JP2004093003A - Air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air conditioner for efficiently discharging drain while making noise generated by the operation of a drain pump, unnoticeable. <P>SOLUTION: This air conditioner is provided with a blower, a heat exchanger, a drain pan for receiving the drain formed in the heat exchanger, and the drain pump for discharging the drain accumulated in the drain pan. The air conditioner is further provided with a microcomputer 53 for controlling to operate the drain pump with high output when determining the formed quantity of drain to be large and to operate the drain pump with low output when determining the formed quantity of drain to be small. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an air conditioner, and more particularly to control of a drain pump used in an air conditioner.
[0002]
[Prior art]
Generally, a blower, a heat exchanger, a drain pan made of polystyrene foam which is disposed below the heat exchanger and receives drain generated by the heat exchanger, and a drain pump which drains the drain accumulated in the drain pan, As an air conditioner including a control device that controls the operation of a motor of a drain pump, for example, a ceiling-mounted air conditioner is known.
[0003]
Drain generated in the heat exchanger during a cooling operation or a dry operation of the air conditioner is accumulated in a drain pan, and the accumulated drain is drained out of the machine via a drain hose by a drain pump. The motor of the drain pump is an AC motor, and the drain pump is operated with a constant output (for example, application of a rated AC voltage of 200 V).
[0004]
The output of the drain pump is set to be large so that the drain can be drained when the air conditioner is operated under the condition where the drain is generated most. That is, the output of the drain pump is set on the basis of the time when the expected load (for example, drainage amount or head) of the drain pump is maximum.
[0005]
During the air conditioning operation of the air conditioner, the blower volume (the number of rotations) of the blower is configured to be switched in three stages (rapid wind, strong wind, weak wind) according to the air conditioning load. Then, during the cooling operation, when the indoor temperature falls below a set temperature set by a remote controller or the like, the control is performed so as to be in a thermo-off state in which the compressor is stopped. In the thermo-off state, the drain pump is stopped in order to prevent noises such as a webbing noise and a vibration noise generated by the drain pump.
[0006]
[Problems to be solved by the invention]
However, when the output of the drain pump is set to be large so that the drain can be drained as in the above-described air conditioner, and the actual load is smaller than the expected load on the drain pump, the output of the drain pump is reduced. Is too large, there is a problem that noise such as a webbing noise and a vibration noise generated by the drain pump is noticeable.
[0007]
In addition, when the output of the drain pump is constant, the larger the blowing amount (the number of rotations) of the blower (for example, if the wind is higher than the strong wind), the more the noise such as the draining sound and the vibration sound generated by the drain pump becomes. Although it is drowned out by the blower noise, it is less noticeable. However, as the blower volume (the number of revolutions) of the blower becomes smaller (for example, less than a weak wind), the vibration noise generated by the drain pump, There is a problem that noise is noticeable.
[0008]
In addition, if the drain pump is stopped at the time of thermo-off, the drain may remain in the drain pan, and slag is easily generated. If the slag clogs the drain port of the drain pump, there is a problem that the drain may not be discharged from the drain pan.
[0009]
An object of the present invention has been made in view of the above circumstances, and an object of the present invention is to provide an air conditioner that can make noise generated by operation of a drain pump inconspicuous and can drain drain efficiently.
[0010]
[Means for Solving the Problems]
In order to solve the above problems, a blower, a heat exchanger, a drain pan for receiving drain generated by the heat exchanger, a drain pump for draining drain accumulated in the drain pan, and controlling operation of the drain pump are controlled. In the air conditioner provided with a control unit, the control unit controls the drain pump with an output of the drain pump set in advance according to an operation state of the air conditioner.
[0011]
In this case, the control means operates the drain pump at a high output when the rotation speed of the blower exceeds a predetermined rotation speed at least during the cooling operation, and at least during the cooling operation, the rotation speed of the blower. When the operating speed is lower than a predetermined number of revolutions, the drain pump may be controlled to operate at a low output.
[0012]
Further, the control means may operate the drain pump even in an operation state in which a thermo-off state is set.
[0013]
Further, the control means may normally operate the drain pump at a low output, and may operate the drain pump at a high output when the float switch is abnormal.
