JP2014092351A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner that prevents idling of a drain pump and reduces noise generated when the drain pump starts and stops.SOLUTION: The air conditioner comprises an indoor heat exchanger, an indoor fan 4, a drain water storage part for storing drain water generated during an air conditioning operation, and a drain pump 10 for discharging the drain water stored in the drain water storage part. The air conditioner also includes an indoor fan control unit 31 which controls motor rotation speed Rf of the indoor fan 4, a drain pump control unit 32 which controls motor rotation speed Rp of the drain pump 10, and a linkage control unit 33 which interlocks the indoor fan control unit 31 with the drain pump control unit 32 so as to increase the motor rotation speed Rp of the drain pump 10 when the motor rotation speed Rf of the indoor fan 4 is high and reduce the motor rotation speed Rp of the drain pump 10 when the motor rotation speed Rf of the indoor fan 4 is low.

Description

  The present invention relates to an air conditioner, and more particularly to an air conditioner equipped with a drain pump for draining drain water.

  Conventionally, some air conditioners, for example, air conditioners installed in high places such as a ceiling-embedded type and a ceiling-suspended type, drain the drain water generated during cooling or dehumidifying operation by using a drain pump. Yes. Moreover, in an air conditioner equipped with such a drain pump, as described in Patent Document 1, the drain pump is generally operated at a constant rotational speed. Also, in such an air conditioner, the drain pump is operated when the water level in the drain water storage section is above a certain level, and the drain pump is stopped when the water level in the drain water storage section is below a certain level. Was. In addition, when the drain pump is operated when the water level in the drain water storage section is below a certain level, the drain pump performs so-called idling operation that bites air, causing the drain pump noise to increase or the drain pump to be damaged. The drain pump was stopped because it occurred.

Japanese Patent Laid-Open No. 05-141686

  By the way, in the case of the method of starting and stopping the drain pump as described above, noise is not generated by the drain pump during the drain pump stop period, but sudden operation noise of the drain pump is generated during the cooling operation or the dehumidifying operation. Or stop. If the operation sound of the drain pump is generated intermittently in this way, even if the operation sound itself is not too loud, it may cause an unpleasant noise in a quiet place such as a library or bedroom. Was uncomfortable. In addition, although the operation sound of the drain pump is not so loud, it may be annoying when the drain pump is operated at high speed in a quiet place.

  The present invention has been made to solve such problems, and reduces the discomfort caused by the occurrence of irregular noise in the drain pump, and the operation sound when the drain pump is rotated at high speed. It aims at providing the air conditioner which reduced the discomfort by.

  An air conditioner according to a first aspect of the present invention stores an indoor heat exchanger, an indoor fan that blows air to the indoor heat exchanger, and drain water generated in the indoor heat exchanger during air conditioning operation. A drain water storage unit, a drain pump for draining drain water stored in the drain water storage unit, an indoor fan control unit that variably controls the motor speed of the indoor fan, and a variable motor speed of the drain pump The drain pump control unit to be controlled, and when the motor speed of the indoor fan is high, the motor speed of the drain pump is increased, and when the motor speed of the indoor fan is low, the motor speed of the drain pump is decreased. As described above, it has an interlocking control unit that interlocks the indoor fan control unit and the drain pump control unit.

  In general, if the air flow rate is increased while the air conditioning operation for cooling or dehumidification is performed, the air conditioning capacity increases and the amount of drain water generated increases. On the other hand, if the air flow rate is small, the air conditioning capacity is small, and the amount of drain water generated is reduced. Therefore, if comprised as mentioned above, when the amount of drain water generation becomes large, the capability of a drain pump will become large, and when the amount of drain water generation becomes small, the capability of a drain pump will become small. For this reason, the water level change in a drain water storage part can be made smaller than before, and a drain pump can be operated continuously for a long period of time. As a result, the frequency of stopping the drain pump to prevent idling can be reduced, and discomfort caused by irregular and intermittent drain pump operation noise can be suppressed. Also, since the noise of the drain pump when operating at high speed is canceled out by the operating sound of the indoor fan when the air flow rate is increased, the unpleasant feeling due to the noise of the drain pump when increasing the drain water drainage capacity is Can be relaxed.

