KR102080844B1 - Multi type air conditioner and method for searching pipes thereof - Google Patents

Abstract

The present invention relates to a pipe search method of a multi-type air conditioner. In one embodiment, a pipe search method of a multi-type air conditioner includes: an outdoor unit, a distributor connected to the outdoor unit, a distributor having a plurality of piping ports, a plurality of variable indoor units connected to the distributor, the outdoor unit and the distributor In the pipe search method of the multi-type air conditioner including a dedicated indoor unit that is connected to the pipe to be connected, the cooling or heating operation, by controlling the refrigerant flow of the pipe connected to any one of the plurality of piping ports, Searching for a variable indoor unit and a dedicated indoor unit; And after completing the search of the dedicated indoor unit, searching for pipes of the remaining variable indoor units among the plurality of variable indoor units connected to the distributor.

Description

Multi type air conditioner and method for searching pipes

The present invention relates to a multi-type air conditioner and a pipe search method thereof.

In general, an air conditioner is a device that cools or heats a room or purifies the air by using a refrigerant cycle including a compressor, a condenser, an expansion device, and an evaporator to create a more comfortable indoor environment for a user.

Such an air conditioner includes an air conditioner in which one indoor unit is connected to one outdoor unit, and a multi-type air conditioner which achieves the same effect as installing a plurality of air conditioners by connecting a plurality of indoor units to one outdoor unit.

In addition, recently, by installing a distributor for controlling the flow of refrigerant between a plurality of indoor units and outdoor units of the multi-type air conditioner, some of the plurality of indoor units to cool the room while the rest of the plurality of indoor units heating the air conditioner simultaneous air type Harmony is being developed.

The distributor of the air-conditioning simultaneous air conditioner may have a plurality of piping ports. In the case of the conventional air-conditioning simultaneous air conditioner, as described in Korean Patent Laid-Open Publication No. 10-2011-0073707, a pipe search process for matching the indoor port and the piping port connected to each piping port of the distributor was performed.

However, according to the conventional air conditioner, since the pipe of the indoor unit connected to the distributor is searched by adjusting the opening and closing of the valve provided in the distributor, there is a problem that the indoor unit not connected to the distributor cannot be searched.

An object of the present invention is to provide a multi-type air conditioner capable of searching for an indoor unit not connected to a distributor, and a pipe search method thereof.

In one embodiment, a pipe search method of a multi-type air conditioner includes: an outdoor unit, a distributor connected to the outdoor unit, a distributor having a plurality of piping ports, a plurality of variable indoor units connected to the distributor, the outdoor unit and the distributor A high-pressure valve connected to a branch pipe branched from a pipe to be connected, a dedicated indoor unit for cooling or heating operation, corresponding to each pipe port, and controlling a refrigerant flow of a variable indoor unit corresponding to each pipe port; Piping of the multi-type air conditioner corresponding to the port, including a low pressure valve for controlling the refrigerant flow of the variable indoor unit provided in a branch pipe branched from the pipe connecting the variable indoor unit and the high pressure valve corresponding to each of the piping port In the search method, by controlling the refrigerant flow of the pipe connected to any one of the plurality of pipe ports Searching for the variable indoor unit and the dedicated indoor unit; And after completing the search for the dedicated indoor unit, searching for pipes of the remaining variable indoor units among the plurality of variable indoor units connected to the distributor, and searching for any one of the variable indoor units and the dedicated indoor unit includes: After opening one of the high-pressure valve and the low-pressure valve corresponding to the predetermined time to detect the temperature change of the pipe connected to the dedicated indoor unit and each variable indoor unit to distinguish the dedicated indoor unit and any one variable indoor unit from the remaining variable indoor unit. ; And distinguishing the dedicated indoor unit from the variable indoor unit by sensing a temperature change of the pipe connected to the dedicated indoor unit and any one variable indoor unit after opening the other one for a predetermined time.

