Electronically commutated motor systems and control therefor
First Claim
1. A brushless DC motor and control arrangement for use with a refrigeration system comprising an evaporator, a compressor for moving a refrigerant through the evaporator, an evaporator fan for moving air about the evaporator for maintaining a desired temperature within a compartment by moving refrigerated air thereto, and wherein said brushless DC motor is coupled to said compressor and comprises a stationary armature having a core and winding means arranged to establish at least two winding stages;
- said winding means comprising concentric winding turns accommodated by said core and arranged to establish a predetermined number of magnetic poles, and the winding turns of each winding stage having a number of sets of axially extending conductor portions with such number equal to the predetermined number of magnetic poles;
the axially extending conductor portions within each given set being disposed in said armature to conduct current instantaneously in a common axial direction along the core thereby contributing to establishment of a magnetic pole when the winding stage containing the given set is energized;
a rotor having constant magnetic polar regions equal in number to the predetermined number of poles, said rotor being adapted to rotate in response to the magnetic poles established by the winding turns;
a commutation circuit for energizing the windings in a predetermined manner wherein said commutation circuit includes a detector circuit for sensing a back emf signal indicative of the back emf condition of at least one winding, position determining circuit means responsive to the emf signal from the detector circuit for integrating the emf signal to a predetermined value of volt-seconds whereupon the position determining circuit means produces a simulated relative position output signal;
means responsive to the simulated relative position output signal from the position determining circuit means for supplying an output signal for energizing a selected one of the winding stages; and
said control arrangement further including a regulating means adapted for controlling the supply of energization power to the winding stages;
said regulating means comprising means for responding to evaporator temperature and for varying the supply of power to the winding stages to thereby vary the speed of the brushless DC motor and control the flow rate of the refrigerant so as to maintain a selected portion of the evaporator at a first preselected reference temperature; and
said regulating means also comprising means for responding to a signal indicative of cooling demand within the compartment for automatically changing the first reference temperature of the selected portion of the evaporator in accordance with the relative cooling demand thereby to cause variance in the temperature of air moved about the evaporator for controlling temperature within the compartment.
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Accused Products
Abstract
Electronically commutated motor and control arrangements particularly adapted for use with refrigeration systems and methods of operating refrigeration systems are disclosed. In one form, a fan control means is provided for responding to temperature of a compartment being cooled by a refrigeration system; comparing the compartment temperature with a desired temperature; and varying the speed of an evaporator fan, thereby varying the movement of refrigerated air across an evaporator and into the compartment. A regulating circuit is provided for maintaining the evaporator at a reference temperature by controlling the output signal of an alternator which supplies energization power to winding stages of a brushless DC motor. By varying the energization level of the winding stages, a compressor, which is coupled to the motor, is caused to vary the flow rate of refrigerant through the evaporator so as to maintain the evaporator at the reference temperature. The regulating circuit includes means for responding to a signal from the fan control means, which is indicative of the fan speed and relative compartment cooling demand, for changing the reference temperature for the evaporator thereby to cause variance in the temperature of air moved about the evaporator by the fan for controlling temperature within the compartment. The regulating circuit also includes: means for limiting and controlling motor winding current to a maximum value; means for limiting motor speed to a predetermined low value; means for limiting and controlling motor speed to a maximum high value; means for assuring a minimum energization level for the motor winding stages; means for limiting the energization level of the winding stages to a maximum voltage value; and means for inhibiting motor operation if the evaporator temperature is less than a predetermined low temperature value.
