KR100691230B1 - Control method of air conditioner - Google Patents

Abstract

A control method for an air conditioner is provided to control cooling capacity of indoor units having relatively high cooling capacities by reducing refrigerant introducing amounts and rpm of indoor fans thereof when indoor units having relatively low cooling capacities can not operate smoothly in simultaneous operation. A control method for an air conditioner includes the steps of determining a first or second indoor unit is in operation alone or the first and second indoor units are in operation simultaneously(S103), and determining operation modes of the first and second indoor units when the first and second indoor units are in operation simultaneously(S104). The first indoor unit is controlled to lower a cooling capacity thereof rather than a cooling capacity set for the operation mode thereof, to prevent decrease of the cooling capacity of the second indoor unit. The first indoor unit has an expansion valve such as an electronic expansion valve, and the second indoor unit has an expansion valve formed of a capillary tube and an opening/closing solenoid valve. In the lowering of the cooling capacity of the first indoor unit, an rpm of a blower fan or an opening degree of the electronic expansion valve set for the operation mode of the first indoor unit are reduced, and the solenoid valve is opened, so that an amount of refrigerant introduced into the second indoor unit becomes increased(S106-S108).

Description

Control method of air conditioner

Figure 1 is a schematic diagram showing an external state connected to the air conditioner according to the present invention.

2 is a view showing a refrigerant cycle of the air conditioner according to the present invention.

3 is a control block diagram of an air conditioner according to the present invention.

4 is a control flowchart of an air conditioner according to the present invention.

* Description of symbols on the main parts of the drawings *

10: outdoor unit 12: first compressor

14: second compressor 20: electromagnetic expansion valve

22: solenoid valve 50: first room

80: room 2

The present invention relates to a control method of an air conditioner, and more particularly, in a case in which a plurality of indoor units operate simultaneously in an air conditioner operating by connecting a plurality of indoor units having different cooling capabilities to an outdoor unit, a cooling capability of an indoor unit having a small cooling capacity It relates to a control method for an air conditioner to prevent this from falling.

In general, an air conditioner uses an endothermic and exothermic action, in which a compressor, a condenser, a refrigerant expansion valve, and an evaporator are connected to each other by a refrigerant pipe to form a closed circuit. It is a device for cooling or heating the surroundings.

In particular, the present invention is a so-called multi-type air conditioner that connects a plurality of indoor units having different cooling capacity to an outdoor unit and performs air conditioning, and such an air conditioner is disclosed in Korean Patent Laid-Open Publication No. 2001-0003908.

Such a conventional air conditioner is connected to the refrigerant pipe so that the outdoor unit and the plurality of indoor units respectively correspond to the refrigerant cycle, and the refrigerant pipe connecting the outdoor unit and the indoor unit has a valve for controlling the flow of the refrigerant or controlling the amount thereof. It was installed.

When the air conditioner equipped with a plurality of indoor units having different cooling capacities is operated, when the indoor unit having a relatively large cooling capacity and the indoor unit having a small cooling capacity operate simultaneously, the relationship between the cooling capacity of the indoor unit and the refrigerant piping connected to the outdoor unit There was a problem that the cooling capacity is not properly implemented on the indoor unit side with a small cooling capacity according to the length.

In other words, when the refrigerant flow rate of the indoor unit having the large cooling capacity is not controlled at all while the indoor unit having the small cooling capacity is installed with a relatively long length and the refrigerant pipe of the indoor unit having the large cooling capacity is not controlled at all, There was a problem that the amount is insufficient to implement the proper cooling capacity.

The present invention has been made to solve the above problems, and the object of the present invention is to provide a control method of an air conditioner for preventing the cooling capacity of an indoor unit having a small cooling capacity when the plurality of indoor units operate simultaneously. .

The present invention for achieving the object, an outdoor unit, a first indoor unit connected to the outdoor unit having a plurality of discharge ports, a second indoor unit connected to the outdoor unit, and an expansion valve installed between the outdoor unit and each indoor unit In the control method of the air conditioner comprising a blowing fan installed in each indoor unit,

A driving mode determination step of determining whether the driving mode of the indoor unit is the single operation of the first indoor unit or the second indoor unit or the simultaneous operation of the first and second indoor units;

An operation mode determination step of determining which operation mode is selected from the operation modes of the first indoor stage when the operation mode determination step is determined to be simultaneous operation;

And a cooling capacity adjusting step of adjusting the cooling capacity of the first indoor unit to realize a cooling capacity lower than the cooling capacity set to be suitable for the operation mode selected in the first indoor room to prevent the lowering of the cooling capacity of the second indoor room. It features.

