JP6113400B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner, and more particularly to detection of clogging of a drain pump.

  In general, an air conditioner has a heat exchanger disposed in a casing, a drain pan disposed below the heat exchanger disposed in the casing, and drain water accumulated in the drain pan through a drainage path. A drain pump for draining the outside of the casing and a water level detection means such as a float switch for detecting the maximum water level of the drain water in the drain pan are provided (for example, Patent Document 1).

  In such an air conditioner, when the suction port of the drain pump is clogged with dust such as foreign matter contained in the drain water, the drain pump is locked. However, since the drain pump does not have a means for detecting the number of rotations, an abnormality of the drain pump itself cannot be detected even when the drain pump is locked. Therefore, by detecting that the water level of the drain pan is abnormal (the highest water level, the state where the drain water overflows from the drain pan) by the float switch, it has been detected that the drain pump has become abnormal indirectly.

JP 2005-55107 A JP 2007-240112 A Japanese Patent No. 3379996

  However, in the invention described in Patent Document 1, if the drain water of the drain pan does not exceed the maximum water level, an abnormality of the drain pump cannot be detected, and as a result, the drain water overflows from the drain pan and greatly increases in the air conditioner. There was a risk of adverse effects.

  Moreover, in invention of patent document 2, although it is disclosed about grasping | ascertaining the residual amount of the waste remaining in a drainage channel and flushing the waste in a drainage channel at a stretch, the suction port of a drain pump is clogged. The detection of abnormality of the drain pump by is not disclosed.

  Further, in the invention described in Patent Document 3, it is determined that an abnormality has occurred in the drain pump when the rotational speed of the drain pump exceeds a predetermined rotational speed, and the cooling operation of the air conditioner is stopped and the drain water is stopped. The overflow from the drain pan is prevented. However, every time the number of revolutions of the drain pump becomes equal to or higher than the predetermined number of revolutions, the immediate stop of the cooling operation is repeated, and there is a problem that the convenience for the user is inferior.

  The present invention has been made to solve the above-described problem, and provides an air conditioner that can detect an abnormality of a drain pump at an early stage and suppress a malfunction caused by the clogging of the drain pump. For the purpose.

In order to achieve the above object, the present invention provides the following means.
That is, the air conditioner of the present invention includes a drain pan that stores drain water dripped from a heat exchanger, and a float switch that detects that the water level is abnormal before the drain water stored in the drain pan reaches a maximum water level. A drain pump for sucking drain water in the drain pan from a suction port and discharging it from a discharge port connected to a drain pipe extending upward, a motor for driving the drain pump, and controlling operation of the motor a control unit, when the current by the motor suction side of the resistance increases reaches elevated to a predetermined value, the overcurrent detection unit for detecting as an overcurrent, the overcurrent detection unit said overcurrent control with a counter for counting the number of times of detection, a timer unit, and a blocking unit for outputting said drain pump while blocking the operation of the motor is abnormal Includes a stage, the said control unit, when the overcurrent detection unit detects the overcurrent, despite the detection of water level abnormality by the float switch, the Rukoto stops the operation of the electric motor, the After stopping the operation of the drain pump and causing the drain water remaining in the drain pipe to flow backward from the discharge port to the drain pan through the suction port, the drain pump is restarted. The operation of the motor is controlled, and the counter unit counts the overcurrent detection switch on when the predetermined number of overcurrent detections are counted within the first predetermined time, and the predetermined number of times within the first predetermined time. When the overcurrent detection is not counted, the count of the overcurrent detection is reset, and the interruption unit counts the first overcurrent detection by the counter unit. When the overcurrent detection switch-on is counted a predetermined number of times within a second predetermined time longer than the first predetermined time, the operation of the electric motor is shut off and the drain pump is abnormal. It is characterized by outputting .

