IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0636825
(2009-12-14)
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등록번호 |
US-8651824
(2014-02-18)
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발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
Smith Gambrell & Russell LLP
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인용정보 |
피인용 횟수 :
1 인용 특허 :
45 |
초록
▼
A condensate pump for an HVAC system includes a reservoir for collecting condensate water, a pump motor connected to an impeller pump for pumping the condensate water out of the reservoir, and a floatless pump control module. The floatless pump's microcontroller detects the water level in the reserv
A condensate pump for an HVAC system includes a reservoir for collecting condensate water, a pump motor connected to an impeller pump for pumping the condensate water out of the reservoir, and a floatless pump control module. The floatless pump's microcontroller detects the water level in the reservoir and, based on the water level in the reservoir, controls the operation of the pump motor, and if necessary, sounds an alarm and shuts down the HVAC system. The floatless pump microcontroller may employ an ultrasonic transducer or capacitance sensors to detect the level of condensate water in the reservoir. The microcontroller implements a variable water lift feature to pump the water using the lowest possible speed for the pump. The microcontroller implements a self-cleaning feature to pump stagnant water out of the reservoir and to pulse water in the drain line and the agitation of the water in the reservoir. The microcontroller implements an anti-clog feature to clear a clogged drain line when an overflow condition is detected.
대표청구항
▼
1. A pump control module for an HVAC system having a reservoir for collecting condensate water, the condensate water being pumped out of the reservoir via a pump impeller driven by a variable speed motor to a destination through an outlet of a drain line located at an elevation above the pump, where
1. A pump control module for an HVAC system having a reservoir for collecting condensate water, the condensate water being pumped out of the reservoir via a pump impeller driven by a variable speed motor to a destination through an outlet of a drain line located at an elevation above the pump, wherein the control module comprises: a) a floatless water level sensor for detecting the level of water in the reservoir;b) a control switch for starting and stopping of the motor, and for controlling the speed of the motor; andc) a microcontroller for controlling the operation of the control switch, in response to the detected water level, the microcontroller implementing is configured to implement the steps of: i. monitoring of the water level sensor and detecting when the water in the reservoir has reached an intermediate level;ii. in response to the water reaching the intermediate level, starting the motor at a first low speed;iii. increasing the speed of the motor until the speed of the pump motor is sufficient to pump the water out of the reservoir through the drain line to the elevation of the outlet of the drain line;iv. monitoring the water level sensor while the speed of the motor is increasing; andv. setting the speed of the motor at the lowest speed reached when the water subsequently falls below the intermediate level. 2. The pump control module of claim 1, wherein the microcontroller further is configured to implement the steps of: a) timing a dwell time that the water stays at or above the intermediate level while the motor is running at the first low speed; andb) in response to the dwell time exceeding a first predetermined threshold increasing the speed of the motor until the dwell time is reduced to a second predetermined threshold thereby keeping the speed of the motor at the lowest speed required to pump the water out of the reservoir through the drain line to the elevation of the outlet of the drain line. 3. The floatless condensate pump control module of claim 1, wherein the starting step includes applying full power to the motor for a short period of time to ensure that the motor starts prior to establishing the first low speed for the motor. 4. The floatless condensate pump control module of claim 1, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir, a run capacitance sensor located at the intermediate water level in the reservoir, and an overflow capacitance sensor located at a near overflow water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level, at an intermediate water level, or at a near overflow water level based on changes in capacitance of each capacitance sensor when each capacitor sensor is in contact with the water in the reservoir. 5. The floatless condensate pump control module of claim 1, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir and a run capacitance sensor located at an intermediate water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level based on a change in capacitance of the empty capacitance sensor when the empty capacitor sensor is in contact with the water in the reservoir, wherein the microcontroller determines whether the water in the reservoir is at an intermediate water level based on a change in capacitance of the run capacitance sensor when the run capacitor sensor is in contact with the water in the reservoir, and wherein the microcontroller determines whether the water in the reservoir is at a near overflow water level based on the time that the water in the reservoir is in contact with the run capacitance sensor while the motor is running. 