METHOD AND APPARATUS FOR OPTIMIZING EFFICIENCY OF INDUCTION MOTOR IN ELECTRIC VEHICLE

Abstract

The present invention is to adjust the relevant parameters at the variable load factor of the motor of the electric vehicle and the arbitrary rotational speed through the optimization algorithm and to operate with high efficiency over the whole range. In order to optimize the efficiency of the motor for the electric vehicle, the optimization control device 20 obtains the operating load factor in real time with the algorithm 9 for calculating the load factor, the rotation speed is obtained by detection 6, the power factor PF is acquired by the PF calculation 4, and the torque current component Iq and the magnetic field current component Id are acquired by the Id and Iq conversion algorithm 5, respectively. Then, the frequency (rotational speed) control amount Fq is calculated by the control 1, the control amount Idk of the magnetic field current by the fuzzy control 2, and the control amount PFk of the power factor by the PF control 3, respectively, each of which is input to the optimum voltage calculation algorithm 7 for calculating the optimum voltage control amount Ud. With the optimum voltage control amount Ud and the frequency (rotation speed) control amount Fq, the waveform of the SPWM generation 8 is adjusted, and the input power of the induction motor 17 is automatically adjusted to the minimum value and high efficiency by the power adjustment unit 12.

Claims

1. A new control method for optimizing efficiency of an induction motor characterized in that a load factor of the induction motor is detected in real time, voltage and frequency control amounts which constantly drive the induction motor at high efficiency with the variable load factor and arbitrary frequency are calculated through an optimization algorithm, and input voltage and frequency of the induction motor are adjusted in real time based on the calculated control amounts of the voltage and frequency so as to ensure that the input power of the induction motor always adapts to the load factor of the induction motor.

2. The control method for optimizing efficiency of an induction motor according to claim 1, characterized in that a load factor of the induction motor is detected in real time, voltage and frequency control amounts which constantly drive the induction motor at high efficiency with the variable load factor and arbitrary frequency are calculated through an optimization algorithm; and, before that, respective relevant parameter values of the induction motor including the input current, the input voltage, the load factor and the rotation speed of the induction motor are acquired in real time.

3. The control method for optimizing efficiency of an induction motor according to claim 2, characterized in that a load factor of the induction motor is detected in real time, voltage and frequency control amounts which constantly drive the induction motor at high efficiency with the variable load factor and arbitrary frequency are calculated through the optimization algorithm; respective relevant parameter values of the induction motor including the operating power factor, the torque current component, the magnetic field current component and the rotational speed control amount are obtained by calculation, the obtained operating power factor is compared with the power factor command value that has been set, compensation control calculation is performed on the deviation value to obtain a power factor control coefficient, the obtained magnetic field current component of the induction motor is compared with the magnetic field current command value that has been set, fuzzy inference is performed on the deviation value and the rate of change of the deviation value to obtain an excitation current control coefficient, a load factor coefficient is obtained by applying the excitation current control coefficient to the acquired power factor control coefficient, the obtained torque current component and the rotation speed of the induction motor are compared with the command value of the rotation speed that has been set, and a cascade control calculation is performed on the deviation value to obtain the frequency control amount, the voltage control amount is obtained by the following equation:
Ud=Fqk1Pk (in the above equation, Ud is a voltage control amount, Fq is a control amount of frequency, k1 is a V/F coefficient, and Pk is a load factor coefficient, respectively).

4. The control method for optimizing efficiency of an induction motor method according to claim 3, characterized in that the rotation speed control amount is obtained by comparing the rotation speed obtained in real time with the command value of the rotation speed that has been set and performing a cascade control calculation on the deviation.

5. A control apparatus for optimizing efficiency of an induction motor comprising: an optimization algorithm for detecting a load factor of the induction motor in real time and calculating voltage and frequency control amounts which constantly drive the induction motor at high efficiency with the variable load factor and arbitrary frequency through the optimization algorithm; and an adjustment algorithm for adjusting input voltage and frequency of the induction motor in real time based on the calculated control amounts of the voltage and frequency so as to always allow the input power of the induction motor adapt to the load factor of the induction motor.

6. The control apparatus for optimizing efficiency of an induction motor apparatus according to claim 5, further comprising: an acquisition algorithm for acquiring each relevant parameter value of the induction motor including the input current, the input voltage, the load factor and the rotation speed of the induction motor.