  According to a second aspect of the present invention, the indoor fan control unit is configured to variably control the motor rotation speed of the indoor fan in stages, and the drain pump control unit controls the motor rotation speed of the drain pump. The motor speed of the indoor fan is variably controlled stepwise by the same number of steps as the stepwise variable control.

  If comprised in this way, since the rotation speed of a drain pump can be changed synchronizing with the rotation speed change of an indoor fan, the change of the drainage capacity of a drain pump can be synchronized with the change of drain water generation amount. it can. Therefore, the water level change in the drain water storage part can be reduced.

The invention according to claim 3 is the air conditioner according to claim 1 or 2, characterized in that the motor of the drain pump is a DC motor.
According to such a configuration, the drive motor of the drain pump can be controlled to be variable in rotational speed by simple input voltage control or inverter control.

  According to a fourth aspect of the present invention, in the air conditioner according to any one of the first to third aspects, the drain water storage unit is provided with a water level sensor that detects a water level of the drain water, and the drain pump control. The unit is characterized in that when it is detected that the water level sensor has reached the upper limit water level, it is determined that there is an abnormality and the air conditioning operation is stopped.

  According to such a configuration, in order to stop the operation of the air conditioner when it is detected that the water level of the drain water storage unit has reached the upper limit water level due to an abnormality of the drain pump or the drain water drainage system, Overflow in the drain water storage part can be prevented.

  According to a fifth aspect of the present invention, in the air conditioner according to any one of the first to third aspects, the drain water storage section is provided with a water level sensor that detects a lower limit water level of the drain water, and the drain pump. The control unit controls to stop the operation of the drain pump when the water level sensor detects a water level lower than a lower limit water level.

  According to such a configuration, it is possible to prevent the drain pump from idling. In the case of the present invention, since the number of rotations of the drain pump is variably controlled according to the amount of drain water generated as described above, the frequency of starting and stopping the drain pump is lower than that of the conventional one.

  According to the present invention, when the motor speed of the indoor fan is high, the motor speed of the drain pump is controlled to be high, and when the motor speed of the indoor fan is low, the motor speed of the drain pump is low. Therefore, the rotational speed of the drain pump is variably controlled in accordance with the amount of drain water generated. As a result, the frequency of starting and stopping the drain pump can be reduced and the operation can be stably performed. In addition, since the noise of the drain pump when the drain pump is operated at high speed is canceled out by the operation sound of the indoor fan when the air flow rate is increased, the noise of the drain pump when the drain water drainage capacity is increased. Can alleviate discomfort.

1 is a schematic configuration diagram of a ceiling-embedded air conditioner according to an embodiment of the present invention. It is a schematic diagram of the drain water storage part in the air conditioner. It is a functional block diagram regarding control of the drain pump in the air conditioner. It is a related figure of the motor rotation speed of the indoor fan and the motor rotation speed of the drain pump in the same drain pump control. It is a control flowchart of the drain pump in the air conditioner.

Hereinafter, an air conditioner according to an embodiment will be described with reference to the drawings.
This air conditioner is one of high-installation type air conditioners, and is a ceiling-embedded indoor unit in a separate air conditioner. As shown in FIG. 1, the indoor unit includes a main body 1 that houses various devices therein, and a decorative panel 2 that is disposed at a lower portion of the main body 1. The main body 1 is attached to the upper ceiling of the ceiling member 3 of the air conditioning room. The decorative panel 2 is fitted into the opening 3a of the ceiling material 3 and is attached in close contact with the air conditioning room side of the ceiling. A suction port 2a for sucking air in the air-conditioning room is formed in the central portion of the decorative panel 2, and a blower port 2b for blowing out the cooled or dehumidified air is formed on the four peripheral sides surrounding the suction port 2a. ing.

