JP6435443B1 - Air conditioner - Google Patents

Abstract

The air conditioner (100) includes a refrigerant circuit (Q) in which a refrigerant circulates in a refrigeration cycle through a compressor (31), a condenser, an outdoor expansion valve (34), and an evaporator in order, and at least the compressor (31) and a controller that controls the outdoor expansion valve (34), one of the condenser and the evaporator is the outdoor heat exchanger (32), and the other is the indoor heat exchanger (12), The controller causes the indoor heat exchanger (12) to function as an evaporator, and reverses the indoor fan (14) during the freezing process for freezing the indoor heat exchanger (12).

Description

  The present invention relates to an air conditioner.

  As a technique for making an indoor heat exchanger of an air conditioner clean, for example, Patent Document 1 describes an air conditioner that includes “a moisture applying unit that attaches water to the fin surface after heating operation”. ing. In addition, an above described water provision means adheres water to the fin surface of an indoor heat exchanger by performing cooling operation after heating operation.

Japanese Patent No. 4931666

  However, in the technique described in Patent Document 1, even if a normal cooling operation is performed after the heating operation, there is a possibility that the amount of water adhering to the indoor heat exchanger is insufficient to clean the indoor heat exchanger. is there.

  This invention is invention for solving the said subject, Comprising: It aims at providing the air conditioner which can wash | clean an indoor heat exchanger appropriately.

  In order to achieve the above object, an air conditioner of the present invention includes a refrigerant circuit in which a refrigerant circulates in a refrigeration cycle through a compressor, a condenser, an expansion valve (for example, an outdoor expansion valve 34) and an evaporator in order. A control unit that controls at least the compressor and the expansion valve, and one of the condenser and the evaporator is an outdoor heat exchanger, the other is an indoor heat exchanger, and the control unit includes an indoor heat exchanger. During the freezing process that functions as an evaporator and freezes the indoor heat exchanger, a blower fan (for example, the indoor fan 14) is reversely rotated. Other aspects of the present invention will be described in the embodiments described later.

  ADVANTAGE OF THE INVENTION According to this invention, the air conditioner which can wash | clean an indoor heat exchanger appropriately can be provided.

It is an appearance lineblock diagram showing the air harmony machine concerning a 1st embodiment. It is explanatory drawing which shows the longitudinal cross-sectional structure of the indoor unit of the air conditioner which concerns on 1st Embodiment. It is explanatory drawing which shows the refrigerant circuit of the air conditioner which concerns on 1st Embodiment. It is a functional block diagram of the air conditioner concerning a 1st embodiment. It is a flowchart which shows the washing | cleaning process which the control part of the air conditioner which concerns on 1st Embodiment performs. It is a flowchart which shows the process for freezing an indoor heat exchanger. It is a map which shows the relationship between the relative humidity of indoor air, and freezing time. It is a map which shows the relationship between outdoor temperature and the rotational speed of a compressor. It is explanatory drawing which shows an example of the time change of the temperature of an indoor heat exchanger. It is explanatory drawing which shows the drive state of a compressor and an indoor fan. It is a schematic diagram which shows the state of the frost in the freezing process at the time of making an indoor fan into a halt condition. It is a schematic diagram which shows the state of the frost in the freezing process at the time of combining an indoor fan with a reverse rotation state and a stop state. It is a flowchart which shows the process for defrosting an indoor heat exchanger. It is a flowchart which shows the process for drying an indoor heat exchanger. It is explanatory drawing which shows the longitudinal cross-sectional structure of the indoor unit of the air conditioner which concerns on 2nd Embodiment.

<< First Embodiment >>
<Configuration of air conditioner>
FIG. 1 is an external configuration diagram showing an air conditioner 100 according to the first embodiment. In FIG. 1, the front view of the indoor unit 10, the outdoor unit 30, and the remote control 40 with which the air conditioner 100 is provided is shown. The air conditioner 100 is an apparatus that performs air conditioning by circulating a refrigerant in a refrigeration cycle (heat pump cycle). As shown in FIG. 1, the air conditioner 100 includes an indoor unit 10 installed indoors (air-conditioned space), an outdoor unit 30 installed outdoors, and a remote controller 40 operated by a user. Yes.

  The indoor unit 10 includes a remote control signal transmission / reception unit 11. The remote control signal transmission / reception unit 11 transmits / receives a predetermined signal to / from the remote control 40 by infrared communication or the like. For example, the remote control signal transmission / reception unit 11 receives signals from the remote control 40 such as an operation / stop command, a change in set temperature, a change in operation mode, and a timer setting. In addition, the remote control signal transmission / reception unit 11 transmits the detected value of the room temperature or the like to the remote control 40. Although omitted in FIG. 1, the indoor unit 10 and the outdoor unit 30 are connected via a refrigerant pipe and connected via a communication line.

  Drawing 2 is an explanatory view showing the longitudinal section composition of indoor unit 10 of air harmony machine 100 concerning a 1st embodiment. The indoor unit 10 includes an indoor heat exchanger 12, a drain pan 13, an indoor fan 14 (blower fan), a housing base 15, a filter 16, in addition to the remote control signal transmission / reception unit 11 (see FIG. 1). 16, a front panel 17, a left / right wind direction plate 18, and an up / down wind direction plate 19.

  The indoor heat exchanger 12 includes fins 12a and heat transfer tubes 12g. The heat transfer tubes 12g are arranged in two rows in a staggered manner in the direction in which air flows. Heat exchange between the refrigerant flowing through the heat transfer tube 12g and room air is performed. The drain pan 13 receives water dripping from the indoor heat exchanger 12 and is disposed below the indoor heat exchanger 12. In addition, the water which fell to the drain pan 13 is discharged | emitted outside via a drain hose (not shown). The indoor fan 14 is, for example, a cylindrical cross flow fan, and is driven in an arrow direction (clockwise direction, forward rotation direction) by an indoor fan motor 14a (see FIG. 4). The housing base 15 is a housing in which devices such as the indoor heat exchanger 12 and the indoor fan 14 are installed. In the present embodiment, in the indoor heat exchanger 12, the filter side (upstream side) is the front surface 12f, and the indoor fan 14 side (downstream side) is the back surface 12r.