[0014]
Still further, a storage means for storing a plurality of control modes in which an operation condition of the air conditioner is associated with an output of the drain pump, wherein the control means controls an output of the drain pump in any one of the control modes. You may make it.
[0015]
In the plurality of control modes, at least during a cooling operation, when the rotation speed of the blower is higher than a predetermined rotation speed, the drain pump performs a high output operation, and at least during the cooling operation, the rotation of the blower is increased. When the number of rotations is lower than a predetermined number of rotations, a control mode for operating the drain pump at a low output may be included.
[0016]
Furthermore, the plurality of control modes may include a control mode for operating the drain pump even in an operation state where the thermo-off state is set.
[0017]
Furthermore, the plurality of control modes may include a control mode in which the drain pump is normally operated at a low output, and when the float switch is abnormal, the drain pump is operated at a high output.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to the accompanying drawings.
[0019]
FIG. 1 is a refrigerant circuit diagram showing an embodiment of an air conditioner according to the present invention.
[0020]
The air conditioner 10 has an outdoor unit 11 and an indoor unit 12, and an outdoor refrigerant pipe 13 of the outdoor unit 11 and an indoor refrigerant pipe 14 of the indoor unit 12 are connected via connection pipes 15 and 16. .
[0021]
The outdoor unit 12 is disposed outdoors. A compressor 17 is disposed in the outdoor refrigerant pipe 13, an accumulator 18 is disposed on a suction side of the compressor 17, and a four-way valve 19 is disposed on a discharge side of the compressor 17. An outdoor heat exchanger 20 is sequentially arranged on the 19 side. An outdoor blower 21 that blows air toward the outdoor heat exchanger 20 is disposed adjacent to the outdoor heat exchanger 20.
[0022]
Each of the indoor units 12 is installed indoors, and an electric expansion valve 22 and an indoor heat exchanger 23 (hereinafter, referred to as “heat exchanger”) are arranged in the indoor refrigerant pipe 14 from the outdoor heat exchanger 20 side. An indoor blower 24 (hereinafter, referred to as “blower”) that blows air from the heat exchanger 23 into the room is disposed adjacent to the heat exchanger 23.
[0023]
The above-described four-way valve 19 is switched as shown by a solid line during cooling or dry operation, and the heat exchanger 23 functions as an evaporator, and is switched as shown by a dotted line during heating operation or humidification operation. 23 functions as a condenser.
[0024]
FIG. 2 shows an indoor unit 12 of an embedded ceiling air conditioner as an air conditioner. The indoor unit 12 of the ceiling-embedded air conditioner has an indoor unit main body 31 made of sheet metal, and the indoor unit main body 31 is suspended from the ceiling by hanging bolts 32.
[0025]
As shown in FIG. 3, the indoor unit main body 31 is formed in a substantially rectangular box shape. In FIG. 3, the upper part of the indoor unit main body 31 is open, but when it is embedded in the ceiling, this opening side faces the conditioned room.
[0026]
Inside the indoor unit main body 31, a thermal insulator 33 made of styrene foam is disposed in a state substantially in contact with the inner surface of the side plate 31 </ b> A of the indoor unit main body 31. The height H1 of the heat insulator 33 is set to a value obtained by subtracting the height H3 of a drain pan 34 described later from the height H2 of the indoor unit main body 31.
[0027]
A motor 24A is fixed to a top plate 31B of the indoor unit main body 31, and an impeller 24B is attached to a shaft of the motor 24A. These constitute the blower 24. A heat exchanger 23 bent into a polygon (for example, a substantially square shape) is arranged inside the heat insulator 33 made of styrene foam so as to surround the blower 24.
[0028]
A styrene foam drain pan 34 is disposed so as to cover the lower surface 23A of the heat exchanger 23, and the drain pan 34 is disposed with its outer periphery 34A substantially in contact with the inner surface of the side plate 31A of the indoor unit main body 31. .
[0029]
Various components such as a reinforcing member 35, a bell mouth 36 of the blower 24, and an electrical box 37 are screwed to the drain pan 34.
[0030]
As shown in FIG. 2, a decorative panel 41 is attached to the lower surface of the indoor unit main body 31, and a suction port 42 and an air outlet 43 are formed in the decorative panel 41, and a filter 45 is formed in the suction port 42. It is installed.
