for the output that direct exchange mold changing block allows according to the temperature of radiator, and then according to permanent-magnet synchronous
The maximum current for the output that phase current, the direct exchange mold changing block of motor allow controls direct exchange and changes the mold block, to realize to forever
The control of magnetic-synchro motor to can not only guarantee the reliability of speed regulation, and is improved to direct exchange mold changing block output
The utilization rate of ability.
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 is the relation schematic diagram between the temperature and output electric current of direct exchange mold changing block;
Fig. 2 is the structural block diagram of the control device of permanent magnet synchronous motor according to an embodiment of the invention;
Fig. 3 is the scheme of installation of an exemplary temperature detecting module according to the present invention;
Fig. 4-Fig. 9 is the circuit diagram of the control device of multiple exemplary permanent magnet synchronous motors according to the present invention;
Figure 10 is the control flow chart of permanent magnet synchronous motor according to an embodiment of the invention;
Figure 11 is the control flow chart of permanent magnet synchronous motor in accordance with another embodiment of the present invention;
Figure 12 is the structural schematic diagram of controller according to an embodiment of the invention.
Specific embodiment
The embodiment of the present invention is described below in detail, examples of the embodiments are shown in the accompanying drawings, wherein from beginning to end
Same or similar label indicates same or similar element or element with the same or similar functions.Below with reference to attached
The embodiment of figure description is exemplary, it is intended to is used to explain the present invention, and is not considered as limiting the invention.
Below with reference to the accompanying drawings the control device and air conditioner of the permanent magnet synchronous motor proposed according to embodiments of the present invention are described.
Fig. 2 is the structural schematic diagram of the control device of permanent magnet synchronous motor according to an embodiment of the invention.Such as Fig. 2 institute
Show, the control device include: direct exchange mold changing block 10, PFC boost module 20, DC link section 30, direct exchange mold changing block 40,
Current sampling module 50, temperature detecting module 60 and controller 70.
Wherein, the input terminal of AC-DC conversion module 10 is connected with AC power source AC, the output of AC-DC conversion module 10
End is connected in parallel by the capacitor Cp of PFC boost module and DC link section, and exports DC voltage Vdc;Direct exchange changes the mold block
40 input terminal input direct-current voltage Vdc, direct exchange mold changing block 40 output end be connected with permanent magnet synchronous motor M;Current sample
Module 10 is used to acquire the phase current of permanent magnet synchronous motor;As shown in figure 3, temperature detecting module 60 is inlaid in direct exchange mold changing
On the radiator 41 of block 40, temperature detecting module 60 is used to detect the temperature T of radiator 410;Controller 70 is examined with temperature respectively
Survey module 60, current sampling module 50 are connected with direct exchange mold changing block 40, and controller 70 is used for according to temperature T0Calculate straight hand over
The maximum current I that stream conversion module 40 allows to exportMAX, and according to maximum current IMAXBlock is changed the mold with phase current control direct exchange
40, permanent magnet synchronous motor M is controlled to change the mold block 40 by direct exchange.
It is appreciated that direct exchange mold changing block 40 is inverter circuit, it is used for inverse of the DC into AC, to pass through
Alternating current controls permanent magnet synchronous motor.
Optionally, temperature detecting module 60 can be temperature sensor, be easily installed.
Wherein, capacitor Cp is electrolytic capacitor, can make the DC voltage V of outputdcSmoothly, i.e., DC bus-bar voltage is flat
It is sliding.
Specifically, rectification circuit (i.e. AC-DC conversion module 10) carries out full-wave rectification to the AC power source AC of input, with
The outlet side shunt capacitor Cp of rectification circuit, after capacitor Cp, the DC voltage V of output smoothingdc(i.e. DC bus electricity
Pressure).The smooth DC voltage that inverter circuit (i.e. direct exchange changes the mold block 40) is exported DC link section using switching tube S1-S6
VdcBe converted to alternating current;Current acquisition module 50 acquires the phase current of permanent magnet synchronous motor simultaneously, and temperature sensor detects Fig. 3 institute
The temperature of the radiator 41 shown;Controller 70 obtains the junction temperature of inverter circuit according to the temperature computation that temperature sensor detects, and
The maximum current I that inverter circuit allows to export is obtained according to the junction temperatureMAX, and then DC bus-bar voltage Vdc, maximum current IMAXWith
The switching tube S1-S6 of the phase current control inverter circuit of sampling, to control permanent magnet synchronous motor M by switching tube S1-S6.By
This, can guarantee the stability of electric machine speed regulation, and can make full use of the fan-out capability of direct exchange mold changing block.