  The filters 16 and 16 remove dust from the air taken in through the air inlet h1 and the like, and are installed on the upper and front sides of the indoor heat exchanger 12. The front panel 17 is a panel that is installed so as to cover the front filter 16 and is rotatable forward with the lower end as an axis. The front panel 17 may be configured not to rotate.

  The left / right airflow direction plate 18 is a plate-like member that adjusts the flow direction of air blown out indoors in the left / right direction. The left / right wind direction plate 18 is disposed on the downstream side of the indoor fan 14 and is rotated in the left / right direction by a left / right wind direction plate motor 21 (see FIG. 4).

  The up-and-down wind direction plate 19 is a plate-like member that adjusts the flow direction of the air blown out indoors in the up-down direction. The vertical wind direction plate 19 is disposed downstream of the indoor fan 14 and is rotated in the vertical direction by the vertical wind direction plate motor 22 (see FIG. 4).

  The air sucked through the air suction port h1 exchanges heat with the refrigerant flowing through the heat transfer tube 12g, and the heat-exchanged air is guided to the blowout air path h2. The air flowing through the blowout air path h2 is guided in a predetermined direction by the left and right airflow direction plates 18 and the vertical airflow direction plate 19, and is further blown out into the room through the air outlet h3.

  FIG. 3 is an explanatory diagram illustrating the refrigerant circuit Q of the air conditioner 100 according to the first embodiment. In addition, the solid line arrow of FIG. 3 has shown the flow of the refrigerant | coolant at the time of heating operation. Moreover, the broken line arrow of FIG. 3 has shown the flow of the refrigerant | coolant at the time of air_conditionaing | cooling operation. As shown in FIG. 3, the outdoor unit 30 includes a compressor 31, an outdoor heat exchanger 32, an outdoor fan 33, an outdoor expansion valve 34 (expansion valve), and a four-way valve 35.

  The compressor 31 is a device that compresses a low-temperature and low-pressure gas refrigerant by driving a compressor motor 31a and discharges it as a high-temperature and high-pressure gas refrigerant. The outdoor heat exchanger 32 is a heat exchanger in which heat is exchanged between the refrigerant flowing through the heat transfer tube (not shown) and the outside air sent from the outdoor fan 33.

  The outdoor fan 33 is a fan that sends outside air to the outdoor heat exchanger 32 by driving of the outdoor fan motor 33 a, and is installed in the vicinity of the outdoor heat exchanger 32. The outdoor expansion valve 34 has a function of decompressing the refrigerant condensed in the “condenser” (one of the outdoor heat exchanger 32 and the indoor heat exchanger 12). The refrigerant decompressed in the outdoor expansion valve 34 is guided to an “evaporator” (the other of the outdoor heat exchanger 32 and the indoor heat exchanger 12).

  The four-way valve 35 is a valve that switches the flow path of the refrigerant according to the operation mode of the air conditioner 100. That is, during the cooling operation in which the refrigerant flows in the direction of the broken line arrow, the compressor 31, the outdoor heat exchanger 32 (condenser), the outdoor expansion valve 34, and the indoor heat exchanger 12 (evaporator) are connected via the four-way valve 35. In the refrigerant circuit Q that is sequentially connected in a ring shape, the refrigerant circulates in the refrigeration cycle.

  Further, during the heating operation in which the refrigerant flows in the direction of the solid arrow, the compressor 31, the indoor heat exchanger 12 (condenser), the outdoor expansion valve 34, and the outdoor heat exchanger 32 (evaporator) are connected via the four-way valve 35. In the refrigerant circuit Q that is sequentially connected in a ring shape, the refrigerant circulates in the refrigeration cycle.

  That is, in the refrigerant circuit Q in which the refrigerant circulates in the refrigeration cycle sequentially through the compressor 31, the “condenser”, the outdoor expansion valve 34, and the “evaporator”, the “condenser” and “evaporator” described above. One of these is the outdoor heat exchanger 32, and the other is the indoor heat exchanger 12.

  FIG. 4 is a block diagram illustrating a control function of the air conditioner 100 according to the first embodiment. The indoor unit 10 illustrated in FIG. 4 includes an imaging unit 23, an environment detection unit 24, and an indoor control circuit 25 in addition to the configuration described above. The image pickup unit 23 picks up an image of a room (a space to be air-conditioned) and includes an image pickup element such as a CCD sensor (Charge Coupled Device) or a CMOS sensor (Complementary Metal Oxide Semiconductor). Based on the imaging result of the imaging unit 23, the indoor control circuit 25 detects a person (resident) in the room. The “person detection unit” that detects a person existing in the air-conditioned space includes an imaging unit 23 and an indoor control circuit 25.

  The environment detection unit 24 has a function of detecting the indoor state and the state of the equipment of the indoor unit 10, and includes an indoor temperature sensor 24a, a humidity sensor 24b, and an indoor heat exchanger temperature sensor 24c. The indoor temperature sensor 24a is a sensor that detects the temperature of the room (the air-conditioned space). The indoor temperature sensor 24a is installed on the air suction side of the filters 16 and 16 (see FIG. 2). Thereby, when the indoor heat exchanger 12 is frozen as will be described later, it is possible to suppress detection errors due to the influence of the heat radiation.

