KR19990019465A - Dehumidifier of air conditioner and control method - Google Patents

Abstract

The present invention relates to a dehumidifier of the air conditioner and a control method thereof, comprising: an indoor heat exchanger for exchanging indoor air circulated by an indoor fan, and a four-way valve for changing a flow of refrigerant to perform heat exchange in the indoor heat exchanger. In the air conditioner having a temperature sensing means for sensing the temperature of the indoor heat exchanger during the dehumidification operation, by controlling the operation of the indoor fan and the four-way valve according to the indoor heat exchanger temperature detected by the temperature sensing means Consists of control means for alternately performing the cooling operation and the heating operation, it is possible to efficiently perform dehumidification without lowering the room temperature during the dehumidification operation, it is possible to set the desired room temperature.

Description

Dehumidifier of air conditioner and control method

The present invention relates to an inverter air conditioner for performing a heating and cooling operation, and more particularly, to a dehumidifying apparatus for an air conditioner for controlling dehumidification without lowering an indoor temperature during a dehumidifying operation of an air conditioner and a control method thereof.

In the conventional air conditioner, as shown in FIG. 1, a suction grill member 5 having a plurality of suction ports 3 through which indoor air is sucked is installed at the front lower part of an indoor main body 1 (hereinafter, referred to as a main body). In addition, a discharge port 7 is formed on the front surface of the main body 1 to discharge the air sucked through the suction port 3 and heat-exchanged with cold or warm air to the room.

In addition, the discharge port 7 is provided with a vertical wind vane 9 for adjusting the direction of the air discharged into the room through the discharge port 7 up and down and the left and right wind vane 11 for adjusting the left and right, the main body On the front surface of (1), the cover member 13 is fixed to the interior of the indoor unit and protects the interior. At the lower side of the cover member 13, the operation mode of the air conditioner (automatic, cooling) , Dehumidification, blowing, heating, etc.) and a start / stop of operation, and an operation unit 15 for adjusting the air volume and the air direction of the air discharged through the discharge port 7.

As shown in FIG. 2, a filter member 17 is installed inside the suction grill member 5 to filter foreign substances such as dust floating in the indoor air sucked through the suction port 3. Inside the filter member 17, a straight indoor heat exchanger 19 is installed to heat-exchange the indoor air filtered by the filter member 17 to cold or warm air by latent heat of evaporation of the refrigerant.

In addition, the upper part of the indoor heat exchanger 19 sucks indoor air through the suction port 3 and simultaneously discharges air heat-exchanged in the indoor heat exchanger 19 to the room through the discharge port 7. A blower fan 23 (hereinafter, referred to as an indoor fan) that rotates as the fan motor 21 is driven is installed, and the suction port is provided at the same time as the indoor fan 23 is covered with an outer side of the indoor fan 23. The duct member 25 which guides the flow of the air which is sucked in through (3) and discharged to the said discharge port 7 is provided.

When the air conditioner configured as described above is an inverter air conditioner that is also used for both heating and cooling, the four-way valve 31 is turned on during heating so that the refrigerant is shown in the dotted line in FIG. → indoor heat exchanger (19) → expansion valve (33) → heating expansion valve (34) → outdoor heat exchanger (35) → four-way valve (31) → compressor (39).

On the other hand, when cooling, the four-way valve 31 is turned off so that the refrigerant is shown by the solid line of FIG. 3, and the compressor 39 → four-way valve 31 → outdoor heat exchanger 35 → one-way valve 36 → expansion. The valve 33 → the indoor heat exchanger 19 → the four-way valve 31 → the compressor 39 is circulated.

At this time, the four-way valve 31 adjusts the flow path so that the refrigerant circulates in a solid line when off, and adjusts the flow path so that the refrigerant circulates in a dotted line when on.

In the air conditioner for dual heating and cooling structure configured as described above, when the user operates the remote controller or the operation unit 15 and presses the operation / stop key and selects a desired operation mode (for example, cooling), the indoor fan motor 21 As the indoor fan 23 rotates in accordance with the driving of the indoor air, the indoor air is sucked into the main body 1 through the suction port 3.

The set temperature Ts when the set temperature Ts is lower than the room temperature Tr by comparing the temperature Tr of the indoor air sucked through the suction port 3 with the set temperature Ts. ) And the operating frequency of the compressor 39 is determined according to the difference between the room temperature Tr and the compressor 39.