According to another aspect of the present invention, a pipe search method of a multi-type air conditioner includes an outdoor unit, a distributor connected to the outdoor unit, having a plurality of piping ports, a plurality of variable indoor units connected to the distributor, the outdoor unit and the distributor A pipe search method of a multi-type air conditioner connected to a pipe to be connected and including a dedicated indoor unit that is cooled or heated, the method comprising: turning on a compressor; Determining an initial temperature of a pipe connected to each indoor unit; Opening a first valve corresponding to any one of the plurality of pipe ports and sensing a temperature of pipe connected to each indoor unit; Opening a second valve corresponding to one of the pipe ports and sensing a temperature of a pipe connected to each indoor unit; And dividing any one of the variable indoor units from the dedicated indoor unit and the plurality of variable indoor units based on the sensed temperature of the pipe.

According to another aspect, a multi-type air conditioner includes an outdoor unit; A distributor connected to the outdoor unit and having a plurality of piping ports; A plurality of variable indoor units connected to the distributor; A dedicated indoor unit connected to a branch pipe branched from a pipe connecting the outdoor unit and the distributor, and configured to be cooled or heated; A temperature sensing unit sensing a temperature of a pipe connected to each of the plurality of variable indoor units and the dedicated indoor unit; And a control unit searching for an indoor unit based on the temperature information detected by the temperature sensing unit, wherein the distributor includes a high pressure valve and a low pressure valve corresponding to each pipe port, and the control unit turns on the compressor. Closing both the high pressure valve and the low pressure valve, the temperature sensing unit detects the initial temperature of the pipe connected to each indoor unit, and the control unit, the high pressure valve corresponding to any one of the plurality of piping ports and low pressure Opening any one of the valves for a predetermined time, by comparing the initial temperature and the temperature of the pipe connected to each indoor unit detected by the temperature sensing unit and distinguishing the dedicated indoor unit and any one variable indoor unit from the remaining variable indoor unit, Opening another one for a certain time, the pipe connected to each indoor unit detected by the temperature sensing unit Detects the temperature and the initial temperature of the dedicated indoor unit and any one of the variable indoor unit, and after the opening of any one indoor unit in which the pipe temperature is kept constant regardless of opening and closing of the high pressure valve and the low pressure valve The indoor unit is decided.

According to the proposed invention, since the high pressure valve and the low pressure valve of a specific port are alternately turned on, the indoor unit is searched based on this after searching for an indoor unit having a variable temperature. There is an advantage that can be explored.

1 is a view showing a refrigerant cycle configuration of a multi-type air conditioner according to an embodiment of the present invention.
2 is a view showing a refrigerant flow during the operation of the heating main body of the multi-type air conditioner according to the present invention.
3 is a control block diagram of the multi-type air conditioner of the present invention /
Figure 4 is a flow chart illustrating a pipe search method of a multi-type air conditioner according to an embodiment of the present invention.

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

1 is a view showing the configuration of the refrigerant cycle of the multi-type air conditioner according to an embodiment of the present invention, Figure 1 shows, for example, the flow of the refrigerant during the operation of the heating room.

Referring to FIG. 1, the multi-type air conditioner of the present invention connects at least one outdoor unit 10, a plurality of indoor units 31 to 35, and connects the outdoor unit 10 and a plurality of indoor units 31 to 35. One or more distributors 20.

In FIG. 1, for example, one outdoor unit 10 and one distributor 20 are disclosed, and three indoor units 31 to 33 are connected to the distributor 20, and the outdoor unit 10 and the distributor ( It is shown that a cooling-only indoor unit 34 is connected to one pipe connecting 20 and a heating-only indoor unit 35 is connected to another pipe connecting the outdoor unit 10 and the distributor 20.

In the present specification, the plurality of indoor units 31 to 33 connected to the distributor 20 may be driven by cooling or by heating. That is, the plurality of indoor units 31 to 33 connected to the distributor 20 may be referred to as variable indoor units 31 to 33 in which an operation mode is changed.