7. The control apparatus for optimizing efficiency of an induction motor apparatus according to claim 6, characterized in that specific uses of the optimization algorithm are as follows: obtaining respective relevant parameter values of the induction motor including the operating power factor, the magnetic field current component, the torque current component, and the rotational speed control amount by calculation; obtaining a power factor control coefficient by comparing the obtained operating power factor of the induction motor with the power factor command value that has been set and performing a compensation control calculation; obtaining an excitation current control coefficient by comparing the obtained magnetic field current component of the induction motor with the magnetic field current command value that has been set and performing fuzzy inference on the deviation value and the rate of change of the deviation value, obtaining a load factor coefficient by applying the excitation current control coefficient to the acquired power factor control coefficient, obtaining the frequency control amount by comparing the obtained torque current component and the rotation speed of the induction motor with the command value of the rotation speed that has been set and performing a cascade control calculation on the deviation value, obtaining the voltage control amount by the following equation:
Ud=Fqk1Pk [in the above equation, Ud is a voltage control amount, Fq is a control amount of frequency, k1 is a V/F coefficient, and Pk is a load factor coefficient, respectively].

8. The control apparatus for optimizing efficiency of induction motor of claim 5, further comprising an induction motor and an output voltage regulating unit, wherein the control apparatus is connected to the AC output voltage regulating unit and the induction motor and has a function of driving the induction motor always with high efficiency.

9. A method for generating an SPWM waveform capable of varying an arbitrary frequency and voltage for driving the AC output voltage regulating unit with the voltage control amount claimed in claim 7.

10. A The control apparatus for optimizing efficiency of induction motor of claim 8 further comprising a vehicle body, wherein the control apparatus is connected to a drive shaft of the vehicle body and has a function of driving the vehicle body at a variable load factor and an arbitrary rotation speed always with high efficiency.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0013] FIG. 1 is an operation efficiency model of an induction motor.

[0014] FIG. 2 illustrates a flowchart of a first embodiment of the efficiency optimizing method of the induction motor.

[0015] FIG. 3 shows a high efficiency operation point of the induction motor in the method for optimizing efficiency of the induction motor according to the present invention.

[0016] FIG. 4 is a vector diagram showing a three-phase AC coordinate system and a three-phase DC coordinate system in the method for optimizing efficiency.

[0017] FIG. 5 illustrates a flowchart of a second embodiment of the method for optimizing efficiency of the induction for according to the present invention.

[0018] FIG. 6 is a structural diagram of a second embodiment of the control apparatus for optimizing efficiency of the induction motor according to tie present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0019] Next, the present invention will be described in detail with reference to a first embodiment and explanatory drawings.

[0020] From the operation efficiency model of the induction motor shown in FIG. 1, the operation efficiency of the induction motor can be calculated by the following equation:

[00001] $\begin{matrix} = \frac{P_{2}}{P_{1}} \\ = \frac{P_{2}}{P_{2} + (P_{cu .Math. .Math. 1} + P_{cu .Math. .Math. 2}) + (P_{re} + P_{mec} + P_{ad})} \end{matrix}$

[0021] wherein:

[0022] P1 is an input capacity of the induction motor;

[0023] P2 is an output capacity of the induction motor (an output capacity of the shaft);

[0024] Pcu1 is a copper loss of the stator, i.e. a power loss that occurs when the stator current flows through the stator winding, the magnitude of which depends on the load;

[0025] Pcu2 is a rotating copper loss, i.e. a power loss that occurs when the current flows through the stator winding, the magnitude of which depends on the load;

[0026] PFe is an iron loss, i.e. the excitation loss caused by the rotating magnetic field in the stator core, the magnitude of which does not depend on the load since it is largely controlled by the excitation electromotive force (proportional to the square of the input voltage of the induction motor);

[0027] Pmec is a machine loss, i.e. a power loss due to the friction generated by bearings, fans, etc., the magnitude of which does not change much;

[0028] Pad is an accessories loss, i.e. a loss caused by stator, rotor core grooves and harmonics, the magnitude of which depends on the load, but can be ignored.

[0029] (Pcu1+Pcu2) is referred to as a variable loss (copper loss) because it depends on the load and (PFePmec+Pad) is referred to as an invariable loss (iron loss) because it is hardly dependent on the load, respectively. As it can be seen from the formula of efficiency , in order to operate the induction motor in the energy saving state while P.sub.2 does not change, it is necessary to increase the efficiency of the induction motor, that is, to reduce the total value of all losses.