6. The pump control module of claim 1, wherein the water level sensor includes an elongated capacitance sensor located in the reservoir with its length vertically oriented in the reservoir, the capacitance sensor being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level, an intermediate water level, or a near overflow water level based on changes in capacitance of the capacitance sensor as the water in the reservoir rises and falls along the length of the capacitance sensor. 7. The pump control module of claim 1, wherein the water level sensor is an ultrasonic transmitter and receiver. 8. The pump control module of claim 1, wherein the floatless condensate pump control module further includes a status indicator light controlled by the microcontroller to indicate visually the operating status of the condensate pump. 9. The pump control module of claim 1, wherein the floatless condensate pump control module further includes an infrared emitter and an infrared receiver connected to the microcontroller for transmitting and receiving data to and from the microcontroller. 10. The floatless condensate pump control module of claim 1, wherein the floatless condensate pump control module further includes an RF transceiver connected to the microcontroller for transmitting and receiving data to and from the microcontroller. 11. The pump control module of claim 1, wherein the floatless condensate pump control module further includes an alarm switch controlled by the microcontroller to sound an alarm when the condensate water in the reservoir reaches a near overflow condition. 12. The pump control module of claim 1, wherein the floatless condensate pump control module further includes a safety switch controlled by the microcontroller to shut down the HVAC system when the condensate water in the reservoir reaches a near overflow condition. 13. A pump control module for an HVAC system having a reservoir for collecting condensate water, the condensate water being pumped out of the reservoir via a pump impeller driven by a variable speed motor, wherein the control module comprises: a) a floatless water level sensor for detecting the level of water in the reservoir;b) a control switch for starting and stopping of the motor, and for controlling the speed of the motor;c) an HVAC control switch to enable and disable the HVAC system; andd) a microcontroller for controlling the operation of the control switch, in response to the detected water level, the microcontroller is configured to implement the steps of: i. detecting when the water in the reservoir has reached a near overflow water level;ii. in response to the water reaching the near overflow water level, increasing the speed of the motor to its maximum speed;iii. timing a first dwell time that the water stays at or above the near overflow water level;iv. in response to the first dwell time exceeding a first predetermined threshold, rapidly changing the speed of the motor to create pulses of water in the drain line;v. timing a second dwell time that the water stays at or above the near overflow water level after the motor begins rapidly changing speeds; andvi. in response to the second dwell time exceeding a second predetermined threshold, shutting off the HVAC system by means of the HVAC control switch. 14. The pump control module of claim 13, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir, a run capacitance sensor located at an intermediate water level in the reservoir, and an overflow capacitance sensor located at the near overflow water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at the low water level, at the intermediate water level, or at the near overflow water level based on changes in capacitance of each capacitance sensor when each capacitor sensor is in contact with the water in the reservoir. 15. The pump control module of claim 13, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir and a run capacitance sensor located at an intermediate water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at the low water level based on a change in capacitance of the empty capacitance sensor when the empty capacitor sensor is in contact with the water in the reservoir, wherein the microcontroller determines whether the water in the reservoir is at the intermediate water level based on a change in capacitance of the run capacitance sensor when the run capacitor sensor is in contact with the water in the reservoir, and wherein the microcontroller determines whether the water in the reservoir is at the near overflow water level based on the time that the water in the reservoir is in contact with the run capacitance sensor while the motor is running. 16. The pump control module of claim 13, wherein the water level sensor includes an elongated capacitance sensor located in the reservoir with its length vertically oriented in the reservoir, the capacitance sensor being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level, an intermediate water level, or the near overflow water level based on changes in capacitance of the capacitance sensor as the water in the reservoir rises and falls along the length of the capacitance sensor. 17. The pump control module of claim 13, wherein the water level sensor is an ultrasonic transmitter and receiver. 