KR100229651B1 - Defrosting method of cooling/heating separation type airconditioner - Google Patents

Abstract

Disclosed is a defrosting method of a separate air conditioner for cooling and heating. The defrosting method of the combined air-conditioning and separate type air conditioner includes: a first step (S1) of periodically detecting a change in operating characteristics of a motor for driving the blower fan when heating operation of the air conditioner starts; A second step (S2) of determining whether the detected operating characteristic of the motor reaches the defrosting operation condition of the air conditioner; When the operation characteristic of the motor reaches the defrosting operation condition of the air conditioner, the defrosting operation of the air conditioner is performed by switching a four-way valve and flowing a high temperature heat exchange medium discharged from the compressor to the outdoor side heat exchanger. Performing a third step (S3); A fourth step S4 of determining whether the air conditioner has reached a predetermined defrosting completion condition; And a fifth step (S5) of switching the four-way valve to return the air conditioner to the heating operation state when the air conditioner has reached the defrost completion condition.

Description

Defrosting method of separate air conditioner combined with heating and cooling

The present invention relates to a defrosting method of a separate air conditioner for combined heating and cooling, and more particularly, to defrost of a separate air conditioner for combined heating and cooling to effectively remove the frost attached to the outdoor heat exchanger during the heating operation of the separate air conditioning for the combined heating and cooling. It is about a method.

In general, an air conditioner is a mechanical device that heats and heats a room by using a heat exchange process between a heat exchange medium and an ambient air that undergoes a phase change process while circulating a closed circuit. One example is shown in FIG. 1.

According to FIG. 1, such an air-conditioning and separate type air conditioner includes a compressor 11, an indoor heat exchanger 13, one side of which is connected to the compressor 11 by a first connecting pipe 12, An outdoor side heat exchanger 16 having one side connected to the other side of the indoor side heat exchanger 13 by a second connecting tube 14 having a capillary tube 15 installed in the middle thereof; The third connection pipe 17 which connects the other side of the outdoor side heat exchanger 16 and the said compressor 11 is comprised.

Here, between the first and third connecting pipes (12, 17) and the compressor 11, the flow direction of the high-temperature, high-pressure gaseous heat exchange medium compressed by the compressor 11 to the third or first Four-way valves 18 are provided for varying the connecting pipes 17, 12, that is, toward the outdoor side heat exchanger 16 or the indoor side heat exchanger 13.

When cooling the room using the combined air-conditioning and separate type air conditioner configured as described above, the heat exchange medium compressed by the compressor 11 is supplied to the outdoor side heat exchanger 16 through the third connecting pipe 17, and the surrounding outdoor It is liquefied after heat exchange with air.

The liquefied heat exchange medium is depressurized through the second connecting pipe 14 and the capillary tube 15 provided thereto, and is supplied to the indoor heat exchanger 13. The heat exchange medium supplied to the indoor heat exchanger 13 is evaporated inside the indoor heat exchanger 13 to take heat from the surrounding indoor air to cool the room.

On the other hand, when heating the room using the combined air-conditioning and separate type air conditioner configured as described above, the heat exchange medium compressed by the compressor 11 is first transferred to the indoor heat exchanger 13 through the first connecting pipe 12. It is supplied and liquefied while releasing heat to the surrounding atmosphere (indoor air). The heat is generated in the room by the heat released in the process of liquefying the heat exchange medium in the indoor heat exchanger (13).

Thereafter, the liquefied heat exchange medium is depressurized through the second connecting pipe 14 and the capillary tube 15 installed therein, and is supplied to the outdoor heat exchanger 16. The heat exchange medium supplied to the outdoor side heat exchanger 16 is evaporated inside the outdoor side heat exchanger 16 to deprive heat from the surrounding atmosphere (outdoor air).

In this process, the surface temperature of the outdoor heat exchanger 16 is relatively lower than that of the atmosphere, which causes the surface of the outdoor heat exchanger 16 to condense moisture condensed from a relatively high temperature atmosphere. Then, the moisture is frozen due to the low temperature of the surface of the outdoor heat exchanger 16, so that frosting starts on the surface of the outdoor heat exchanger 16.

The freezing state of the moisture on the surface of the outdoor heat exchanger 16 becomes thicker with time, and thus the amount of air in the outdoor air passing through the outdoor heat exchanger 16 decreases, so that the outdoor heat exchanger The heat exchange efficiency of the heat exchange medium and the outdoor air in the air 16 is reduced. Therefore, the defrosting operation to remove the frost attached to the outdoor side heat exchanger 16 regularly is required.

When the heat exchange efficiency of the outdoor heat exchanger 16 decreases as the outdoor heat exchanger 16 is attracted, the temperature of the entire cycle is lowered and the temperature of the indoor heat exchanger 13 is also lowered. Since the temperature of the discharged air discharged from the indoor heat exchanger 13 is lowered and the rising speed of the indoor temperature is slowed, the heating efficiency is lowered. Therefore, it has been conventionally determined whether the air conditioner is defrosted by sensing the temperature.