On the other hand, the heating-only indoor unit 35 is an indoor unit which is operated only by heating without changing the mode, and the cooling-only indoor unit 34 means an indoor unit which is operated only by cooling without changing the mode.

In the present invention, it is noted that there is no limit to the number of outdoor units, the number of distributors, and the number of indoor units connected to the distributors.

The distributor 20 may include the same number of piping ports as the number of indoor units. An indoor unit is connected to each pipe port.

The outdoor unit 10 includes a compression unit 110, an outdoor heat exchanger 140, an outdoor expansion mechanism (not shown), and a heating / cooling switching valve 130 (hereinafter referred to as a “switching valve”).

The compression unit 110 includes one or more compressors 111 and 112 for compressing a refrigerant. Hereinafter, the compression unit 110 will be described as including a plurality of compressors (111, 112).

The plurality of compressors 111 and 112 may include an inverter compressor 111 having a variable capacity and a constant speed compressor 112. The plurality of compressors 111 and 112 may be arranged in parallel. The suction pipes 131 of the plurality of compressors 111 and 112 are connected to the switching valve 130, and an accumulator 132 is installed in the suction pipe 131.

Oil separators 113 and 114 separating the refrigerant and the oil may be installed in the discharge passages of the plurality of compressors 111 and 112. Oil separated from the refrigerant in the oil separators 113 and 114 may be recovered to the compression unit 110.

The outdoor heat exchanger 140 may act as a condenser when operating the cooling chamber or the cooling main body, and may function as an evaporator when driving the heating chamber or the heating main body.

In this specification, a case in which all of the plurality of variable indoor units 31 to 33 are cooling operation is referred to as a cooling front room operation, and a case in which all of the plurality of variable indoor units 31 to 33 is heating operation is called a heating full room operation. In addition, a case in which some of the variable indoor units 31 to 33 are cooled and operated while the other is heated, and the capacity of the indoor unit that is cooled and operated is greater than the capacity of the indoor unit that is operated by heating is called a cooling main body operation. In addition, a case in which some of the plurality of variable indoor units 31 to 33 are cooled and the other is heated, and the capacity of the indoor unit to be heated is larger than the capacity of the indoor unit to be cooled is called heating main operation.

The internal refrigerant of the outdoor heat exchanger 140 may exchange heat with outdoor air blown by the outdoor fan.

The outdoor expansion mechanism does not expand the refrigerant when the refrigerant passing through the outdoor heat exchanger 140 passes, and expands the refrigerant when the refrigerant not passing through the outdoor heat exchanger 140 passes. The outdoor expansion mechanism is composed of an outdoor expansion valve disposed between the outdoor heat exchanger 140 and the distributor 20, or the refrigerant flow path in parallel between the refrigerant flow path and the distributor 20 of the outdoor heat exchanger 140. It can consist of a connected outdoor expansion valve and a check valve. For example, the outdoor expansion valve may be an electronic expansion valve (EEV).

The switching valve 130 allows the refrigerant compressed by the plurality of compressors 111 and 112 to flow to the outdoor heat exchanger 140 when the cooling chamber or the cooling main body is operated, and the outdoor heat exchanger when the heating chamber or the heating main body is operated. The refrigerant passing through the device 140 is allowed to flow toward the suction pipe 131.

The outdoor heat exchanger 140 is connected to the distributor 20 by a liquid pipe 182, and the suction pipe 131 is connected to the distributor 20 by a low pressure engine 183.

Although not shown, each of the plurality of variable indoor units 31 to 33, a cooling-only indoor unit 34, and a heating-only indoor unit 35 may include an indoor heat exchanger that cools or heats indoor air while the refrigerant exchanges heat with the indoor air. It may include a fan and an indoor expansion mechanism for expanding the refrigerant flowing toward the indoor heat exchanger. The indoor expansion mechanism may be an electronic expansion valve (EEV) that can control the flow rate of the refrigerant. The electromagnetic expansion valve may adjust the flow rate of the refrigerant through the opening degree control.

