JP2003329291A - Air conditioning system and exterior unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To smooth communication and to eliminate the need of providing a command control unit in each refrigerant system by linking between the respective exterior units. <P>SOLUTION: In this air conditioning system 1, two or more systems of air conditioners 10, 20 are installed, and exterior units 11 to 13 and interior units 14, 15, 23 are connected through a communication line 17. The exterior unit 11 out of two or more exterior units 11 to 13, 21, 22 is functioned as a representative exterior unit, and the representative exterior unit 11 performs communication with the interior units 14, 15, 23 through a network as a representative of the exterior units. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioning system and an outdoor unit, and more particularly, a plurality of air conditioning units each having an outdoor unit and an indoor unit to constitute one refrigerant circulation system are installed. The present invention relates to an air conditioning system and an outdoor unit in which machines are connected to each other via a network.

[0002]

2. Description of the Related Art In an air conditioning system in which a plurality of air conditioning apparatuses each having an outdoor unit and an indoor unit and constituting one refrigerant circulation system are installed, the outdoor unit and the indoor unit are connected to each other via a network. There was something that was done. In such an air conditioning system, each outdoor unit controls the indoor unit in the refrigerant circulation system to which the outdoor unit belongs by using a network.

When constructing the air conditioning system as described above in a building, the network of the air conditioning system is constituted by a single transmission line in order to facilitate the construction.

The actual communication management is performed by a command control unit (CCU) provided for each refrigerant system.
Was going by.

[0005]

Therefore, in each of the outdoor units, if communication is attempted simultaneously with the indoor units of the corresponding refrigerant circulation system, there is a possibility that collision will occur due to collision of communication data. was there.

Particularly when constructing a large-scale air conditioning system, the probability of collision is high, and there is a possibility that communication cannot be performed smoothly.

Further, in the above conventional air conditioning system, it is necessary to provide a command control unit for each refrigerant system, which causes a problem that installation labor and installation cost increase.

[0008] Therefore, an object of the present invention is to provide an air conditioning system and an outdoor unit in which communication can be smoothly performed, cooperation between the outdoor units is achieved, and a command control unit need not be provided.

[0009]

In order to solve the above-mentioned problems, a plurality of air conditioners, each having an outdoor unit and an indoor unit and constituting one refrigerant circulation system, are installed, and the outdoor unit and the indoor unit are networked. In the air conditioning system connected via, any one of the plurality of outdoor units functions as a representative outdoor unit, and the representative outdoor unit represents all of the outdoor units via the network. It is characterized by performing communication with the indoor unit.

According to the above configuration, one of the plurality of outdoor units constituting the air conditioning system functions as the representative outdoor unit, and the representative outdoor unit represents the outdoor unit and is the indoor unit via the network. Communication with the machine.

In this case, the representative outdoor unit may control another outdoor unit based on communication performed with the indoor unit on behalf of the outdoor unit.

Further, all the outdoor units may receive the communication data in order to share the communication data transmitted from the plurality of indoor units to the representative outdoor unit.

Further, an outdoor unit address for specifying each outdoor unit is assigned to all the outdoor units,
A system address corresponding to the refrigerant circulation system may be assigned to at least a part of the outdoor units of all the outdoor units.

Further, the representative outdoor unit is in an abnormal setting state when there is an address duplication determination unit that determines the duplication of the outdoor unit address in all the outdoor units and the outdoor unit address duplication. An address abnormality notifying unit for notifying the user may be provided.

Furthermore, each of the outdoor units is in an abnormal setting state when there is an address duplication determination unit that determines the duplication of the outdoor unit addresses in all of the outdoor units and the outdoor unit address duplication. An address abnormality notifying unit for notifying that there is an address may be provided.

When the outdoor unit functioning as the representative outdoor unit cannot function as the representative outdoor unit, any one of the other outdoor units is selected as a new representative outdoor unit. You may do it.

