KR101140704B1 - A multi air conditioner system and pipe search method - Google Patents

Abstract

The present invention relates to a multi air conditioner system and a pipe search method, and an object of the present invention is to provide a multi air conditioner system and a pipe search method that can quickly find a refrigerant pipe connected to each indoor unit in a multi air conditioner system.

To this end, the present invention provides an outdoor unit, a plurality of indoor units connected to the outdoor unit, a plurality of indoor units coupled to each of the indoor units to supply the refrigerant delivered from the outdoor unit to the plurality of indoor units or to send the refrigerant discharged from the indoor unit to the outdoor unit. In a pipe search method of a multi-air conditioner system having a refrigerant pipe, a refrigerant flows through a refrigerant pipe having different refrigerant flow characteristics set for each refrigerant pipe while driving a compressor, and measures a temperature change pattern of each indoor unit. The indoor unit having a temperature change pattern associated with the flow characteristics is identified to find an indoor unit connected to the plurality of refrigerant pipes.

Description

A air conditioner system and pipe search method             

1 is a view showing a refrigerant passage of a multi-air conditioner system according to an embodiment of the present invention.

FIG. 2 is a block diagram showing the components of the multi-air conditioner system shown in FIG.

3 is a flowchart illustrating a pipe search operation of the multi-air conditioner system shown in FIG.

[Description of the Reference Numerals]

          10: outdoor unit 20a to 20d: first to fourth indoor

30a, 30b: 1st and 2nd air conditioning switch 31a-21d: 1st-4th heating valve

32a to 32d: first to fourth cooling valves 35a to 35d: first to fourth refrigerant piping

36a to 36d: first to fourth indoor microcomputers 37a to 37d: first to fourth temperature sensors

38a, 38b: First and second air conditioning converter microcomputer

The present invention relates to a multi air conditioner system and a pipe search method, and more particularly, to a multi air conditioner system and a pipe search method for searching an indoor unit coupled to a plurality of pipes installed between the indoor unit and the outdoor unit to move the refrigerant.

In general, the multi-air conditioner system includes an outdoor unit, a plurality of indoor units connected in parallel to the outdoor unit, a communication line connecting the outdoor unit and the indoor unit, a power line and a refrigerant pipe, and an electric valve installed in the refrigerant pipe.

In the conventional multi-air conditioner system, when the first system is installed, the installer connects the outdoor unit and the plurality of indoor units with communication lines, power lines, and refrigerant pipes, and the refrigerant pipes and the indoor units to be connected to each refrigerant pipe have a plurality of indoor units. There was a problem that can not easily find whether the refrigerant pipe is connected.

In order to solve this problem, a method of finding an indoor unit connected to a plurality of refrigerant pipes after the installation of the multi-air conditioner system has been proposed. The initial pipe search method of the multi-air conditioner system is disclosed in detail in Korean Patent Publication No. 10-0382504. .

In the conventional multi-air conditioner system, all the electric valves installed in a plurality of refrigerant pipes are opened while the compressor is driven to find a pipe connected to each indoor unit, and then each electric valve is sequentially closed for a predetermined time and then opened again. The inflection point of was measured. In addition, when the inflection point of the indoor unit piping temperature is measured and the maximum inflection point is confirmed, the signal according to the inflection point is stored in the indoor unit at each time interval and transmitted to the outdoor unit to check the connection relationship between the indoor unit and the refrigerant piping in the outdoor unit, and the number determined in each indoor unit. Was given.

However, since the conventional multi-air conditioner system detects a temperature change of the indoor unit pipe while closing and opening a plurality of electric valves sequentially, there is a problem in that the pipe search takes much time when the number of indoor units connected to the outdoor unit increases.

The present invention is to solve the above problems, an object of the present invention to provide a multi-air conditioning system and a pipe search method that can quickly find the refrigerant pipe connected to each indoor unit in a multi-air conditioning system.