It is appreciated that the control device further includes voltage sample module (being not shown in figure), to acquire DC bus electricity
Press Vdc。
In one embodiment of the invention, if PFC boost module 20 is passive PFC, such as Fig. 4, Fig. 5, Fig. 6 institute
Show, PFC boost module 20 includes capacitor C, the first inductance L1 and first diode D1.
Wherein, one end of the first inductance L1 is connected with one end of capacitor C, and forms first node a1;First diode D1
Anode be connected with the other end of the first inductance L1, the cathode of first diode D1 is connected with the other end of capacitor C, and forms the
Two node a2.Wherein, first node a1 is connected with the positive output end of AC-DC conversion module 10, second node a2 and direct exchange
The positive input terminal for changing the mold block 40 is connected.
In another embodiment of the present invention, as shown in Fig. 7, Fig. 8, Fig. 9, if PFC boost module 20 is active
PFC, then PFC boost module 20 includes the second inductance L2, the second diode D2, and the switching tube K being connected in parallel and the three or two
Pole pipe D3.
Wherein, one end of the second inductance L2 is connected with the positive output end of AC-DC conversion module 11;Second diode D2's
Anode is connected with the other end of the second inductance L2, the positive input terminal phase of the cathode and direct exchange mold changing block 40 of the second diode D2
Even;The anode of third diode D3 and the source grounding of switching tube K, the drain electrode of the cathode and switching tube K of third diode D3
It is connected with the anode of the second diode D2.
It should be noted that in an embodiment of the present invention, the frequency conversion control for passive PFC module and active PFC module
Principle processed is same or similar.
In one embodiment of the invention, controller 70 is according to temperature T0Calculating direct exchange mold changing block 40 allows to export
Maximum current IMAXWhen, controller 70 calculates the junction temperature T of direct exchange mold changing block 40 especially by following formula (1)j:
Tj=T0+2.5℃ (1)
Wherein, T0For the temperature of radiator 41, TjThe junction temperature of block 40 is changed the mold for direct exchange.
Further, controller 70 changes the mold the junction temperature T of block 40 according to direct exchangejIt is calculated with predetermined current-temperature relation
The maximum current I that direct exchange mold changing block 40 allows to exportMAX。
For example, Fig. 1 shows predetermined current-temperature relation, if T0Value be 75 DEG C, then TjValue be 77.5 DEG C,
It will be seen from figure 1 that the maximum current I that the block 40 of direct exchange mold changing at this time allows to exportMAXValue is 20A.
In an embodiment of the present invention, when sampling the phase current of permanent magnet synchronous motor M, different electric currents can be set and adopt
Sample loading mode, specific as follows:
In first example of the invention, as shown in Fig. 4, Fig. 7, current sampling module 50 includes the first sampling resistor
Rs1 and the second sampling resistor Rs2.Wherein, the first sampling resistor Rs1 and the second sampling resistor Rs2 is changed the mold with direct exchange respectively
Two lower bridge arms of block 40 are connected in series, and the first sampling resistor Rs1 and the second sampling resistor Rs2 are in each PWM carrier cycle T
The corresponding biphase current I of acquisition permanent magnet synchronous motor M respectivelyu、Iv.And then controller can be according to biphase current Iu、IvCalculate third
Phase current Iw, i.e. Iw=-(Iu+Iv)。
It is appreciated that the first sampling resistor Rs1 and the second sampling resistor Rs2 can be connected on direct exchange mold changing block 40
Any two in three lower bridge arms, to acquire the corresponding phase current of permanent magnet synchronous motor M, such as Iu、Iv。
In second example of the invention, as shown in Figure 5, Figure 8, current sampling module 50 includes third sampling resistor
One end of Rs3, third sampling resistor Rs3 are connected with the negative input end of direct exchange mold changing block 40, and third sampling resistor Rs3's is another
One end ground connection, the three-phase current of third sampling resistor Rs3 acquisition time permanent magnet synchronous motor M in each PWM carrier cycle T
Iu、Iv、Iw。
In third example of the invention, as shown in Fig. 6, Fig. 9, current sampling module 50 includes being galvanically isolated sensing
Device, separate current sensor are connected with the output end of direct exchange mold changing block 40, and separate current sensor is in each PWM carrier cycle
The three-phase current I of acquisition permanent magnet synchronous motor M in phase Tu、Iv、Iw。
It should be noted that current sampling module 50 sample permanent magnet synchronous motor M phase current when, permanent magnet synchronous motor
M is in operational process.