Further, when the outdoor units communicate with each other, the outdoor unit address may be used for the communication.

Furthermore, a device that communicates with any of the outdoor units or any of the indoor units via the network may specify the communication partner using the outdoor unit address and the system address. .

In addition, a plurality of air conditioners that form a refrigerant circulation system including an indoor unit are installed, and the outdoor unit that constitutes an air conditioning system in which the air conditioners are connected via a network is the air conditioner. It is characterized in that it functions as a representative outdoor unit that communicates with the indoor unit via the network on behalf of all the outdoor units in cooperation with other outdoor units constituting the harmony system.

According to the above structure, the outdoor unit functions as a representative outdoor unit that cooperates with other outdoor units and communicates with the indoor units via the network on behalf of all the outdoor units.

[0021] Further, a plurality of air conditioners including an indoor unit that constitute a refrigerant circulation system are installed, and the outdoor unit that constitutes an air conditioner in which the air conditioners are connected via a network is the air conditioner. In order to share the communication data transmitted to the representative outdoor unit that communicates with the indoor unit via the network on behalf of all the outdoor units configuring the harmony system, the communication data is received. It has a feature.

According to the above configuration, the outdoor unit represents communication data to be transmitted to the representative outdoor unit that communicates with the indoor unit via the network on behalf of all the outdoor units constituting the air conditioning system. Receive communication data for sharing.

In addition, an outdoor unit that constitutes an air conditioning system in which a plurality of air conditioning units that constitute a refrigerant circulation system including an indoor unit are installed and the air conditioning units are connected via a network is the outdoor unit. An outdoor unit address for identifying a machine and a system address corresponding to the refrigerant circulation system are assigned.

In this case, an address duplication discriminating section for discriminating whether or not the combination of the refrigerant system address and the device address in the outdoor unit overlaps with the combination of the refrigerant system address and the device address of another outdoor unit. If there is an overlap, an address abnormality notification unit that notifies that the setting is abnormal may be provided.

In addition, a plurality of air conditioners that form a refrigerant circulation system including an indoor unit are installed, and an outdoor unit that constitutes an air conditioner system in which the air conditioners are connected via a network is One of the outdoor units that constitutes the air conditioning system is selected as the representative outdoor unit together with the other outdoor units that configure the conditioning system.

[0026]

BEST MODE FOR CARRYING OUT THE INVENTION Next, a preferred embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a system diagram of the air conditioning system of the embodiment.

The air conditioning system 1 is roughly classified into the first
The air conditioner 10 of the second refrigerant system and the air conditioner 20 of the second refrigerant system are provided.

The air conditioner 10 roughly includes a first outdoor unit 11, a second outdoor unit 12, a third outdoor unit 13, a first indoor unit 14, and a second indoor unit 15. Here, the first indoor unit 14 is provided with a remote controller 16.

The air conditioner 20 is roughly provided with a fourth outdoor unit 21, a fifth outdoor unit 22, and a third indoor unit 23.

In this case, the first outdoor unit 11 and the second outdoor unit 11
Outdoor unit 12, third outdoor unit 13, fourth outdoor unit 21, fifth outdoor unit 22, first indoor unit 14, second indoor unit 15, and third
The indoor unit 23 has a single data communication line (transmission path) 17
Are connected to each other, and a network is built in the air conditioning system 1.

Further, the first outdoor unit 11, the second outdoor unit 12,
Third outdoor unit 13, first indoor unit 14, and second indoor unit 15
Are connected to each other by a refrigerant pipe 18-1 (gas pipe and liquid pipe).

Further, the fourth outdoor unit 21, the fifth outdoor unit 22 and the third indoor unit 23 are connected to each other by a refrigerant pipe 18-2 (gas pipe and liquid pipe).

If necessary, the air conditioning system 1 is connected to an inspection device 30 composed of a personal computer or the like.

