초록 ▼

A motor control system for use in heating, ventilation, and air conditioning applications includes a blower, a motor coupled to drive the blower, an inverter coupled to provide energization to the motor, and a controller coupled to the inverter. The controller provides signals to control the output

A motor control system for use in heating, ventilation, and air conditioning applications includes a blower, a motor coupled to drive the blower, an inverter coupled to provide energization to the motor, and a controller coupled to the inverter. The controller provides signals to control the output of the inverter in response to received input control signals. Input control signals received by the controller can define first and second operating states. In response to the input control signals defining the first operating state, the controller controls the output of the inverter in accordance with a first volts vs. hertz relationship. In response to the input control signals defining the second operating state, the controller controls the output of the inverter in accordance with a second volts vs. hertz relationship, where the first volts vs. hertz relationship is different than the second volts vs. hertz relationship.

대표청구항 ▼

1. A motor control system for use in heating, ventilation, and air conditioning applications comprising:a blower,a single phase motor coupled to drive the blower;an inverter coupled to provide energization to the motor, the inverter providing at its output a single-phase sinusoidal waveform; anda co

1. A motor control system for use in heating, ventilation, and air conditioning applications comprising:a blower,a single phase motor coupled to drive the blower;an inverter coupled to provide energization to the motor, the inverter providing at its output a single-phase sinusoidal waveform; anda controller coupled to the inverter, the controller providing signals to control the output of the inverter in response to received input control signals,wherein the input control signals received by the controller can define a first operating state and a second operating state,wherein, in response to the input control signals defining the first operating state, the controller controls the output of the inverter in accordance with a first volts vs. hertz relationship, andwherein, in response to the input control signals defining the second operating state, the controller controls the output of the inverter in accordance with a second volts vs. hertz relationship, the first volts vs. hertz relationship being different than the second volts vs. hertz relationship and both the first and the second volts vs. hertz relationships being linear relationships. 2. The control system of claim 1 wherein the single phase motor is a permanent split capacitor motor. 3. The control system of claim 1 wherein each operating state corresponds to a desired current level in the motor. 4. The control system of claim 1 wherein each operating state corresponds to a desired output frequency of the inverter. 5. The control system of claim 1 further comprising input conversion circuitry for converting input signals of a first form and at a first voltage level to the input control signals, the input control signals being of a second form and having voltage levels below the first voltage level. 6. The control system of claim 1 wherein each operating state corresponds to a desired level of output power from the inverter. 7. A motor control system comprising:a permanent split capacitor motor;an inverter coupled to provide energization to the motor;a controller coupled to the inverter, the controller providing signals to control the output of the inverter in response to received input control signals,wherein the input control signals received by the controller can define at least two operating states, each operating state defining a desired level of current in the motor and a linear volts vs. hertz relationship, andwherein, in response to a set of input control signal, the controller controls the output of the inverter in accordance with the volts vs. hertz relationship corresponding to the set of input control signals to drive the motor current to the current level that corresponds to the set of input control signals. 8. A motor control system comprising:a permanent split capacitor motor;an inverter coupled to provide energization to the motor;a controller coupled to the inverter, the controller providing signals to control the output of the inverter in response to received input control signals, wherein the input control signals received by the controller can define at least two operating states, each operating state defining a desired level of current in the motor and a linear volts vs. hertz relationship, and wherein, in response to a set of input control signal, the controller controls the output of the inverter in accordance with the volts vs. hertz relationship, corresponding to the set of input control signals to drive the motor current to the current level that corresponds to the set of input control signals; anda relay having:a first input coupled to receive line power;a second input coupled to receive the output of the inverter;an output coupled to the motor; anda control input coupled to receive a control signal controlled by the controller,wherein the controller controls the relay to cause the motor to be energized by line power when the desired frequency for energization of the motor as defined by the controller in response to the input control signals is at or near line frequency. 9. The motor control system of claim 8 further including fail-safe circuitry for ensuring that, in the event of a failure in the controller, the relay will be configured to cause the motor to be energized by line power. 