The distributor 20 includes a low pressure gas pipe 218, a liquid pipe 216, and a high pressure gas pipe 214.

The low pressure gas pipe 218 is connected to the outdoor unit 10 by the low pressure pipe 183, the liquid pipe 216 is connected to the outdoor unit 10 by the liquid pipe 182, the high pressure gas pipe ( 214 is connected to the outdoor unit 10 by a high-pressure engine 181.

The high pressure engine 181 is connected to the connection pipe 115 connecting the oil separators 113 and 114 and the switching valve 120.

The low pressure gas pipe 218, the liquid pipe 216, and the high pressure gas pipe 214 may be connected to the variable indoor units 31 to 33 by piping ports.

The distributor 20 may be connected to each of the variable indoor units 31 to 33 by an indoor engine 314 and an indoor liquid pipe 315. The indoor liquid pipe 315 connected to the variable indoor units 31 to 33 is connected to the common indoor liquid pipe 324, and the common indoor liquid pipe 324 is connected to the liquid pipe 216 of the distributor 20.

Each indoor engine 314 is provided with a high pressure valve 211 that controls the flow of refrigerant between the high pressure gas pipe 214 and each of the variable indoor units 31 to 33. A branch pipe 316 connected to the low pressure gas pipe 218 is connected to the indoor engine 314. The branch pipe 316 is provided with a low pressure valve 323 for controlling the flow of the refrigerant between the low pressure gas pipe 218 and the variable indoor units 31 to 33.

When the variable indoor units 31 to 33 are cooled and operated, the low pressure valve 212 may be opened and the high pressure valve 211 may be closed. On the other hand, when the variable indoor units 31 to 33 are heated and operated, the low pressure valve 212 may be closed and the high pressure valve 211 may be opened. In the present invention, the low pressure valve 212 and the high pressure valve 211 may be an electromagnetic expansion valve (EEV) of which the opening degree is linearly or stepwise adjusted.

On the other hand, the liquid pipe 182 is connected to the branch liquid pipe 341 connected to the cooling indoor unit 34. In addition, the low pressure engine 183 is connected to the branch low pressure engine 342 connected to the cooling indoor unit 34.

Some of the refrigerant of the liquid pipe 182 flows into the cooling only indoor unit 34 and evaporates, and the refrigerant evaporated from the cooling only indoor unit 34 passes through the branch low pressure engine 342 to the low pressure engine 342. Flow to

The high-pressure engine 181 is connected to the branch high-pressure engine 351 is connected to the heating-only indoor unit 35, the liquid pipe 182 is connected to the branch liquid pipe 352 is connected to the heating-only indoor unit (35). do.

Some of the refrigerant of the high-pressure engine 181 flows into the heating-only indoor unit 35 and condenses, and the refrigerant condensed in the heating-only indoor unit 35 passes through the branch liquid pipe 352 to the liquid pipe 182. Flow.

The high pressure gas pipe 214 and the low pressure gas pipe 218 may be connected and may be selectively communicated by the valve 219.

In the valve 219, the liquid refrigerant does not accumulate in the high pressure gas pipe 214 during the air conditioner operation, and the refrigerant in the high pressure gas pipe 214 passes through the low pressure gas pipe 218 to the outdoor unit 10. Can be opened to flow in

Hereinafter, the refrigerant flow in the multi-type air conditioner will be described.

First, a full heating room operation will be described. FIG. 1 shows, for example, a flow of a refrigerant during full heating room operation.

When all the variable indoor units 31 to 33 are operated in the heating mode, the low pressure valve 212 is closed and the high pressure valve 211 is opened. At this time, regardless of the operation mode of the variable indoor unit, the cooling only indoor unit 34 is cooled and the heating-only indoor unit 35 is heated.