Prior to the description of the operation of the embodiment, address allocation for identifying each outdoor unit, each indoor unit or remote controller during communication will be described.

FIG. 2 is an explanatory diagram of an example of address allocation in the air conditioning system 1.

In this case, each address is represented by 8 bits, and these 8 bits are represented by upper 4 bits and lower 4 bits. In addition, the address is a system address representing the refrigerant system and each device (outdoor unit,
Indoor unit, remote controller, inspection device, etc.).

In the following description, for simplification of description, it is assumed that the maximum number of outdoor units installed is 15 for each system, and the maximum number of indoor units and other devices installed is 16 for each system. To do.

Specifically, the system address representing the first refrigerant system is "00" and the system address representing the second refrigerant system is "01". Further, "01" to "0F" can be assigned as the device address of the outdoor unit, "10 to 1F" can be assigned as the device address of the indoor unit, and "10" to 1F "can be assigned as the device address of the remote controller. 40 "~
It is assumed that "4F" can be assigned and that "70" to "7F" can be assigned as the device address of the inspection device.

Address allocation under the above conditions is shown in FIG. 2, and in FIG.
In the notation "-YY", "XX" represents a system address and "YY" represents a device address.

That is, the assigned address of each device is as follows.

First outdoor unit 11: System address = “00”, device address = “01” Second outdoor unit 12: System address = “00”, device address = “02” Third outdoor unit 13: System address = "00", device address = "03" First indoor unit 14: System address = "00", device address = "10" Second indoor unit 15: System address = "00", device address = "11" Remote control 16 : System address = "00", device address = "40" Fourth outdoor unit 21: System address = "01", device address = "01" Fifth outdoor unit 22: System address = "01", device address = " 02 ”Third indoor unit 23: System address =“ 01 ”, device address =“ 10 ”Fourth indoor unit 24: System address =“ 01 ”, device address =“ 11 ”Inspection device 30: System A Les = "00", described device address = "70" then the data format of the communication data.

FIG. 3 shows an example of the data format of communication data. Although a header and the like are actually added, they are omitted for simplification of description.

The communication data 40 roughly includes transmission source address data 41, transit destination address data 44, transmission destination address data 47, transmission data 50, and error check data 51.

The source address data 41 is address data for identifying the source device of the communication data 40, and includes source system address data 42 and source device address data 43.

The transit destination address data 44 is address data for specifying the transit destination device when the communication data 40 is transmitted, and includes transit destination system address data 45 and transit destination device address data 46.

The destination address data 47 is address data for specifying the destination device of the communication data 40, and includes destination system address data 48 and destination device address data 49.

The transmission data 50 is data to be transmitted from the transmission source to the transmission destination, such as various communication control data, command data indicating the control content for the transmission destination device, size data indicating the data amount of the communication data 40, etc. Contains various data.

The error check data 51 is data added when necessary for ensuring communication reliability, and includes, for example, a frame check code for performing a frame error check in the transmission destination device. .

Next, the operation of the embodiment will be described. In the following description, in the initial state, the first outdoor unit 1
The description will be made assuming that 1 is the representative outdoor unit.

First, the operation during normal operation will be described. During this normal operation, in principle, the representative outdoor unit manages communication with each indoor unit.

In FIG. 4, the remote controller 16 provided in the first indoor unit 14 is the first outdoor unit 1 which is a representative outdoor unit.
FIG. 3 is an explanatory diagram of communication data in the case of performing communication with 1 for instructing driving, stopping, etc.

The remote controller 16 generates the communication data 40A based on the operation content corresponding to the user's operation.

Specifically, the remote controller 16
Sets, as the source address data 41, the source system address data 42 = “00” and the source device address data 43 = “40” corresponding to the remote controller 16 that is the source.

Next, the remote controller 16 sets, as the transit destination address data 44, the transit destination system address data 45 = "00" and the transit destination device address data 46 = "10" corresponding to the first indoor unit which is the transit destination. Set.

