PULSE WIDTH MODULATING MOTOR CONTROLLER
BACKGROUND OF THE INVENTION
(1) Field of the Invention
This invention is in the field of motor controllers for variable speed and variable torque electric motors, such as switched reluctance, or SR, motors and permanent magnet, or PM motors, but is not limited to such motors; and more particularly relates to improvements in controlling the pulse width modulation (PWM) of the power drive signals that determine the speed and torque of variable speed electric motors.
(2) Description of Related Art Recent developments in power semiconductor devices such as power MOSFETs and insulated gate thyristors (IGT)s have led to the development of electronically commutated motors for use in applications requiring variable speed drive motors. Common examples of the types of electric motors the speed and torque of which are controlled by controllers which pulse width modulate the current flow through the power phase winding circuits of such motors, are SR motors and PM motors; however, the controller of this invention can be used with any electric motor that can be controlled by pulse width modulating the flow of electrical current through the motor's power phase windings. The cost and reliability of the pulse width modulation (PWM) controllers for electric motors compare favorably with those of more conventional controllers for variable speed motors.
Motors such as SR motors and PM motors conventionally have multiple poles on both the stator and rotor. In a SR motor, there are power phase windings on the stator poles, but no windings or permanent magnets on the rotor. Each pole of each pair of diametrically opposite stator poles of a SR motor have series connected windings that form an independent power phase winding. In a PM motor, permanent magnets are usually mounted on the rotor.
Torque to rotate the rotor is produced by switching current into each of the power phase windings in a predetermined sequence that is synchronized with the angular position of the rotor, to polarize an associated pair of stator poles. While generally the power phase windings are placed on poles of the stator, they can be placed on poles of the rotor if so desired. The resulting magnetic force attracts the nearest pair of rotor poles. In a SR motor, current is switched off in each power, or stator, phase winding before the poles of
the rotor nearest the excited stator poles rotate past the aligned position. In such motors, the torque developed, while a function of the magnitude of the current flow in the stator windings, is independent of the direction of current flow so that unidirectional current pulses synchronized with the rotation of the rotor can be applied to the stator power phase windings by a converter using unidirectional current switching elements such as thyristors or power transistors. The desired commutation of current through the stator phase windings can be accomplished by producing a rotor position signal by means of a shaft position sensor; i.e., an encoder, or resolver, for example, which is driven by the motor's rotor. The rotor position signal is applied to the motor controller. The motor controller also typically has applied to it a signal indicating the desired direction of rotation of the rotor and a speed set signal indicating the desired angular velocity of the rotor which is typically measured in revolutions per minute (RPM). Such speed and direction signals are controlled by a human operator, or an automated control system. In addition, a rotor position signal, which is also known as the motor electrical (Me) signal; and a torque, or current, feedback signals are also applied to the motor controller. Current for each of the power phase windings of a SR motor is derived from a unidirectional power source, and each of the power phase windings is connected in series with a power transistor to control the flow of current through its associated power phase winding. The motor controller produces pulse width modulation (PWM) power drive signals which are applied to the power transistors to turn them on and off. The timing of such current flows relative to the position of the rotor causes the rotor to rotate, and the order in which the power phase windings are energized determines the direction of rotation of the rotor.
The power drive signals applied to the power transistors in series with power phase windings are pulse width modulated (PWM) to maintain current levels through the power phase windings at a level to cause the rotor to rotate at the desired RPM while limiting the torque, or current, in the power phase windings to a predetermined maximum. It should be noted that the magnitude of the torque of a motor is a function of the magnitude of the current flowing through its power phase winding circuits. The magnitude of this current flow is sensed and used to produce a current, or torque, feedback signal which is applied to the motor controller. A prior art circuit for pulse width modulating the power drive signal for a SR motor is illustrated in Fig. 9 of U.S. Patent 5,196,775.
A problem with prior art PWM motor controllers is that there is no fixed relationship between the frequency of the PWM power drive signals and the motor electrical, Me, or power phase commutation signals which results in a beat frequency (PWM-Me) that causes fluctuations at this beat frequency in the speed and torque of the motor. Such fluctuations in and of themselves are undesirable, and in addition they also increase the noise produced by a motor in which such fluctuations occur.
SUMMARY OF THE INVENTION The present invention provides a pulse width modulation controller for a variable speed variable torque electric motor in which the motor controller produces PWM power drive signals the frequency of which is a fixed integral multiple "n" of the frequency of the power phase commutation, or power phase enable, signals. These power phase enable signals determine the time period each power phase winding can be energized and the order, or sequence, in which they are energized which determines the direction of rotation of the rotor. This invention provides a PWM controller for a variable speed and variable torque motor that produces PWM power drive signals, the frequency of which is a fixed integral multiple of the frequency of the power phase enable signals also produced by the controller.