When the compressor 39 is driven, as the refrigerant is shown by the solid line in FIG. 3, the compressor 39 → the four-way valve 31 → the outdoor heat exchanger 35 → the one-way valve 36 → the expansion valve 33. → the indoor heat exchanger (19) → the four-way valve (31) → the compressor (39) is circulated in order to start cooling the indoor heat exchanger (19).

Therefore, the indoor air sucked into the main body 1 through the suction port 3 passes through the indoor heat exchanger 19, and is heat-exchanged with cold air by the latent evaporation of the refrigerant flowing in the indoor heat exchanger 19, The cold air heat exchanged in 19 is guided to the upper part and discharged into the room through the discharge hole 7, and the cold air discharged through the discharge hole 7 is inclined to the wind direction angle of the upper and lower wind vanes 9 and the left and right wind vanes 11. As the wind direction is adjusted up and down or left and right according to the indoor cooling.

On the other hand, when the user selects the heating operation, the set temperature (Ts) and the room temperature (Tr) are compared and the set temperature (Ts) and the room temperature (Tr) of the set temperature (Ts) are higher than the room temperature (Tr). The driving frequency of the compressor 39 is determined according to the difference, and the compressor 39 is driven.

When the compressor 39 is driven, as the refrigerant is shown by the dotted line in Fig. 3, the compressor 39 → the four-way valve 31 → the indoor heat exchanger 19 → the expansion valve 33 → the heating expansion valve 34. ) → the outdoor heat exchanger (35) → the four-way valve (31) → the compressor (39) is circulated in order to start the heating of the indoor heat exchanger (19), at this time depending on the temperature of the indoor heat exchanger (19) changes The drive of the fan 23 is controlled.

If the temperature of the indoor heat exchanger 19 is lower than a predetermined temperature (about 27 ° C.), the indoor fan 23 is stopped to prevent cold air from being discharged to the room at the beginning of heating. If the temperature is equal to or higher than a predetermined temperature (about 27 ° C.), the indoor fan 23 is driven.

When the indoor fan 23 is driven, the indoor air sucked into the main body 1 through the suction port 3 passes through the indoor heat exchanger 19 while the warm air is caused by the latent heat of evaporation of the refrigerant flowing in the indoor heat exchanger 19. Heat exchanged by the heat exchanger, and the warm air heat-exchanged in the indoor heat exchanger 19 is guided to the upper portion and discharged into the room through the discharge hole 7, and the warm air discharged through the discharge hole 7 is the up-down wind vane 9 and the left-right wind direction Air conditioning is performed up and down or left and right according to the wind direction angle of the wing 11 to perform the indoor heating.

In the air conditioner that performs the cooling and heating operation as described above, when the user sets the dehumidification operation, the four-way valve 31 is turned off and the refrigerant is shown in the solid line of FIG. → same as the refrigerant cycle during the cooling operation circulated in the order of the outdoor heat exchanger (35) → one-way valve (36) → expansion valve (33) → indoor heat exchanger (19) → four-way valve (31) → compressor (39). .

At this time, after the indoor fan 23, the outdoor fan 37, and the compressor 39 are turned on, the operation is performed irrespective of the room temperature for the first 30 minutes, and after 30 minutes, the compressor is operated according to the room temperature (about 23 ° C.). (39) is turned on and off to perform the dehumidification operation.

However, the purpose of the dehumidification operation is to remove moisture from the room without lowering the indoor temperature, but in the conventional dehumidification operation, since the room is cooled by the same refrigerant cycle as the cooling operation, the dehumidification efficiency is lowered (for example, In the rainy season, when the indoor temperature is appropriate or low but the humidity is relatively high, the user wants to remove only the moisture, but when the dehumidification operation is performed, the indoor temperature also drops.

In addition, even when the user wants to perform the dehumidification operation while raising the room temperature, the conventional dehumidification operation has a problem in that it does not meet the user's desire for the product because the user cannot set the room temperature.

Accordingly, the present invention has been made in order to solve the above-mentioned problems, the dehumidification apparatus of the air conditioner that can efficiently perform dehumidification without lowering the room temperature during the dehumidification operation, and can set the desired room temperature; Its purpose is to provide a control method.

In order to achieve the above object, the air conditioner dehumidification apparatus of the present invention includes an indoor heat exchanger for exchanging indoor air circulated by an indoor fan, and a four-way valve for changing a flow of refrigerant to perform heat exchange in the indoor heat exchanger. In the air conditioner provided, the temperature sensing means for sensing the temperature of the indoor heat exchanger during the dehumidification operation, and by controlling the driving of the indoor fan and the four-way valve in accordance with the indoor heat exchanger temperature detected by the temperature sensing means for cooling Characterized in that the control means for performing the operation and the heating operation alternately.