  Conventionally, even if the drain pump is clogged and it becomes impossible to drain the drain water from the drain pan to the drainage channel, it is not possible to detect an abnormality (clogging) of the drain pump, and the water level detection means Therefore, before the drain water overflowed from the drain pan, the water level was detected and the operation of the air conditioner was stopped. However, if the drain pump is clogged and the water level detection means that detects the water level is faulty, the water level abnormality cannot be detected, and there is a risk of overflow. There was a risk of malfunction.

Here, when the drain pump is clogged, the current value of the electric motor driving the drain pump increases. Therefore, in the present invention, the control means includes a control unit for controlling the operation of the electric motor and the electric motor. An overcurrent detection unit for detecting the overcurrent is provided, and when the overcurrent detection unit detects an overcurrent, the control unit stops the operation of the motor. When the drain pump stops in this way, a reverse flow phenomenon occurs in which the drain water returns from the drainage path to the drain pan through the drain pump. Therefore, clogging of the drain pump can be eliminated by the drain water due to the reverse flow phenomenon. Therefore, the malfunction of the air conditioner due to the drain water overflowing from the drain pan (water leakage) due to the abnormality of the drain pump can be suppressed.
Furthermore, when the clogging of the drain pump is not eliminated due to the backflow phenomenon, the overcurrent detection unit repeats the detection of the overcurrent. However, since the operation of the air conditioner is continued during that period, there is a possibility that the drain water increases and the drain water overflows from the drain pan. Therefore, the control means includes a shut-off unit that shuts off the operation of the motor and outputs that the drain pump is abnormal, a counter unit that counts the number of times the over-current detection unit detects over-current, and a timer unit, When the counter unit detects an overcurrent a predetermined number of times within a predetermined time set in the timer unit, the interruption unit is activated to output that the operation of the electric motor is interrupted and that the drain pump is abnormal. Thereby, before a drain pan becomes an abnormal water level (water level which drain water overflows), the abnormal state of a drain pump can be detected. Therefore, it is possible to prevent the air conditioner from malfunctioning due to the abnormality of the drain pump.
Here, the predetermined number of times and the predetermined time mean the number of times and the time that the drain water does not overflow from the drain pan even when the drain pump is operated in a locked state.

  As described above, in the air conditioner according to the present invention, the control unit includes the control unit that controls the operation of the motor and the overcurrent detection unit that detects the overcurrent of the motor, and the overcurrent detection unit is an overcurrent. When this is detected, the controller restarts after stopping the operation of the motor. When the drain pump stops in this way, a reverse flow phenomenon occurs in which the drain water returns from the drainage path to the drain pan through the drain pump. Therefore, clogging of the drain pump can be eliminated by the drain water due to the reverse flow phenomenon. Therefore, the malfunction of the air conditioner due to the drain water overflowing from the drain pan (water leakage) due to the abnormality of the drain pump can be suppressed.

In addition, the clogging of the drain pump means that the drain pan is contaminated with foreign matter.
Therefore, in the present invention, by detecting the clogging of the drain pump, cleaning of the drain pan can be promoted, and hygiene maintenance can be promoted.

1 is a schematic configuration diagram of an air conditioner according to an embodiment of the present invention. It is a schematic block diagram of the control apparatus of the air conditioner shown in FIG. It is a figure which shows the relationship between the electric current value or rotational speed of a drain pump, and a viscosity. It is a time chart which shows detection of abnormality of the drain pump shown in FIG.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is a schematic configuration diagram of an air conditioner according to an embodiment of the present invention. This air conditioner is a separation-type air conditioner, and is arranged in an indoor unit 1 constituting the air conditioner so as to surround a blower (not shown) and the outer periphery of the blower. A drain pan 3 below the heat exchanger 2 and storing drain water dripping from the heat exchanger 2, and a drain for discharging the drain water in the drain pan 3 to a drain pipe (drainage path) 4. A pump 5, a motor (electric motor) 6 that drives the drain pump 5, and a control device (control means) that controls the operation of the motor 6 are provided.
In addition, in FIG. 1, although the heat exchanger 2 is shown by the substantially rectangular shape, when the indoor unit 1 of the air conditioner of this embodiment is looked up, it connects integrally and surrounds a fan. Has been placed.