This invention discloses a PWM controller for an electric motor in which the frequency of the PWM power drive signal is a fixed integral multiple of the power phase enable signal over the complete operating ranges for the RPM and the torque of the motor.
Further, this invention teaches a controller which reduces noise and variations in the speed and torque in a variable speed variable torque electric motor by maintaining constant the number of pulses of the PWM power drive signals controlling the flow of electrical current through each power phase winding circuit of a motor during the period of time that each power phase winding circuit can be energized.
BRIEF DESCRIPTION OF THE DRAWINGS
Other objects, features and advantages of the invention will be readily apparent from the following description of a preferred embodiment thereof, taken in conjunction with the accompanying drawings, although variations and modifications may be affected without departing from the spirit and scope of the novel concepts of the disclosure, and in which:
Fig. 1 is a schematic diagram of a prior art SR motor illustrating a conventional motor controller energizing a single stator phase winding of the motor; Fig. 2 is a schematic cross section through a prior art PM motor. Fig. 3 is schematic block diagram of a motor controller incorporating the invention for a SR motor;
Fig. 4 is a block diagram of the motor controller of Fig. 3;
Fig. 5 is a block diagram of the PWM current control and power switch logic circuit of Fig. 4; and
Fig. 6 is a timing diagram showing the relationship between pulses of the power phase enable signals and pulses of the PWM power drive signals.
DESCRIPTION OF THE INVENTION
For convenience, the operation of the pulse width modulation controller of this invention is described in conjunction with a switched reluctance motor. As pointed out above, the controller of this invention can be used with any type electric motor in which the speed and torque produced by the motor is controlled by pulse width modulation of the power flow through the power phase winding circuits of the motor such as a permanent magnet motor. Referring to Fig. 1, prior art SR motor 10 has a rotor 12 which has no windings, permanent magnets, or commutator. Stator 14 has a relatively small number of stator power phase windings 16 with only one such winding, 16A which includes a pair of series connected coils 18A1 and 18A2 being illustrated in Fig. 1. Rotor 12 is mounted on shaft 20 for rotation around an axis of rotation which coincides with the longitudinal axis of cylindrical shaft 20. Rotor 12 is preferably made from a plurality of laminations formed, or stamped, from sheets of a magnetically permeable steel alloy. Stator 14 likewise is preferably formed from a plurality of laminations made of a magnetically permeable steel alloy.
Stator 14, as illustrated in Fig. 1, has eight stator poles 22 and rotor 12 has six rotor poles 24. Coils 18 on diametrically opposite stator poles 22 are connected in series to form four power phase windings 16A, 16B, 16C, and 16D. For ease of illustration, phase windings 16B, 16C, and 16D are not shown in Fig. 1; instead, the stator poles associated with these phase windings are labeled "B", "C", and "D". In a SR motor, different combinations of numbers of stator and rotor poles may be used; for example, a six stator pole and a four rotor pole combination would constitute a three phase motor since it would
have three stator power phase windings; and an eight stator pole and a six rotor pole motor would constitute a four phase motor since it would have four stator power phase windings. It should be noted that the number of stator and rotor poles is always an even number.
When a direct current flows through stator power phase winding 16A, both the stator 14 and the rotor 12 are magnetized. This produces a torque causing the rotor 12 to align a pair of its diametrically opposite poles 24 with the excited, or magnetized, stator poles 22A1 and 22A2. The polarity of the torque does not depend on the polarity of the current since the rotor 12 is always attracted to the stator 14 and rotates to an orientation that provides a minimum reluctance path between energized poles. Thus, a SR motor requires only unipolar current through its power phase windings from power source 26. Sequential excitation of the phase windings 16A-16D causes rotor 12 to rotate by synchronously aligning a pair of rotor poles 24 with the stator poles 22 whose power phase winding 16 are energized, or excited. While the power phase windings are typically sequentially energized with one phase being turned off concurrent with the next phase being turned on, the energization of the power phase windings may overlap with the succeeding phase being energized before the preceding phase is deenergized. Rotor position sensor 28 provides controller 30 with information as to the position of rotor 12 relative to stator 14 necessary for synchronization of the rotation of rotor 12 and the sequential excitation, or energization, of stator power phase windings 16A-16D. In Fig. 1, only a basic electrical circuit for energizing stator power phase winding, or phase, 16A is illustrated. Similar circuitry is provided for phases 16B-16D, but are not illustrated. When switch pair 32 are closed, an electrical current builds up in phase 16A from DC power source 26. When switch pair 32 are opened, the current transfers to diodes 34 which quickly remove and recover any stored energy as the result of energizing phase 16 A.