The refrigerant compressed by the plurality of compressors 111 and 112 during the heating of the entire room flows from the connection pipe 115 to the high pressure engine 181 without passing through the switching valve 120. The refrigerant flowing along the high pressure engine 181 flows to the high pressure gas pipe 214.

The refrigerant flowing into the high pressure gas pipe 214 is sent to the indoor heat exchanger of each of the variable indoor units 31 to 33 through an indoor engine 314, and after passing through the indoor expansion mechanism without expansion after condensing in the indoor heat exchanger. One should. The refrigerant then flows from each of the variable indoor units 31 to 33 to the liquid pipe 216 of the distributor 20 through the indoor liquid pipe 315. The refrigerant flowing into the liquid pipe 216 is sent to the outdoor expansion mechanism of the outdoor unit 10 through the liquid pipe 182 to expand and then evaporated in the outdoor heat exchanger 140 before the switching valve 120. Passes through the plurality of compressors (111, 112).

Next, the operation of the heating main body is explained.

2 is a view showing a refrigerant flow during the heating main operation of the multi-type air conditioner according to the present invention.

2, for example, a refrigerant flow when the first and second variable indoor units 31 and 32 are operated in a heating mode and the third variable indoor unit 33 is operated in a cooling mode is illustrated.

During the operation of the heating main body, the low pressure valve 212 corresponding to the first and variable indoor units 31 and 32 operating in the heating mode is closed, and the high pressure valve 211 is opened. On the other hand, the low pressure valve 212 corresponding to the third variable indoor unit operating in the cooling mode is opened, and the high pressure valve 211 is closed.

The refrigerant compressed by the plurality of compressors 111 and 112 flows from the outdoor unit 10 to the high pressure gas pipe 214 of the distributor 20 through the high pressure engine 181 and is operated in a heating mode. It condenses in the indoor heat exchanger of the second variable indoor unit (31, 32). The condensed refrigerant passes through the indoor expansion mechanism without expansion, and the liquid pipe 216 of the distributor 20 is passed through the indoor liquid pipe 315 and the common indoor liquid pipe 324 in the first and second variable indoor units 31 and 32. Flows).

Some of the refrigerant flowing into the common indoor liquid pipe 324 flows to the indoor expansion mechanism of the third variable indoor unit 33 through the indoor liquid pipe connected to the third variable indoor unit 33 operating in the cooling mode and expands. The expanded refrigerant is evaporated in the indoor heat exchanger 511 of the third variable indoor unit 33 and then flows to the low pressure gas pipe 218 through the indoor engine, and then the plurality of compressors 111 through the low pressure engine 183. , 112).

The rest of the refrigerant flowing into the common indoor liquid pipe 324 is sent to the outdoor expansion mechanism of the outdoor unit 10 through the liquid pipe 216 and the liquid pipe 182 to expand and then evaporated in the outdoor heat exchanger 140 The plurality of compressors 111 and 112 flow through the switching valve 120.

3 is a control block diagram of the multi-type air conditioner of the present invention.

Referring to FIG. 3, the multi-type air conditioner includes a controller 160, a display unit 162 for displaying information, a memory 164 for storing information, a temperature sensor 166 for sensing temperature, and It may include an input unit 170 for inputting a command.

The control unit 160 may be composed of an indoor unit control unit installed in each indoor unit (31 to 35), an outdoor unit control unit installed in the outdoor unit 10, and a distributor control unit provided in the distributor 20, the outdoor unit 10 and the distributor It is also possible to comprise one control unit provided in one of the (20). Hereinafter, the controller 160 will be described as including an outdoor unit controller installed in the outdoor unit 10 and a distributor control unit installed in the distributor 20.

For example, the display unit 162 may be provided in the outdoor unit 10. The display unit 162 may display at least information of the variable indoor units 31 to 33 connected to the respective piping ports of the distributor and information of the dedicated indoor units 34 and 35 not connected to the distributor.