  The humidity sensor 24 b is a sensor that detects the humidity of the air in the room (air-conditioned space), and is installed at a predetermined position of the indoor unit 10. The indoor heat exchanger temperature sensor 24c is a sensor that detects the temperature of the indoor heat exchanger 12 (see FIG. 2), and is installed in the indoor heat exchanger 12. The detection values of the indoor temperature sensor 24a, the humidity sensor 24b, and the indoor heat exchanger temperature sensor 24c are output to the indoor control circuit 25.

  Although not shown, the indoor control circuit 25 includes electronic circuits such as a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and various interfaces. Then, the program stored in the ROM is read out and expanded in the RAM, and the CPU executes various processes.

  As shown in FIG. 4, the indoor control circuit 25 includes a storage unit 25a and an indoor control unit 25b. In addition to a predetermined program, the storage unit 25a stores an imaging result of the imaging unit 23, a detection result of the environment detection unit 24, data received via the remote control signal transmission / reception unit 11, and the like. The indoor control unit 25b performs predetermined control based on the data stored in the storage unit 25a. The processing executed by the indoor control unit 25b will be described later.

  The outdoor unit 30 includes an outdoor temperature sensor 36 and an outdoor control circuit 37 in addition to the configuration described above. The outdoor temperature sensor 36 is a sensor that detects an outdoor temperature (outside air temperature), and is installed at a predetermined location of the outdoor unit 30. Although omitted in FIG. 4, the outdoor unit 30 also includes sensors that detect the suction temperature, discharge temperature, discharge pressure, and the like of the compressor 31 (see FIG. 3). The detection value of each sensor including the outdoor temperature sensor 36 is output to the outdoor control circuit 37.

  Although not illustrated, the outdoor control circuit 37 includes electronic circuits such as a CPU, a ROM, a RAM, and various interfaces, and is connected to the indoor control circuit 25 via a communication line. As shown in FIG. 4, the outdoor control circuit 37 includes a storage unit 37a and an outdoor control unit 37b. The storage unit 37a stores detection values and the like of each sensor including the outdoor temperature sensor 36 in addition to a predetermined program. The outdoor control unit 37b controls the compressor motor 31a (that is, the compressor 31), the outdoor fan motor 33a, the outdoor expansion valve 34, and the like based on the data stored in the storage unit 37a. Hereinafter, the indoor control circuit 25 and the outdoor control circuit 37 are referred to as “control unit K”.

Next, the process for washing | cleaning the indoor heat exchanger 12 (refer FIG. 2) is demonstrated.
As described above, the filter 16 (see FIG. 2) for collecting dust and dirt is installed on the upper and front sides (air suction side) of the indoor heat exchanger 12. However, since fine dust or dust may pass through the filter 16 and adhere to the indoor heat exchanger 12, it is desirable to periodically clean the indoor heat exchanger 12. Therefore, in the present embodiment, the moisture contained in the air taken into the indoor unit 10 is frozen in the indoor heat exchanger 12, and then the indoor heat exchanger 12 is melted to clean the indoor heat exchanger 12. Like to do. Such a series of processes is referred to as “cleaning process” of the indoor heat exchanger 12.

  FIG. 5 is a flowchart showing a cleaning process executed by the control unit K of the air conditioner 100 according to the first embodiment. This flowchart will be described with reference to FIGS. 3 and 4 as appropriate. It is assumed that a predetermined air-conditioning operation (cooling operation, heating operation, etc.) has been performed until “START” in FIG.

  Further, it is assumed that the start condition of the cleaning process for the indoor heat exchanger 12 is satisfied when “START”. This “cleaning process start condition” is, for example, a condition that the value obtained by integrating the execution time of the air conditioning operation from the end of the previous cleaning process has reached a predetermined value (dirt adheres to the surface of the indoor heat exchanger 12) And the timing for cleaning). It should be noted that the time zone for performing the cleaning process may be set by the operation of the remote controller 40 by the user.

  In step S101, the control unit K stops the air conditioning operation for a predetermined time (for example, several minutes). The predetermined time is a time for stabilizing the refrigeration cycle, and is set in advance. For example, when the heating operation performed until “START” is interrupted and the indoor heat exchanger 12 is frozen (S102), the control unit K causes the refrigerant to flow in the opposite direction to that during the heating operation. The valve 35 is controlled.

  Here, if the direction in which the refrigerant flows suddenly changes, the compressor 31 is overloaded, and the user feels uncomfortable with sound or the like. Therefore, in the present embodiment, the air-conditioning operation is stopped for a predetermined time prior to freezing of the indoor heat exchanger 12 (S102) (S101). In this case, the control unit K may freeze the indoor heat exchanger 12 after a predetermined time has elapsed since the stop of the air conditioning operation.

  When the cooling operation is interrupted and the indoor heat exchanger 12 is frozen, the process of step S101 may be omitted. This is because the direction in which the refrigerant flows during the cooling operation (START) and the direction in which the refrigerant flows during freezing of the indoor heat exchanger 12 (S102) are the same.

  Next, in step S102, the control unit K freezes the indoor heat exchanger 12 (the control unit K executes a freezing process). That is, the control unit K causes the indoor heat exchanger 12 to function as an evaporator, causes moisture contained in the air taken into the indoor unit 10 to frost on the surface of the indoor heat exchanger 12 and freezes it. Moreover, the control part K reverse-rotates the indoor fan 14 (blower fan) in the freezing process which freezes the indoor heat exchanger 12 (counterclockwise in FIG. 2), and thereby the back surface of the indoor heat exchanger 12 The frosting on the fins on the 12r side (downstream side, see FIG. 2) is promoted and frozen.