According to an aspect of the present invention, a plurality of indoor units connected to the outdoor unit, a plurality of indoor units connected to the outdoor unit, and a plurality of indoor units may be supplied with the refrigerant delivered from the outdoor unit or the refrigerant discharged from the indoor unit may be sent to the outdoor unit. A plurality of refrigerant pipes coupled to each indoor unit, the flow of the plurality of refrigerant pipes are adjusted, a plurality of cooling valves that are opened when the plurality of indoor units is a cooling operation and a plurality of heating is opened when the plurality of indoor units is a heating operation In a pipe search method of a multi-air conditioner system having a heating and cooling diverter having a valve, while driving a compressor, some of the plurality of refrigerant pipes allow the cooling valves to be opened for different periods of time, and the other refrigerant pipes are connected to the heating valves. Open for different time through the refrigerant pipe The refrigerant is flowed by the refrigerant flow characteristics set differently for each refrigerant pipe, the temperature change pattern of each indoor unit is measured, and the indoor unit connected to the plurality of refrigerant pipes is identified by checking the indoor unit showing the temperature change pattern associated with the refrigerant flow characteristic. It is characterized by finding.

In addition, the refrigerant flow characteristic is a refrigerant flow time, the refrigerant pipe is characterized in that the refrigerant control valve for controlling the flow of the refrigerant is installed.

In addition, the process of flowing the refrigerant is characterized in that is made together in the plurality of refrigerant pipes.

In addition, the refrigerant flow time is characterized in that by controlling the opening and closing time different for each refrigerant control valve.

Also, in the plurality of refrigerant control valves installed in the plurality of refrigerant pipes, the opening time of the refrigerant control valve installed in the n (n is a natural number) th refrigerant pipe is 1/2 of the opening time of the refrigerant control valve installed in the n-1 th refrigerant pipe. It is set to be, wherein the temperature change pattern is characterized in that the temperature change amount per unit time of the indoor unit piping.

In addition, the larger the temperature change amount of the indoor unit is determined that the indoor unit is connected to the refrigerant pipe with a longer refrigerant flow time, and the smaller the temperature change amount of the indoor unit is determined that the indoor unit is connected to the refrigerant pipe with a smaller refrigerant flow time. It features.

Another object of the present invention is to supply an outdoor unit, a plurality of indoor units connected to the outdoor unit, a refrigerant delivered from the outdoor unit to the plurality of indoor units, or to send the refrigerant discharged from the indoor unit to the outdoor unit. A plurality of refrigerant pipes coupled to each of the plurality of indoor units, the flow of the plurality of refrigerant pipes are adjusted, a plurality of cooling valves to be opened when the plurality of indoor units is a cooling operation and a plurality of openings when the plurality of indoor units is a heating operation In a pipe search method of a multi-air conditioner system having a heating and cooling converter having a heating valve, the serial numbers are assigned to the plurality of refrigerant pipes, temporary addresses are set in the plurality of indoor units, and the compressors are operated while driving a compressor. Some refrigerant piping to open the cooling valve for different times In the remaining refrigerant pipe, the heating valve is opened for different times to allow refrigerant to flow for different refrigerant flow times for each refrigerant pipe through the refrigerant pipe, measure the temperature change pattern of each indoor unit pipe, and measure the refrigerant flow time. Check the temporary address of the indoor unit showing the associated temperature change pattern to find the indoor unit connected to each refrigerant pipe. If the serial number of the refrigerant pipe and the size order of the indoor unit temporary address connected to each refrigerant pipe do not match, the temporary address of the indoor unit is It is characterized in that the reset to match the size order of the serial number.