Further, controller 70 obtains three-phase current Iu、IvAnd IwAbsolute value in maximum value Imax, in timing time
When reaching PWM carrier cycle T, I is judgedmaxWhether maximum current I is greater than or equal toMAX。
In one embodiment of the invention, controller 70 is used in ImaxMore than or equal to maximum current IMAXWhen, control
The d axis of permanent magnet synchronous motor M, the resultant current threshold limit value of q axis increase the first preset value (such as 5A), in ImaxIt is maximum less than institute
Electric current IMAXWhen, the resultant current threshold limit value reduction the first preset value (such as 5A) of control d axis, q axis;And judge to increase or reduce
Whether the resultant current threshold limit value of d axis, q axis afterwards exceeds preset range [Idqmin, Idqmax], and is increasing or reducing
When the resultant current threshold limit value of d axis, q axis afterwards exceeds preset range [Idqmin, Idqmax], the synthesis of d axis, q axis is controlled
Electric current threshold limit value takes boundary value Idqmax or Idqmin.
Optionally, Idqmin value can be 12A, and the value of Idqmax can be 20A.
For example, if ImaxValue is 15A, less than the maximum current I for allowing to exportMAX, such as 20A, then d axis, q axis
Resultant current threshold limit value, such as 16A, increase the first preset value, after 5A, electric current threshold limit value be 21A, be greater than value
The Idqmax of 20A then controls d axis, the resultant current threshold limit value of q axis takes boundary value 20A.
Further, at the beginning of controller 70 adjusts the d axis of permanent magnet synchronous motor according to the resultant current threshold limit value of d axis, q axis
Begin to give constant current Idref0Constant current I is initially given with q axisqref0, constant current I is given to obtain d axisdrefConstant current I is given with q axisqref, and
Constant current I is given by d axisdrefConstant current I is given with q axisqrefIt controls direct exchange and changes the mold block 40, to change the mold block by direct exchange
40 control permanent magnet synchronous motor M.
Specifically, as shown in Figure 10, the control process of the control device of permanent magnet synchronous motor is as follows:
S101, judges whether permanent magnet synchronous motor is in operation process, and S102 is then gone to step in operation, is then turned in stopping
Step S111 terminates.
S102, controller control the temperature T of the radiator of temperature sensor detection direct exchange mold changing block0。
S103, controller is according to the temperature T of radiator0Speculate the junction temperature value T of direct exchange mold changing blockj.Wherein, Tj=T0+
2.5℃。
S104 changes the mold the junction temperature T of block according to direct exchangejAnd direct exchange shown in FIG. 1 changes the mold the junction temperature of block and permits
Perhaps the current relationship exported calculates direct exchange and changes the mold block maximum allowed current IMAX。
S105 samples the phase current I of permanent magnet synchronous motor by current sampling moduleu、Iv、Iw。
S106 calculates Iu、Iv、IwMaximum value I in three-phase actual current absolute valuemax。
Whether S107, controller judge each calculating cycle timing time to time T, if arrived, execute step S108.
Wherein, the value of T can be 1 second, 2 seconds etc..
If being appreciated that not timed out T of each calculating cycle timing time, controller 70 according to given rotating speed and d,
Q axis initially gives constant current control permanent magnet synchronous motor.
S108, controller judge the maximum value I of three-phase actual current absolute valuemaxWhether changed more than or equal to direct exchange
Module maximum allowed current value IMAX, if so, executing step S109b;If not, executing step S109a.