In addition, the expansion valve connected to the first chamber is composed of an electromagnetic expansion valve, the expansion valve connected to the second chamber includes a capillary tube and an open / close solenoid valve,

In the cooling capacity adjusting step, the rotational speed of the blower fan or the opening degree of the electronic expansion valve set for each operation mode selected in the first chamber is reduced to decrease the cooling capacity of the first chamber and open the solenoid valve to open the first chamber. It is characterized in that to increase the amount of the refrigerant flowing into the room 2 to prevent a decrease in the cooling capacity of the second room.

In addition, the rotational speed of the blower fan of the first indoor unit or the opening degree of the electronic expansion valve may be reduced in the rotational speed or the opening degree set in the operation mode one step lower than the selected operation mode.

In addition, the number of the discharge openings opened in accordance with each operation mode of the first indoor chamber is set in advance, and in the cooling capacity adjusting step, the cooling capacity of the first indoor chamber is compensated by being maintained without decreasing the number of the openings opening. Characterized in that.

In addition, the operation mode of the first indoor chamber is made in three stages according to its cooling capacity, the discharge chamber of the first indoor chamber is made of three, one discharge opening is opened in the first stage operation, the discharge opening in the second stage operation Two are opened, and three discharge ports are opened during a three-step operation.

The control method of the air conditioner characterized in that the higher the step of the operation mode, the rotational speed of the blower fan and the opening degree of the electromagnetic expansion valve increases in stages.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

As shown in FIG. 1, in the present invention, two indoor units 50 and 80 having different cooling capacities are connected to an outdoor unit 10, and a first indoor unit having relatively large cooling capacities among two indoor units 50 and 80. 50 is installed in a living room, such as a large number of plains, the second room 80 having a small cooling capacity is generally installed in a small room.

The first indoor room 50 can adjust its intensity in consideration of its cooling capacity, and is divided into first, second, and third stages according to its strength, and the cooling capacity increases as the step increases.

The first indoor unit 50 has side discharge ports 54 formed on both sides thereof, and an upper surface discharge port 52 formed on its upper surface, and the top discharge port 52 or the side surface according to the operation mode of the first indoor unit 50. The air volume of the discharged air can be adjusted by opening and closing the discharge port 54.

A refrigerant pipe 48 is connected between the first indoor unit 50 and the second indoor unit 80 and the outdoor unit 10, and serves as a refrigerant passage 48. Generally, the first indoor unit 50 is installed. The refrigerant pipe connected to the second indoor unit 80 is installed longer than the refrigerant pipe connected to the).

As shown in FIG. 2, the outdoor compressor 10 includes a first compressor 12 for compressing a refrigerant into a liquid phase at high temperature and high pressure, and a second compressor 14 having a larger compression capacity than the first compressor 12. ), An outdoor heat exchanger (16) connected to the discharge parts of the first and second compressors (12, 14) to heat-exchange the refrigerant, and an outdoor fan to blow external air toward the heat exchanger so that heat exchange can proceed smoothly. (18), a bypass pipe (26) connected to the discharge portion of the outdoor heat exchanger (16) to bypass a predetermined amount of refrigerant to the first and second compressors (12, 14), and the bypass pipe ( The bypass valve 24 is installed at 26 to interrupt the flow of the refrigerant to be bypassed.

In addition, the outdoor unit 10 is connected to the discharge portion of the outdoor heat exchanger 16 and the electromagnetic expansion valve 20 for reducing the refrigerant flowing to the first chamber 50, the second chamber 80 and The capillary tube 28 is installed in parallel, and the front end portion of the capillary tube 28 is provided with an open / close solenoid valve 22 to control the flow of refrigerant flowing to the capillary tube 28.

In particular, the electromagnetic expansion valve 20 is a device that can increase or decrease the amount of refrigerant by adjusting the opening degree, which is installed between the discharge portion of the outdoor heat exchanger 16 and the first chamber 50. The capillary tube 28 and the solenoid valve 22 are installed at the side of the second chamber 80 where the amount of the refrigerant is relatively small.

The first indoor chamber 50 and the second indoor chamber 80 are connected in parallel, and the first indoor heat exchanger 56 for heat-exchanging the refrigerant and the air inside the interior of the first indoor chamber 50, A first indoor fan 58 for blowing air toward the first indoor heat exchanger 56 is installed, and the second indoor heat exchanger 82 and the second indoor fan 84 are provided inside the second indoor chamber 80. ) Is installed.

As shown in FIG. 3, in the control block diagram of the air conditioner according to the present invention, various control units installed in the first indoor unit 50 and the second indoor unit 80 are provided at the input terminal of the control unit 102. It is connected.

The first indoor unit 50 has a first power supply unit 60 for supplying or cutting off power, a first key operation unit 62 for adjusting an operation mode and air volume according to a cooling capacity, and a first indoor heat exchanger. The first sensor unit 64 having a heat exchanger temperature sensor capable of measuring the temperature of the room temperature and a room temperature sensor capable of sensing the indoor temperature, and a communication unit 66 for communicating with the outdoor unit 10, etc. It is provided.