Further, the remote controller 16 uses, as the transmission destination address data 47, the transmission destination system address data 48 = “00” corresponding to the representative outdoor unit that is the transmission destination.
The destination device address data 49 = “00” is set.
At this time, as the remote controller 16, which of the outdoor units the actual representative outdoor unit is (in this case, the first outdoor unit 1
It is not necessary to recognize whether it is 1), but simply set the transmission address data 47 for specifying the representative outdoor unit.

Then, the remote controller 16 sets the transmission data 50 according to the operation contents of the user, and sets the error check data 51 corresponding to the communication data as necessary.

When the setting of the communication data 40A is completed, the remote controller 16 transmits the communication data 40A to the first indoor unit 14 via the data communication line 17.

The first indoor unit 1 which has received the communication data 40A
4 refers to the destination address data 47 and transfers the communication data 40A to the representative outdoor unit via the data communication line 17.

As a result, all the outdoor units 11 to 13, 2
1 and 22 will receive the communication data 40A from the first indoor unit 14, but by referring to the destination address data 47, the first and second units functioning as the representative outdoor unit
Other outdoor units 12, 13, 21, 22 excluding the outdoor unit 11
Does not perform control because it is not the communication data transmitted to itself, and only stores the content as necessary.

On the other hand, when the received communication data 40A includes the error check data 51, the first outdoor unit 11 performs the error check of the communication data 40A based on the error check data and the transmission data 50. The first indoor unit 14 and the second indoor unit 1 corresponding to the user's operation content on the remote controller 16 with reference to FIG.
Control of one or a plurality of indoor units to be controlled among the 5 or the third indoor units 23 and the outdoor unit to be controlled is performed via the data communication line 17.

Similarly, the first indoor unit 14 and the second indoor unit 1
When the communication data is transmitted from the fifth indoor unit 23 or the third indoor unit 23 to the representative outdoor unit, the first outdoor unit 11 performs control corresponding to the communication data.

Further, the first functioning as a representative outdoor unit
The outdoor unit 11 performs regular communication and state change report communication with each of the indoor units 14, 15, 23 using the system address and the device address. For these communications, other outdoor units 1
2, 13, 21, and 22 also receive the communication data, store the contents thereof, and share the control contents. This is, for example,
The first outdoor unit 11 functioning as a representative outdoor unit has failed,
This is to enable any one of the other outdoor units 12, 13, 21, and 22 to immediately function as the representative outdoor unit when it becomes inoperable due to inspection or the like. In this case, the other outdoor units 12, 1
3, 21 and 22 are first units that function as representative outdoor units.
When it is detected that communication with the outdoor unit 11 cannot be performed for a predetermined time or longer, a new representative outdoor unit is selected. As a method of selection, for example, a method of selecting the outdoor unit having the smallest system address and the smallest device address as the representative outdoor unit can be considered. More specifically, when the outdoor unit having the smallest system address value and the smallest device address value is selected as the representative outdoor unit, the second outdoor unit 12 is selected as the new representative outdoor unit. The Rukoto.

Furthermore, all the outdoor units 11 to 13, 21, and 22 including the representative outdoor unit function as an address duplication determination section, and when the air conditioning system 1 is constructed or the configuration of the air conditioning system 1 is changed (apparatus). For every device that constitutes the air conditioning system 1 when a new power supply is turned on again after a temporary power-off for inspection, etc., there is a device having the same system address and device address. Or not.

A concrete method for determining the address duplication will be described later. Further, all of the outdoor units 11 to 13, 21, and 22 including the representative outdoor unit function as an address abnormality notification unit, and when it is detected that duplicate settings have been made, an alarm lamp, an alarm display to that effect is displayed, The operator will be notified by a warning voice.

FIG. 5 is an explanatory diagram of communication data when the inspection device 30 is connected to the inspection terminal of the second indoor unit 15 and the communication for performing the inspection of the fourth outdoor unit 21 is performed.