[0030] From the principle of the induction motor, as can be seen from the energy conservation law, when the copper loss and the iron loss are the same, i.e., (Fcu1+Pcu2)=(PFe+Pmec+Pad), the induction motor has the lowest loss and the highest operation efficiency at the intersection point (optimum efficiency point) in. FIG. 3.

[0031] As shown in the flowchart of FIG. 2 illustrating the method for optimizing efficiency of the induction motor, when the iron loss and the copper loss of the induction motor are Pf=V1.sup.2g0 and Pc=I.sup.2(R1+R2) (Pcu1+Pcu2)=(PFe+Pmec+Pad), respectively, i.e. Pf=Pc=V1.sup.2g0=I.sup.2(R1+R2)=(V1/Z).sup.2(R1+R2), it becomes V1.sup.2/I.sup.2=Z.sup.2=(R1+R2)/g0, that is, the induction motor of the induction characteristic represents the resistance load, and the operation efficiency and the power factor of the induction motor become the highest level. It can be seen that, for the fluctuating load of the induction motor, if the input voltage is changed instantaneously and accurately to Pf=Pc in real time, the induction motor can be operated at the optimum efficiency.

[0032] FIG. 5 is a flowchart of a second embodiment of the method for realizing efficiency optimization control of the induction motor according to the present invention, and implementing steps of which are described in detail.

[0033] In step 30, respective relevant parameter values of the induction motor including induction motor input current ia, ib, ic, input voltage ua, ub, uc and phase angle of the induction motor are obtained in real time

[0034] Among them, the phase angle is closely related to the load factor of the induction motor. The phase angle is inversely proportional to the load factor of the induction motor. That is, the larger the phase angle, the smaller the load factor, and the smaller the phase angle, the larger the load factor.

[0035] In step 31, respective relevant parameter values of the induction motor including the operating power factor PF, the magnetic field current component id, the torque current component iq and the rotational speed are obtained by calculation.

[0036] In this embodiment, the magnetic field current component id and the torque current component iq can be obtained by vector conversion. Refer to the explanatory diagram showing the vectors included in the three-phase AC coordinate system and the two-phase DC coordinate system shown in FIG. 4

[0037] Three-phase excitation currents of A, B and C can be converted to the rotor torque current and the stator magnetic field current of the induction motor by coordinate transformation between the induction motor three-phase windings A, B, C and the two-phase winding. The vectors included in the two coordinate systems and the induction motor three-phase A, B and C overlap the origins of the two coordinate systems and further overlap the A axis with the a axis. Based on the principle of equivalence of the magnetomotive force, since the three-phase synthesized magnetomotive force is the same as the two-phase synthesized magnetomotive force, and therefore the projections of the two wire magnetomotive forces in the qd axis are the same, the following determinant is used.

[00002] $[\begin{matrix} iq \\ id \end{matrix}] = \sqrt{\frac{2}{3}} .Math. [\begin{matrix} 1 & - \frac{1}{2} & - \frac{3}{2} \\ 0 & \frac{\sqrt{3}}{2} & - \frac{\sqrt{3}}{2} \end{matrix}] .Math. [\begin{matrix} iA \\ iB \\ iC \end{matrix}]$

[0038] In step 32, the obtained operating power factor PF of the induction motor is compared with the command value of the power factor that has been set to obtain a deviation value, and compensation control calculation is performed on the deviation value to obtain the power factor control coefficient PFk.

[0039] In step 33, the obtained magnetic field current component Id of the induction motor is compared with the command value of the magnetic field current that has been set to obtain the deviation value, and fuzzy inference is performed on the deviation value to obtain the excitation current control coefficient Idk.

[0040] In step 34, the excitation current control coefficient Idk is applied to the calculated power factor control coefficient PFk to calculate a load factor coefficient Pk.

[0041] In step 35, the obtained torque current component Iq and the rotation speed of the induction motor are compared with toe command value of the rotation speed that has been set to obtain the deviation value, and the cascade control calculation is performed on the deviation value to obtain the frequency control amount Fq.

[0042] In step 36, the voltage control amount is obtained by the following equation:

Ud=Fqk1Pk

[0043] In the above equation, Ud is a voltage control amount, Fq is a control amount of frequency (rotation speed), and k1 is a V/F coefficient (rated voltage V/rated frequency F), respectively. For example, when the rated voltage V and the rated frequency F of the induction motor are 200V and 50 Hz, respectively, the V/F coefficient is 200/50, that is, 4.0. The rated voltage V here is not limited to 200V, or the rated frequency F is not necessarily 50 Hz. The present invention may be applied to the rated voltage, for example, 60V-700V and other rated frequency, for example, 10 Hz-500 Hz. Pk represents a load factor.