  The drain pump 5 is a centrifugal pump. A rotary blade (not shown) is accommodated in the pump housing 8. The drain pump 5 is formed in the lower portion of the pump housing 8 and sucks the drain water. And a discharge port 10 for discharging water. Further, the drain pump 5 is connected to a motor 6 that drives the rotary blades. The drain pump 5 sucks up drain water from the suction port 9 by the centrifugal force generated by the motor 6 driving the rotating blades, and discharges the drain water from the discharge port 10. A drain pipe 4 is connected to the discharge port 10 of the drain pump 5, and drain water is discharged outside the indoor unit 1.

  The drain pan 3 condenses the water in the air heat-exchanged in the heat exchanger 2 and stores it as drain water. The drain pan 3 is installed in the lower part of the heat exchanger 2 in order to store the dripped drain water. Yes. The drain pan 3 is provided with a float switch 11. This float switch 11 detects that the water level is abnormal before the drain water stored in the drain pan 3 reaches the highest water level (the water level overflowing from the drain pan 3).

As shown in FIG. 2, the control device supplies current to the motor 6 from a DC power supply 25 through an overcurrent detection circuit (overcurrent detection unit) 22 and a motor output circuit 23. The control device includes a microcomputer (control unit) 21 that controls the operation of the motor 6, an overcurrent detection circuit 22 that detects an overcurrent of the motor 6, and an output current to the motor 6 based on an output signal from the microcomputer 21. And a forced stop circuit (shut-off unit) that outputs a shut-off signal that immediately shuts off current supply to the motor 6 to the motor output circuit 23 based on an overcurrent detection switch-on signal that will be described later. 24.
The control device also includes a counter unit (not shown) that counts the number of times that the overcurrent detection circuit 22 has detected an overcurrent, and a timer unit (not shown).

  The microcomputer 21 outputs an output signal for controlling the motor 6 to the motor output circuit 23. The output signal output from the microcomputer 21 is output in two stages when the motor 6 is started. First, when a current value (for example, about 200 mA) for driving the motor 6 is 100%, an output signal for transmitting the current value, which is 30%, to the motor 6 is transmitted from the microcomputer 21 to the motor output circuit 23. The Thereafter, an output signal for transmitting a 100% current value (that is, about 200 mA) is transmitted from the microcomputer 21 to the motor output circuit 23.

Further, when the microcomputer 21 receives the overcurrent detection signal and stops the motor 6, the microcomputer 21 immediately stops supplying current to the motor 6 and supplies the current to the motor 6 for about 10 seconds, for example. An output signal that continues to stop is transmitted to the motor output circuit 23. Further, the microcomputer 21 transmits an output signal for reporting that the suction port 9 of the drain pump 5 (see FIG. 1) is clogged and that the drain pump 5 is abnormal. An output signal indicating that the drain pump 5 is abnormal is displayed on, for example, a remote controller (not shown) of the indoor unit 1.
The counter unit provided in the control device counts the number of times when the overcurrent detection circuit 22 detects the overcurrent.

The overcurrent detection circuit 22 is a substrate circuit that detects an overcurrent (for example, 600 mA) output from the motor 6. The overcurrent detection circuit 22 transmits an overcurrent detection signal to the microcomputer 21 when an overcurrent is detected.
The motor output circuit 23 is a circuit that supplies, stops, or shuts off current to the motor 6 in accordance with an output signal or a cut-off signal transmitted from the microcomputer 21 or the forced stop circuit 24.

  The forced stop circuit 24 transmits an output signal (shut off signal) for shutting down the operation of the motor 6 directly to the motor output circuit 23 without sending an output signal to the motor output circuit 23 via the microcomputer 21. is there.