18. The pump control module of claim 13, wherein the floatless condensate pump control module further includes a status indicator light controlled by the microcontroller to indicate visually the operating status of the condensate pump. 19. The pump control module of claim 13, wherein the floatless condensate pump control module further includes an infrared emitter and an infrared receiver connected to the microcontroller for transmitting and receiving data to and from the microcontroller. 20. The floatless condensate pump control module of claim 13, wherein the floatless condensate pump control module further includes an RF transceiver connected to the microcontroller for transmitting and receiving data to and from the microcontroller. 21. The pump control module of claim 13, wherein the floatless condensate pump control module further includes an alarm switch controlled by the microcontroller to sound an alarm when the condensate water in the reservoir reaches a near overflow condition. 22. The pump control module of claim 13, wherein the floatless condensate pump control module further includes a safety switch controlled by the microcontroller to shut down the HVAC system when the condensate water in the reservoir reaches a near overflow condition. 23. A pump control module for an HVAC system having a reservoir for collecting condensate water, the condensate water being pumped out of the reservoir via a pump impeller driven by a variable speed motor, wherein the pump control module comprises: a) a floatless water level sensor for detecting the level of water in the reservoir;b) a control switch for starting and stopping of the motor, and for controlling the speed of the motor; andc) a microcontroller for controlling the operation of the control switch, in response to the detected water level, the microcontroller is configured to implement the steps of: i. timing a cleaning dwell time;ii. determining that the cleaning dwell time has exceed a predetermined threshold and that the water in the reservoir has reached an intermediate water level; andiii. in response to the cleaning dwell time exceeding the predetermined threshold and in response to the water being at or above the intermediate water level, starting the motor and rapidly changing the speed of the motor to create pulses of water in the drain line and to agitate the water in the reservoir. 24. The pump control module of claim 23, wherein the starting step includes applying full power to the motor for a short period of time to ensure that the motor starts prior to rapidly changing the speed of the motor. 25. The pump control module of claim 23, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir, a run capacitance sensor located at the intermediate water level in the reservoir, and an overflow capacitance sensor located at a near overflow water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at the low water level, at the intermediate water level, or at the near overflow water level based on changes in capacitance of each capacitance sensor when each capacitor sensor is in contact with the water in the reservoir. 26. The pump control module of claim 23, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir and a run capacitance sensor located at the intermediate water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at the low water level based on a change in capacitance of the empty capacitance sensor when the empty capacitor sensor is in contact with the water in the reservoir, wherein the microcontroller determines whether the water in the reservoir is at the intermediate water level based on a change in capacitance of the run capacitance sensor when the run capacitor sensor is in contact with the water in the reservoir, and wherein the microcontroller determines whether the water in the reservoir is at the near overflow water level based on the time that the water in the reservoir is in contact with the run capacitance sensor while the motor is running. 27. The pump control module of claim 23, wherein the water level sensor includes an elongated capacitance sensor located in the reservoir with its length vertically oriented in the reservoir, the capacitance sensor being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level, the intermediate water level, or a near overflow water level based on changes in capacitance of the capacitance sensor as the water in the reservoir rises and falls along the length of the capacitance sensor. 28. The pump control module of claim 23, wherein the water level sensor is an ultrasonic transmitter and receiver. 29. The pump control module of claim 23, wherein the floatless condensate pump control module further includes a status indicator light controlled by the microcontroller to indicate visually the operating status of the condensate pump. 30. The pump control module of claim 23, wherein the floatless condensate pump control module further includes an infrared emitter and an infrared receiver connected to the microcontroller for transmitting and receiving data to and from the microcontroller. 31. The floatless condensate pump control module of claim 23, wherein the floatless condensate pump control module further includes an RF transceiver connected to the microcontroller for transmitting and receiving data to and from the microcontroller. 32. The pump control module of claim 23, wherein the floatless condensate pump control module further includes an alarm switch controlled by the microcontroller to sound an alarm when the condensate water in the reservoir reaches a near overflow condition. 