S109a, d, q axis resultant current maximum threshold limit improve the first preset value, and see if fall out [Idqmin,
Idqmax], boundary value is taken if exceeding.
S109b, d, q axis resultant current maximum threshold limit reduce the first preset value, and see if fall out [Idqmin,
Idqmax], boundary value is taken if exceeding.
Wherein, Idqmin can be 12A, and Idqmax can be 20A.
S110 obtains q axis according to the resultant current threshold limit value of d axis, q axis and gives constant current IqrefWith d axis to constant current
Idref, and constant current I is given according to q axisqref, d axis give constant current IdrefThe direct exchange, which is controlled, with given rotating speed changes the mold block, with
Realize the control to permanent magnet synchronous motor.
S111 terminates.In another embodiment of the present invention, in ImaxMore than or equal to maximum current IMAXWhen, control
Device 70 is also used to control the given rotating speed w of permanent magnet synchronous motor M*Reduce the second preset value.
Further, controller 70 is according to the given rotating speed (w after reducing the second preset value*- the second preset value) control is directly
Conversion module 40 is exchanged, controls permanent magnet synchronous motor M to change the mold block 40 by direct exchange.
Specifically, as shown in figure 11, the control process of the control device of permanent magnet synchronous motor is as follows:
S201, judges whether permanent magnet synchronous motor is in operation process, and S202 is then gone to step in operation, is then turned in stopping
Step S211 terminates.
S202, controller control the temperature T of the radiator of temperature sensor detection direct exchange mold changing block0。
S203, controller is according to the temperature T for pacifying hot device0Speculate the junction temperature value T of direct exchange mold changing blockj.Wherein, Tj=T0+
2.5℃。
S204 changes the mold the junction temperature T of block according to direct exchangejAnd direct exchange shown in FIG. 1 changes the mold the junction temperature of block and permits
Perhaps the current relationship exported calculates direct exchange and changes the mold block maximum allowed current IMAX。
S205 samples the phase current I of permanent magnet synchronous motor by current sampling moduleu、Iv、Iw。
S206 calculates Iu、Iv、IwMaximum value I in three-phase actual current absolute valuemax。
Whether S207, controller judge calculating cycle timing time to time T, if arrived, execute step S208.
Wherein, the value of T can be 1 second, 2 seconds etc..
If being appreciated that not timed out T of each calculating cycle timing time, if controller 70 according to given rotating speed and d,
Q axis initially gives constant current control permanent magnet synchronous motor.
S208, controller judge the maximum value I of three-phase actual current absolute valuemaxWhether changed more than or equal to direct exchange
Module maximum allowed current value IMAX, if so, executing step S209.
In an embodiment of the present invention, if maximum value ImaxIt is less than direct exchange mold changing block maximum allowed current value
IMAX, controller 70 then according to given rotating speed and d, q axis initially give constant current control permanent magnet synchronous motor control.
S209, control given rotating speed reduce the second preset value.
Wherein, the second preset value can be 1Hz.
S210 initially gives constant current I according to q axisqref0, d axis initially give constant current Idref0After reducing the second preset value
Given rotating speed controls direct exchange and changes the mold block, to realize the control to permanent magnet synchronous motor.
S211 terminates.
In an embodiment of the present invention, understand for convenience controller 70 to the double-closed-loop control process of permanent magnet synchronous motor M,
It is illustrated by taking rotational speed regulation as an example:
Firstly, estimating the rotor-position of permanent magnet synchronous motor M, to obtain the rotor angle of permanent magnet synchronous motor M
Estimated values thetaestWith spinner velocity estimated value ωest。
Specifically, above-mentioned rotor angle estimated values theta can be obtained by flux observation methodestWith spinner velocity estimated value
ωest.Specifically, can be according to the voltage V in two-phase stationary coordinate systemα、VβWith electric current Iα、IβPermanent magnet synchronous motor is calculated two
The estimated value of useful flux in phase rest frame α, β axis direction, specific formula for calculation such as following formula (2):
Wherein,WithThe respectively estimated value of permanent magnet synchronous motor useful flux in α and β axis direction, R are stator electricity
Resistance, LqFor the q axis magnetic linkage of motor.