In addition, the dehumidification control method of the air conditioner according to the present invention includes an operation discrimination step of determining whether the operation condition set by the remote control is a dehumidification operation, and if the dehumidification operation is performed in the operation determination step, the four-way valve and the indoor fan are turned off, and the compressor and A cooling operation step of turning on an outdoor fan to perform a cooling operation, a freezing temperature sensing step of sensing a temperature of the indoor heat exchanger in which indoor moisture is frozen according to the cooling operation in the cooling operation step, and the freezing operation If the indoor heat exchanger temperature detected in the temperature sensing step is less than a predetermined temperature, the heating operation step of heating the four-way valve and the indoor fan to perform a heating operation, and the heating operation in the heating operation step is implanted in the indoor heat exchanger Defrost temperature sensing step of detecting the temperature of the indoor heat exchanger defrosting the moisture melted, the defrost temperature detection step It characterized in that the interior heat exchanger temperature is above a predetermined temperature to give off the four-way valve and the indoor fan consisting of a cooling operation, the feedback step for feeding back to the cooling operation.

1 is a perspective view showing an indoor unit of a conventional air conditioner,

2 is a longitudinal cross-sectional view of FIG.

3 is a cooling and heating cycle of a general air conditioner,

4 is a control block diagram of a dehumidifier of an air conditioner according to an embodiment of the present invention;

Fig. 5 is a flowchart showing the operation procedure of the dehumidification control of the air conditioner according to the present invention.

* Explanation of symbols for main parts of the drawings

19: indoor heat exchanger 23: indoor fan

37: outdoor fan 39: compressor

104: control means 106: room temperature detection means

108: indoor piping temperature sensing means 122: compressor driving means

124: outdoor fan motor driving means 126: indoor fan motor driving means

128: four-way valve driving means

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 4, the power supply means 100 converts a commercial AC voltage supplied from an AC power supply terminal (not shown) into a predetermined DC voltage required for the operation of the air conditioner, and outputs the signal. The operating conditions (automatic, cooling, dehumidification, blowing, heating, etc.) of the air conditioner desired by the user, the amount of air discharged through the discharge port 7 (strong wind, weak wind, breeze, etc.), wind direction, set temperature (Ts) ), An optical receiver for receiving an infrared signal transmitted from a remote controller according to a key operation of a remote controller (not shown) to input an operation / stop of the air conditioner.

In addition, the control unit 104 determines the operating condition selected by the user according to the infrared signal received by the signal receiving unit 102 to control the overall operation of the air conditioner, as well as the signal receiving unit 102. A microcomputer for controlling the overall operation of the air conditioner in accordance with the operation selection signal input by the control unit 104, the control means 104 according to the temperature of the indoor heat exchanger 19 during the dehumidification operation, the indoor fan 23 and the four sides The driving of the valve 31 is controlled to alternately perform the cooling operation and the heating operation.

The indoor temperature detecting means 106 controls the indoor temperature by the set temperature Ts input from the signal receiving means 102 to perform the cooling and heating operation of the air conditioner. Detects the temperature Tr, and the indoor pipe temperature detecting means 108 passes through the pipe temperature of the indoor heat exchanger 19 that changes during the dehumidification operation of the air conditioner, that is, passes through the indoor heat exchanger 19. The coolant temperature is sensed and output to the control means 104.

In addition, the wind direction control unit 120 controls the drive of the wind direction motor 121 to vertically and horizontally adjust the direction of the discharged air so that the air discharged through the discharge port 7 is evenly spread throughout the room, and the compressor driving means ( 122 is output from the control means 104 according to the difference between the set temperature Ts input by the signal receiving means 102 and the room temperature Tr sensed by the room temperature sensing means 106. In response to the control signal, the compressor 39 is driven and controlled.

The outdoor fan motor driving means 124 controls the control means according to the difference between the set temperature Ts input by the signal receiving means 102 and the room temperature Tr sensed by the indoor temperature sensing means 106. Receiving a control signal output from the 104 to drive the outdoor fan 37 by controlling the rotation speed of the outdoor fan motor 125 to blow the air heat exchanged in the outdoor heat exchanger 35 to the outside, the indoor fan motor The drive means 126 receives the control signal output from the control means 104 in accordance with the set air volume input by the signal receiving means 20 (air or cold air heat exchanged in the indoor heat exchanger 19) It drives the indoor fan 23 by controlling the rotation speed of the indoor fan motor 21 to blow the air into the room.