  In step S103, the control unit K thaws the indoor heat exchanger 12 (ice attached to the surface). For example, the control unit K causes the indoor heat exchanger 12 to function as a condenser, thereby melting and thawing ice on the surface of the indoor heat exchanger 12. Thereby, the dust and dirt adhering to the indoor heat exchanger 12 are washed away. Note that natural thawing may be used, or the indoor fan 14 may be turned to perform thawing.

  In step S104, the control unit K dries the indoor heat exchanger 12. For example, the controller K dries the water on the surface of the indoor heat exchanger 12 by driving the indoor fan 14. Thereby, the indoor heat exchanger 12 can be made into a clean state. After performing the process of step S104, the control unit K ends the series of processes (END).

Next, details of each step of FIG. 5 will be described.
FIG. 6 is a flowchart showing a process (S102 in FIG. 5) for freezing the indoor heat exchanger 12 (see FIGS. 3 and 4 as appropriate). In step S102a, the control unit K performs initial setting. At this time, the control unit K sets the reverse rotation determination code N of the indoor fan 14 to 0 (zero), and puts the indoor fan 14 in a stopped state.

  In step S102b, the control unit K controls the four-way valve 35. That is, the control unit K controls the four-way valve 35 so that the outdoor heat exchanger 32 functions as a condenser and the indoor heat exchanger 12 functions as an evaporator. When the cooling operation is performed immediately before performing the “cleaning process” (a series of processes shown in FIG. 5), the control device maintains the state of the four-way valve 35 in step S102a.

  In step S102c, the control unit K sets a freezing time. More specifically, the control unit K sets the freezing time based on the relative humidity of the room air (air in the air-conditioned space). The “freezing time” is a time during which predetermined control (S102c to S102e) for freezing the indoor heat exchanger 12 is continued. Of the freezing time of the present embodiment, the time for reverse rotation of the indoor fan 14 (reverse rotation time) may be set at a predetermined ratio.

  FIG. 7 is a map showing the relationship between the relative humidity of room air and the freezing time. The horizontal axis in FIG. 7 is the relative humidity of the room air and is detected by the humidity sensor 24b (see FIG. 4). The vertical axis | shaft of FIG. 7 is the freezing time set corresponding to the relative humidity of room air. As shown in FIG. 7, the controller K shortens the freezing time for freezing the indoor heat exchanger 12 as the relative humidity of the indoor air is higher. The reason is that as the relative humidity of the room air is higher, the amount of moisture contained in the predetermined volume of room air is larger, and moisture is more likely to adhere to the indoor heat exchanger 12. By setting the freezing time in this way, an appropriate amount of moisture required for cleaning the indoor heat exchanger 12 can be attached to the indoor heat exchanger 12 and further frozen. Similarly, the control part K shortens the reverse rotation time of the indoor fan 14 which freezes the indoor heat exchanger 12, so that the relative humidity of indoor air is high.

  Further, the reverse rotation of the indoor fan 14 may not be performed when the relative humidity of the indoor air is equal to or higher than a predetermined value. The reason is that when the indoor fan 14 is rotated in the reverse direction when the relative humidity of the indoor air is equal to or higher than a predetermined value, the back surface of the front panel 17 becomes excessively wet and water drops from the front panel 17 may fall. . This is to prevent this.

  A predetermined mathematical formula may be used instead of the map (data table) shown in FIG. Further, the control unit K may set the freezing time based on the absolute humidity of the room air instead of the relative humidity of the room air. That is, the control unit K may shorten the freezing time as the absolute humidity of the room air is higher.

  Next, in step S <b> 102 d in FIG. 6, the control unit K sets the rotation speed of the compressor 31. That is, the control unit K sets the rotational speed of the compressor motor 31 a based on the outdoor temperature that is the detection value of the outdoor temperature sensor 36 and drives the compressor 31.

  FIG. 8 is a map showing the relationship between the outdoor temperature and the rotational speed of the compressor 31. When freezing the indoor heat exchanger 12, the controller K increases the rotational speed of the compressor motor 31a as the outdoor temperature increases, as shown in FIG. The reason is that, in order to take heat from the indoor air in the indoor heat exchanger 12, it is necessary to sufficiently radiate heat in the outdoor heat exchanger 32 correspondingly. For example, when the outdoor temperature is relatively high, the control unit K increases the temperature / pressure of the refrigerant discharged from the compressor 31 by increasing the rotational speed of the compressor motor 31a. As a result, the heat exchange in the outdoor heat exchanger 32 is appropriately performed, and thus the indoor heat exchanger 12 is also properly frozen. A predetermined mathematical formula may be used instead of the map (data table) shown in FIG.

  Incidentally, in normal air conditioning operation (cooling operation or heating operation), the rotational speed of the compressor 31 is often controlled based on the temperature of the refrigerant discharged from the compressor 31 or the like. On the other hand, when the indoor heat exchanger 12 is frozen, the temperature of the refrigerant discharged from the compressor 31 tends to be lower than that during normal air-conditioning operation. Therefore, the outdoor temperature is used as another parameter. .

  Next, in step S <b> 102 e in FIG. 6, the control unit K adjusts the opening degree of the outdoor expansion valve 34. In step S102e, it is desirable to make the opening degree of the outdoor expansion valve 34 smaller than in the normal cooling operation. As a result, the refrigerant at a lower temperature and lower pressure than in the normal cooling operation flows into the indoor heat exchanger 12 through the outdoor expansion valve 34. Therefore, the water adhering to the indoor heat exchanger 12 can be easily frozen, and the power consumption required for freezing the indoor heat exchanger 12 can be reduced.

  In step S102f, the control unit K determines whether or not the temperature TE of the indoor heat exchanger 12 is within a predetermined range (T1 ≦ TE ≦ T2). The “predetermined range” described above is a range suitable for allowing moisture contained in the air taken into the indoor unit 10 to be frozen in the indoor heat exchanger 12, and is set in advance.