Further, the rotor angle estimated values theta of permanent magnet synchronous motor is calculated by following formula (3)estAnd spinner velocity
Estimated value ωest:
Wherein, Kp_pllAnd Ki_pllRespectively proportional integration parameter, θerrFor misalignment angle estimated value, ωfFor speed low pass filtered
The bandwidth of wave device.
Specifically, as shown in figure 12, controller 70 includes speed ring control unit 71, weak magnetic control unit 72, clipping list
Member 73, coordinate transformation unit 74, current control unit 75 and PWM control unit 76.
Wherein, speed ring control unit 71 first calculates the three-phase current I of permanent magnet synchronous motor Mu、IvAnd IwAbsolute value in
Maximum value Imax, and when each calculating cycle clocking internal time reaching PWM carrier cycle T, judge ImaxWhether it is greater than or waits
In maximum current IMAX;And in ImaxMore than or equal to maximum current IMAXWhen, control given rotor speed ω*It is pre- to reduce second
If being worth (such as 1Hz), given rotor speed is obtainedAnd then according to given rotor speedSpinner velocity estimated value
ωest, input ac voltage shape and phase estimation value θgeThe q axis for calculating permanent magnet synchronous motor initially gives constant current Iqref0。
Weak magnetic control unit 72 changes the mold the maximum output voltage V of block 40 according to direct exchangemaxBlock 40 is changed the mold with direct exchange
Output voltage amplitude V1The d axis for calculating permanent magnet synchronous motor initially gives constant current Idref0。
Specifically, to the maximum output voltage V of inverter circuit (i.e. direct exchange changes the mold block 40)maxIt is defeated with inverter circuit
Voltage magnitude V out1Difference carry out weak magnetic control to obtain d axis initial current Id0;To d axis initial current Id0It is handled to obtain
D axis initially gives constant current Idref0。
Specifically, d axis initial current I can be calculated by following formula (4)d0:
Wherein, KiFor integral control coefficient,VdAnd VqRespectively permanent magnet synchronous motor M
D axis virtual voltage and q axis virtual voltage, VdcFor the DC bus-bar voltage of permanent magnet synchronous motor M.
Further, d axis is calculated by following formula (5) initially give constant current Idref0:
Wherein, IdemagFor permanent magnet synchronous motor M demagnetization current limits value.
Further, clipping unit 73 initially gives constant current I to q axisqref0Constant current I is just given with d axisdref0Carry out clipping
Processing, gives constant current I to obtain q axisqrefConstant current I is given with d axisdref。
Coordinate transformation unit 74 calculates α shaft current I by following formula (6)αWith β shaft current Iβ, pass through following formula (7)
Calculate d axis actual current, q axis actual current:
Wherein, Iu、IvAnd IwIt is the three-phase current of permanent magnet synchronous motor respectively.
Further, current control unit 75 gives constant current I according to q axisqref, d axis give constant current Idref, q axis actual current
IqWith d axis actual current IdObtain the q axis given voltage V of permanent magnet synchronous motorqrefWith d axis given voltage Vdref, and according to q axis
Given voltage Vqref, d axis given voltage Vdref, rotor angle estimated values thetaestControl signal is generated, and logical according to control signal
Inverter circuit is crossed to control permanent magnet synchronous motor M.
Specifically, q axis given voltage V can be calculated by following formula (8)qrefWith d axis given voltage Vdref:
Wherein, KpdAnd KidRespectively the control proportional gain of d shaft current and integral gain, KpqAnd KiqRespectively q shaft current control
Proportional gain processed and integral gain, ω are the revolving speed of motor, KeFor the back emf coefficient of motor, LdAnd LqRespectively d axle inductance and
Q axle inductance,Indicate the integral of x (τ) in time.