Next, a method for detecting abnormality of the drain pump 5 when the suction port 9 of the drain pump 5 (see FIG. 1) of the air conditioner according to the present embodiment is clogged will be described with reference to FIGS. .
FIG. 3 shows a graph showing the general characteristics of the drain pump 5. In FIG. 3, the vertical axis represents the current value of the motor 6 or the rotational speed of the drain pump 5, and the horizontal axis represents the viscosity. Here, the viscosity is the viscosity of drain water sucked by the drain pump 5, and the viscosity increases toward the right side of the horizontal axis in FIG.

  As shown in FIG. 3, the current value of the motor 6 of the drain pump 5 increases as the viscosity of the drain water to be sucked increases, that is, the resistance on the suction side increases, and the rotational speed of the drain pump 5 decreases. It is generally known that the change in the resistance on the suction side has the same tendency as the degree of clogging of the suction port 9 of the drain pump 5, and the degree of clogging of the suction port 9 of the drain pump 5 increases. The current value of the motor 6 increases and the rotational speed of the drain pump 5 decreases.

  FIG. 4 shows a time chart for detecting an abnormality of the drain pump 5 based on an overcurrent of the motor 6 that drives the drain pump 5 of the present embodiment. FIG. 4 shows that time elapses toward the right side of the page.

  When the operation of the drain pump 5 is started, an output signal is transmitted from the my computer 21 of the control device to the motor output circuit 23 (pump on). Here, the output signal output from the microcomputer 21 is output in two stages as described above. Based on the output signal transmitted from the microcomputer 21 to the motor output circuit 23 over two stages, the motor output circuit 23 supplies current to the motor 6 and the motor 6 is started. When the motor 6 is started, the drain pump 5 is started.

  When the suction port 9 of the drain pump 5 operating in this way is clogged, the motor 6 is driven, but the rotating blades of the drain pump 5 are locked. When the drain pump 5 is locked (when the resistance on the suction side increases), the current value of the motor 6 increases as shown in FIG. Thus, when the current value of the motor 6 rises and a current value of 600 mA is output from the motor 6, the overcurrent detection circuit 22 provided in the control device converts the current value of 600 mA to an overcurrent (hereinafter referred to as “current value”). , “First overcurrent”). The overcurrent detection circuit 22 that has detected the first overcurrent transmits an overcurrent detection signal to the microcomputer 21. The counter unit provided in the control device counts the first overcurrent detection when the overcurrent detection circuit 22 detects the first overcurrent.

  The microcomputer 21 that has received the overcurrent detection signal immediately stops the operation of the drain pump 5 and transmits, for example, an output signal that maintains the stopped state for 10 seconds after the drain pump 5 stops to the motor output circuit 23. . The motor output circuit 23 that has received the output signal for stopping the drain pump 5 immediately stops the supply current to the motor 6.

  As described above, the supply current to the motor 6 is immediately stopped, whereby the operation of the drain pump 5 is immediately stopped. Since the operation of the drain pump 5 is immediately stopped, a back flow phenomenon occurs in which the drain water remaining in the drain drain pipe 4 flows back from the discharge port 10 of the drain pump 5 to the drain pan 3 through the suction port 9 at a stretch. At that time, the drain water flows back from the discharge port 10 of the drain pump 5 through the suction port 9 to the drain pan 3 at once, so that the clogging of the suction port 9 is eliminated.

  After about 10 seconds have elapsed since the operation of the drain pump 5 was stopped, the microcomputer 21 transmits an output signal for restarting (pumping on) the operation of the drain pump 5 to the motor output circuit 23. The motor output circuit 23 receives the pump-on output signal and transmits the above-described two-stage current value to the motor 6. Thereby, the operation of the drain pump 5 is restarted.

  When the drain pump 5 that has been restarted has not been clogged with the suction port 9 of the drain pump 5 due to the above-described reverse flow phenomenon, the drain pump 5 is again locked. When the drain pump 5 is locked again, a second overcurrent of 600 mA is output from the motor 6. An overcurrent detection signal is detected by the overcurrent detection circuit 22 by the output second overcurrent, and the overcurrent detection signal is sent from the overcurrent detection circuit 22 to the microcomputer 21 as in the case of the first overcurrent described above. Is transmitted and the counter unit counts the second overcurrent detection.