  In step S102f, when the temperature of the indoor heat exchanger 12 is outside the predetermined range (S102f: No), the process of the control unit K returns to step S102e. For example, when the temperature of the indoor heat exchanger 12 is higher than a predetermined range, the control unit K further reduces the opening degree of the outdoor expansion valve 34 (S102e). Thus, when the indoor heat exchanger 12 is frozen, the control unit K adjusts the opening degree of the outdoor expansion valve 34 so that the temperature TE of the indoor heat exchanger 12 is within a predetermined range.

  FIG. 9 is an explanatory diagram illustrating an example of a temporal change in the temperature TE of the indoor heat exchanger 12. The horizontal axis in FIG. 9 represents the elapsed time from “START” in FIG. 9 represents the temperature TE of the indoor heat exchanger 12 (the detected value of the indoor heat exchanger temperature sensor 24c: see FIG. 4). Note that the predetermined range F where the temperature is less than 0 ° C. is a temperature range that serves as a determination criterion in step S102f (see FIG. 6), and is set in advance as described above.

As shown in FIG. 9, the temperature of the indoor heat exchanger 12 gradually decreases as the “elapsed time” from the start of the predetermined control for freezing the indoor heat exchanger 12 starts. Then, past the elapsed time t _A, the temperature of the indoor heat exchanger 12 is within the predetermined range F. Thereby, the indoor heat exchanger 12 can be frozen while ensuring the reliability of the indoor unit 10 (suppressing the temperature of the indoor heat exchanger 12 being excessively low).

Incidentally, past the elapsed time t _A, since the freezing of the indoor heat exchanger 12 proceeds, over time, the thickness of the ice of the indoor heat exchanger 12 is gradually thickened. Thereby, a sufficient amount of water required for cleaning the indoor heat exchanger 12 can be frozen in the indoor heat exchanger 12.

  In the present embodiment, the control unit K starts reverse rotation of the indoor fan 14 after the time TE when the temperature TE of the indoor heat exchanger 12 is equal to or lower than a predetermined temperature (T2 or lower). In FIG. 9, the control part K can fully freeze the back surface 12r (refer FIG. 2) of the indoor heat exchanger 12 by reversely rotating the indoor fan 14 between the time t21 and the time t22. .

  In step S102f of FIG. 6, when the temperature TE of the indoor heat exchanger 12 is within the predetermined range (S102f: Yes), the process of the control unit K proceeds to step S102g.

  In step S102g, the control unit K determines whether or not the reverse rotation determination code N of the indoor fan 14 is 1. If the reverse rotation determination code N is not 1 (S102g: No), the indoor fan 14 is reversely rotated in step S102h, and the process proceeds to step S102i. If the reverse rotation determination code N is 1 (S102g: Yes), the process of the control unit K proceeds to step S102k.

  In step S102i, the controller K determines whether or not the reverse rotation time of the indoor fan 14 (period from time t21 to t22) has elapsed. If the reverse rotation time of the indoor fan 14 has not elapsed (S102i: No), the process of the control unit K returns to step S102h. If the reverse rotation time of the indoor fan 14 has elapsed (S102i: Yes), the process of the control unit K proceeds to step S102j.

  In step S102j, the control unit K stops the indoor fan 14, sets the reverse rotation determination code N of the indoor fan 14 to 1, and the process of the control unit K proceeds to step S102k.

  In step S102k, the control unit K determines whether or not the freezing time set in step S102c has elapsed. When the predetermined freezing time has not elapsed since “START” (S102k: No), the process of the control unit K returns to step S102d. On the other hand, when a predetermined freezing time has elapsed from the “START” time (S102k: Yes), the control unit K ends a series of processes for freezing the indoor heat exchanger 12 (END).

  It is not based on the elapsed time from “START” in FIG. 6 but based on the elapsed time after the temperature TE of the indoor heat exchanger 12 falls within the predetermined range F (the elapsed time from time t21 shown in FIG. 9). Thus, the determination process in step S102f may be performed.

  Although omitted in FIG. 6, when the outdoor temperature is below freezing point, the control unit K preferably does not freeze the indoor heat exchanger 12. This is to prevent a large amount of water flowing down by the subsequent thawing of the indoor heat exchanger 12 from freezing in the drain hose (not shown), and thus preventing the drainage through the drain hose from being hindered. .

  FIG. 10 is an explanatory diagram showing driving states of the compressor 31 and the indoor fan 14. The horizontal axis in FIG. 10 is time. The vertical axis in FIG. 10 indicates the ON / OFF driving state of the compressor 31 and the ON / OFF driving state of the indoor fan 14. In the example shown in FIG. 10, the predetermined air conditioning operation is performed until time t1, and the compressor 31 and the indoor fan 14 are driven (that is, in the ON state). Thereafter, at time t1 to t2, the compressor 31 and the indoor fan 14 are stopped (step S101 in FIG. 5). And the freezing of the indoor heat exchanger 12 is performed in the time t2-t3 (step S102 of FIG. 5). The time from t2 to t3 is the freezing time set in step S102b (see FIG. 6).

  In the example shown in FIG. 10, during the freezing process of the indoor heat exchanger 12, the indoor fan 14 is stopped from time t2 to t21, and the indoor fan 14 is driven in the reverse rotation direction from time t21 to t22. ing. And from time t22 to t3, the indoor fan 14 is stopped. As shown in FIG. 10, the effect of rotating the indoor fan 14 in the reverse direction will be described with reference to FIGS. 11A and 11B. The processing after time t3 will be described later.

  FIG. 11A is a schematic diagram illustrating a state of frost during the freezing process when the indoor fan 14 is stopped. FIG. 11B is a schematic diagram illustrating a state of frost during the freezing process when the indoor fan 14 is combined with a reverse rotation state and a stopped state.