  In the main body 1, an indoor fan 4 that sucks air in the air-conditioned room into the main body 1 through an inlet 2 a provided in the center of the decorative panel 2 and blows it out in the outer peripheral direction, and surrounds the outer periphery of the indoor fan 4. The arranged indoor heat exchanger 5 is accommodated. A drain pan 6 that receives dripping of drain water generated in the indoor heat exchanger 5 during the air conditioning operation for cooling or dehumidification is disposed below the indoor heat exchanger 5. In the present specification, the term “air-conditioning operation” means an operation in which cooling or dehumidifying operation is performed.

  The motor (electric motor) that drives the indoor fan 4 is an induction motor, and is operated by changing the rotational speed in two stages. That is, the indoor fan 4 is operated at a preset high speed when the power circuit is connected to the H tap, and is operated at a preset low speed when the power circuit is connected to the L tap. It is comprised so that.

  A drain water storage part 7 for storing drain water is formed in a part of the drain pan 6, and a drain pump 10 for draining the drain water is attached to the drain water storage part 7. In addition, in FIG. 1, although the indoor side heat exchanger 5 is described in right and left, these are connected integrally when seeing planarly. In addition, the drain pan 6 also appears to be separated into left and right in FIG. 1, but these are integrally connected in plan view.

  The drain pump 10 is a motor-driven (electric motor-driven) centrifugal pump, and as schematically shown in FIG. 2, a main body housing 12 that houses the rotating blades 11 and a DC motor that drives the rotating blades 11. 13, a suction port 14 formed in the lower portion of the main body housing 12, and a discharge port 15 that discharges the drained water. The drain pump 10 having such a configuration sucks drain water from the suction port 14 by centrifugal force generated by rotating the rotary blade 11 and discharges the drain water from the discharge port 15. A drain pipe 16 led out of the apparatus is connected to the discharge port 15 of the drain pump 10. The drain pipe 16 is started up and disposed in order to suppress the backflow of drain water from the drain pipe 16 when the drain pump 10 is stopped.

  As shown in FIG. 2, a water level sensor 20 is installed in the drain water storage unit 7. The water level sensor 20 includes a float 21 that rises or falls according to a change in the water level of the drain water, and a support cylinder 22 that supports the float 21. The water level sensor 20 includes a low level switch 23 that operates at the lower limit water level L of the drain water storage unit 7 and a high level switch 24 that operates at the upper limit water level H of the drain water storage unit 7.

  The low level switch 23 of the water level sensor 20 is for preventing the water level of the drain water storage unit 7 from lowering and the drain pump 10 biting in air, and the water level of the drain water storage unit 7 is the lower limit water level L. When it becomes above, the drain pump 10 is operated, and when it becomes less than the lower limit water level L, the drain pump 10 is stopped. The high level switch 24 of the water level sensor 20 prevents the drain water from overflowing from the drain water storage section 7 when an abnormality occurs in the drain water drainage due to abnormal operation of the drain pump 10 or clogging of the drain pipe 16. When the water level of the drain water storage part 7 reaches the upper limit water level H, this is detected as an abnormal state. When the high level switch 24 of the water level sensor 20 is activated, the operation of the air conditioner is stopped.

Next, a control system for such a drain pump 10 will be described with reference to FIGS.
First, the configuration of the control system of the drain pump 10 will be described with reference to FIG. The control system of the drain pump 10 includes an indoor fan 4, a drain pump 10, a water level sensor 20, an indoor fan control unit 31, a drain pump control unit 32, an interlock control unit 33, an operation unit 34, and the like. Yes.

  The indoor fan control unit 31 includes one or a plurality of integrated circuits, and includes a motor drive circuit for the indoor fan 4. Then, the indoor fan control unit 31 is based on the air volume selected by the operation unit 34, specifically, based on the “strong” airflow, “weak” airflow, and “automatic” airflow selected by the operation unit 34. 4 is controlled.