In addition, the second indoor unit 80 also includes a second power supply unit 86, a second key operation unit 88, a second sensor unit 90 having a heat exchanger temperature sensor, a room temperature sensor, and the like. The signal unit 92 for transmitting the compressed signal of the indoor unit 80 to the outdoor unit 10 is installed.

In addition, the output terminal of the controller 102 drives the first compressor driver 11, the second compressor driver 13, and the outdoor fan 18 to drive the first and second compressors 12 and 14. The first indoor fan driving means 57 and the second indoor fan driving means 83 for driving the outdoor fan driver 15, the first indoor fan 58, and the second indoor fan 84 are connected to each other. Discharge port opening and closing means 51 capable of opening and closing the discharge ports 52 and 54 of the first indoor unit 50 are also connected.

In addition, the solenoid valve driving means 21 for opening and closing the solenoid valve 22 and the solenoid valve driving means 19 which can adjust the opening degree of the solenoid expansion valve 20 are connected.

Hereinafter, the operation of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 2, the first indoor unit 50 is in communication with the outdoor unit 10 in accordance with a single operation or simultaneous operation of the first indoor unit 50 and the second indoor unit 80. When the first compressor 12 and the second compressor 14 in the outdoor unit 10 operate alone or simultaneously, the refrigerant is converted into a gas state of high temperature and high pressure.

In this state, the refrigerant discharged from the compressor is moved to the outdoor heat exchanger 16 to be exchanged with external air to be converted into a low-temperature, high-pressure liquid state.

In a single operation of the second indoor unit 80 or in a mode in which the lowest cooling capacity in the first indoor unit 50 is required, that is, the first stage cooling, only the first compressor 12 is operated to operate the refrigerant. At the same time the bypass valve 24 is opened, so that some refrigerant flows toward the first compressor 12.

In addition, only the second compressor 14 is operated when the first indoor unit 50 is operated in two stages of cooling, and the first and second compressors 12 and 14 are operated in the single operation of three stages of cooling. ) Operates simultaneously, and the first and second compressors 12 and 14 operate simultaneously when the first indoor unit 50 and the second indoor unit 80 are operated simultaneously.

When the solenoid valve 20 is operated alone in relation to the operation of the solenoid valve 20 and the solenoid valve 22, only the solenoid valve 20 is opened so that refrigerant flows into this portion. As a result, the state changes to a low temperature low pressure state, and in this state, heat exchanges with indoor air through the first indoor heat exchanger 56, and then changes to a low temperature low pressure gas state, and then returns to the first compressor 12 or the second compressor 14. Inflow.

In case of the sole operation of the second indoor unit 80 alone, the electromagnetic expansion valve 20 is closed and the solenoid valve 22 is opened so that the refrigerant flows into the capillary tube 28 through the step-up process. The refrigerant cycle is achieved by performing a heat exchange process with indoor air in the indoor heat exchanger (82).

In addition, when the first and second chambers 50 and 80 operate, respectively, the electromagnetic expansion valve 20 and the solenoid valve 22 are opened, and the refrigerant is the electromagnetic expansion valve 20 and the capillary tube ( After the decompression process in 28), the first and second indoor heat exchangers 56 and 82 undergo a heat exchange process with indoor air.

As shown in Figure 3 and Figure 4, looking at the control flow chart of the air conditioner of the present invention, first, the control unit 102 determines whether the power input for operating the air conditioner (S100), the It is determined whether the operation mode of the first and second indoor units 50 and 80 is determined to determine whether the first or second indoor unit is a single operation or a simultaneous operation of the first and second indoor units (S101).

If the operation mode is the single operation of the first indoor unit 50 or the second indoor unit 80, the cooling operation is performed in the operation mode in the selected operation mode (S101), and the change in the operation mode or operation mode is later performed. The process of determining whether there is or not (S102).

If the operation mode is a simultaneous operation, it is then determined which operation mode is selected in the first indoor. At this time, the operation mode is divided into first, second and third stages according to the cooling capacity. The higher the value, the greater the cooling capacity. At this stage, the rotation speed of the first indoor fan 58, the opening degree of the electromagnetic expansion valve 20, and the discharge ports 52 and 54 opened in advance. The number is set, and as the step increases, the number of rotational openings and the number of discharge openings that are opened increases (S104).

When one of the operation modes of the first indoor is selected, the discharge ports 52 and 54 are opened by the number set according to the selected operation mode (S105), and the opening degree of the electromagnetic expansion valve 20 is increased. In step S106, the first indoor unit 50 undergoes a step of reducing the opening degree to one degree lower than the opening degree set for the selected driving mode (S106).