10. The motor control system of claim 9 wherein the volts vs. hertz relationship for each set of acceptable input control signals defines a minimum output frequency and a maximum output frequency and wherein the minimum and maximum frequency values for each of the defined volts vs. hertz relationships is the same. 11. A motor control system comprising:a permanent split capacitor motor;an inverter coupled to provide energization to the motor; anda controller coupled to the inverter, the controller providing signals to control the output of the inverter in response to received input control signals,wherein the input control signals received by the controller can define at least two operating states, each operating state defining a desired level of current in the motor and a linear volts vs. hertz relationship,wherein, in response to a set of input control signal, the control controls the output of the inverter in accordance with the volts vs. hertz relationship corresponding to the set of input control signals to drive the motor current to the current level that corresponds to the set of input control signals, andwherein the volts vs. hertz relationship for each set of acceptable input control signals defines a minimum output voltage and a maximum output voltage and wherein the minimum and maximum frequency voltages for at least two of the defined volts vs. hertz relationships are different. 12. A motor control system comprising:a permanent split capacitor motor;an inverter coupled to provide energization to the motor; anda controller coupled to the inverter, the controller providing signals to control the output of the inverter in response to received input control signals,wherein the input control signals received by the controller can define at least two operating states, each operating state defining a desired level of current in the motor and a linear volts vs. hertz relationship,wherein, in response to a set of input control signal, the controller controls the output of the inverter in accordance with the volts vs. hertz relationship corresponding to the set of input control signals to drive the motor current to the current level that corresponds tot he set of input control signals, andwherein the defined volts vs. hertz relationships are all linear. 13. A motor control system comprising:a permanent split capacitor motor;an inverter coupled to provide energization to the motor;a controller coupled to the inverter, the controller providing signals to control the output of the inverter in response to received input control signals, wherein the input control signals received by the controller can define at least two operating states, each operating state defining a desired level of current in the motor and a linear volts vs. hertz relationship, and wherein, in response to a set of input control signal, the controller controls the output of the inverter in accordance with the volts vs. hertz relationship corresponding to the set of input control signals to drive the motor current to the current level that corresponds to the set of input control signals; andcurrent detection circuitry for monitoring the current provided by the inverter and resetting the controller in the event that an abnormally high current is detected. 14. The motor control system of claim 7, further including:a generally L-shaped bracket assembly;a lid element adapted to be coupled to the curved exterior of a blower housing, the lid being hingedly coupled to the generally L-shaped bracket assembly; anda control module containing circuit components for an inverter and an electronic controller, the control module mounted to the generally L-shaped bracket assembly such that, when the L-shaped bracket assembly is in a first position wherein the L-shaped bracket assembly makes contact with the lid assembly, access to the control module is blocked by the bracket assembly, and when the L-shaped bracket assembly is swung open along the hinged connection access to the control module is enabled. 15. A motor control system for use with a permanent split capacitor motor coupled to a blower in a heating, ventilation, and air conditioning applications comprising:an inverter having outputs providing a single-phase sinusoidal waveform of variable amplitude and frequency and adapted to energize the permanent split capacitor motor;means for controlling the output of the inverter in response to received input control signals in accordance with a plurality of linear volts vs. hertz relationships. 16. The motor control system of claim 15 wherein the received input control signals are AC voltage signals and the system further includes means for converting the received input control signals into digital control signals. 17. A motor control system for use with a motor coupled to a blower in a heating, ventilation, and air conditioning applications comprising:an inverter having outputs adapted to energize the motor;means for controlling the output of the inverter in response to received input control signals in accordance with a plurality of volts vs. hertz relationships; andfield adjustable means for making field adjustments to the output of the inverter such that the output of the inverter, for a given set of received input control signals will vary depending on the field adjustments. 18. The motor control system of claim 17 further including a relay coupled between the inverter outputs and the motor, the relay being switchable form a first position where the motor is energized from the inverter to a second position where the motor is energized from line power.