[0031]
FIG. 4 shows the upper surface 34B of the drain pan 34.
[0032]
A concave groove portion (part of the drain reservoir) 100 extending in the circumferential direction is formed on the upper surface 34B of the drain pan 34.
[0033]
As is apparent from FIG. 2, the concave groove portion 100 accommodates the lower surface 23 </ b> A of the heat exchanger 23 bent into a polygon (for example, a substantially square shape), in which the drain from the heat exchanger 23 is supplied. Collected. The concave groove portion 100 extends continuously in the circumferential direction, and a drain reservoir 101 is formed in a part thereof.
[0034]
The drain pool 101 is formed to be deeper than the other groove portions 100, and all drains are collected in the deepest drain pool 101. A suction port 102 </ b> A of a drain pump 102 (FIG. 2) faces the drain reservoir 101, and the drain collected in the drain reservoir 101 is discharged to the outside of the indoor unit main body 1 through the drain pump 102.
[0035]
Note that a humidifying element (not shown) is disposed adjacent to the heat exchanger 23, and when the humidifying operation of the air conditioner 10 is performed, heat generated when the heat exchanger 23 functions as a condenser is used. The water in the humidifying element is evaporated to humidify the room. At this time, the drain attached to the heat exchanger 23 is collected by the drain pan 34.
[0036]
As shown in FIG. 5, a control device 51 for operating the drain pump 102, that is, the motor 102B of the drain pump 102, is connected to the motor 102B of the drain pump 102.
[0037]
The motor 102B of the drain pump 102 is connected to a microcomputer 53 (hereinafter, referred to as “microcomputer”) via a driving unit 52 that drives the motor 102B. The microcomputer 53 is connected to a rewritable nonvolatile memory 54 (for example, EEPROM) and a remote controller 55 (hereinafter, referred to as “remote controller”). The drive unit 52, the microcomputer 53, and the EEPROM 54 are mounted on the board 37A (FIG. 3) and housed in the electrical box 19 (FIG. 3).
[0038]
As shown in FIG. 5, a float switch 56 provided on the drain pan 34 (FIG. 3) is connected to the microcomputer 53 so that the amount of water (water level) accumulated in the drain pan 34 exceeds a predetermined amount indicating a water level abnormality. Then, the float switch 56 is turned on, and a signal indicating that the float switch 56 is turned on is transmitted to the microcomputer 53. The microcomputer 53 receiving this signal determines that the water level is abnormal.
[0039]
As shown in FIG. 5, a temperature sensor 57 installed near the suction port 42 of the indoor unit 12 is connected to the microcomputer 53, and the temperature sensor 57 detects the temperature of the suction air.
[0040]
The microcomputer 53 controls the entire air-conditioning apparatus based on a control program stored in advance on a recording medium (not shown) such as a ROM. In particular, the microcomputer 53 controls the drain pump 102 with an output of the drain pump 102 set in advance according to the operation state of the air conditioner 10 based on a control program stored in advance in a ROM or the like. The microcomputer 53 also controls the indoor unit so that the deviation between the suction air temperature of the suction port 42 of the indoor unit 12 (hereinafter referred to as “indoor temperature”) and the indoor set temperature set by the remote controller 55 approaches zero. It controls twelve compressors 17 and the like. If the difference is smaller than a predetermined value, the microcomputer 53 sets the compressor 17 to a thermo-off state in which the compressor 17 is stopped, and if the difference is larger than a predetermined value, sets the compressor 17 to a thermo-on state in which the compressor 17 is operated.
[0041]
The microcomputer 53 controls the blower 24 of the indoor unit 12 at a plurality of rotation speeds (that is, a plurality of blowing amounts) stepwise according to the air conditioning load. Here, the higher the rotation speed of the blower 24, the larger the amount of blown air, and the lower the rotation speed of the blower 24, the smaller the blown air amount. Therefore, according to the air-conditioning load, for example, in the thermo-on state, the microcomputer 53 sets the rotation speed of the blower 24 in descending order (in order of increasing the amount of blown air), steep wind (HH wind), strong wind (H wind), and weak wind. The wind (L wind) is set to three stages, and in the thermo-off state, the blower 24 is set to a weak wind (LL wind) having a lower rotation speed (small blow volume) than a weak wind (L wind).