The input unit 170 may include a switch operated to check the information of the variable indoor units 31 to 33 connected to the respective piping ports of the distributor 20. The input unit 170 may be provided in an outdoor unit or a distributor.

The temperature sensing unit 166 may detect the temperature of the branch high pressure engine 351 connected to the indoor engine 314, the branch liquid pipe 341 connected to the cooling indoor unit 34, and the heating indoor unit 35. Can be. However, the branch liquid pipe 341 may be provided with an indoor expansion mechanism, and the temperature sensing unit 166 may detect a pipe temperature between the indoor expansion mechanism and an indoor heat exchanger of the heating-only indoor unit. Alternatively, the temperature detector 166 may detect the temperature of the branch low pressure engine 342.

The memory 164 may store at least the temperature sensed by the temperature detector 166 and information of a variable indoor unit and a dedicated indoor unit connected to respective piping ports of the distributor. The memory 164 may be provided in the outdoor unit or the distributor.

4 is a flowchart illustrating a pipe search method of a multi-type air conditioner according to an embodiment of the present invention.

2 to 4, the multi-type air conditioner is initially driven after installation, or when a pipe search is requested as a predetermined button provided in an outdoor unit or an indoor unit is operated, or when no matching data exists, the pipe search is performed. You can start

When the pipe search is started, the controller 160 controls the outdoor unit 10 to be heated. Then, the compression unit 110 is operated (S2).

In this case, all of the high pressure valve 211 and the low pressure valve 212 of the distributor 20 are closed. The opening degrees of the indoor expansion mechanisms 513 and 543 of the indoor units 51 to 57 are either fully open (opening degree 100) or maintained at a specific opening degree.

And, in each of the temperature sensing unit 166, the temperature of the branch high-pressure engine 351 connected to the indoor engine 514, the branch liquid pipe 341 connected to the cooling indoor unit 34, the heating-only indoor unit 35. The detected temperature is stored as an initial temperature in the memory 164 (S3). That is, at the beginning of the pipe search, the temperatures of the inlet-side pipes (or the refrigerant pipes constituting the indoor heat exchanger) of all the indoor units are sensed and stored in the memory at the initial temperature.

Then, the first high pressure valve 211 of the distributor 20 is opened (S4). When the first high pressure valve 211 is opened, since the high-temperature gas phase refrigerant flows into the variable indoor unit connected to the pipe port where the first high pressure valve 211 is installed, any one variable indoor unit is heated. In addition, when the compression unit 110 is operated, since the low-temperature expansion refrigerant passing through the branch liquid pipe 341 flows in, the cooling-only indoor unit flows, so that the cooling-only indoor unit is cooled. In addition, when the compressor 110 is operated, since the high-temperature gas phase refrigerant flows into the branch high pressure engine 351, the heating-only indoor unit is heated and operated.

When the first high pressure valve 211 is opened and a predetermined time elapses, the temperature of each pipe is sensed through the temperature sensor 166. The controller 160 finds an indoor unit having a temperature changed at an initial temperature, and stores information of the indoor unit having a temperature change in the memory 164 (S5). At this time, the indoor unit whose temperature is changed is a cooling indoor unit in which the temperature is lower than the initial temperature, a heating indoor unit in which the temperature is higher than the initial temperature, and any one variable indoor unit in which the temperature is higher than the initial temperature.

However, in the current state, it is not possible to distinguish between a heating-only indoor unit and a variable indoor unit. Therefore, in order to distinguish between the heating-only indoor unit and the variable indoor unit, the controller 160 closes the first high pressure valve 211 of the distributor 20 and opens the first low pressure valve 212 (S6).

When the first low pressure valve 212 is opened, any one of the variable indoor units connected to the pipe port in which the first low pressure valve 212 is installed is cooled, and thus the temperature of the pipe of the variable indoor unit decreases. Of course, even in this state, the heating-operated indoor unit is continuously heated and the cooling-only indoor unit is continuously cooled and operated, and the temperature of the piping of each dedicated indoor unit is hardly changed.