The inspection device 30 generates the communication data 40B based on the operation content corresponding to the operation of the operator.

Specifically, the inspection device 30 uses, as the transmission source address data 41, the inspection device 30 that is the transmission source.
Source system address data 42 = “00” corresponding to
The source device address data 43 = “70” is set.

Next, the inspection device 30 uses, as the transit destination address data 44, the transit destination system address data 45 = "00" and the transit destination device address data 46 = "" corresponding to the second indoor unit 15 to which the inspection device 30 is connected. 11 ”is set.

Further, the inspection device 30 sets the transmission destination system address data 48 = "01" and the transmission destination device address data 49 = "01" as the transmission destination address data 47 corresponding to the fourth outdoor unit 21 to be inspected. Set.

Then, the inspection device 30 sets the inspection transmission data 50 according to the inspection purpose (operation content) of the operator, and sets the error check data 51 corresponding to the communication data as necessary.

When the setting of the communication data 40B is completed, the inspection device 30 stores the communication data 40B in the second indoor unit 15.
To send.

The second indoor unit 1 which has received the communication data 40B
5 refers to the destination address data 47 and transfers the communication data 40B to the fourth outdoor unit 21.

As a result, all the outdoor units 11-13, 2
1 and 22 will receive the communication data 40B from the second indoor unit 15, but by referring to the destination address data 47, the other outdoor units 11 to 13 except the corresponding fourth outdoor unit 21. , 22 do not perform control because they are not the communication data transmitted to themselves, and discard the data.

On the other hand, when the received communication data 40B includes the error check data 51, the fourth outdoor unit 21 performs an error check on the communication data 40A based on the error check data and sends the transmission data 50. The report data is generated in accordance with the inspection purpose of the operator in the inspection device 30, and the operating state and the like are notified to the inspection device 30 via the second indoor unit 15.

Here, a specific method of address duplication determination will be described with reference to FIG.

FIG. 6 is an explanatory diagram of an example of address allocation in the air conditioning system 1A.

In this case, the method of assigning each address is the same as that described with reference to FIG.
System address representing the first refrigerant system corresponding to 0 = "0
0 ”, and the system address representing the second refrigerant system corresponding to the air conditioner 20 =“ 01 ”, and the air conditioner 30
System address representing the third refrigerant system corresponding to “= 0
2 ".

In this case, the air conditioner 10 and the air conditioner 20 each have a plurality of outdoor units and indoor units connected to the same refrigerant system. On the other hand, in the air conditioner 30, one outdoor unit and one indoor unit are connected to the same refrigerant system. Then, the address is actually assigned as shown in FIG. In FIG. 6, as in FIG. 2, the notation [XX-YY]
“XX” represents a system address, and “YY” represents a device address.

That is, the assigned address of each device is as follows. Air conditioner 10 First outdoor unit 11: System address = "00", device address = "01" Second outdoor unit 12: System address = "00", device address = "02" Third outdoor unit 13: System address = "00", device address = "03" First indoor unit 14: System address = "00", device address = "10" Second indoor unit 15: System address = "00", device address = "11" Remote control 16: System address = "00", device address = "40" Air conditioner 20 Fourth outdoor unit 21: System address = "01", Device address = "01" Fifth outdoor unit 22: System address = "01" , Device address = "02" third indoor unit 23: system address = "01", device address = "10" fourth indoor unit 24: system address = "01", device address = "11" Air conditioner 30 Sixth outdoor unit 31: System address = "02", device address = "none" Fifth indoor unit 32: System address = "02", device address = "10" In this case, the outdoor unit and the indoor unit Air conditioner 10 in which a plurality of machines are connected to the same refrigerant system
In the air conditioner 20, first, duplicate confirmation of device addresses within the same refrigerant system, that is, within the same system address is performed.