Another object of the present invention is to supply an outdoor unit, a plurality of indoor units connected to the outdoor unit, a refrigerant delivered from the outdoor unit to the plurality of indoor units, or to send the refrigerant discharged from the indoor unit to the outdoor unit. A plurality of refrigerant pipes coupled to each of the plurality of indoor units, the flow of the plurality of refrigerant pipes are adjusted, a plurality of cooling valves to be opened when the plurality of indoor units is a cooling operation and a plurality of openings when the plurality of indoor units is a heating operation In a pipe search method of a multi-air conditioner system having a heating and cooling converter having a heating valve, some refrigerant pipes of the plurality of refrigerant pipes are different for each refrigerant pipe by controlling the plurality of cooling valves for cooling operation of the indoor unit. The refrigerant flows for the set refrigerant flow time, and the remaining refrigerant pipe is the indoor Through the control of the plurality of heating valves for the heating operation of the air flow to the refrigerant during the refrigerant flow time set differently for each indoor unit, measuring the temperature change pattern of each indoor unit pipe, the temperature change pattern associated with the refrigerant flow time By checking the indoor unit is shown is characterized in that to find the indoor unit connected to the plurality of refrigerant pipes.

In addition, the refrigerant for the cooling operation of the indoor unit is a cooling valve of the heating and cooling converter to open the flow to the indoor unit, the refrigerant for the heating operation of the indoor unit is characterized in that the heating valve of the cooling and heating converter to flow to the indoor unit. do.

In addition, the opening time of the cooling valve installed in the n (n is natural water) th refrigerant pipe among the refrigerant pipes supplying the refrigerant for the cooling operation is set to be 1/2 of the opening time of the cooling valve installed in the n-1 th refrigerant pipe. The opening time of the heating valve installed in the n (n is a natural number) refrigerant pipe among the refrigerant pipes supplying the refrigerant for the heating operation is 1/2 of the opening time of the heating valve installed in the n-1 th refrigerant pipe. It is characterized by setting to.

Another object of the present invention for achieving the above object is a plurality of indoor units connected to an outdoor unit, a plurality of refrigerant pipes for supplying the refrigerant delivered from the outdoor unit to the indoor unit or the refrigerant discharged from the indoor unit to the outdoor unit, the plurality of A cooling and heating diverter having a plurality of cooling valves which regulate the flow of the refrigerant pipe of the plurality of indoor units and open when the plurality of indoor units are in the cooling operation, and a plurality of heating valves which are open when the plurality of indoor units are in the heating operation, and the piping temperature of the indoor unit. A plurality of temperature sensors for measuring the temperature, some of the plurality of refrigerant pipes in the refrigerant pipe to open the cooling valve for a different time, and the remaining refrigerant pipe to open the heating valve for a different time refrigerant set differently for each refrigerant pipe Flowing refrigerant during the flow time is associated with the refrigerant flow time It characterized in that it comprises a control unit for identifying the indoor unit showing the temperature change pattern to find the indoor unit connected to the plurality of refrigerant pipes.

According to yet another aspect of the present invention, a plurality of indoor units connected to an outdoor unit, a plurality of refrigerant pipes supplying the refrigerant delivered from the outdoor unit to the indoor unit, or a refrigerant pipe discharged from the indoor unit to the outdoor unit, the refrigerant A heating and cooling converter for controlling the flow of the pipe, the air conditioner having a plurality of cooling valves to be opened when the indoor unit is in the cooling operation and a plurality of heating valves to be opened when the indoor unit is in the heating operation, a plurality of temperatures for measuring the pipe temperature of the indoor unit And a sensor, wherein the cooling and heating converter is configured to open the cooling valve for a different time in some refrigerant pipes of the plurality of refrigerant pipes, and to open the heating valve for different time in the remaining refrigerant pipes. Check the indoor unit showing the associated temperature change pattern and the plurality of cold It characterized by a control unit to find the indoor unit connected to the pipe.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. As shown in FIG. 1, the multi-air conditioner system according to an exemplary embodiment of the present invention includes an outdoor unit 10, a plurality of indoor units 20a, 20b, 20c, and 20d connected in parallel to the outdoor unit 10, and each indoor unit 20a and 20b. And heating and cooling converters 30a and 30b for converting the operation mode of 20c and 20d into a cooling operation mode or a heating operation mode.

The outdoor unit 10 includes a four-way valve 12 that determines a flow direction of the refrigerant discharged from the compressor 11, an outdoor heat exchanger 13 that performs heat exchange by outdoor air introduced into the outdoor unit 10, and a refrigerant. An outdoor electric valve 14 to expand, a receiver tank 15 and an accumulator 16 for separating gaseous and liquid refrigerant from each other are provided.