When the first low pressure valve 212 is opened and a predetermined time elapses, the temperature of each pipe is sensed through the temperature sensor 166. The controller 160 finds an indoor unit having a temperature changed at an initial temperature, and stores information of the indoor unit having a temperature change in a memory (S7). As another example, the controller 160 may find an indoor unit whose temperature is changed from a temperature stored in the memory to a reference temperature or more in step S5, and store information of the temperature-converted indoor unit in the memory.

Next, the controller 160 matches the variable indoor unit of the indoor unit having a temperature change to the first high pressure valve (first piping port) based on the temperature information stored in the memory 164. Specifically, since the control unit 160 maintains the temperature of the pipe of the cooling only indoor unit lower than the initial temperature, the control unit 160 may first search for the cooling only indoor unit.

Next, in the case of the pipe temperature of the heating indoor unit, the temperature is kept constant after rising from the initial temperature, but in the case of the temperature of the pipe of any one variable indoor unit is lowered after rising from the initial temperature. Therefore, the controller 160 determines that the indoor unit connected to the pipe maintaining the temperature is a heating-only indoor unit, and determines that the indoor unit connected to the pipe whose temperature is changed is the first variable indoor unit 211. Then, the determined first variable indoor unit 211 is matched to the first high pressure valve (first piping port).

When performing steps S4 to S8, since the search for the dedicated indoor unit and any one variable indoor unit is completed, steps S4 to S8 may be referred to as a dedicated indoor unit search step.

After the search for any one of the variable indoor units is completed in step S8, the controller 160 opens the Nth high-pressure valve to search for the variable indoor unit connected to the second piping port (however, N≥2 is satisfied).

Then, after the N-th high pressure valve is opened and the predetermined time has elapsed, the temperature sensing unit 166 detects a temperature, and the controller 160 matches the indoor unit having a temperature change to the N-th pipe port (S10).

In addition, the controller 160 determines whether the matching is completed for all piping ports of the distributor 20, and when not completed, performs matching of the variable indoor unit with respect to the next piping port (S7 to S8).

When matching of the variable indoor unit is completed in all the piping ports, matching data may be stored in the memory 164, and the matching data information may be displayed on the display unit 162.

In FIG. 7, for example, pipe search is performed after all outdoor units are heated and heated. Alternatively, pipe search may be performed after allowing outdoor units to be cooled.

According to the present invention, by alternately performing the heating operation and the cooling operation of a specific variable indoor unit connected to the distributor, through the search process of the dedicated indoor unit, it is possible to search not only the variable indoor unit connected to the distributor but also the dedicated indoor unit not connected to the distributor. have.

10: outdoor unit 20: distributor
31, 32, 33: variable indoor unit 34, 35: dedicated indoor unit

Claims (8)