[0042]
During the dry operation, if the thermostat is on, the blower 24 is set to L-wind.
[0043]
When the difference between the indoor temperature and the indoor set temperature is lower than a predetermined value, the microcomputer 53 performs control for turning off the thermostat, and sets the blower 24 to LL wind.
[0044]
In the present embodiment, the motor 102B of the drain pump 102 is a DC motor (DC motor), and the output (that is, the rotation speed) of the motor 102B can be varied by varying the DC voltage applied to the motor 102B. It is. For example, the output of the motor 102B can be increased by increasing the DC voltage applied to the motor 102B, and the output of the motor 102B can be decreased by decreasing the DC voltage applied to the motor 102B.
[0045]
The drive unit 52 varies the DC voltage applied to the motor 102B under the control of the microcomputer 53.
[0046]
The microcomputer 53 performs control for varying the output of the drain pump 102 in a plurality of stages. For example, the microcomputer 53 changes the DC voltage applied to the motor 102B of the drain pump 102 to a High level (hereinafter, referred to as “H level”), a Low level (hereinafter, referred to as “L level”), and a 0 level. Perform control. The H level is, for example, 12 [V], the L level is, for example, 10 [V], and the 0 level is, for example, 0 [V].
[0047]
The H-level voltage is, for example, a rated voltage applied to the motor 102B, and the L-level voltage is, for example, a voltage lower than the rated voltage.
[0048]
In the drain pump 102, when the DC voltage applied to the motor 102B of the drain pump 102 is at the H level, it is referred to as high output operation, and when the DC voltage applied to the motor 102B of the drain pump 102 is at the L level, the low output operation is performed. It is assumed that.
[0049]
That is, the high-output operation indicates, for example, a rated output operation when a rated voltage is applied to the motor 102B, and the low-output operation indicates, for example, an operation with an output lower than the rated output operation.
[0050]
The EEPROM 54 has a plurality of (for example, seven) control modes in which the operating condition of the air conditioner and the DC voltage applied to the motor 102B of the drain pump 102 (that is, the output of the drain pump 102) are stored in a table. 54A. For example, the EEPROM 54 stores a table 54A shown in FIG. As described above, since the table 54A in which a plurality of control modes are set is provided, by switching to a control mode suitable for the state of drain generation, the noise of the drain pump 102 can be suppressed and the drain can be efficiently drained. Things.
[0051]
Numbers 0 to 6 are assigned to the seven control modes. Further, as the operation status of the air conditioner, for example, as shown in FIG. 6, a plurality of (for example, eight types of a to h) operation statuses are determined.
[0052]
The operation state a is an operation state at the time of thermo-ON when the air flow of the blower 24 is operated by the HH wind in the cooling operation. The operation state b is an operation state at the time of thermo-ON when the air flow of the blower 24 is operated by the H wind in the cooling operation. The operation status c is an operation status at the time of thermo-ON when the air flow of the blower 24 is operated with the L wind in the cooling operation or the dry operation. The operation status d is an operation status at the time of thermo-off when the air conditioner is operated in the cooling operation or the dry operation. The operating condition e is an operating condition when the operation of the air conditioner is stopped (including a forced stop due to an abnormality of the air conditioner) or when a control for outputting an alarm due to the abnormality of the air conditioner is performed. The operation status f is an operation status of the heating operation. The operation state g is an operation state of the humidification operation. The operating condition h is that when the water level of the drain pan 34 rises abnormally, that is, when the float switch 56 is on, it is determined that the float switch 56 is abnormal, and the drain pump 102 is forcibly operated (for example, the drain pump 102 High-power operation).
[0053]
At the time of normal dry operation, control is performed so that the operation state becomes c or d.
[0054]
The remote controller 55 is provided with a switch (not shown) for setting an indoor set temperature and a switch (control mode selection means) for selecting any one of a plurality of control modes. By using the switch for selecting the control mode of the remote controller 55, the control mode can be easily selected.