The plurality of indoor units 20a, 20b, 20c, and 20d are indoor heat exchangers 21a, 21b, 21c, and 21d, and indoor electric valves 22a, 22b, which are connected in series with the indoor heat exchangers 21a, 21b, 21c, and 21d. 22c and 22d, and each indoor unit (20a, 20b, 20c, 20d) and the outdoor unit 10 deliver the refrigerant through the high pressure gas pipe 17, the low pressure gas pipe 18 and the high pressure liquid pipe 19. .

The heating and cooling diverters 30a and 30b are the first to fourth heating valves 31a, 31b and 31c installed in the first to fourth high pressure gas distributors 33a, 33, 33c and 33d branched from the high pressure gas pipe 17, respectively. 31d) and the first to fourth cooling valves 32a, 32b, 32c, and 32d installed in the first to fourth low pressure gas distributors 34a, 34b, 34c, and 34d branched from the low pressure gas pipe 18. . In addition, the first heating valve 31a and the first cooling valve 32a are connected to the first refrigerant pipe 35a connected to the first indoor heat exchanger 20a and the second to fourth heating valves 31b and 31c. And 31d) and the cooling valves 32b, 32c, and 32d are sequentially connected to the second to fourth refrigerant pipes 35b, 35c, and 35d.                     

On the other hand, in the outdoor unit 10, the low pressure gas pipe 18 is connected to the suction side of the compressor 11 through the accumulator 16, the outdoor heat exchanger 13 and the outdoor electric valve 14 is connected in series, The high pressure liquid pipe 19 is connected to an outdoor transmission valve 14 via a receiver tank 15. In addition, a bypass valve 21a functioning as a flow regulating valve is connected to the outdoor electric valve 14 in parallel with the check valve 21b, and the liquid refrigerant from the outdoor heat exchanger 13 is bypass valve at the time of cooling operation. Through the check valve 21b and the check valve 21b, the outdoor electric valve 14 can be bypassed. In the heating operation, the bypass valve 21a is closed so that the refrigerant can pass through the outdoor electric valve 14. Make sure

Between the four-way valve 12 and the high-pressure liquid pipe 19, there is a high-pressure branch pipe 22 branched from the high-pressure gas pipe 17, the high-pressure branch pipe 22, the solenoid valve 23a that functions as an open / close valve and a high pressure The check valve 23b which prevents the backflow of the refrigerant from the gas pipe 22 side is provided. In addition, another check valve 24 is provided between the four-way valve 12 and the high pressure liquid pipe 19 to prevent the backflow of the refrigerant.

During the operation of the cooling main body of such a multi-air conditioner system (operation in which the number of indoor units that operate in the cooling operation in the entire indoor unit is larger than the number of indoor units that heat operation), the first and second ports 12A, 12B of the four-way valve 12 And the third and fourth ports 12C and 12D are connected to each other, and at the same time, the solenoid valve 23a of the high-pressure branch pipe 22 is opened. In addition, the heating valve is connected to the indoor unit that is air-cooled in the cooling and heating converters (30a, 30) is closed at the same time the cooling valve is opened, on the contrary, the heating valve is connected to the indoor unit is heated at the same time the air-conditioning valve is closed.                     

Accordingly, the refrigerant discharged from the compressor 11 is condensed by the outdoor heat exchanger 13 via the first and second ports 12A and 12B of the four-way valve 12, and the outdoor electric valve 14 as a high pressure liquid refrigerant. The air is supplied to the indoor unit for cooling operation through the high pressure liquid pipe 19, and the air is decompressed in the indoor electric valve to evaporate in the indoor heat exchanger to cool the room. The refrigerant passing through the indoor heat exchanger is circulated to the suction side of the compressor (11) through the low pressure gas pipe (18) and the accumulator (16) via the cooling valves of the air conditioning and heating converters (30a, 30b).