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Citations
11 Claims
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1. A brushless DC motor and control arrangement for use with a refrigeration system comprising an evaporator, a compressor for moving a refrigerant through the evaporator, an evaporator fan for moving air about the evaporator for maintaining a desired temperature within a compartment by moving refrigerated air thereto, and wherein said brushless DC motor is coupled to said compressor and comprises a stationary armature having a core and winding means arranged to establish at least two winding stages;
- said winding means comprising concentric winding turns accommodated by said core and arranged to establish a predetermined number of magnetic poles, and the winding turns of each winding stage having a number of sets of axially extending conductor portions with such number equal to the predetermined number of magnetic poles;
the axially extending conductor portions within each given set being disposed in said armature to conduct current instantaneously in a common axial direction along the core thereby contributing to establishment of a magnetic pole when the winding stage containing the given set is energized;
a rotor having constant magnetic polar regions equal in number to the predetermined number of poles, said rotor being adapted to rotate in response to the magnetic poles established by the winding turns;
a commutation circuit for energizing the windings in a predetermined manner wherein said commutation circuit includes a detector circuit for sensing a back emf signal indicative of the back emf condition of at least one winding, position determining circuit means responsive to the emf signal from the detector circuit for integrating the emf signal to a predetermined value of volt-seconds whereupon the position determining circuit means produces a simulated relative position output signal;
means responsive to the simulated relative position output signal from the position determining circuit means for supplying an output signal for energizing a selected one of the winding stages; and
said control arrangement further including a regulating means adapted for controlling the supply of energization power to the winding stages;
said regulating means comprising means for responding to evaporator temperature and for varying the supply of power to the winding stages to thereby vary the speed of the brushless DC motor and control the flow rate of the refrigerant so as to maintain a selected portion of the evaporator at a first preselected reference temperature; and
said regulating means also comprising means for responding to a signal indicative of cooling demand within the compartment for automatically changing the first reference temperature of the selected portion of the evaporator in accordance with the relative cooling demand thereby to cause variance in the temperature of air moved about the evaporator for controlling temperature within the compartment. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
- said winding means comprising concentric winding turns accommodated by said core and arranged to establish a predetermined number of magnetic poles, and the winding turns of each winding stage having a number of sets of axially extending conductor portions with such number equal to the predetermined number of magnetic poles;
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10. A method of controlling a refrigeration system comprising an evaporator, a compressor for circulating refrigerant through the evaporator, an evaporator fan for moving air about the evaporator to maintain a desired temperature within a compartment, a brushless DC motor coupled to said compressor and having a core with a longitudinal axis and at least two winding stages disposed on said core for producing magnetic fields, a rotor adapted to rotate about the longitudinal axis in response to the magnetic fields produced by the winding stages, and a commutation circuit for sensing the position of the rotor and selectively switching a power source to selectively energize the winding stages in accordance with the relative position of the rotor and winding stages, said method comprising:
- sensing temperature of the compartment being cooled by the system, comparing said temperature with a desired compartment temperature and varying operating speed of the evaporator fan in accordance with the difference between the sensed temperature and desired temperature;
sensing evaporator temperature, comparing the evaporator temperature with a reference temperature, and controlling the power source output in accordance with the difference between the evaporator temperature and the reference temperature, thereby varying the speed of the brushless DC motor whereby the flow rate of refrigerant moved through the evaporator is varied to control operating temperature of the evaporator;
automatically varying the reference temperature for the evaporator in accordance with a signal indicative of the evaporator fan speed, thereby changing the temperature of the air being moved by the fan for facilitating control of the compartment temperature at the desired temperature.
- sensing temperature of the compartment being cooled by the system, comparing said temperature with a desired compartment temperature and varying operating speed of the evaporator fan in accordance with the difference between the sensed temperature and desired temperature;
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11. An improved brushless DC motor control circuit for controlling application of power to winding stages of a brushless DC motor having a stationary armature comprising a core with a longitudinal axis and at least two winding stages disposed on the core to establish magnetic fields, a rotor adapted to rotate about said longitudinal axis in response to the magnetic fields established by said armature, and a commutation circuit for controlling energization of the winding stages in accordance with the relative rotor position of the rotor and winding stages, said control circuit being particularly adapted for use in a refrigeration system comprising a compressor coupled to said brushless DC motor for moving refrigerant through an evaporator and an evaporator fan for moving air about the evaporator so as to maintain a predetermined temperature within a compartment subjected to cooling by the refrigeration system, said brushless DC motor control circuit comprising:
- evaporator fan control means for responding to temperature within the compartment for varying the speed of the evaporator fan in accordance with differences between the measured compartment temperature and a desired compartment temperature and for producing an output signal indicative of the relative operating speed of the fan motor;
a regulating circuit including means for connection to a power source for supplying power to the winding stages, for responding to evaporator temperature and for controlling the output of the power source to thereby vary the speed of the brushless DC motor to cause the evaporator temperature to vary; and
said regulating circuit being responsive to the output signal of the fan control means for adjusting the evaporator temperature in accordance with the relative operating speed of the fan motor, whereby the temperature of the air being moved by the evaporator fan is varied to achieve the desired cooling within the compartment.
- evaporator fan control means for responding to temperature within the compartment for varying the speed of the evaporator fan in accordance with differences between the measured compartment temperature and a desired compartment temperature and for producing an output signal indicative of the relative operating speed of the fan motor;
Specification