Getting q axis given voltage VqrefWith d axis given voltage VdrefAfterwards, coordinate transformation unit 74 can be according to rotor angle
Spend estimated values thetaestTo q axis given voltage VqrefWith d axis given voltage VdrefPark inverse transformation is carried out, two-phase stationary coordinate system is obtained
On voltage Vα、Vβ, specific transformation for mula is as follows:
Further, to the voltage V in two-phase stationary coordinate systemα、VβClark inverse transformation is carried out, three-phase voltage command is obtained
Vu、Vv、Vw, specific transformation for mula is as follows:
PWM control unit 76 can be according to DC bus-bar voltage VdcWith three-phase voltage command Vu、Vv、VwThree-phase duty ratio is calculated,
Obtain duty cycle control signal, i.e. three-phase duty ratio Du、Dv、Dw, specific formula for calculation is as follows:
Finally, controller 70 is according to three-phase duty ratio Du、Dv、DwThe switching tube of inverter circuit is controlled, with realization pair
The control of permanent magnet synchronous motor.It is given to constant current and d axis that q axis is rationally adjusted by the junction temperature that direct exchange changes the mold block as a result,
Electric current guarantees the stability of speed regulation so that the input current waveform of permanent magnet synchronous motor can satisfy harmonic requirement.
To sum up, the control device of the permanent magnet synchronous motor of the embodiment of the present invention detects straight exchange by temperature detecting module
The temperature of the radiator of conversion module, the phase current of permanent magnet synchronous motor is acquired by current acquisition module, and passes through controller
The maximum current for the output that direct exchange mold changing block allows is obtained according to the temperature of radiator, and then according to permanent magnet synchronous motor
The maximum current for the output that phase current, direct exchange mold changing block allow controls direct exchange and changes the mold block, to realize to permanent-magnet synchronous
The control of motor to can not only guarantee the reliability of speed regulation, and is improved to direct exchange mold changing block fan-out capability
Utilization rate.
Based on the above embodiment, the invention also provides a kind of air conditioners comprising the control of above-mentioned permanent magnet synchronous motor
Device processed.
The air conditioner of the embodiment of the present invention is detected by the temperature detecting module of the control device of above-mentioned permanent magnet synchronous motor
Direct exchange changes the mold the temperature of module radiator, and the phase current of permanent magnet synchronous motor is acquired by current acquisition module, and passes through control
Device processed obtains the maximum current for the output that direct exchange mold changing block allows according to the temperature of radiator, and then according to permanent magnet synchronous electric
The maximum current for the output that phase current, the direct exchange mold changing block of machine allow controls direct exchange and changes the mold block, to realize to permanent magnetism
The control of synchronous motor to can not only guarantee the reliability of speed regulation, and is improved to direct exchange mold changing block output energy
The utilization rate of power.
In addition, air conditioner according to an embodiment of the present invention other compositions and effect for this field ordinary skill people
Member for be all it is known, in order to reduce redundancy, be not repeated herein.
In the description of the present invention, it is to be understood that, term " center ", " longitudinal direction ", " transverse direction ", " length ", " width ",
" thickness ", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom" "inner", "outside", " up time
The orientation or positional relationship of the instructions such as needle ", " counterclockwise ", " axial direction ", " radial direction ", " circumferential direction " be orientation based on the figure or
Positional relationship is merely for convenience of description of the present invention and simplification of the description, rather than the device or element of indication or suggestion meaning must
There must be specific orientation, be constructed and operated in a specific orientation, therefore be not considered as limiting the invention.
In addition, term " first ", " second " are used for descriptive purposes only and cannot be understood as indicating or suggesting relative importance
Or implicitly indicate the quantity of indicated technical characteristic.Define " first " as a result, the feature of " second " can be expressed or
Implicitly include at least one this feature.In the description of the present invention, the meaning of " plurality " is at least two, such as two, three
It is a etc., unless otherwise specifically defined.
In the present invention unless specifically defined or limited otherwise, term " installation ", " connected ", " connection ", " fixation " etc.
Term shall be understood in a broad sense, for example, it may be being fixedly connected, may be a detachable connection, or integral;It can be mechanical connect
It connects, is also possible to be electrically connected;It can be directly connected, can also can be in two elements indirectly connected through an intermediary
The interaction relationship of the connection in portion or two elements, unless otherwise restricted clearly.For those of ordinary skill in the art
For, the specific meanings of the above terms in the present invention can be understood according to specific conditions.