  As shown in FIG. 11A, if the indoor fan 14 is stopped without reverse rotation during the freezing process of the indoor heat exchanger 12, the air sucked in by natural convection flows to the surface 12 f side of the indoor heat exchanger 12. Since it is dried when cooled to the back surface 12r side of the indoor heat exchanger 12 (see FIG. 2), the amount of frost on the back surface 12r side of the indoor heat exchanger 12 is small. In order to maintain the overall cleanliness of the indoor heat exchanger 12, it is a problem to increase the amount of frost attached to the back surface 12r side of the indoor heat exchanger 12.

  On the other hand, as shown in FIG. 11B, the amount of frost attached to the back surface 12r side of the indoor heat exchanger 12 is increased by reversely rotating the indoor fan 14 during the freezing process of the indoor heat exchanger 12. When the frost is melted, the dirt is washed away with the generated water, and the entire indoor heat exchanger can be kept clean.

  In addition, the control part K is good to open the up-and-down wind direction board 19 (refer FIG. 2) at the time of reverse rotation of the indoor fan 14. FIG. Thereby, the air volume at the time of reverse rotation of the indoor fan 14 can be increased, and the amount of frost adhesion can be increased.

Next, processing for thawing and processing for drying will be described.
FIG. 12 is a flowchart showing a process (S103 in FIG. 5) for thawing the indoor heat exchanger 12 (see FIGS. 3 and 4 as appropriate). The control part K performs the series of processes shown in FIG. 12 after freezing the indoor heat exchanger 12 by the process of step S102 (see FIG. 6).

  In step S103a, the controller K determines whether or not the room temperature (temperature of the air-conditioned space) is equal to or higher than a predetermined value. This predetermined value is a threshold value that is a criterion for determining whether or not the indoor heat exchanger 12 functions as a condenser, and is set in advance.

  When the room temperature is equal to or higher than the predetermined value in step S103a (S103a: Yes), the control unit K ends the process for thawing the indoor heat exchanger 12 (END). As will be described next, when the indoor heat exchanger 12 is thawed, the four-way valve 35 is controlled as in the heating operation. The reason is that when the room temperature is equal to or higher than a predetermined value, the heat load on the condensing side of the refrigeration cycle becomes too large to be balanced with the evaporation side. Further, when the indoor temperature is relatively high, the ice in the indoor heat exchanger 12 is naturally melted with time.

  The processing after step S103b is a control method of a modified example, unlike the times t3 to t4 in FIG. In step S103b, the control unit K controls the four-way valve 35. That is, the control unit K controls the four-way valve 35 so that the indoor heat exchanger 12 functions as a condenser and the outdoor heat exchanger 32 functions as an evaporator. That is, the control unit K controls the four-way valve 35 as in the heating operation.

  In step S103c, the control unit K closes the up / down wind direction plate 19 (see FIG. 2). Thereby, even if the indoor fan 14 is driven next (S103d), it is possible to prevent water droplets from jumping into the room together with air.

  In step S103d, the control unit K drives the indoor fan 14. As a result, air is taken in through the air suction port h1 (see FIG. 2), and further, the taken-in air leaks into the room through a gap between the vertical wind direction plate 19 and the front panel 17. Therefore, it can suppress that the temperature of the indoor heat exchanger 12 (condenser) becomes too high.

  In step S103e, the control unit K sets the rotation speed of the compressor 31 to a predetermined value and drives the compressor 31. In step S103f, the control unit K adjusts the opening degree of the outdoor expansion valve 34. Thus, by appropriately controlling the compressor 31 and the outdoor expansion valve 34, a high-temperature refrigerant flows through the indoor heat exchanger 12 that is a condenser. As a result, the ice in the indoor heat exchanger 12 melts all at once, so that dust and dirt adhering to the indoor heat exchanger 12 are washed away. And dust and water containing dust fall to the drain pan 13 (refer FIG. 2), and are discharged | emitted outside via a drain hose (not shown).

In step S103g, the controller K determines whether or not a predetermined time has elapsed from when the "START" of FIG 2. This predetermined time is a time required for the indoor heat exchanger 12 to be thawed, and is set in advance. If it is determined in step S103g that the predetermined time has not elapsed since “START” (S103g: No), the process of the control unit K returns to step S103f. On the other hand, when the predetermined time has elapsed from the “START” time (S103g: Yes), the control unit K ends a series of processes for thawing the indoor heat exchanger 12 (END).

  Instead of the series of processes shown in FIG. 12, the compressor 31 and the indoor fan 14 may be maintained in a stopped state as shown in the time chart (time t3 to t4) in FIG. The reason is that the ice in the indoor heat exchanger 12 naturally melts at room temperature without causing the indoor heat exchanger 12 to function as a condenser. Thereby, the power consumption required for the defrosting of the indoor heat exchanger 12 can be reduced. Moreover, it can suppress that a water droplet adheres to the inner side of the up-and-down wind direction board 19 (refer FIG. 2).

  FIG. 13 is a flowchart showing a process for drying the indoor heat exchanger 12 (S104 in FIG. 5). Control part K performs a series of processings shown in Drawing 12, after defrosting indoor heat exchanger 12 by processing (refer to Drawing 11) of above-mentioned Steps S103a-S103g.

  In step S104a, the control unit K maintains the driving state of the four-way valve 35, the compressor 31, the indoor fan 14, and the like. That is, the control unit K controls the four-way valve 35 in the same way as when the indoor heat exchanger 12 is thawed so that the indoor heat exchanger 12 becomes a condenser, and drives the compressor 31, the indoor fan 14, and the like. Continue to let. By performing the same control as in the heating operation in this way, a high-temperature refrigerant flows into the indoor heat exchanger 12 and air is taken into the indoor unit 10. As a result, the water adhering to the indoor heat exchanger 12 evaporates.