Outdoor unit,
A distributor connected to the outdoor unit and having a plurality of piping ports;
A plurality of variable indoor units connected to the distributor,
A dedicated indoor unit connected to a branch pipe branched from a pipe connecting the outdoor unit and the distributor, and cooled or heated;
A high pressure valve corresponding to each piping port and controlling a refrigerant flow of the variable indoor unit corresponding to each piping port;
A multi-type air conditioner corresponding to each of the piping ports and provided in a branch pipe branched from a pipe connecting the variable indoor unit and the high pressure valve corresponding to each of the piping ports to control a refrigerant flow of the variable indoor unit includes a multi-type air conditioner. In the pipe search method of the machine,
Searching for one of the variable indoor units and the dedicated indoor unit by controlling a refrigerant flow of a pipe connected to any one of a plurality of pipe ports; And
After completion of the search for the dedicated indoor unit, searching for pipes of the remaining variable indoor units among the plurality of variable indoor units connected to the distributor,
The step of searching for one of the variable indoor unit and the dedicated indoor unit, after opening any one of the high pressure valve and the low pressure valve corresponding to the one pipe port for a predetermined time to change the temperature of the pipe connected to the dedicated indoor unit and each variable indoor unit. Sensing and distinguishing the dedicated indoor unit and any one variable indoor unit from the other variable indoor unit; And
Detecting the temperature change of the pipe connected to the dedicated indoor unit and any one variable indoor unit after opening the other one time to distinguish the dedicated indoor unit from the variable indoor unit; Way. The method of claim 1,
In the searching of the variable indoor unit and the dedicated indoor unit,
Turning on the compressor and closing the high pressure valve and the low pressure valve of the distributor; And
Determining an initial temperature of a pipe connected to each indoor unit;
The temperature change of the pipe, the pipe search method of the multi-type air conditioner is determined by comparing the initial temperature and the temperature of the pipe detected after the opening of the high pressure valve or the low pressure valve. The method of claim 2,
In the searching of the variable indoor unit and the dedicated indoor unit,
After a certain time after the opening of the first high pressure valve corresponding to the one pipe port, the temperature of the pipe of the dedicated indoor unit and the pipe temperature of the variable indoor unit are sensed, and the information of the indoor unit of which the temperature is changed at the initial temperature is detected. Pipe search method of the multi-type air conditioner comprising the step of storing in the memory. The method of claim 3, wherein
The searching of the variable indoor unit and the dedicated indoor unit may include:
Opening a first low pressure valve corresponding to one of the pipe ports; And
Detecting a temperature of a pipe of the dedicated indoor unit and a pipe temperature of the variable indoor unit after a predetermined time after the first low pressure valve is opened, and storing information of the indoor unit whose temperature is changed at the initial temperature in a memory; Piping search method of a multi-type air conditioner. The method of claim 4, wherein
Regardless of the type of valve being opened, the pipe temperature of the dedicated indoor unit is kept constant,
The piping search method of the multi-type air conditioner of which the piping temperature of the said variable indoor unit varies according to the kind of valve opened. The method of claim 1,
In the step of searching for piping of the remaining variable indoor unit,
A pipe search method of a multi-type air conditioner in which one of the high pressure valve and the low pressure valve corresponding to each pipe port is sequentially opened for a predetermined time, and the pipe is detected by detecting the temperature of the pipe connected to each pipe port. delete Outdoor unit;
A distributor connected to the outdoor unit and having a plurality of piping ports;
A plurality of variable indoor units connected to the distributor;
A dedicated indoor unit connected to a branch pipe branched from a pipe connecting the outdoor unit and the distributor, and configured to be cooled or heated;
A temperature sensing unit sensing a temperature of a pipe connected to each of the plurality of variable indoor units and the dedicated indoor unit; And
It includes a control unit for searching for the indoor unit based on the temperature information detected by the temperature sensor,
The distributor includes a number of high pressure valves and low pressure valves corresponding to each pipe port,
The control unit turns on the compressor and closes both the high pressure valve and the low pressure valve,
The temperature detection unit, detects the initial temperature of the pipes connected to each indoor unit,
The control unit opens one of the high pressure valve and the low pressure valve corresponding to any one of the plurality of piping ports for a predetermined time, and the temperature of the pipe connected to each indoor unit detected by the temperature sensing unit and the initial temperature. Compare the dedicated indoor unit and any one variable indoor unit with the other variable indoor unit,
The other one is opened for a predetermined time, by detecting the temperature and the initial temperature of the pipe connected to each indoor unit detected by the temperature sensing unit to distinguish between the dedicated indoor unit and the one variable indoor unit,
The multi-type air conditioner, wherein the indoor unit in which the pipe temperature is kept constant regardless of opening and closing of the high pressure valve and the low pressure valve after the opening of the one is determined as the dedicated indoor unit.

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