  That is, when the “strong” air volume is selected in the operation unit 34, the motor of the indoor fan 4 is connected to the H tap and is operated at a predetermined high speed. Further, when the “weak” air volume is selected in the operation unit 34, the motor of the indoor fan 4 is connected to the L tap and is operated at a predetermined low speed. When the “automatic” air volume is selected in the operation unit 34, the motor of the indoor fan 4 is operated at a high or low speed depending on the temperature difference between the air conditioning set temperature and the room temperature in the air conditioning room. The room temperature is a temperature measured by an indoor air temperature sensor 35 installed on the inlet side of the indoor heat exchanger 5.

  When the temperature difference between the air conditioning set temperature and the room temperature in the air conditioned room is larger than a predetermined temperature difference, the motor of the indoor fan 4 is the same as when the “strong” air volume is selected in the operation unit 34. Operated at high speed. When this temperature difference is smaller than a predetermined temperature difference, the motor of the indoor fan 4 is operated at the same high speed as when the “strong” air volume is selected in the operation unit 34.

  The drain pump control unit 32 includes one or a plurality of integrated circuits, and includes a motor drive circuit for the drain pump 10. In addition, an operation command from the operation unit 34 is transmitted to the interlock control unit 33 via the indoor fan control unit 31. The drain pump control unit 32 controls the motor rotation speed Rp of the drain pump 10 based on the operation command from the interlock control unit 33. Further, the water level information of the drain water storage unit 7 is input from the water level sensor 20 to the drain pump control unit 32. The drain pump control unit 32 controls the motor rotation speed Rp of the drain pump 10 based on the operation command and the water level information transmitted in this way.

  The interlock control unit 33 includes one or a plurality of integrated circuits, and includes a nonvolatile memory such as a mask ROM and a flash memory. The nonvolatile memory stores a control program for controlling the motor rotational speed Rp of the drain pump 10 with respect to the motor rotational speed Rf of the indoor fan 4 as shown in FIG.

Next, variable speed control of the drain pump 10 will be described as an explanation of the operation of the air conditioner based on the control flowchart of FIG.
In the air conditioner according to the present embodiment, when the operation switch provided in the operation unit 34 is turned on and the air conditioning operation for cooling or dehumidification is started, the operation is started after a certain time (step). S1). In the first operation, a timer is started in order to shift the motor rotation speed Rp of the drain pump 10 in synchronization with the motor rotation speed Rf of the indoor fan 4 at regular intervals (step S2). Next, it is determined whether the water level in the drain water storage unit 7 is equal to or higher than the lower limit water level L (step S3). Here, when the water level in the drain water storage unit 7 is equal to or higher than the lower limit water level L (YES in step S3), an operation command based on the motor rotational speed Rf of the indoor fan 4 is sent from the interlock control unit 33 to the drain pump control unit 32. Is transmitted to.

  Then, based on the command transmitted from the interlock control unit 33, the motor rotation speed Rf of the indoor fan and the motor rotation speed Rp of the drain pump 10 are interlocked so as to have the relationship of FIG. 4 (step S4). That is, when the motor of the indoor fan 4 is connected to the L tap and the motor rotational speed Rf is low, the motor rotational speed Rp of the drain pump 10 is controlled to low speed, and the motor of the indoor fan 4 is connected to the H tap. When the motor rotational speed Rf 4 is high, the motor rotational speed Rp of the drain pump 10 is controlled at high speed.

  In addition, when the water level of the drain water storage part 7 is less than the minimum water level L in step S3 (in the case of NO in step S3), the drain pump 10 is held in an operation stop state to prevent idling (step S8). .

  If the predetermined time has elapsed with the operation switch of the operation unit 34 being turned on (YES in step S5) and the timer has finished counting (YES in step S6), the timer is reset ( Step S7) and return to step S2. In step S6, if the timer has not been counted, the process returns to step S6.

  In this manner, the process returns to step S2 every time a certain time (for example, 2 to 3 minutes) elapses, and after confirming whether the water level in the drain water storage unit 7 is the lower limit water level (step S3), the drain pump 10 The motor rotational speed Rp is shifted in conjunction with the motor rotational speed Rf of the indoor fan 4. That is, when the motor rotational speed Rf of the indoor fan 4 is changed during this period, the motor rotational speed Rp of the drain pump 10 is variably controlled so as to be changed (step S4).