[0055]
When the control mode number is selected by the remote controller 55, the microcomputer 53 refers to the table 54A of the EEPROM 54 and controls the drain pump 102 by setting the control mode corresponding to the control mode number. In the initial setting (for example, the setting at the time of shipment), the control mode is set so as to refer to the control mode with the number “0”.
[0056]
Here, the amount of drain generated depends on the capacity (horsepower) of the heat exchanger 23. The greater the capacity of the heat exchanger 23, the greater the amount of drainage during operation (particularly during cooling operation or dry operation). The amount of drain generated increases. As described above, since the load applied to the drain pump 102 increases as the amount of generated drain increases, the control mode of the number “0” sets the DC mode applied to the motor 102B of the drain pump 102 based on the case where the amount of generated drain is large. The drain pump 102 is operated at a high output by setting the voltage to the H level.
[0057]
The capacity of the heat exchanger 23 is larger as the heat exchanger 23 itself is larger, and the capacity of the heat exchanger 23 is smaller as the heat exchanger 23 itself is smaller.
[0058]
In the present embodiment, for example, in the case of HH wind (or H wind) during the cooling operation, unless the drain pump 102 is operated at a high output (that is, the DC voltage applied to the motor 102B of the drain pump 102 must be at the H level). B), the capacity (horsepower) of the heat exchanger 23 that cannot completely drain the drain of the drain pan 34 is called high horsepower. For example, in the case of HH wind (or H wind) during the cooling operation, the drain pump 102 Is operated at a low output (that is, the DC voltage applied to the motor 102B of the drain pump 102 is set to the L level), the capacity (horsepower) of the heat exchanger 23 such that the drain of the drain pan 34 can be discharged in time is It shall be low horsepower. For example, horsepower of 4 hp or more is referred to as high horsepower, and horsepower lower than 4 hp (for example, 3 hp) is referred to as low horsepower.
[0059]
In the control mode with the number “0” in FIG. 6, control is performed to stop the drain pump 102 when the thermostat is turned off for high horsepower. In the initial setting, the control mode with the number “0” is set so as to be referred to. ing.
[0060]
Conventionally, an AC motor (AC motor) is used as a motor of the drain pump. In the thermo-on state, a rated AC voltage of 200 V is applied to the motor to operate at a constant rated output, and in the thermo-off state, the motor is driven. Had been controlled to stop. In the present embodiment, the control of the motor 102B of the operating conditions a to d in the control mode of the number “0” corresponds to the control of the conventional motor.
[0061]
In the control mode of the number “0”, the microcomputer 53 performs control to perform a high-output operation of the drain pump 102 in an operation state in which the thermostat is turned on during the cooling operation (or the dry operation), and performs the cooling operation (or If the operation state is a thermo-off state during the dry operation), control is performed to stop the drain pump 102 (that is, set the DC voltage applied to the motor 102B of the drain pump 102 to the 0 level). That is, when the DC voltage is at the 0 level, the drain pump 102 is stopped.
[0062]
In any of the control modes, the microcomputer 53 performs control to stop the drain pump 102 in the operation state e.
[0063]
In any of the control modes, no drain is generated during the heating operation. Therefore, in the operation state f, the microcomputer 53 performs control to stop the drain pump 102.
[0064]
In any of the control modes, the drain may accumulate in the drain pan 34 during the humidification operation. Therefore, in the operation state g, the microcomputer 53 controls the operation of the drain pump 102. As a result, drain generated during the humidification operation can be discharged.
[0065]
In any of the control modes, when the float switch is abnormal (abnormal water level), there is a possibility that the drain may overflow into the drain pan 34. Therefore, in the operation state h, the microcomputer 53 operates the drain pump 102 (for example, Control for high output operation). Thereby, it is possible to prevent the drain from overflowing from the drain pan 34.
[0066]
In the present embodiment, the control mode with the number “1” is a control mode for performing control for high output operation of the drain pump 102 at the time of thermo-off corresponding to high horsepower.
[0067]
When the control mode of the number “1” is selected by the remote controller 55, the microcomputer 53 controls the drain pump 102 to operate at a high output in the operating conditions a to d and g.