  The microcomputer 21 that has received the overcurrent detection signal immediately stops the operation of the drain pump 5 and transmits an output signal for maintaining the stop of the drain pump 5 to the motor output circuit 23 for about 10 seconds after the stop. The motor output circuit 23 that has received the output signal for stopping the drain pump 5 immediately stops the supply current to the motor 6. When the supply current to the motor 6 is immediately stopped again, the operation of the drain pump 5 is immediately stopped, and a reverse flow phenomenon occurs in the drain pump 5 as described above.

  After about 10 seconds have elapsed since the operation of the drain pump 5 was immediately stopped, the operation of the drain pump 5 is restarted (pump on). When the clogging of the suction port 9 of the restarted drain pump 5 has not been eliminated due to the backflow phenomenon, the drain pump 5 is repeatedly blocked, and a third overcurrent of 600 mA is output from the motor 6. The output third overcurrent is detected by the overcurrent detection circuit 22. Then, when the overcurrent detection circuit 22 detects the third overcurrent, the overcurrent detection circuit 22 detects an overcurrent from the overcurrent detection circuit 22 to the microcomputer 21 as in the first and second overcurrents. While the current detection signal is transmitted, the counter unit counts the third overcurrent detection.

Here, for example, when the third overcurrent detection is counted within about 3 minutes after the counter unit counts the first overcurrent detection, the overcurrent is detected by software provided in the microcomputer 21. Detection switch-on is output. When this overcurrent detection switch-on signal is output, the counter unit counts the first overcurrent detection switch-on.
If the counter unit does not count the third overcurrent detection within about 3 minutes after counting the first overcurrent detection, the overcurrent detection count is reset.

  When the counter unit counts the first overcurrent detection switch on, the drain pump 5 restarts (pump on) with the first overcurrent detection switch on count. Thereafter, as in the case described above, when the overcurrent is detected three times within about 3 minutes from the restarted drain pump 5, the counter unit counts the second overcurrent detection switch-on.

  Further, when the counter unit counts the second overcurrent detection switch on, the drain pump 5 restarts (pump on) with the second overcurrent detection switch on count. Thereafter, as in the case described above, when an overcurrent is detected three times within about 3 minutes from the restarted drain pump 5, the counter unit counts the third overcurrent detection switch-on.

  As described above, when the overcurrent detection switch-on is counted a total of three times within 8 minutes, for example, within 8 minutes after the counter unit counts the first overcurrent, the forced stop circuit 24 (see FIG. 2) A cut-off signal for cutting off the operation of the motor 6 is transmitted directly to the output circuit 23. In addition, the forced stop circuit 24 transmits an output signal for notifying that an abnormality has occurred in the drain pump 5 to the remote controller along with transmission of the cutoff signal to the motor output circuit 23.

  As described above, the operation of the drain pump 5 is immediately stopped by the control from the microcomputer 21, and the reverse flow phenomenon of the drain water is repeated nine times (a plurality of times) within a predetermined time (for example, about 8 minutes). Even in this case, if the suction port 9 of the drain pump 5 is still clogged, the operation of the drain pump 5 is shut off by the cutoff signal from the forced stop circuit 24 and the drain pump 5 is abnormal. Can be detected.

Next, a release method when the operation is interrupted due to an abnormality of the drain pump 5 will be described.
After the operation of the drain pump 5 is interrupted due to abnormal operation of the drain pump 5, the float switch 11 provided in the drain pan 3 is in a normal state (off state, the water level of the drain pan 3 is low), and The abnormality of the drain pump 5 can be canceled on the condition that the display indicating that the drain pump 5 displayed on the remote controller of the machine 1 is abnormal is reset.