A part of the refrigerant discharged from the compressor 11 and passing through the four-way valve 12 is sent to the high-pressure gas pipe 17 through the high-pressure branch pipe 22 and is heated indoors through the heating valves of the air-conditioning converters 30a and 30b. And condensed in an indoor heat exchanger to heat the room. The refrigerant passing through the heat exchanger of the indoor unit for heating operation is supplied to the high pressure liquid pipe (19) through the indoor electric valve and joined with the refrigerant supplied to the indoor unit for cooling operation to provide cooling, and then to the compressor (11) through the low pressure gas pipe (18). Circulated.

On the other hand, during the operation of the heating main body (operation in which the number of the indoor units heating operation of the entire indoor unit is larger than the number of indoor units cooling operation), the first and third ports 12A, 12C of the four-way valve 12 and the second and second The four ports 12B and 12D are connected to each other, and the solenoid valve 23a of the high pressure branch pipe 22 is closed. In addition, on the indoor unit side, the heating valve associated with the indoor unit that is heated in the same manner as the cooling main body operation is opened and the cooling valve is closed at the same time. On the contrary, the heating valve associated with the indoor unit being cooled is closed and the cooling valve is opened at the same time.

Therefore, the refrigerant discharged from the compressor 11 is supplied to the high-pressure gas pipe 17 through the check valve 24 through the first and third ports 12A and 12C of the four-way valve 12, and the cold heating converter 30a. It is supplied to the indoor heat exchanger of the indoor unit to heat the heating operation of the heating valve of (30b) and condensed to heat the room, and is sent to the high pressure liquid pipe (19) through the indoor electric valve. Some of the refrigerant sent to the high pressure liquid pipe 19 is supplied to the indoor unit for cooling operation and evaporated in the indoor heat exchanger to be used for cooling the room, and passes through the accumulator 16 through the low pressure gas pipe 18 connected to the indoor heat exchanger. It is circulated to the suction side of (11).

In addition, the remaining refrigerant sent to the high pressure liquid pipe 19 may be returned to the outdoor unit 10 and circulated to the compressor 11 via the receiver tank 15 and the outdoor electric valve 14.

When the number of the cooling operation and the heating operation among the plurality of indoor units 20a, 20b, 20c, and 20d are the same, it is determined whether to perform the heating main operation or the cooling main operation according to the outdoor temperature. For example, if the outdoor temperature is higher than the reference temperature, the cooling subject operation may be performed. If the outdoor temperature is lower than the reference temperature, the heating subject operation may be performed. Here, the reference temperature may be set in consideration of the characteristics of the system, or an appropriate value may be selected by experiment.

However, the refrigerant does not flow in the high pressure branch pipe 22 and the low pressure gas pipe 18 in the heating main operation when the number of indoor units to be heated and cooled is the same.

As shown in FIG. 2, in the multi-air conditioner system according to the exemplary embodiment of the present invention, the outdoor unit 10 includes an outdoor unit microcomputer 26 for controlling each device of the outdoor unit 10 in addition to the apparatus shown in FIG. It further includes an outside temperature sensor 25 for measuring.

In addition, the first and fourth indoor units 20a, 20b, 20c, and 20d measure the first to fourth indoor microcomputers 36a, 36b, 36c, and 36d that control the devices of each indoor unit, and the pipe temperature of each indoor unit. It further comprises a first to fourth temperature sensors (37a, 37b, 37c, 37d).

In addition, the first heating and cooling diverter 30a further includes a first cooling and heating diverter microcomputer 38a for controlling the first to second cooling valves 32a and 32b and the first to second heating valves 31a and 31b. The second cooling and heating converter 30b further includes a second cooling and heating converter microcomputer 38b for controlling the third to fourth cooling valves 32c and 32d and the third to fourth heating valves 31c and 31d.