  Next, in step S104b, the control unit K determines whether or not a predetermined time has elapsed since the process of step S104a was started. When the predetermined time has not elapsed (S104b: No), the process of the control unit K returns to step S104a. On the other hand, when the predetermined time has elapsed (S104b: Yes), the process of the control unit K proceeds to step S104c.

  In step S104c, the control unit K performs a blowing operation. That is, the control unit K stops the compressor 31 and drives the indoor fan 14 at a predetermined rotation speed. As a result, the interior of the indoor unit 10 is dried, so that the effect of antibacterial / antifungal effects is exhibited.

  During the processing in step S104a and step S104c, the up / down wind direction plate 19 (see FIG. 2) may be closed, or the up / down wind direction plate 19 may be opened.

  Next, in step S104d, the control unit K determines whether or not a predetermined time has elapsed since the process of step S104c was started. When the predetermined time has not elapsed (S104d: No), the process of the control unit K returns to step S104c. On the other hand, when the predetermined time has elapsed (S104d: Yes), the control unit K ends a series of processes for drying the indoor heat exchanger 12 (END).

  In the time chart shown in FIG. 10, after heating (S104a in FIG. 12) is performed at time t4 to t5 (after the operation of the same refrigerant flow as that of heating is performed), air is blown at time t5 to t6 ( S104c) of FIG. 12 is performed. Thus, the indoor heat exchanger 12 can be efficiently dried by performing heating and ventilation sequentially.

<Effect>
According to the first embodiment, the control unit K causes the indoor heat exchanger 12 to function as an evaporator and reversely rotates the indoor fan 14 (blower fan) during the freezing process for freezing the indoor heat exchanger 12. Thereby, the adhesion amount of the frost on the back surface 12r (refer FIG. 2) side of the indoor heat exchanger 12 can be increased.

  In particular, in the case of the indoor heat exchanger 12 in which two or more rows of heat transfer tubes 12g are arranged in the direction of air flow, the amount of frost on the front surface 12f (see FIG. 2) side of the indoor heat exchanger 12 is the back surface 12r (see FIG. (See 2). Therefore, according to 1st Embodiment, the adhesion amount of the frost of the indoor heat exchanger 12 can be equalized.

  In FIG. 10, the indoor fan 14 is in a stopped state, a reverse rotation state, and a stopped state pattern during the freezing process at times t <b> 2 to t <b> 3, but is not limited thereto. For example, the pattern may be a reverse rotation state or a stop state pattern, or may be a stop state or a reverse rotation state pattern.

  Moreover, the control part K opens the up-down wind direction board 19 when the indoor fan 14 reversely rotates. Thereby, air volume increases and the adhesion amount of the frost on the back surface 12r (refer FIG. 2) side of the indoor heat exchanger 12 can be increased.

  Moreover, the control part K performs both the freezing process which stopped the indoor fan 14 and the freezing process which reversely rotates the indoor fan 14 during a freezing process. Thereby, the adhesion amount of the frost of the surface 12f (refer FIG. 2) side and the back surface 12r (refer FIG. 2) side of the indoor heat exchanger 12 can be equalized.

  Further, the control unit K causes the indoor fan 14 to reversely rotate when the time of the freezing process in which the indoor fan 14 is stopped (for example, the addition time between the time t2 to t21 and the time t22 to t3 in FIG. 10). It is longer than the time of the freezing process (for example, the time from time t21 to t22 in FIG. 10). Thereby, the part (refer FIG. 11B) in which the part frozen with frost flows forward and the part (refer FIG. 11B) backflow arises, and the adhesion amount of the frost of the part which flows forward can be increased.

  Moreover, the control part K starts reverse rotation of the indoor fan 14 after the temperature of the indoor heat exchanger 12 becomes below predetermined temperature (for example, below T2 of FIG. 9). Thereby, the reverse rotation time of the indoor fan 14 can be shortened.

  Moreover, the control part K repeats the stop and reverse rotation of the indoor fan 14 during a freezing process. Thereby, the adhesion amount of the frost of the surface 12f side (refer FIG. 2) and the back surface 12r (refer FIG. 2) side of the indoor heat exchanger 12 can be equalized.

  Further, the control unit K may be configured not to perform forward rotation of the blower fan during the freezing process. It is possible to prevent the cool air from flowing into the indoor space, and the user does not feel uncomfortable.

  Further, after freezing the indoor heat exchanger 12 (S102 in FIG. 5), the ice in the indoor heat exchanger 12 is thawed (S103). As a result, more moisture (ice) can be attached to the indoor heat exchanger 12 than during normal cooling operation. Since a large amount of water flows on the surface of the indoor heat exchanger 12 by thawing, dust and dirt attached to the indoor heat exchanger 12 can be washed away.

  Moreover, when freezing the indoor heat exchanger 12, the control part K sets freezing time based on the relative humidity of indoor air, for example (refer S102c of FIG. 6, FIG. 7). Thereby, an appropriate amount of water required for cleaning the indoor heat exchanger 12 can be frozen in the indoor heat exchanger 12.

  Further, when the indoor heat exchanger 12 is frozen, the control unit K sets the rotation speed of the compressor motor 31a based on the outdoor temperature (see S102d in FIG. 6, FIG. 8). As a result, it is possible to appropriately dissipate heat in the outdoor heat exchanger 32 while the indoor heat exchanger 12 is frozen.

  Further, when the indoor heat exchanger 12 is frozen, the control unit K adjusts the opening degree of the outdoor expansion valve 34 based on the temperature of the indoor heat exchanger 12 (S102e in FIG. 6). Thereby, the temperature of the refrigerant flowing through the indoor heat exchanger 12 can be sufficiently lowered, and moisture contained in the air taken into the indoor unit 10 can be frozen in the indoor heat exchanger 12.