[0044] In step 37, based on the obtained voltage control amount Ud and frequency control amount Fq, the SPWM generation waveform is adjusted, and the voltage regulating unit regulates three-phase input voltages ua, ub and uc of the induction motor (currents ia, ib and ic change in accordance with the change of the voltages) and frequency (speed) in real time, thereby always allowing the input power of the induction motor to adapt to the load factor of the induction motor.

[0045] In this embodiment, furthermore, a control apparatus for optimizing efficiency of the induction motor comprising an apparatus for realizing efficiency optimization control of the induction motor, an induction motor and a voltage regulator has been proposed. The control apparatus for optimizing efficiency of the induction motor is connected to the induction motor and the voltage regulating unit and used to operate the induction motor always with high efficiency.

[0046] The present embodiment also proposes an electric vehicle comprising the control apparatus for optimizing efficiency of the induction motor and the vehicle body. The control apparatus for optimizing efficiency of the induction motor is connected to the drive shaft of the vehicle body and used to operate the vehicle body at high efficiency at a variable load factor and at any rotation speed (frequency), thereby increasing the use time after charging a storage battery of the electric vehicle and the traveling distance of the electric vehicle.

[0047] Each of the steps and calculation algorithms proposed above in the present invention can be implemented In one computing device or distributed to a network connecting several computing devices or can be realized in a general computing device. As another alternative, it can be realized by a program installed in a computing device so that they can be stored in a storage device and executed by the computing device, or they can be produced on each integrated circuit module or printed circuit board, or a plurality of steps and calculation algorithms included therein can be realized in one integrated circuit module or a printed circuit board, and thus it will be obvious to one skilled in the art that the present invention is not limited to any combination of hardware and software.

[0048] In addition, the above disclosure is merely an embodiment with highest priority, and the present invention is not limited to the embodiment. Various modifications can be made to the invention by one skilled in the art. However, any modifications, rearrangements, replacements, improvements, etc., of the present invention are considered to be subject to protection according to the present invention as long as they conform to the spirit and principle of the present invention.

INDUSTRIAL APPLICABILITY

[0049] It can be applied in an electric vehicle, and the induction motor of the present invention is operated in the state of high efficiency of the minimum current and the optimum voltage under the variable load factor (for example, low load, medium load, high load, etc.) due to the influence of various factors in the course of the driving of the electric vehicle (for example, uphill slope, downhill slope, road condition, weight bearing, etc.), enabling extension of the cruising time and mileage of the charged electric storage battery of the electric vehicle.

DESCRIPTION OF REFERENCE NUMERALS

[0050] 1 cascade controller [0051] 2 fuzzy inference device [0052] 3 power factor compensation controller [0053] 4 power factor operation controller [0054] 5 current conversion operator [0055] 6 speed detector [0056] 7 optimum voltage operator [0057] 8 drive waveform generator [0058] 9 load factor acquisition operator [0059] 10 power battery [0060] 11 capacitor [0061] 12 voltage regulating unit [0062] 13 drive cable [0063] 14 voltage detection sensor [0064] 15 current detection sensor [0065] 16 output terminal stand. [0066] 17 induction motor [0067] 20 apparatus for optimizing efficiency

METHOD AND APPARATUS FOR OPTIMIZING EFFICIENCY OF INDUCTION MOTOR IN ELECTRIC VEHICLE

Assignee

Inventors

Cpc classification

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B60L50/51

PERFORMING OPERATIONS; TRANSPORTING

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B60L15/025

PERFORMING OPERATIONS; TRANSPORTING

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B60Y2400/112

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

Y02T10/64

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

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B60Y2200/91

PERFORMING OPERATIONS; TRANSPORTING

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H02P21/001

ELECTRICITY

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Y02T10/70

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

Classification Explorer

Y02T10/72

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

Classification Explorer

B60L2240/429

PERFORMING OPERATIONS; TRANSPORTING

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B60L2240/423

PERFORMING OPERATIONS; TRANSPORTING

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B60L15/2045

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

H02P27/08

ELECTRICITY

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H02P23/26

ELECTRICITY

International classification

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H02P21/00

ELECTRICITY

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B60L15/20

PERFORMING OPERATIONS; TRANSPORTING

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B60L11/18

PERFORMING OPERATIONS; TRANSPORTING

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B60L15/02

PERFORMING OPERATIONS; TRANSPORTING

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H02P27/08

ELECTRICITY

Abstract

Claims

Description