In addition, in the figure, the four-way valve driving means 128 is a control output from the control means 104 to convert the flow of the refrigerant in accordance with the operating conditions (cooling or heating) input by the signal receiving means 102 Receiving a signal, the four-way valve 31 is controlled on / off, and the display means 130 controls the operation selection mode (automatic or cooling) input by the signal receiving means 102 under the control of the control means 104. , Dehumidification, blowing, heating, etc.) and the set temperature (Ts) and the room temperature (Tr), as well as the operating state of the air conditioner.

Hereinafter, the operation and effect of the dehumidifier and the control method of the air conditioner configured as described above will be described.

FIG. 5 is a flowchart showing a dehumidification control operation procedure of the air conditioner according to the present invention. In FIG. 5, S denotes a step.

First, when power is applied to the air conditioner, the power supply means 100 converts a commercial AC voltage supplied from an AC power terminal (not shown) into a predetermined DC voltage required for driving the air conditioner, thereby driving each circuit and control means ( Output to 104).

Therefore, in step S1, the DC voltage output from the power supply means 100 is input from the control means 104 to initialize the air conditioner.

At this time, when the user operates the remote controller (not shown) and presses the operation / stop key and then presses the operation selection key to select a desired operation mode (for example, dehumidification), the remote control receives a remote control signal corresponding to a key input. It encodes by a protocol, modulates the encoded signal, and transmits an infrared signal.

When the infrared signal is transmitted from the remote controller, the signal receiving unit 102 receives the signal and converts it into an electrical signal, and demodulates the converted electrical signal to control the operation mode and the operation start signal (hereinafter referred to as a driving signal). (104).

Accordingly, in step S2, the control means 104 determines whether the operation signal is input from the signal receiving means 102, and maintains the air conditioner in the operation standby state when the operation signal is not input (NO). End the operation.

As a result of the discrimination in step S2, when an operation signal is input (YES), the process proceeds to step S3, and the control means 104 determines whether the operation mode input by the signal receiving means 102 is a dehumidification operation, If it is not the dehumidification operation (NO), the flow advances to step S31 to finish the operation while performing the cooling or heating operation of the air conditioner according to the setting of the remote controller.

As a result of the determination in step S3, in the case of the dehumidification operation (YES), the flow goes to step S4, and the control means 104 outputs a control signal for controlling the four-way valve 31 to the four-way valve driving means 128. At the same time, a control signal for turning off the indoor fan 23 is output to the indoor fan motor driving means 126.

Accordingly, the indoor fan motor driving means 126 stops the indoor fan motor 21 by turning off the driving of the indoor fan 23 according to the control of the control means 104, and controls the four-way valve driving means 128. Under the control of the means 104, the four-way valve 31 is turned off to switch the flow of refrigerant to the cooling cycle.

Subsequently, in step S5, when the control means 104 outputs a control signal for driving the compressor 39 and the outdoor fan 37 to the compressor driving means 122 and the outdoor fan motor driving means 124, the compressor driving means. The means 122 drives (on) the compressor 39 under the control of the control means 104, and the outdoor fan motor driving means 124 drives the outdoor fan motor 125 under the control of the control means 104. Drive to drive (on) the outdoor fan 37.

When the compressor 39 and the outdoor fan 37 are turned on, as shown in the solid line in FIG. 3, the refrigerant 39, the four-way valve 31, the outdoor heat exchanger 35, and the one-way valve 36. → the expansion valve (33) → the indoor heat exchanger (19) → the four-way valve (31) → the compressor (39) in order to circulate the low-temperature refrigerant flows through the indoor heat exchanger (19) to cool the indoor heat exchanger (19). At this time, since the indoor fan 19 is off, heat exchange is not performed in the indoor heat exchanger 19, so that the indoor heat exchanger 19 is frozen.

When the indoor heat exchanger 19 freezes, the indoor moisture exchanges on the indoor heat exchanger 19 and freezes. In step S6, the temperature Tip of the indoor heat exchanger 19 which is frozen during the cooling operation by the cooling cycle is determined. The indoor pipe temperature sensing means 108 senses.

Therefore, the control means 104 converts the analog data of the indoor piping temperature (Tip) detected by the indoor piping temperature sensing means 108 into digital, so that the indoor piping temperature (Tip) is a predetermined temperature (T1; indoor during dehumidification operation). If it is determined whether or not the heat exchanger is frozen, the process returns to step S4 and continues the cooling operation when the indoor piping temperature (Tip) is not below the predetermined temperature (T1) (NO). By repeating the operation of step S4 or less while performing, in this case, it is possible to set the desired room temperature according to the cooling operation time.