  Moreover, although FIG. 7 demonstrated changing freezing time based on the relative humidity of indoor air, it is not necessarily limited to this. In FIG. 10, the time from time t1 to time t6 is shown as the total time for freeze cleaning, but the total time for freeze cleaning may be changed based on the room temperature and humidity of the room air. Specifically, when the room temperature is high, the indoor heat exchanger 12 is difficult to freeze, and when the humidity is low, the indoor heat exchanger 12 is difficult to freeze.

  In addition, when the air conditioning operation before time t1 in FIG. 10 is a cooling or dehumidifying operation, the temperature change of the temperature TE (see FIG. 9) of the indoor heat exchanger 12 is made slower than in the heating operation. In the case of cooling or dehumidifying operation, water droplets are often attached to the fins 12a, and the possibility of squeaking noise from the fins 12a increases when the temperature is below freezing. For this reason, generation | occurrence | production of a squeak noise can be prevented by making the temperature change of the temperature TE of the indoor heat exchanger 12 slow.

<< Second Embodiment >>
In 1st Embodiment, although shown about the example of the wall-hanging type indoor unit 10 shown in FIG. 2, it is not necessarily limited to this. The second embodiment shows that the present invention can also be applied to a ceiling-embedded indoor unit 10A. 2 and 4 are denoted by the same reference numerals, and description thereof is omitted.

  FIG. 14 is an explanatory diagram illustrating a longitudinal cross-sectional configuration of the indoor unit 10A of the air conditioner according to the second embodiment. The indoor unit 10A is configured as a substantially octagonal flat box with four square corners cut off, embedded in the upper ceiling R of the ceiling opening, and the indoor unit 10A includes an indoor heat exchanger. 12A and indoor fan 14A are arranged. The lower opening of the indoor unit 10A is covered with a substantially square ceiling panel 2. And the air inlet h1 is formed in the center part of the ceiling panel 2, and the rectangular air outlet h3 in alignment with each edge of the ceiling panel 2 is formed in the outer side of this air inlet h1.

The indoor unit 10A, when driving the indoor fan 14 A by the indoor fan motor 14Aa arranged inside the room of the room air, the air inlet h1 through the filter 16, is sucked into the indoor unit 10A, the indoor heat In the process of passing through the exchanger 12A, it is cooled or heated to become conditioned air, which is guided from the air outlet h3 to the wind direction louver 26 and blown into the room. In FIG. 14, 13A is a support frame that also serves as a drain pan, and 27 is a wind guide plate.

  Also in the second embodiment, the control unit K causes the indoor heat exchanger 12A to function as an evaporator and reversely rotates the indoor fan 14A (blower fan) during the freezing process for freezing the indoor heat exchanger 12A. Thereby, the adhesion amount of the frost on the back surface 12r side of the indoor heat exchanger 12A can be increased.

  Each embodiment is described in detail for easy understanding of the present invention, and is not necessarily limited to one having all the configurations described. Moreover, it is possible to add / delete / replace other configurations for a part of the configurations of the embodiments. In addition, the above-described mechanisms and configurations are those that are considered necessary for the description, and do not necessarily indicate all the mechanisms and configurations on the product.

For example, in the first implementation embodiment, the heat transfer tube 12g but is described indoor heat exchanger 12 arranged two rows in a staggered manner in the air flow direction is not limited thereto. The heat transfer tubes 12g may not be arranged in a staggered manner. The heat transfer tubes 12g are not limited to two rows, and one row of heat transfer tubes 12g or three or more rows of heat transfer tubes 12g may be arranged.

100 Air conditioner 10, 10A Indoor unit 12, 12A Indoor heat exchanger (evaporator / condenser)
12f Front 12r Back 14, 14A Indoor fan (fan)
17 Front panel 18 Left and right wind direction plate 19 Up and down wind direction plate 23 Imaging unit (human detection unit)
26 Wind direction louver 27 Air guide plate 30 Outdoor unit 31 Compressor 31a Compressor motor (motor of compressor)
32 Outdoor heat exchanger (condenser / evaporator)
33 Outdoor fan 34 Outdoor expansion valve (expansion valve)
35 Four-way valve 40 Remote control K Control unit Q Refrigerant circuit

Claims (8)

A refrigerant circuit in which the refrigerant circulates in the refrigeration cycle through the compressor, the condenser, the expansion valve, and the evaporator sequentially;
A controller that controls at least the compressor and the expansion valve, and
One of the condenser and the evaporator is an outdoor heat exchanger, the other is an indoor heat exchanger,
The said control part is an air conditioner which makes the said indoor heat exchanger function as said evaporator, and reverse | rotates a ventilation fan during the freezing process which freezes the said indoor heat exchanger. The air conditioner according to claim 1, wherein the control unit opens a wind direction plate when the blower fan is rotated in the reverse direction. 2. The air conditioner according to claim 1, wherein the control unit performs both a freezing process in which the blower fan is stopped and a freezing process in which the blower fan is reversely rotated during the freezing process. The air conditioner according to claim 3, wherein the time of the freezing process in which the blower fan is stopped is longer than the time of the freezing process in which the blower fan is reversely rotated. The air conditioner according to claim 1, wherein the controller starts reverse rotation of the blower fan after the temperature of the indoor heat exchanger becomes equal to or lower than a predetermined temperature. The air conditioner according to claim 1, wherein the control unit repeatedly stops and reversely rotates the blower fan during the freezing process. The air conditioner according to claim 1, wherein the control unit does not perform forward rotation of the blower fan during the freezing process. The air conditioner according to claim 1, wherein the indoor heat exchanger has two or more rows of heat transfer tubes arranged in a direction in which air flows.

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