Rotor 12 rotates in the opposite direction to the sequence in which stator phase windings 16A-16D are energized, or excited. Current pulses through phase windings 16A-16D are controlled by controller 30 in response to motor electrical (Me) timing signals produced by rotor position sensor 28 and are timed to occur at specific angles "q" of rotor 12. Thus, the commutation of the current through stator phase windings 16A-16D occur at specific rotor angles q with the object being to produce a relatively smooth rotational transition of a rotor pole 24 past an attracting stator pole 22. To accomplish this,
each power phase winding is substantially deenergized before the attracting stator poles and the attracted rotor poles align.
The timing of when energizing current pulses flow through a stator power phase winding and the duration of such a period, is determined by controller 30 which produces power phase commutation, or power phase enable, signals which are a function of the rotor angle q and the RPM of the motor. The magnitude of the currents in the stator phase windings is controlled by pulse width modulating (PWM) the energizing current flowing through a given power phase winding while that power phase winding is enabled by a power phase enable signal, or pulse. Referring to Fig. 2, prior art PM motor 36 has a rotor 38 on which are mounted two diametrically opposed permanent magnets 40, 41 with magnets 40 and 41 constituting rotor poles 42, 43. Rotor 38 is positioned within stator 44 for rotation with respect to the longitudinal axis of shaft 46 on which rotor 38 is mounted. Stator 44 in the embodiment illustrated in Fig. 2 is provided with two sets of diametrically opposed stator poles 48, 49. Stator 44 has two stator power phase windings 50, 52 with each of the windings 50, 52 including a pair of series connected coils. Since PM motor 36 has a total of four stator poles, it is a two phase motor.
Other than having permanent magnets mounted on rotor 38, different numbers of stator and rotor poles, and the need to reverse the direction of current flow through the power phase windings 50, 52 each time the current is commutated. For additional information concerning PM motors, reference is made to "D.C. Motors, Speed Control, and Servo Systems; Engineering Handbook; published by Electrocraft Corp.; 3rd. Edition, 1975.
In Fig. 3, motor 10, its rotor 12, stator, power phase windings, and rotor position sensor are essentially the same as illustrated in Fig. 1. Motor controller 56 has applied to its input terminal 58 a speed set signal, a DC voltage, which is a function of the desired RPM of rotor 12 of motor 10, and to input terminal 60 a direction of rotation signal the polarity of which represents the desired direction of rotation of rotor 12. Electric current for energizing the coils of each of the power phase windings 16A-16D is derived from power source V+. Each of the power phase windings 16A-16D is connected in series with one of the power switches 62A-D, which are preferably power MOSFETs. Motor controller 56 produces PWM power drive signals at output terminals 64A-D which are
applied respectively to power switches 62A-D. The "on" portion of each pulse of the power drive signal turns on the power switch 62 to which it is applied permitting current to flow through the power phase winding connected in series with the power switch as well as through the one of resistors 66A-D connected in series with each of the power switches 62A-D. Power phase winding 16 A, power switch 62 A, and resistor 66 A collectively form power phase winding circuit 68A. Similarly power phase windings circuits 68B-D are each made up of a series connected power phase winding, a power switch, and a resistor.
The voltage drop across each of the resistors 66A-D is proportional to the magnitude of the current flowing through its respective power phase winding circuit 68A- D and provides a measure of the magnitude of the current in any one of the phase windings at any given instant in time. The voltages across resistors 66A-D, constitute a power phase current, or torque feedback, signal, and are applied respectively to input terminals 70A-D of motor controller 56. Rotor position sensor 28 which can be an encoder, or resolver, for example, produces the motor electrical (Me) signal the timing of the signals of which is a function of the angular position of rotor 12 with respect to stator 14, and the frequency of which is a function of the number of revolutions per minute (RPM) of rotor 12 multiplied by the number of rotor poles 24, six in the preferred example. The Me signal is applied to input terminal 72 of motor controller 56.
In Fig. 4, which is a block diagram in greater detail of motor controller 56, the Me signal applied to input terminal 72 of controller 56 is applied to phase comparator 74 of phase-locked loop, (PLL) 76. The output of voltage controlled oscillator, VCO, 78 of PLL 76 is the pulse width modulation, PWM, signal used in generating pulse width modulated power drive signals that are applied to power transistor 62A-D through output terminals
64A-D of controller 56, as will be explained below. The PWM signals are also applied to "÷ N" counter 80, the output of which is a power phase commutation signal. The output of ÷ N counter 80 is applied as the second input to phase comparator 74 and also to the clock input terminal 82 of up-down counter 84. The outputs at terminals A-D of up-down counter 84, power phase enable signals, determine the period of time during which each power phase winding of motor 10 can be energized, and the sequence in which they are to be energized. Counter 84, depending on
the polarity of the signal applied to it through direction of rotation terminal 60 can be sequenced to count up; i.e. A, B, C, D; or to count down; i.e., D, C, B, A. The direction of the count determines whether power phase windings 16A-16D are sequenced in a clockwise or counter clockwise direction, which in turn determines the direction of rotation of rotor 12. Thus, the motor direction command signal applied to input terminal
60 of controller 56 and thence to the up/down control terminal of counter 84 determines the direction of rotation of rotor 12 of motor 10.