In addition, the rotation speed of the first indoor fan 58 is also changed to the rotation speed one step lower than the rotation speed set for the operation mode selected in the first indoor unit 50 (S107).

For example, when the operation mode is selected by the simultaneous operation of the first indoor unit 50 and the second indoor unit 80, and the operation mode of the first indoor unit is selected as the third step mode, the discharge port 52, 54, three discharge ports are opened in accordance with the third step, but the opening degree of the electromagnetic expansion valve 20 is not set to the opening degree for the third step, but is changed to the opening degree for the second step, which is the lower step. The rotation speed of the indoor fan 58 is also set to be changed to the rotation speed suitable for the second step.

In addition, the solenoid valve 22 is opened to allow the refrigerant to flow into the capillary tube, and the second chamber 80 operates so that heat exchange occurs in the second chamber 80 (S108).

As such, by reducing the opening degree of the electromagnetic expansion valve 20 and the rotation speed specification of the first indoor fan 58, the amount of the refrigerant flowing into the first indoor unit 50 is partially reduced, and thus reduced. By introducing additional refrigerant corresponding to the amount of refrigerant into the second indoor unit 80, the length of the refrigerant pipe between the outdoor unit 10 and the second indoor unit 80 is long, so that a proper amount of refrigerant does not reach the second indoor unit 80. It is possible to prevent the problem that can not properly implement the cooling capacity of.

When the first indoor unit 50 and the second indoor unit 80 are operated at the same time and there is a change in the operation mode or operation mode, the operation is again performed according to the changed specifications (S107).

According to the present invention as described above, when a plurality of indoor units having different cooling capacities are installed in one outdoor unit and the cooling operation is performed at the same time, the amount of the refrigerant flowing toward the indoor unit having the small cooling capacities decreases so that the cooling capacity of the indoor unit is appropriately adjusted. If it is impossible to implement, by reducing the refrigerant flow rate of the indoor unit having a large cooling capacity and the number of revolutions of the indoor fan, it is possible to control the cooling capacity of the indoor unit having a large cooling capacity while preventing the cooling capacity of the indoor unit having a small cooling capacity. .

In addition, in the indoor unit having a large cooling capacity, it is possible to compensate for the reduced cooling capacity to some extent by reducing the amount of discharged air or refrigerant and reducing the cooling capacity instead of changing the number of openings.

Claims (5)

An indoor unit, a first indoor unit connected to the outdoor unit and having a plurality of discharge ports, a second indoor unit connected to the outdoor unit, an expansion valve installed between the outdoor unit and each indoor unit, and an air blowing unit installed in each indoor unit In the control method of the air conditioner including a fan, A driving mode determination step of determining whether the driving mode of the indoor unit is the single operation of the first indoor unit or the second indoor unit or the simultaneous operation of the first and second indoor units; An operation mode determination step of determining which operation mode is selected from the operation modes of the first indoor stage when the operation mode determination step is determined to be simultaneous operation; And a cooling capacity adjusting step of adjusting the cooling capacity of the first indoor unit to realize a cooling capacity lower than the cooling capacity set to be suitable for the operation mode selected in the first indoor room to prevent the lowering of the cooling capacity of the second indoor room. A control method of an air conditioner, characterized in that. The method of claim 1, The expansion valve connected to the first chamber is composed of an electronic expansion valve, the expansion valve connected to the second chamber includes a capillary tube and an open / close solenoid valve, In the cooling capacity adjusting step, the rotation speed of the blower fan or the opening degree of the electronic expansion valve set for each operation mode selected in the first chamber is reduced to decrease the cooling capacity of the first chamber and open the solenoid valve. The control method of the air conditioner, characterized in that to increase the amount of refrigerant flowing into the second chamber to prevent a decrease in the cooling capacity of the second chamber. The method of claim 2, And the rotational speed of the blower fan of the first indoor unit or the opening degree of the electronic expansion valve is reduced in the rotational speed or opening degree set in the operation mode one step lower than the selected operation mode. The method of claim 3, The number of the discharge openings opened in accordance with each operation mode of the first indoor unit is set in advance, The control method of the air conditioner in the cooling capacity adjusting step is to compensate for the cooling capacity of the first room by maintaining the number of the discharge opening is not reduced. The method of claim 1, The operation mode of the first indoor chamber is composed of three stages according to its cooling capacity, and the discharge chamber of the first indoor chamber is composed of three, one discharge opening is opened during the first stage operation, and the discharge opening is two during the second stage operation. The dog is opened, characterized in that three discharge openings are opened during the three-step operation, The control method of the air conditioner, characterized in that the higher the step of the operation mode of the first indoor room, the rotational speed of the blower fan and the opening degree of the electromagnetic expansion valve increases step by step.

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