Referring to Fig. 3, the pipe search operation of the multi-air conditioner system shown in Figs. 1 and 2 will be described. Initially, the system is initialized to check the indoor unit connected to the first to fourth refrigerant pipes 35a, 35b, 35c, and 35d. After initialization of the system, the outdoor unit micom 26 sets a temporary address to each indoor unit micom 36a, 36b, 36c, 36d through data communication with each indoor unit micom 36a, 36b, 36c, 36d. In addition, the first and second air-conditioning converters microcomputers 38a and 38b identify the number of indoor units connected to each of the air-conditioning converters 30a and 30b. In the present embodiment, since the first and second indoor units 20a and 20b are connected to the first air conditioning converter 30a, and the third and fourth indoor units 20c and 20d are connected to the second air conditioning converter 30b. Heating and cooling converter micom (38a, 38b) confirms that the two indoor units are connected.

The outdoor unit microcomputer 26 receives the outdoor temperature measured by the outdoor air temperature sensor 25 and determines whether to operate the main air conditioner system (ie, to operate the cooling main body or the heating main body) of the multi-air conditioning system according to the outdoor temperature. (52).

When the main operation mode of the system is determined, the outdoor unit microcomputer 26 controls the compressor 11 to be driven, and appropriately controls the opening degree of the outdoor electric valve 14 (54). Further, the first to fourth indoor microcomputers 36a, 36b, 36c, and 36d also adjust the opening degree of the first to fourth indoor motorized edges 22a, 22b, 22c, and 22d.

Next, the first cooling and heating converter microcomputer 38a turns on / off the first cooling valve 32a according to a predetermined opening and closing cycle (for example, opening for T / 2 and closing for T / 2). The two cooling valves 32b are turned on / off at a period different from the opening and closing cycles of the first cooling valve 32a (for example, opening for T / 4 and closing for 3T / 4).

The second cooling / heating converter micom 38a turns the third heating valve 31c on / off according to a preset opening and closing cycle (for example, opening for T / 2 and closing for T / 2), and for the fourth heating valve 31c. The valve 31d is turned on / off (56, 58) at a cycle different from the opening and closing cycle of the third heating valve 31c (for example, opening for T / 4 and closing for 3T / 4).

As described above, the indoor units 20a and 20b connected to the first air conditioning converter 30a operate in the cooling mode by opening the first and second cooling valves 32a and 32b, and the indoor units connected to the second air conditioning converter 30b. 20c and 20d open the third and fourth heating valves 31c and 31d to operate in the heating mode so that the temperature change patterns to be described later are easily distinguished for each indoor unit.

That is, the operation mode of the indoor unit connected to the air conditioners 30a and 30b as described above than the temperature change pattern of each indoor unit measured while operating the indoor units connected to the first and second air conditioner units 30a and 30b in the same operation mode. By differently measuring the temperature change pattern of each indoor unit, it is easy to grasp the temperature change characteristic of each indoor unit.

In addition, in the present embodiment, the indoor unit connected to the first cooling and heating converter 30a was operated in the cooling mode and the indoor unit connected to the second cooling and heating converter 30b in the heating mode, but the indoor unit connected to the first cooling and heating converter 30a was reversed. The indoor unit connected to the heating mode and the second cooling and heating converter 30b may be operated in the cooling mode.

However, it is not necessary to operate the indoor units belonging to the first air conditioning converter 30a and the second air conditioning converter 30b in different operation modes, and to measure the temperature change pattern of the indoor units while operating the entire indoor unit in the same operation mode. It may be. If all the indoor units are operated in the same operation mode and the temperature change pattern of the indoor unit is measured, the cooling / heating converters 30a and 30b of FIGS. 1 and 2 are not necessary, and only the refrigerant control valve is connected to the refrigerant pipe connecting the outdoor unit and indoor unit. It can also be applied to installed systems.

When the first and second cooling valves 32a and 32b and the third and fourth heating valves 31c and 31d are opened and closed at predetermined intervals, and a predetermined time elapses, the first to fourth temperature sensors provided in each indoor unit ( Temperature change patterns of the indoor units 20a, 20b, 20c, and 20d are measured through 37a, 37b, 37c, and 37d (60). In this embodiment, the temperature change pattern is a temperature change amount per unit time.