When it is determined whether the air conditioner is defrosted, the 4-way valve 18 is operated so that the circulation direction of the heat exchange medium is in the reverse direction in the heating mode, that is, in the cooling mode (solid arrow direction in FIG. 1). . In this case, since the high temperature heat exchange medium compressed by the compressor 11 flows to the outdoor heat exchanger 16, the frost attached to the outdoor heat exchanger 16 is melted and removed. At this time, the indoor blower fan is stopped to prevent the cold wind from being discharged into the room.

However, as described above, whether the dehumidification operation of the air conditioner is performed by detecting the temperature of the indoor heat exchanger 13 or the temperature of the air discharged from the indoor heat exchanger 13 is performed when the indoor temperature is high. Even if the heat exchanger 16 is defrosted and the defrosting operation is required, the temperature of the indoor heat exchanger 13 does not become the defrosting operation, and thus the heating operation may continue. Therefore, the heating efficiency cannot be kept constant. There was a problem.

On the other hand, in order to exclude the condition of the indoor heat exchanger 13 as described above, it is possible to determine whether the defrost operation by measuring the temperature of the outdoor heat exchanger 16, in this case, the outdoor air The temperature setting of the outdoor heat exchanger 16 according to the temperature of the outdoor heat exchanger 16 has been set incorrectly or the humidity of the outdoor air is low. The case may be a defrost operation in the state.

When the defrosting operation is performed in such a state, since the heating operation is stopped for a predetermined time for defrosting, the indoor temperature is lowered due to the influence of outside air during the defrosting operation, and the time for raising the lowered temperature even when the heating operation is started again is Since it is necessary, there was a problem that the difference in operating time required to raise the room temperature to a certain temperature is increased.

Therefore, the technical problem to be achieved by the present invention, that is, the object of the present invention is to solve the above problems of the defrosting method of the conventional air-conditioning combined type separate air conditioner, which is actually stuck in the outdoor heat exchanger It is to provide a defrosting method of a separate air conditioner for combined use of heating and cooling to maximize the heating efficiency by performing the defrosting operation of the air conditioner only.

1 is a cycle configuration diagram of a general air-conditioning combined type separate air conditioner.

Figure 2 is a flow chart for explaining a defrosting method of a separate air conditioner according to the present invention.

Explanation of symbols on the main parts of the drawings

11; Compressor 12; 1st connector

13; Indoor side heat exchanger 14; 2nd connector

15; Capillary tube 16; Outdoor side heat exchanger

17; Third connector 18; 4-way valve

19; Blowing fan 19a; Motor

An object of the present invention as described above, the compressor; An indoor side heat exchanger having one side connected to the compressor by a first connector; One side is connected to the other side of the indoor side heat exchanger by a second connecting tube having a capillary tube installed in the middle thereof, and the other side is connected to the compressor by the third connecting tube. A heat exchanger; A blower fan installed near the outdoor heat exchanger to allow ambient air to flow through the outdoor heat exchanger; And a four-way valve disposed between the first and third connectors and the compressor to change a flow direction of the heat exchange medium compressed by the compressor toward the third or first connectors. A defrosting method of a separate air conditioner, comprising: a first step (S1) of periodically detecting a change in operating characteristics of a motor for driving the blower fan when heating operation of the air conditioner starts; A second step (S2) of determining whether the detected operating characteristic of the motor reaches the defrosting operation condition of the air conditioner; When the operation characteristic of the motor reaches the defrosting operation condition of the air conditioner, the defrosting operation of the air conditioner is performed by switching a 4-way valve to flow a high temperature heat exchange medium discharged from the compressor to the outdoor side heat exchanger. Performing a third step (S3); A fourth step S4 of determining whether the air conditioner has reached a predetermined defrosting completion condition; And a fifth step (S5) of switching the 4-way valve to return the air conditioner to the heating operation state when the air conditioner has reached the defrosting completion condition, according to the present invention. By providing a defrosting method of the air conditioner.

Here, the operating characteristics of the motor may be a rotational speed of the motor, or may be a current value applied to the motor.

In this way, when the operating characteristics of the motor driving the blower of the outdoor heat exchanger are sensed, and it is determined whether the air conditioner has reached the defrosting operation condition, only when the outdoor heat exchanger is actually stuck The defrosting operation of the air conditioner can be performed, thus maximizing the heating efficiency.

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

1 shows a cycle configuration of a general air-conditioning combined type separate air conditioner, and FIG. 2 shows a defrosting method of the separate type air conditioner according to the present invention as a flow chart.

According to FIG. 1, a general air-conditioning combined type separate air conditioner, as described above, has a compressor 11, a first connecting pipe 12, an indoor side heat exchanger 13, and a second connecting pipe ( 14) and a capillary tube 15, an outdoor side heat exchanger 16, a third connecting pipe 17 and a four-way valve 18, and the outdoor side heat exchanger ( In the vicinity of 16), an air blower 19 driven by a motor 19a is installed to allow air around the outdoor heat exchanger 16 to pass through the outdoor heat exchanger 16.