[0068]
The control mode of the number “2” is such that the drain pump 102 is set to a high level when the rotation speed (blowing amount) of the blower 24 exceeds a predetermined rotating speed (predetermined blowing amount) at least during the cooling operation (for example, if the air flow is H or more). The output mode is a control mode in which the drain pump 102 is operated at a low output when the rotation speed (blowing amount) of the blower is lower than a predetermined rotating speed (blowing amount) at least during the cooling operation (for example, when the wind speed is equal to or less than L wind). .
[0069]
In other words, the control mode of the number “2” is a control mode for controlling the drain pump 102 to output a low output when the air volume is low (L wind) and to stop the drain pump 102 when the thermostat is turned off. Specifically, the control mode of the number “2” is a control mode in which the drain pump 102 is operated at a high output during the operating conditions a and b, and is operated at a low output during the operating condition c. is there.
[0070]
When the control mode of the number “2” is selected by the remote controller 55, the microcomputer 53 operates the drain pump 102 at a high output if the rotation speed (blowing amount) of the blower 24 is equal to or higher than the H wind during the cooling operation. In addition, when the rotation speed (blowing amount) of the blower 24 is equal to or less than the L wind during the cooling operation, or when the dry operation is performed, the drain pump 102 is controlled to perform the low output operation. In addition, when the thermostat is turned off, the drain pump 102 is controlled to be stopped.
[0071]
The control mode of No. “3” is a control mode for controlling the drain pump 102 to output a low output at a low airflow (L wind) for high horsepower and performing a low output operation to the drain pump 102 when the thermostat is turned off. . That is, the control mode of the number “3” is a control mode in which the control for performing the low output operation of the drain pump 102 is performed even in the thermo-off state, in contrast to the control mode of the number “2”.
[0072]
The control mode of the number “4” is a control mode for controlling the drain pump 102 to output a low output when the air flow is low (L wind) and to stop the drain pump 102 when the thermostat is off, corresponding to low horsepower. In other words, the control mode of number "4" is when the heat exchanger 23 is at low horsepower, and when the operating conditions are a, b, c and g, the amount of drain generated is small. This is a control mode in which operation is performed with
[0073]
The control mode of the number “5” is a control mode for performing low power operation of the drain pump 102 when the air flow is low (L wind) corresponding to low horsepower and performing low output operation of the drain pump 102 when the thermostat is off. In other words, the control mode of the number “5” is a control mode for performing control to operate the drain pump 102 at a low output even in the thermo-off state, in contrast to the control mode of the number “4”.
[0074]
The control mode of the number “6” is a control mode for performing control to operate the drain pump 102 at a low output at the time of thermo-off for high horsepower. That is, the control mode with the number “6” is a control mode for performing control to operate the drain pump 102 at a low output even in the thermo-off state, in contrast to the control mode with the number “0”.
[0075]
In the above configuration, when controlling based on the control mode of the number “0” which is the initial setting, the drain pump 102 may be operated with an excessive capacity. That is, when the heat exchanger 11 is low in horsepower and the amount of drain generated is small, the drain pump 102 may be operating at a high output (rated output operation). As described above, when the drain pump 102 is operated with an excessive capacity, the drain pump is operated even in the operation state a (or the operation state b), that is, even when the blower 24 is operated in the HH style (or the H style). The noise (for example, a webbing sound or a vibration sound) generated from 102 may be conspicuous without being drowned out by the blowing sound of the blower 24. In such a case, the microcomputer 53 selects the control mode with the number “4” or “5”, that is, the control mode corresponding to the low horsepower, by the remote controller 55, so that the microcomputer 53 sets the number “4” in the table 54A of the EEPROM 54. Since the drain pump is controlled with reference to the control mode of "" or "5", the drain pump 102 is operated at a low output even in the operation condition a (or the operation condition b), so that the noise generated from the drain pump 102 (For example, a webbing sound and a vibration sound) are suppressed.
[0076]
Further, in the case where control is performed based on the control mode of the number “0” which is the initial setting, the operation state c, that is, the operation state of the thermo-on state in which the blower 24 is operated with the L wind during the cooling operation (or the dry operation). At this time, noise generated from the drain pump 102 may be conspicuous because the blower amount (the number of rotations) of the blower 24 is low. In such a case, the remote controller 55 outputs the drain pump 102 with a low output in the control mode of, for example, the number “2” or “3”, that is, in the operation state c when the blower 24 is at a low rotation speed (L wind). By selecting the control mode for controlling the operation, the microcomputer 53 controls the drain pump 102 with reference to the control mode of the number “2” or “3” in the table 54A of the EEPROM 54. Is operated at a low output in the case of the operating condition c, that is, when the blower 24 is operated with the L wind, so that the noise (for example, the watering noise and the vibration noise) generated from the drain pump 102 is suppressed.