When the temperature change patterns of the indoor units 20a, 20b, 20c, and 20d are detected, the first and second indoor microcomputers 20a and 20b transmit data about the temperature change pattern through the data communication to the first air-conditioning telephone microcomputer 38a. The third and fourth indoor microcomputers 20c and 20d transmit data about the temperature change pattern to the second air conditioning converter microcomputer 38b.

The first heating and cooling converter microcomputer 38a analyzes the temperature change patterns transmitted from the first and second indoor microcomputers 20a and 20b to identify temporary addresses of the indoor units connected to the first and second refrigerant pipes 35a and 35b. (62). That is, since the opening time of the first cooling valve 32a and the second cooling valve 32b is different, the temperature change amount per unit time of the indoor unit connected to the first and second refrigerant pipes 35a and 35b is different, and the temperature change amount is The indoor unit connected to each of the refrigerant pipes 35a and 35b is identified in association with the opening times of the first and second cooling valves 32a and 32b.

For example, if the opening time of the first cooling valve 32a is twice the opening time of the second cooling valve 32b, the amount of temperature change per unit time of the indoor unit connected to the first refrigerant pipe 35a is the second refrigerant pipe 35b. When the temperature change per unit time measured in each indoor unit is transmitted to the first air conditioning converter micom 38a together with the temporary address of each indoor unit, the first air conditioner micom 38a is 2. It is determined that an indoor unit having a large temperature change among the two indoor units is connected to the first refrigerant pipe 35a, and that an indoor unit having a small temperature change among the two indoor units is connected to the second refrigerant pipe 35b. In addition, since the temporary address was transmitted together with the temperature change of each indoor unit, the temporary address of the indoor unit connected to each of the refrigerant pipes 35a and 35b can be known.

The second cooling and heating converter micom 38b also checks the temporary addresses of the indoor units connected to the third and fourth refrigerant pipes 35c and 35d in the same manner as the first cooling and heating converter micom 38a.

Next, the first and second air-conditioning converters microcomputers 38a and 38b are provided in order of the number sizes of the first to fourth refrigerant pipes 35a, 35b, 35c, and 35d, and to the refrigerant pipes 35a, 35b, 35c, and 35d. Check if the temporary address size order of the connected indoor unit is identical (64).

Refrigerant Piping Number Indoor unit address (case1) Indoor unit address (Case2) One One 2 → 1 2 2 1 → 2 3 3 4 → 3 4 4 3 → 4

In case of Case 1 in the above table, the larger the refrigerant piping number, the larger the indoor unit address. Therefore, the order of the size of the refrigerant piping and the size of the indoor unit address connected to each refrigerant piping are identical. However, in case 2, the number of refrigerant pipes and the order of the indoor unit addresses connected to the refrigerant pipes are different.

The first and second air-conditioning converters microcomputers 38a and 38b determine the temporary address of the indoor unit as the address of the indoor unit when the size order of the refrigerant pipes and the size order of the indoor units connected to each refrigerant pipe as shown in Case 1 match (70). ). However, if the size sequence of the refrigerant pipe and the indoor unit connected to each refrigerant pipe do not match as shown in Case 2, the temporary address of the indoor unit connected to the refrigerant pipes 35a and 35c having the low pipe number as shown in the above table is low. The temporary address of the indoor unit connected to the refrigerant pipes 35b and 35d having the high pipe number is reset to a high address (66). Then, the set address of the indoor unit is determined (68).

As described above, when the indoor units connected to the first to fourth refrigerant pipes 35a, 35b, 35c, and 35d are identified, and the addresses of the indoor units are determined, the first and second air conditioning converter micoms 38a and 38b are the first to the third. 4 Cooling valves 32a, 32b, 32c, and 32c and heating valves 31a, 31b, 31c, and 31d can be controlled to appropriately control the refrigerant flow of each indoor unit.

Although the present embodiment exemplifies a multi-air conditioner system having only two air-conditioning converters 30a and 30b, the present invention can be applied to a multi-air conditioner system having two or more air-conditioning converters. In this case, the process of searching for pipes is performed two by one out of a plurality of air-conditioning converters.