When the combined air-conditioning and separate type air conditioner configured as described above is operated in the heating mode, the heat exchange medium compressed by the compressor 11 is supplied to the indoor heat exchanger 13 through the first connection pipe 12 to heat the room. At this time, the high-temperature, high-pressure gaseous heat exchange medium compressed by the compressor 11 passes through the indoor heat exchanger 13 to release heat into the air and change into a liquid state.

The liquefied heat exchange medium is supplied to the outdoor heat exchanger 16 through the second connecting pipe 14 and the capillary tube 15 installed therein. The liquid heat exchange medium supplied to the outdoor side heat exchanger 16 is evaporated while passing through the outdoor side heat exchanger 16 to extract heat from the surrounding atmosphere.

As described above, when the temperature of the outdoor heat exchanger 16 is lowered in the process of heating the room, frost is caused on the surface thereof, and the heat exchange efficiency of the outdoor heat exchanger 16 is lowered, thereby reducing the heat exchange efficiency of the outdoor heat exchanger 16. The temperature is lowered, and thus, the temperature of the indoor heat exchanger 13 is also lowered so that the room cannot be sufficiently heated.

Therefore, a defrosting operation for removing the debris attached to the surface of the outdoor heat exchanger 16 is required, and this defrosting operation is performed by the following method.

First, when the heating operation of the air conditioner is started, a first step S1 of periodically detecting a change in operating characteristics of the motor 19a for driving the blower fan 19 is performed. Here, the operating characteristic of the motor 19a may be the rotation speed of the motor 19a or may be a current value applied to the motor 19a.

When frost is trapped in the outdoor heat exchanger 16, the cross sectional area of the air blown through the outdoor heat exchanger 16 is relatively small, and thus the rotation speed of the motor 19a is increased. Accordingly, the current value applied to the motor 19a is changed.

It is determined whether the detected operating characteristic of the motor reaches the defrosting operation condition of the air conditioner (second step; S2). As a result of the determination in the second step S2, when the operation characteristic of the motor 19a reaches the defrosting operation condition of the air conditioner, the 4-way valve 18 is switched to discharge from the compressor 11. The defrosting operation of the air conditioner is performed by flowing the high temperature heat exchange medium to the outdoor heat exchanger 16 (third step; S3).

It is determined whether the air conditioner has reached a predetermined defrosting completion condition (fourth step; S4). As a result of the determination in the fourth step S4, when the air conditioner reaches the defrosting completion condition, the four-way valve 18 is switched to return the air conditioner to the heating operation state again (S5 step S5).

Therefore, according to the defrosting method of the separate air conditioner for combined heating and cooling according to the present invention configured as described above, by detecting the change in the operating characteristics of the motor for driving the blow fan of the outdoor heat exchanger in the heating mode, thereby Since the conditioner determines whether the defrosting operation condition is reached, the defrosting operation of the air conditioner can be performed only when the external heat exchanger is actually stuck with the defroster, thereby maximizing the heating efficiency.

Although specific embodiments of the present invention have been illustrated and described above, the present invention is not limited to the above-described embodiments, and the present invention is not limited to the scope of the present invention as claimed in the claims. Anyone of ordinary skill in the art will be able to implement various modifications.

Claims (3)

A compressor; An indoor side heat exchanger having one side connected to the compressor by a first connector; One side is connected to the other side of the indoor side heat exchanger by a second connecting tube having a capillary tube installed in the middle thereof, and the other side is connected to the compressor by the third connecting tube. A heat exchanger; A blower fan installed near the outdoor heat exchanger to allow ambient air to flow through the outdoor heat exchanger; And a four-way valve disposed between the first and third connectors and the compressor to change a flow direction of the heat exchange medium compressed by the compressor toward the third or first connectors. In the defrosting method of a separate air conditioner, A first step (S1) of periodically detecting a change in operating characteristics of a motor for driving the blower fan when a heating operation of an air conditioner starts; A second step (S2) of determining whether the detected operating characteristic of the motor reaches the defrosting operation condition of the air conditioner; When the operation characteristic of the motor reaches the defrosting operation condition of the air conditioner, the defrosting operation of the air conditioner is performed by switching a four-way valve and flowing a high temperature heat exchange medium discharged from the compressor to the outdoor side heat exchanger. Performing a third step (S3); A fourth step S4 of determining whether the air conditioner has reached a predetermined defrosting completion condition; And a fifth step (S5) of switching the four-way valve to return the air conditioner to the heating operation state when the air conditioner has reached the defrosting completion condition. Defrosting method. The method of claim 1, wherein the operating characteristics of the motor is a defrosting method of a separate air conditioner for combined heating and cooling, characterized in that the rotation speed of the motor. The method of claim 1, wherein the operating characteristics of the motor is a defrosting method of a separate air conditioner for combined heating and cooling, characterized in that the current value applied to the motor.

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