In the present invention unless specifically defined or limited otherwise, fisrt feature in the second feature " on " or " down " can be with
It is that the first and second features directly contact or the first and second features pass through intermediary mediate contact.Moreover, fisrt feature exists
Second feature " on ", " top " and " above " but fisrt feature be directly above or diagonally above the second feature, or be merely representative of
First feature horizontal height is higher than second feature.Fisrt feature can be under the second feature " below ", " below " and " below "
One feature is directly under or diagonally below the second feature, or is merely representative of first feature horizontal height less than second feature.
In the description of this specification, reference term " one embodiment ", " some embodiments ", " example ", " specifically show
The description of example " or " some examples " etc. means specific features, structure, material or spy described in conjunction with this embodiment or example
Point is included at least one embodiment or example of the invention.In the present specification, schematic expression of the above terms are not
It must be directed to identical embodiment or example.Moreover, particular features, structures, materials, or characteristics described can be in office
It can be combined in any suitable manner in one or more embodiment or examples.In addition, without conflicting with each other, the skill of this field
Art personnel can tie the feature of different embodiments or examples described in this specification and different embodiments or examples
It closes and combines.
Although the embodiments of the present invention has been shown and described above, it is to be understood that above-described embodiment is example
Property, it is not considered as limiting the invention, those skilled in the art within the scope of the invention can be to above-mentioned
Embodiment is changed, modifies, replacement and variant.
Claims (12)
1. a kind of control device of permanent magnet synchronous motor characterized by comprising
AC-DC conversion module, PFC boost module, DC link section and direct exchange change the mold block, wherein the AC-DC conversion mould
The input terminal of block is connected with AC power source, the output end of the AC-DC conversion module by the PFC boost module with it is described
The capacitor of DC link section is connected in parallel, and exports DC voltage, and the input terminal input of the direct exchange mold changing block is described straight
The output end of galvanic electricity pressure, the direct exchange mold changing block is connected with permanent magnet synchronous motor;
Current sampling module, for acquiring the phase current of the permanent magnet synchronous motor;
Temperature detecting module, the temperature detecting module are inlaid on the radiator of the direct exchange mold changing block, the temperature
Detection module is used to detect the temperature of the radiator;
Controller, the controller respectively with the temperature detecting module, the current sampling module, the DC link section and institute
It states direct exchange mold changing block to be connected, the controller allows to export for the mold changing block of the direct exchange according to the temperature computation
Maximum current, and the direct exchange is controlled according to the maximum current and the phase current and changes the mold block, by described straight
It exchanges conversion module and controls the permanent magnet synchronous motor, wherein the phase current includes three-phase current Iu、IvAnd Iw;
Wherein, the controller is specifically used for:
Calculate the three-phase current Iu、IvAnd IwAbsolute value in maximum value Imax, and reach PWM carrier cycle in timing time
When T, I is judgedmaxWhether maximum current I is greater than or equal toMAX;
In ImaxMore than or equal to the maximum current IMAXWhen, control the d axis of the permanent magnet synchronous motor, the resultant current of q axis
Threshold limit value reduces the first preset value, in ImaxLess than the maximum current IMAXWhen, control the synthesis electricity of the d axis, the q axis
It flows threshold limit value and increases by first preset value;
Judge the d axis after increasing or reducing, whether the resultant current threshold limit value of the q axis exceeds preset range
[Idqmin, Idqmax];And
The resultant current threshold limit value of the d axis, the q axis after increasing or reducing beyond the preset range [Idqmin,
Idqmax] when, control the d axis, the resultant current threshold limit value of the q axis takes boundary value Idqmax or Idqmin.