 As described above in detail, according to the present invention, it is possible to quickly find a plurality of indoor units connected to the plurality of refrigerant pipes.

Claims (12)

A plurality of refrigerant pipes coupled to each of the plurality of indoor units to supply an outdoor unit, a plurality of indoor units connected to the outdoor unit, the refrigerant delivered from the outdoor unit to the plurality of indoor units or to send the refrigerant discharged from the indoor unit to the outdoor unit, the plurality of refrigerant pipes To control the flow of the refrigerant pipe of the multi-air conditioner system having a plurality of air conditioning valves having a plurality of cooling valves opened when the plurality of indoor units is a cooling operation and a plurality of heating valves opening when the plurality of indoor units is a heating operation. In the pipe search method, While driving a compressor, some refrigerant pipes of the plurality of refrigerant pipes may be configured to open the cooling valves for different times, and in the other refrigerant pipes, the heating valves may be opened for different periods of time to be set differently for each refrigerant pipe through the refrigerant pipes. Refrigerant flow characteristics allow the refrigerant to flow, Measure the temperature change pattern of each indoor unit, Identifying the indoor unit showing the temperature change pattern associated with the refrigerant flow characteristics to find the indoor unit connected to the plurality of refrigerant pipes, the pipe search method of the multi air conditioning system The method of claim 1, The refrigerant flow characteristic is a refrigerant flow time, and the pipe search method of the multi-air conditioner system, characterized in that the refrigerant control valve is installed in the refrigerant pipe to control the flow of the refrigerant is installed. 3. The method of claim 2, The process of flowing the refrigerant is a pipe search method of the multi-air conditioner system, characterized in that is made in the plurality of refrigerant pipes together. The method of claim 3, The refrigerant flow time is a pipe search method of the multi-air conditioning system, characterized in that for controlling by varying the opening and closing time for each refrigerant control valve The method of claim 3, In the plurality of refrigerant control valves installed in the plurality of refrigerant pipes, the opening time of the refrigerant control valve installed in the n (n is a natural number) refrigerant pipe is 1/2 of the opening time of the refrigerant control valve installed in the n-1 th refrigerant pipe. The temperature change pattern is set so as to, the pipe search method of the multi-air conditioning system, characterized in that the temperature change per unit time of the indoor unit piping The method of claim 5, The larger the temperature change amount of the indoor unit is determined that the indoor unit is connected to the refrigerant pipe with a longer refrigerant flow time, and the smaller the temperature change amount of the indoor unit is determined that the indoor unit is connected to the refrigerant pipe with a smaller refrigerant flow time. Pipe search method of multi-air conditioner system A plurality of refrigerant pipes coupled to each of the plurality of indoor units to supply an outdoor unit, a plurality of indoor units connected to the outdoor unit, the refrigerant delivered from the outdoor unit to the plurality of indoor units or to send the refrigerant discharged from the indoor unit to the outdoor unit, the plurality of refrigerant pipes To control the flow of the refrigerant pipe of the multi-air conditioner system having a plurality of air conditioning valves having a plurality of cooling valves opened when the plurality of indoor units is a cooling operation and a plurality of heating valves opening when the plurality of indoor units is a heating operation. In the pipe search method, Assign a serial number to the plurality of refrigerant pipes and set temporary addresses to the plurality of indoor units, While driving a compressor, some refrigerant pipes of the plurality of refrigerant pipes allow the cooling valves to be opened for different times, and in the other refrigerant pipes, the heating valves are opened for different periods of time, and different refrigerants are different for each refrigerant pipe through the refrigerant pipes. The refrigerant flows during the flow time, Measure the temperature change pattern of each indoor unit pipe, Finding the indoor unit connected to each refrigerant pipe by checking the temporary address of the indoor unit showing the temperature change pattern associated with the refrigerant flow time, If the serial numbers of the refrigerant pipes and the temporary order of the indoor unit temporary addresses connected to each refrigerant pipe do not match, the temporary address of the indoor unit is reset to match the size order of the serial numbers. delete delete delete delete delete

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