The speed set signal, the magnitude of which is a function of the desired RPM of motor 10, is applied to input terminal 58 of controller 56 and to the positive input terminal of operational amplifier (op-amp) 86. The output of source follower 88 of PLL 76 is applied to the negative input terminal of op amp 86. The magnitude of the voltage produced by source follower 88 of PLL 76 is an actual motor speed voltage signal, and is a function of the instantaneous RPM of rotor 12. The output of op-amp 86, a speed error signal, is positive if the RPM of rotor 12 is less than that specified by the speed set signal and negative if greater. The circuit including diode 90, transistor 92, and potentiometer 94 limits the magnitude of positive speed error signals to limit the maximum current in the power phase windings which in turn limits the maximum torque of motor 10. The speed error signal and PWM signals are applied to each of the PWM current control and power switch logic circuits 96A-D. The phase enable signals present at the A-D output terminals of counter 84 are applied, respectively, to circuits 96A-D as are phase current feedback signals which are applied to input terminals 70A-D.
Referring to Fig. 5, each of the circuits 96A-D includes an op-amp 98A-D, a set- reset flip flop 100A-D, and an AND gate 102A-D. The PWM signals from PLL 76 are applied to the set terminal "S" of each of the flip flops 100 A-D. The signal applied to the reset terminal "R" of flip flop 100A is the output of op-amp 98 A of circuit 96A. The speed error signal from the circuit including op-amp 86 is applied to the negative input terminals of op-amps 98A-D, and the phase A current feedback signal, for example, is applied to the positive input terminal of op amp 98 A.
When a pulse of the PWM signal applied to the set terminal S of flip flop 100A goes positive, the "Q" output of flip flop 100A goes high and remains so until the voltage at its reset terminal R reaches a value that resets flip flop 100A. The time period between when the Q output goes high and flip flop 100A is reset and the Q output goes low is
determined by how long it takes for the output of op-amp 98A to reach the magnitude required to reset flip flop 100A. This is determined by the magnitude and polarity of the speed error signal and the magnitude of the Phase A current feedback signal applied to op amp 98A. The greater the magnitude of the phase A current the narrower the positive portion, or duty cycle, of the pulses at the Q output of flip flop 78. If the speed error is negative, the wider the positive portions and the greater the duty cycle of the pulses, and if the speed error is positive, the smaller the duty cycle.
The Q output of flip flop 100a is applied as one input to AND gate 102A. The other input to AND gate 102 A is the phase A enable signal available at the A output terminal of counter 84. The output of AND gate J02A at terminal 64A is the Phase A power drive signal that is applied to power transistor 62A. The operations of circuits 96B, 96C, and 96D are substantially identical with that of circuit 96A as set forth above. The result of the operation of circuit 96A, for example, is that the duration of the power on portion, or duty cycle, of each pulse of the power drive signal applied to power switch 62A is a function of the speed error signal and the power phase current, or torque, feedback signals from power phase winding circuit 68A.
In Fig. 6, signals SI, S2, S3, and S4 illustrate the timing of the A, B, C, and D power phase enable signals produced at the A. B, C, and D output terminals of counter 84.
Thus, when the B power phase enable signal is positive, AND gate 102B in Fig 5 is enabled so that PWM power drive signals present at the "Q" output of flip flop 100B are transmitted to the power transistor 62B of power phase winding circuit 68B. With respect to signal S5 and S6, the horizontal scale has been increased to better illustrate the shape and number of power drive pulses applied to power transistor 62A, for example, during the time period that the phase A enable pulse of S4 is positive, or on, and during which period AND gate 102A is enabled. Wave form S5 illustrates the width, or duration, of the power on portion, or duty cycle, of each phase A power drive signal applied to power drive transistor 62A while the phase A enable pulse is positive and in particular when motor 10 is driving a normal load. Wave form S6 illustrates the width of the power on portion of each phase A power drive signal when motor 10 is driving a small load. It should be noted that the number of power drive signals applied to a power transistor of a stator phase winding during the period each phase winding is enabled by a phase enable signal is a constant integral, five in the illustrated embodiment, at any motor
JO- speed and at any loading or torque up to a predetermined maximum torque. Stated another way, the frequency of the power drive signals is a constant integral multiple of the frequency of the power enable, or power phase commutation, signals at any RPM of the motor. The limitation as to the maximum torque that motor 10 can generate prevents excessively large currents from flowing through the phase windings which could damage the motor.
Obviously many modification and variations of the present invention are possible in the light of the above teachings. It is therefore to be understood that within the scope of the appended claims the invention may be practiced other than as specifically described and illustrated.