33. The pump control module of claim 23, wherein the floatless condensate pump control module further includes a safety switch controlled by the microcontroller to shut down the HVAC system when the condensate water in the reservoir reaches a near overflow condition. 34. A pump control module for an HVAC system having a reservoir for collecting condensate water, the condensate water being pumped out of the reservoir via a pump impeller driven by a variable speed motor to a destination through an outlet of a drain line located at an elevation above the pump, wherein the control module comprises: a) a floatless water level sensor for detecting the level of water in the reservoir;b) a control switch for starting and stopping of the motor, and for controlling the speed of the motor; andc) a microcontroller for controlling the operation of the control switch, in response to the detected water level, the microcontroller is configured to implement the steps of: i. monitoring of the water level sensor and detecting when the water in the reservoir has reached an intermediate level;ii. in response to the water reaching the intermediate level, starting the motor at a first low speed; andiii. increasing the speed of the motor until the speed of the motor is sufficient to pump the water out of the reservoir through the drain line to the elevation of the outlet of the drain line;iv. timing a dwell time that the water stays at or above the intermediate level while the motor is running at the first low speed; andv. in response to the dwell time exceeding a first predetermined threshold increasing the speed of the motor until the dwell time is reduced to a second predetermined threshold thereby keeping the speed of the motor at the lowest speed required to pump the water out of the reservoir through the drain line to the elevation of the outlet of the drain line. 35. The pump control module of claim 34, wherein the microcontroller further is configured to implement the steps of: a) monitoring the water level sensor while the speed of the motor is increasing; andb) setting the speed of the motor at the lowest speed reached when the water subsequently falls below the intermediate level. 36. The pump control module of claim 34, wherein the starting step includes applying full power to the motor for a short period of time to ensure that the motor starts prior to establishing the first low speed for the motor. 37. The pump control module of claim 34, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir, a run capacitance sensor located at the intermediate water level in the reservoir, and an overflow capacitance sensor located at a near overflow water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level, at an intermediate water level, or at a near overflow water level based on changes in capacitance of each capacitance sensor when each capacitor sensor is in contact with the water in the reservoir. 38. The pump control module of claim 34, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir and a run capacitance sensor located at an intermediate water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level based on a change in capacitance of the empty capacitance sensor when the empty capacitor sensor is in contact with the water in the reservoir, wherein the microcontroller determines whether the water in the reservoir is at an intermediate water level based on a change in capacitance of the run capacitance sensor when the run capacitor sensor is in contact with the water in the reservoir, and wherein the microcontroller determines whether the water in the reservoir is at a near overflow water level based on the time that the water in the reservoir is in contact with the run capacitance sensor while the motor is running. 39. The pump control module of claim 34, wherein the water level sensor includes an elongated capacitance sensor located in the reservoir with its length vertically oriented in the reservoir, the capacitance sensor being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level, an intermediate water level, or a near overflow water level based on changes in capacitance of the capacitance sensor as the water in the reservoir rises and falls along the length of the capacitance sensor. 40. The pump control module of claim 34, wherein the water level sensor is an ultrasonic transmitter and receiver. 41. The pump control module of claim 34, wherein the floatless condensate pump control module further includes a status indicator light controlled by the microcontroller to indicate visually the operating status of the condensate pump. 42. The floatless condensate pump control module of claim 34, wherein the floatless condensate pump control module further includes an infrared emitter and an infrared receiver connected to the microcontroller for transmitting and receiving data to and from the microcontroller. 43. The pump control module of claim 34, wherein the floatless condensate pump control module further includes an alarm switch controlled by the microcontroller to sound an alarm when the condensate water in the reservoir reaches a near overflow condition. 44. The pump control module of claim 34, wherein the floatless condensate pump control module further includes a safety switch controlled by the microcontroller to shut down the HVAC system when the condensate water in the reservoir reaches a near overflow condition. 