As a result of the discrimination in step S6, when the indoor piping temperature Tip is equal to or less than the predetermined temperature T1 (YES), it is determined that the indoor heat exchanger 19 is in a frozen state, and the control means 104 proceeds to step S7. A control signal for controlling the four-way valve 31 is output to the four-way valve driving means 128 and a control signal for driving the indoor fan 23 is output to the indoor fan motor driving means 126.

Therefore, the indoor fan motor driving means 126 controls the rotational speed of the indoor fan motor 21 according to the set air volume to drive the indoor fan 23, and the four-way valve driving means 128 controls the means 104. According to the control of the four-way valve 31 is turned on to switch the flow of the refrigerant to the heating cycle.

When the four-way valve 31 and the indoor fan 23 are turned on, as shown by the dotted line in FIG. 3, the refrigerant 39 is a compressor 39 → a four-way valve 31 → an indoor heat exchanger 19 → an expansion valve 33. ) → the expansion valve for heating (34) → the outdoor heat exchanger (35) → the four-way valve (31) → the compressor (39) in order to flow the refrigerant of the high temperature to the indoor heat exchanger (19), the indoor heat exchanger (19) Starts to heat and the moisture that has been implanted in the indoor heat exchanger (19) melts to defrost.

When the indoor heat exchanger 19 is heated, the indoor moisture that has been implanted in the indoor heat exchanger 19 is removed. In step S8, the temperature (Tip) of the indoor heat exchanger 19 defrosted during the heating operation by the heating cycle. Detects the indoor piping temperature detection means (108).

Therefore, in the control means 104, the indoor pipe temperature Tip detected by the indoor pipe temperature detecting means 108 is equal to or higher than a predetermined temperature T2 (reference temperature for determining whether the indoor heat exchanger is defrosted during the dehumidification operation). If the indoor piping temperature (Tip) is not equal to or higher than the predetermined temperature (T2) (NO), the operation returns to the step S7 and continues the heating operation while repeatedly performing the operation of the step S7 or less. The user can set the desired room temperature according to the heating operation time.

As a result of the determination in step S8, when the indoor piping temperature Tip is equal to or higher than the predetermined temperature T1 (YES), it is determined that the frost formed on the indoor heat exchanger 19 is removed and the process returns to step S4. To perform the dehumidification operation by repeatedly performing the operation of step S4 or less while switching the flow of the refrigerant back to the cooling cycle.

According to the dehumidification apparatus and control method of the air conditioner according to the present invention as described above, it is possible to efficiently perform dehumidification without lowering the room temperature during the dehumidification operation, it is possible to set the desired room temperature have.

Claims (4)

An air conditioner having an indoor heat exchanger for heat-exchanging indoor air circulated by an indoor fan, and a four-way valve for changing a flow of refrigerant to perform heat exchange in the indoor heat exchanger, Temperature sensing means for sensing a temperature of the indoor heat exchanger during a dehumidification operation; Dehumidifying apparatus of the air conditioner comprising a control means for alternately performing the cooling operation and heating operation by controlling the operation of the indoor fan and the four-way valve in accordance with the indoor heat exchanger temperature sensed by the temperature sensing means. An operation discrimination step of determining whether the operation condition set by the remote controller is a dehumidification operation; A cooling operation step of performing a cooling operation by turning off the four-way valve and the indoor fan and turning on the compressor and the outdoor fan when the dehumidification operation is performed in the operation determination step; A freezing temperature sensing step of detecting a temperature of the indoor heat exchanger in which indoor moisture is implanted and frozen according to the cooling operation in the cooling operation step; A heating operation step of performing heating operation by turning on the four-way valve and the indoor fan when the indoor heat exchanger temperature detected in the freezing temperature detection step is equal to or less than a predetermined temperature; Defrost temperature sensing step of detecting the temperature of the indoor heat exchanger defrosted by melting the moisture implanted in the indoor heat exchanger in accordance with the heating operation in the heating operation step; And a cooling operation feedback step of turning off the four-way valve and the indoor fan and feeding back to the cooling operation when the indoor heat exchanger temperature detected in the defrost temperature sensing step is higher than a predetermined temperature. The method of claim 2, The cooling operation step is a dehumidification control method of the air conditioner, characterized in that for setting the room temperature according to the cooling operation time by the indoor heat exchanger temperature. The method of claim 2 or 3, The heating operation step is a dehumidification control method of the air conditioner, characterized in that for setting the room temperature according to the heating operation time by the indoor heat exchanger temperature.