Specifically, in the air conditioner 10, the first outdoor unit 11, the second outdoor unit 12, the third outdoor unit 1
3, first indoor unit 14, second indoor unit 15 and remote control 1
Device address corresponding to each of 6 = “01”, “0”
2 "," 03 "," 10 "," 11 ", and" 40 "are compared to determine the duplication of the device address (outdoor unit address, indoor unit address, etc.). In this case, it is determined that the device addresses do not overlap.

Next, in the air conditioner 20, the device address = “01” corresponding to each of the fourth outdoor unit 21, the fifth outdoor unit 22, the third indoor unit 23, and the fourth indoor unit 24,
"02", "10" and "11" are compared to determine the duplication of the device address (outdoor unit address or indoor unit address). In this case, it is determined that the device addresses do not overlap.

In the air conditioner 30, the device address corresponding to each of the sixth outdoor unit 31 and the fifth indoor unit 32 = “10” and “none” are compared, and the device address (outdoor unit address or indoor unit It is determined that there is no device address duplication in this case as well.

Subsequently, the first outdoor unit 1 constituting the air conditioner 10, the air conditioner 20 and the air conditioner 30.
1, second outdoor unit 12, third outdoor unit 13, first indoor unit 1
4, second indoor unit 15, fourth outdoor unit 21, fifth outdoor unit 2
2, third indoor unit 23, fourth indoor unit 24, fourth outdoor unit 2
1, 5th outdoor unit 22, 3rd indoor unit 23, 4th indoor unit 24
System address corresponding to each of "00", "0"
"0", "00", "00", "00", "01", "0"
The duplication of "1", "01", "01", "02", and "02" is determined.

As a result, the first outdoor unit 11, the second outdoor unit 12, the third outdoor unit 13, and the first outdoor unit 11 which compose the air conditioner 10.
In the indoor unit 14 and the second indoor unit 15, it is determined that the system address = “00” is duplicated. However, regarding these, it is determined that there was no duplication of the device address previously performed. Therefore, it is determined that there is no duplication of the system address and the device address.

Similarly, the fourth component of the air conditioner 20
In the outdoor unit 21, the fifth outdoor unit 22, the third indoor unit 23, and the fourth indoor unit 24, it is determined that the system address = “01” is duplicated. Since it is determined that there is no duplication of the device address performed, it is determined that there is no duplication of the system address and the device address.

Further, in the sixth outdoor unit 31 and the fifth indoor unit 32 which compose the air conditioner 30, it is determined that the system address = “02” is duplicated. Since it is determined that there is no duplication of the device address, the system address and the device address are determined to have not overlapped.

Therefore, in the case of the above-described example, it is determined that the system address and the device address do not overlap in the air conditioning system 1A as a whole.

As described above, according to this embodiment, it is not necessary to provide the control command unit for each refrigerant system, so that the system construction cost can be reduced and the system construction period can be shortened.

Further, when viewed from the indoor unit side, it is equivalent to a plurality of outdoor units functioning as one outdoor unit through the representative outdoor unit, so that it is possible to reduce traffic in the network. The load of can be reduced.

Further, even when the outdoor unit selected as the representative outdoor unit fails to function as the representative outdoor unit due to failure or leveling of operating time, the other outdoor units are operated in the same manner as the immediately preceding representative outdoor unit. Since the data for controlling the indoor unit is stored, any of the outdoor units can immediately function as the representative outdoor unit, and backup control at the time of failure can be easily realized.

In the above description, the case where all the devices communicate using the system address data and the device address data has been described, but some devices other than the outdoor unit are used in the conventional air conditioning system. In the case where only the device address data is used, if the representative outdoor unit functions as the outdoor unit of the refrigerant system to which the device belongs, the same application is possible. For example,
The remote controller 16 and the inspection device 30 operate without any problem even with only the device address data.