As described above, the air conditioner according to the present embodiment has the following effects.
The control device (control means) is provided with a microcomputer (control unit) 21 that controls the operation of the motor (electric motor) 6 and an overcurrent detection circuit (overcurrent detection unit) 22 that detects an overcurrent of the motor 6. When the overcurrent detection circuit 22 detects an overcurrent, the microcomputer 21 or the forced stop circuit 24 outputs an output signal or a cut-off signal to the motor output circuit 23 to temporarily stop the operation of the motor 6. Thus, the operation of the drain pump 5 is immediately stopped, and then the microcomputer 21 outputs an output signal to the motor output circuit 23 to restart the operation of the motor 6 to start the operation of the drain pump 5. . As the drain pump 5 immediately stops in this way, a reverse flow phenomenon occurs in which drain water returns from the drain pipe (drainage path) 4 to the drain pan 3 through the drain pump 5. Therefore, clogging of the suction port 9 of the drain pump 5 can be eliminated by the drain water due to the reverse flow phenomenon. Therefore, it is possible to suppress the occurrence of problems in the indoor unit 1 of the air conditioner (not shown) due to overflow of the drain water of the drain pan 3 due to an abnormality (clogging) of the drain pump 5.

  A forced stop circuit (shutoff unit) 24 that shuts down the operation of the drain pump 5 without going through the microcomputer 21, a counter unit (not shown) that counts the number of times the overcurrent detection circuit 22 detects overcurrent, a timer When the counter unit detects overcurrent nine times (predetermined number of times) within about 8 minutes (predetermined time) set in the timer unit with a control unit (not shown) in the control unit (not shown) The microcomputer 21 stops the output signal to the motor 6 and shuts down the operation of the drain pump 5, and outputs that the drain pump 5 is abnormal to a remote controller (not shown). Thereby, the abnormal state of the drain pump 5 can be detected before the drain pan 3 reaches an abnormal water level (water level overflowing with drain water). Therefore, it is possible to prevent the malfunction of the indoor unit 1 of the air conditioner due to the abnormality of the drain pump 5.

1 Indoor unit (air conditioner)
2 Heat exchanger 3 Drain pan 4 Drain piping (drainage route)
5 Drain pump 6 Motor (electric motor)
21 Microcomputer (control unit)
22 Overcurrent detection circuit (overcurrent detection unit)
24 Forced stop circuit (interrupt section)

Claims (1)

A drain pan for storing drain water dripping from the heat exchanger;
A float switch for detecting that the water level is abnormal before the drain water stored in the drain pan reaches the maximum water level;
A drain pump that sucks drain water in the drain pan from a suction port and discharges it from a discharge port connected to a drain pipe extending upward ;
An electric motor for driving the drain pump;
A control unit that controls the operation of the motor; an overcurrent detection unit that detects an overcurrent when the current increases and reaches a predetermined value due to an increase in resistance on the suction side of the motor; and the overcurrent A control unit having a counter unit that counts the number of times that the detection unit has detected the overcurrent, a timer unit, and a cutoff unit that shuts down the operation of the electric motor and outputs that the drain pump is abnormal. ,
Wherein, said when the overcurrent detecting unit detects the over-current, irrespective of the detection of the water level abnormality by the float switch, the Rukoto stops the operation of the motor, stopping the operation of the drain pump And controlling the operation of the electric motor so that the drain pump is restarted after the drain water remaining in the drain pipe flows back from the discharge port to the drain pan through the suction port. ,
The counter unit counts an overcurrent detection switch on when a predetermined number of overcurrent detections are counted within a first predetermined time, and counts the predetermined number of overcurrent detections within the first predetermined time. If not, reset the overcurrent detection count,
The interrupting unit counts the overcurrent detection switch on a predetermined number of times within a second predetermined time longer than the first predetermined time after the counter unit counts the first overcurrent detection. An air conditioner that shuts off the operation of the electric motor and outputs that the drain pump is abnormal .

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