45. A pump control module for an HVAC system having a reservoir for collecting condensate water, the condensate water being pumped out of the reservoir via a pump impeller driven by a variable speed motor to a destination through an outlet of a drain line located at an elevation above the pump, wherein the control module comprises: a) a floatless water level sensor for detecting the level of water in the reservoir;b) a control switch for starting and stopping of the motor, and for controlling the speed of the motor; andc) a microcontroller for controlling the operation of the control switch, in response to the detected water level, the microcontroller is configured to implement the steps of: i. monitoring of the water level sensor and detecting when the water in the reservoir has reached an intermediate level;ii. in response to the water reaching the intermediate level, starting the motor at a first low speed; andiii. increasing the speed of the motor until the speed of the motor is sufficient to pump the water out of the reservoir through the drain line to the elevation of the outlet of the drain line, and wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir and a run capacitance sensor located at an intermediate water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level based on a change in capacitance of the empty capacitance sensor when the empty capacitor sensor is in contact with the water in the reservoir, wherein the microcontroller determines whether the water in the reservoir is at an intermediate water level based on a change in capacitance of the run capacitance sensor when the run capacitor sensor is in contact with the water in the reservoir, and wherein the microcontroller determines whether the water in the reservoir is at a near overflow water level based on the time that the water in the reservoir is in contact with the run capacitance sensor while the motor is running. 46. The pump control module of claim 45, wherein the microcontroller further is configured to implement the steps of: a) monitoring the water level sensor while the speed of the motor is increasing; andb) setting the speed of the motor at the lowest speed reached when the water subsequently falls below the intermediate level. 47. The pump control module of claim 45, wherein the microcontroller further is configured to implement the steps of: a) timing a dwell time that the water stays at or above the intermediate level while the motor is running at the first low speed; andb) in response to the dwell time exceeding a first predetermined threshold increasing the speed of the motor until the dwell time is reduced to a second predetermined threshold thereby keeping the speed of the motor at the lowest speed required to pump the water out of the reservoir through the drain line to the elevation of the outlet of the drain line. 48. The pump control module of claim 45, wherein the starting step includes applying full power to the motor for a short period of time to ensure that the motor starts prior to establishing the first low speed for the motor. 49. The pump control module of claim 45, wherein the water level sensor includes an empty capacitance sensor located at a low water level in the reservoir, a run capacitance sensor located at the intermediate water level in the reservoir, and an overflow capacitance sensor located at a near overflow water level in the reservoir, each of the capacitance sensors being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level, at an intermediate water level, or at a near overflow water level based on changes in capacitance of each capacitance sensor when each capacitor sensor is in contact with the water in the reservoir. 50. The pump control module of claim 45, wherein the water level sensor includes an elongated capacitance sensor located in the reservoir with its length vertically oriented in the reservoir, the capacitance sensor being connected to the microcontroller, wherein the microcontroller determines whether the water in the reservoir is at a low water level, an intermediate water level, or a near overflow water level based on changes in capacitance of the capacitance sensor as the water in the reservoir rises and falls along the length of the capacitance sensor. 51. The pump control module of claim 45, wherein the water level sensor is an ultrasonic transmitter and receiver. 52. The pump control module of claim 45, wherein the floatless condensate pump control module further includes a status indicator light controlled by the microcontroller to indicate visually the operating status of the condensate pump. 53. The pump control module of claim 45, wherein the floatless condensate pump control module further includes an infrared emitter and an infrared receiver connected to the microcontroller for transmitting and receiving data to and from the microcontroller. 54. The pump control module of claim 45, wherein the floatless condensate pump control module further includes an alarm switch controlled by the microcontroller to sound an alarm when the condensate water in the reservoir reaches a near overflow condition. 55. The pump control module of claim 45, wherein the floatless condensate pump control module further includes a safety switch controlled by the microcontroller to shut down the HVAC system when the condensate water in the reservoir reaches a near overflow condition.
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