  If the operation switch is not ON in step S5 (NO in step S5), that is, if the operation of the air conditioner is stopped, the operation of the drain pump 10 is stopped (step S9). The case where the operation switch is not ON in step S5 is, for example, a case where the operation switch is turned off immediately after the start of operation, or the operation is stopped after a certain period of time has elapsed since the start of operation. .

  In addition, when the water level of the drain water storage unit 7 reaches the upper limit water level H during the air-conditioning operation, an abnormality occurs in the drain water piping system or the drain pump 10, and thus overflow in the drain water storage unit 7 is prevented. Therefore, the drain pump control unit 32 transmits an air conditioning operation stop command regardless of the control of the drain pump 10 described above.

Since the air conditioner according to the present embodiment is configured as described above, the following effects can be achieved.
(1) When the motor rotation speed Rf of the indoor fan 4 is set to a high speed, the motor rotation speed Rp of the drain pump 10 is set to a high speed, and when the motor rotation speed Rf of the indoor fan 4 is set to a low speed, the motor rotation speed of the drain pump 10 Rp is low. Therefore, since the rotation speed of the drain pump 10 is increased when the drain water generation amount is increased and the rotation speed of the drain pump 10 is decreased when the drain water generation amount is decreased, the water level change in the drain water storage section 7 is achieved. The drain pump 10 can be operated continuously for a long period of time. As a result, it is possible to reduce the frequency of stopping the drain pump 10 for preventing so-called idling operation that bites the air of the drain pump 10, and to suppress the generation of irregular and intermittent operation sounds of the drain pump 10. it can.

  (2) Since the operation sound when the drain pump 10 is operated at a high speed is canceled out by the operation sound of the indoor fan 4 when the air flow rate is increased, the drain pump 10 when the drain water drainage capacity is increased. Discomfort due to noise can be reduced.

  (3) The indoor fan control unit 31 is configured to step-control (in this case, two steps) the motor rotation speed Rf of the indoor fan 4, whereas the drain pump control unit 32 is configured to perform motor rotation speed of the drain pump 10. Rp is variably controlled stepwise by the same number of steps as the indoor fan 4 (in this case, two steps). Therefore, since the motor speed Rp of the drain pump 10 can be changed in synchronism with the change in the motor speed Rf of the indoor fan 4, the drainage capacity of the drain pump 10 is synchronized with the change in the amount of drain water generated. Can be changed.

  (4) Since the drain pump 10 is driven by the DC motor 13, the motor rotational speed Rp of the drain pump 10 can be variably controlled by simple input voltage control or inverter control.

  (5) The drain water storage unit 7 is provided with a water level sensor 20 for detecting the upper limit water level H of the drain water. Thereby, when it is detected that the water level of the drain water storage unit 7 has reached the upper limit water level H due to an abnormality in the drain pump 10 or the drain water drainage system, the drain pump control unit 32 determines that this is abnormal. Since the air conditioning operation stop command is transmitted, overflow in the drain water storage unit 7 can be prevented.

  (6) The drain water storage unit 7 is provided with a water level sensor 20 that detects a lower limit water level L of the drain water. Thereby, when the water level sensor 20 detects a water level lower than the lower limit water level L, the drain pump control unit 32 performs control so as to stop the operation of the drain pump 10, thereby preventing the drain pump 10 from being idle. it can.

(Modification)
The air conditioner is not limited to the above-described embodiments, and the following modifications are possible. In this case, the following modified example is not applied only to the target embodiment, and can be implemented in combination with other embodiments or other modified examples as appropriate.

  In the embodiment described above, the motor rotation number Rf of the indoor fan 4 is variably controlled in two stages, but the motor rotation number Rf may be variably controlled in three or more stages or continuously. In this case, it is preferable that the motor rotation speed Rp of the drain pump 10 is also variably controlled in three or more steps or in a stepless manner in synchronization with the speed change mode of the motor rotation number Rf of the indoor fan 4.