[0077]
Further, in the case where control is performed based on the control mode of the number “0” which is the initial setting, since the drain pump 102 is controlled to be stopped when the thermostat is turned off, water may accumulate in the drain pan 34 and slag may easily occur. is there. In such a case, the microcomputer 53 selects the control mode of the number “1”, “3”, “5”, or “6” with the remote controller 55, and the microcomputer 53 makes the numbers “1”, “3” in the table 54A of the EEPROM 54. , "5" or "6" to control the drain pump 102, so that the drain pump 102 is operated at the time of thermo-off, so that the drain of the drain pan 34 is agitated and slag occurs. This makes it difficult to prevent the drainage path of the drain pump 102 from being clogged with slag.
[0078]
In particular, by selecting the control mode of the number “3”, “5” or “6” with the remote controller 55, the microcomputer 53 controls the control of the number “3”, “5” or “6” in the table 54A of the EEPROM 54. Since the drain pump 102 is controlled with reference to the mode, the drain pump 102 is operated at a low output when the thermostat is turned off, so that noise generated from the drain pump 102 can be suppressed.
[0079]
When rewriting the data of the table 54A of the EEPROM 54, the data is rewritten by operating a rewriting switch (rewriting means) of the remote controller 55, which is not shown.
[0080]
Since the EEPROM 54 is a rewritable nonvolatile memory, the table 54A is rewritable. That is, it is possible to rewrite the data of the output of the drain pump 102 (that is, the DC voltage applied to the motor 102B of the drain pump 102) corresponding to the operation state of each control mode. For example, it is possible to rewrite the output data of the drain pump 102 corresponding to the operation status “b” of the control mode with the number “3” in the table 54A from H level to L level. Then, the microcomputer 53 controls the motor 102B with reference to the rewritten control mode of the table 54A of the EEPROM 54.
[0081]
As described above, according to the present embodiment, when the control mode of the number “3”, “5” or “6” is selected, the microcomputer 53 enters the thermo-off state at least during the cooling operation (or during the dry operation). In the operating condition, since the drain pump 102 is operated at a low output, the drain of the drain pan 34 is agitated, and it is difficult to generate slag, and it is possible to prevent the slag from being clogged in the drain passage of the drain pump 102. Therefore, the drain can be efficiently drained, and the noise generated by the drain pump 102 can be suppressed because the drain pump 102 operates at a low output.
[0082]
According to the present embodiment, the plurality of control modes stored in the EEPROM 54 include a control mode in which the drain pump 102 operates at a low output when the heat exchanger 23 has a low horsepower (for example, a number “4”). , “5”) and control modes (for example, numbers “1”, “2”, “3”, and “6”) in which the drain pump 102 operates at high output when the heat exchanger 23 has a high horsepower. Therefore, if a control mode suitable for the capacity of the heat exchanger 23 is selected, noise such as a draining sound and a vibration sound generated by the drain pump 102 can be made inconspicuous, Drain can be drained efficiently.
[0083]
Further, according to the present embodiment, since the remote control 55 is provided as a control mode selecting means for selecting one of the plurality of control modes, the control mode can be easily switched.
[0084]
Further, according to the present embodiment, since a DC motor is used as the motor 102B of the drain pump 102, the output of the drain pump 102 can be controlled only by changing the DC voltage applied to the motor 102B. The performance is improved.
[0085]
Further, according to the present embodiment, the control mode is stored in EEPROM 54 which is a rewritable nonvolatile memory, and the remote controller rewrites the output of drain pump 102 corresponding to the operation status of each control mode stored in EEPROM 54. Since the air conditioner 55 is provided, the rewriting operation is simple, and the drain pump 102 suitable for the installation location of the indoor unit 32 can be controlled.