2. the control device of permanent magnet synchronous motor as described in claim 1, which is characterized in that the current sampling module packet
It includes:
First sampling resistor and the second sampling resistor, first sampling resistor and second sampling resistor respectively with it is described straight
Two lower bridge arms for exchanging conversion module are connected in series, and first sampling resistor and second sampling resistor are in each PWM
The corresponding biphase current I of the permanent magnet synchronous motor is acquired in carrier cycle T respectivelyu、Iv;
Wherein, the controller is used for according to the biphase current Iu、IvCalculate third phase current Iw。
3. the control device of permanent magnet synchronous motor as described in claim 1, which is characterized in that the current sampling module packet
It includes:
One end of third sampling resistor, the third sampling resistor is connected with the negative input end of direct exchange mold changing block, institute
State third sampling resistor the other end ground connection, the third sampling resistor in each PWM carrier cycle T described in acquisition time forever
The three-phase current I of magnetic-synchro motoru、Iv、Iw。
4. the control device of permanent magnet synchronous motor as described in claim 1, which is characterized in that the current sampling module packet
It includes:
Separate current sensor, the separate current sensor are connected with the output end of direct exchange mold changing block, the electricity
Stream isolation sensor acquires the three-phase current I of the permanent magnet synchronous motor in each PWM carrier cycle Tu、Iv、Iw。
5. the control device of permanent magnet synchronous motor as described in claim 1, which is characterized in that the boost module includes:
Capacitor;
One end of first inductance, first inductance is connected with one end of the capacitor, and forms first node;
First diode, the anode of the first diode are connected with the other end of first inductance, the first diode
Cathode be connected with the other end of the capacitor, and form second node;
Wherein, the first node is connected with the positive output end of the AC-DC conversion module, the second node and described straight
The positive input terminal for exchanging conversion module is connected.
6. the control device of permanent magnet synchronous motor as described in claim 1, which is characterized in that the boost module includes:
Second inductance, one end of second inductance are connected with the positive output end of the AC-DC conversion module;
Second diode, the anode of second diode are connected with the other end of second inductance, second diode
The positive input terminal of cathode and the direct exchange mold changing block be connected;
The switching tube and third diode being connected in parallel, the anode of the third diode connect with the source electrode of the switching tube
Ground, the cathode of the third diode are connected with the anode of second diode with the drain electrode of the switching tube.
7. the control device of the permanent magnet synchronous motor as described in any one of claim 2-4, which is characterized in that the controller
According to the temperature T0Calculate the maximum current I that the direct exchange mold changing block allows to exportMAXWhen, the control implement body is used
In:
The junction temperature T that the direct exchange changes the mold block is calculated by following formulaj:
Tj=T0+ 2.5 DEG C,
Wherein, T0For the temperature of the radiator, TjThe junction temperature of block is changed the mold for the direct exchange;And
The junction temperature T of block is changed the mold according to the direct exchangejThe direct exchange mold changing block is calculated with predetermined current-temperature relation to permit
Perhaps the maximum current I exportedMAX。
8. the control device of permanent magnet synchronous motor as described in claim 1, which is characterized in that the controller is specifically used for:
Q axis, which is obtained, according to the resultant current threshold limit value of the d axis, the q axis gives constant current IqrefConstant current I is given with d axisdref,
And constant current I is given according to the q axisqref, the d axis give constant current IdrefThe direct exchange mold changing block is controlled, by described
Direct exchange changes the mold block and controls the permanent magnet synchronous motor, whereinThe preset range [Idqmin,
Idqmax] in.
9. the control device of permanent magnet synchronous motor as described in claim 1, which is characterized in that the controller is also used to:
In ImaxMore than or equal to the maximum current IMAXWhen, the given rotating speed for controlling the permanent magnet synchronous motor reduces by second in advance
If value.
10. the control device of permanent magnet synchronous motor as claimed in claim 9, which is characterized in that the controller is specifically used for:
The direct exchange is controlled according to the given rotating speed after reduction by second preset value and changes the mold block, to pass through the straight exchange
Conversion module controls the permanent magnet synchronous motor.
11. the control device of permanent magnet synchronous motor as claimed in claim 10, which is characterized in that second preset value is
1Hz。
12. a kind of air conditioner, which is characterized in that the control including permanent magnet synchronous motor such as of any of claims 1-11
Device processed.
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CN112118981A (en) * | 2018-03-12 | 2020-12-22 | 捷普有限公司 | Multilevel motor driver with integrated battery charger |
US11271505B2 (en) * | 2018-05-30 | 2022-03-08 | Mitsubishi Electric Corporation | Permanent-magnet synchronous motor and ventilation blower |
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