  -In the said embodiment, although the depth of the drain water storage part 7 and the drain pan 6 is not made different especially, you may make the drain water storage part 7 deep with respect to the depth of the general part of the drain pan 6. FIG. In this way, since the difference between the lower limit water level L and the upper limit water level H of the drain water storage unit 7 can be increased, the operation period of the drain pump can be further prolonged.

  -Although the air conditioner in the said embodiment has mention | raise | lifted the ceiling embedded type air conditioner as an example, as an air conditioner, it is not specifically limited to this form. What is necessary is just to drain drain water using the drain pump 10.

  In the above-described embodiment, one water level sensor 20 detects the lower limit water level L and the upper limit water level H of the drain water storage unit 7, but these water levels are individually detected by another water level sensor. It may be.

  In the above embodiment, the air conditioning operation is stopped when the water level sensor 20 detects that the upper limit water level H has been reached, but a notification device that notifies this simultaneously with this operation may be provided. As the notification device, an alarm lamp, an alarm sound generator, or the like can be used.

  In the above embodiment, when the water level sensor 20 detects a water level lower than the lower limit water level L, the operation of the drain pump 10 is stopped or the stopped state is continued. You may provide alerting | reporting apparatuses, such as a display lamp which alert | reports the driving | running state of the pump 10. FIG.

  In the above embodiment, the water level sensor 20 includes the low level switch 23 that operates at the lower limit water level L of the drain water storage unit 7 and the high level switch 24 that operates at the upper limit water level H of the drain water storage unit 7. Only one of these switches may be provided. For example, only the high level switch 24 may be provided.

  H: Upper water level, L: Lower water level, Rf, Rp: Motor rotation speed, 4 ... Indoor fan, 5 ... Indoor heat exchanger, 7 ... Drain water reservoir, 10 ... Drain pump, 13 ... DC motor, 20 ... Water level sensor, 31 ... indoor fan control unit, 32 ... drain pump control unit, 33 ... interlock control unit.

Claims (5)

An indoor heat exchanger (5),
An indoor fan (4) for blowing air to the indoor heat exchanger (5);
A drain water storage section (7) for storing drain water generated in the indoor heat exchanger (5) during the air conditioning operation;
A drain pump (10) for draining the drain water stored in the drain water storage section (7);
An indoor fan control section (31) for controlling the motor rotation speed (Rf) of the indoor fan (4);
A drain pump controller (32) for controlling the motor rotation speed (Rf) of the drain pump (10);
When the motor rotation speed (Rp) of the drain pump (10) is increased when the motor rotation speed (Rf) of the indoor fan (4) is high, and the motor rotation speed (Rf) of the indoor fan (4) is low. And an interlock control unit (33) for interlocking the indoor fan control unit (31) and the drain pump control unit (32) so as to lower the motor rotation speed (Rp) of the drain pump (10). An air conditioner characterized by that. The air conditioner according to claim 1,
The indoor fan control unit (31) is configured to variably control the motor rotational speed (Rf) of the indoor fan (4) in a stepwise manner, and the drain pump control unit (32) includes the drain pump ( The motor rotational speed (Rp) of 10) is variably controlled stepwise by the same number of steps as the motor rotational speed (Rf) of the indoor fan (4) is variably controlled stepwise. An air conditioner characterized by that. The air conditioner according to claim 1 or 2,
The air conditioner characterized in that the motor of the drain pump (10) is a DC motor (13). In the air conditioner according to any one of claims 1 to 3,
The drain water reservoir (7) is provided with a water level sensor (20) for detecting the upper limit water level (H) of the drain water,
The drain pump control unit (32) controls to stop the air-conditioning operation by determining that it is abnormal when detecting that the water level sensor (20) has reached the upper limit water level (H). Air conditioner to do. In the air conditioner according to any one of claims 1 to 3,
The drain water reservoir (7) is provided with a water level sensor (20) for detecting a lower limit water level (L) of the drain water,
The drain pump control unit (32) controls to stop the operation of the drain pump (10) when the water level sensor (20) detects a water level lower than a lower limit water level (L). Air conditioner to do.