[0086]
In the present embodiment, a case has been described in which the amount of rotation (the number of rotations) of the blower is controlled according to the difference between the indoor temperature and the indoor set temperature. However, the present invention is not limited to this. There is provided a switch for selecting the amount of air (the number of rotations) of the fan, and the present invention can be applied even when the amount of air (the number of rotations) of the air blower is selected by the remote controller.
[0087]
Further, in the present embodiment, the case where the microcomputer controls the drain pump in the selected control mode among the plurality of control modes has been described, but the present invention is not limited to this. For example, the drain pump may be controlled only in the control mode corresponding to the control mode of the number “2” in FIG. In this case, it is possible to omit a switch defining a plurality of control modes and a switch of a remote controller for selecting any one of the plurality of control modes.
[0088]
Further, in the present embodiment, a case has been described in which seven control modes are stored as a plurality of control modes as a table in the EEPROM serving as storage means. However, the present invention is limited to a case where all these seven control modes are stored as a table. Instead, the number of control modes in the table can be set arbitrarily.
[0089]
Further, in the present embodiment, a case has been described in which a table defining a plurality of control modes is stored in an EEPROM which is a rewritable nonvolatile memory. However, the present invention is not limited to this. For example, a flash memory may be used instead of the EEPROM. For example, a table may be stored. Further, a case where the table is stored in the ROM may be employed. When the table is stored in the ROM, the means for rewriting the table can be omitted.
[0090]
As described above, the present invention has been described based on the above embodiment, but the present invention is not limited to this.
[0091]
【The invention's effect】
According to the present invention, the noise generated by the operation of the drain pump can be made inconspicuous, and the drain can be efficiently drained.
[Brief description of the drawings]
FIG. 1 is a refrigerant circuit diagram illustrating an air conditioner according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view illustrating the indoor unit of the air-conditioning apparatus according to one embodiment of the present invention.
FIG. 3 is an exploded perspective view of the air conditioner.
FIG. 4 is a top view of the drain pan.
FIG. 5 is a block diagram of a control device that controls a motor of the drain pump.
FIG. 6 is a table defining a plurality of control modes.
[Explanation of symbols]
10 Air conditioner
11 indoor units
23 Heat exchanger
24 blower
34 drain pan
53 Microcomputer
54 EEPROM
54A table
102 Drain pump

Claims (8)

Air provided with a blower, a heat exchanger, a drain pan for receiving the drain generated by the heat exchanger, a drain pump for draining the drain accumulated in the drain pan, and control means for controlling the operation of the drain pump In the harmony device,
The air conditioner, wherein the control means controls the drain pump with an output of the drain pump preset according to an operation state of the air conditioner. The air conditioner according to claim 1,
The control means, at least during the cooling operation, when the rotation speed of the blower is higher than a predetermined rotation speed, operates the drain pump at a high output, and at least during the cooling operation, the rotation speed of the blower is the predetermined rotation speed. An air conditioner characterized by controlling the drain pump to operate at a low output when the operating condition is lower than. The air conditioner according to claim 1,
The air conditioner according to claim 1, wherein the control means operates the drain pump even in an operation state in which the thermostat is turned off. The air conditioner according to claim 1,
The air conditioner, wherein the control means normally operates the drain pump at a low output, and operates the drain pump at a high output when a float switch is abnormal. The air conditioner according to claim 1,
Storage means for storing a plurality of control modes corresponding to the operation status of the air conditioner and the output of the drain pump,
The air conditioner, wherein the control means controls an output of the drain pump in any one of control modes. The air conditioner according to claim 5,
In the plurality of control modes, at least during the cooling operation, when the rotation speed of the blower is higher than a predetermined rotation speed, the drain pump performs a high output operation, and at least during the cooling operation, the rotation speed of the blower is increased. An air conditioner characterized by including a control mode for operating the drain pump at a low output when the operating condition is lower than a predetermined number of revolutions. The air conditioner according to claim 5,
The air conditioner according to claim 1, wherein the plurality of control modes include a control mode for operating the drain pump even in an operation state in which a thermo-off state is set. The air conditioner according to claim 5,
The plurality of control modes include a control mode in which the drain pump is normally operated at a low output, and when the float switch is abnormal, the drain pump is operated at a high output. .

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