In the above description, the air-conditioning system in which the common refrigerant pipe 18 is composed of the gas pipe and the liquid pipe has been described, but a so-called 3 way system capable of selectively performing either cooling or heating for each indoor unit. The same can be applied to the common refrigerant pipe composed of a high-temperature high-pressure gas pipe (for heating), a low-temperature low-pressure gas pipe (for cooling), and a medium-temperature medium-pressure liquid pipe (common for heating / cooling). Is.

[0094]

According to the present invention, it is possible to smoothly communicate through a network while coordinating a plurality of outdoor units, and it is not necessary to provide a command control unit. Further, the redundancy of the air conditioning system becomes high, and the backup control can be easily realized even when any one of the devices fails.

[Brief description of drawings]

FIG. 1 is a system diagram of an air conditioning system of an embodiment.

FIG. 2 is an explanatory diagram of an example of address allocation in the air conditioning system 1.

FIG. 3 is an example of a data format of communication data.

FIG. 4 is an explanatory diagram of communication data when the remote controller provided in the first indoor unit communicates with the representative outdoor unit.

FIG. 5 is an explanatory diagram of communication data when the inspection device connected to the second indoor unit communicates with the fourth outdoor unit.

FIG. 6 is an explanatory diagram for determining address duplication.

[Explanation of symbols]

1 Air Conditioning System 10 Air Conditioning Device of First Refrigerant System 11 First Outdoor Unit (Representative Outdoor Unit, Address Duplication Discrimination Unit,
Address abnormality notification unit) 12 Second outdoor unit (address duplication determination unit, address abnormality notification unit) 13 Third outdoor unit (address duplication determination unit, address abnormality notification unit) 14 First indoor unit 15 Second indoor unit 16 Remote controller 20 Air Conditioner for Second Refrigerant System 21 Fourth Outdoor Unit (Address Duplication Discrimination Unit, Address Abnormality Notification Unit) 22 Fifth Outdoor Unit (Address Duplication Discrimination Unit, Address Abnormality Notification Unit) 23 Third Indoor Unit 30 Inspection Device 40, 40A, 40B Communication data 41 Source address data 42 Source system address data 43 Source device address data 44 Transit destination address data 45 Transit destination system address data 46 Transit destination device address data 47 Transmission destination address data 48 Transmission destination system Address data 49 Destination device address data 50 Transmission data 51 Error Ekkudeta

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Claims (14)

[Claims] 1. An air conditioning system in which a plurality of air conditioners, each of which comprises an outdoor unit and an indoor unit and constitutes one refrigerant circulation system, are installed, and wherein the outdoor unit and the indoor unit are connected via a network, Any one of the plurality of outdoor units functions as a representative outdoor unit, and the representative outdoor unit represents the outdoor unit and performs communication with the indoor unit via the network. A characteristic air conditioning system. 2. The air conditioning system according to claim 1, wherein the representative outdoor unit controls another outdoor unit based on communication performed with the indoor unit on behalf of the outdoor unit. Air conditioning system characterized by. 3. The air conditioning system according to claim 1, wherein all the outdoor units share the communication data so as to share the communication data transmitted from the plurality of indoor units to the representative outdoor unit. An air conditioning system characterized by receiving. 4. The air conditioning system according to claim 1, wherein all the outdoor units are assigned an outdoor unit address for identifying each outdoor unit, A system address corresponding to the refrigerant circulation system is assigned to at least a part of the outdoor units of the outdoor unit. 5. The air conditioning system according to claim 4, wherein the representative outdoor unit has an address duplication determining unit that determines duplication of the outdoor unit address in all the outdoor units, and the outdoor unit address does not overlap. The air conditioning system is characterized by having an address abnormality notifying unit that notifies that the setting is abnormal. 6. The air conditioning system according to claim 4, wherein each of the outdoor units has an address duplication determination unit that determines duplication of the outdoor unit address in all the outdoor units, and the outdoor unit address does not overlap. The air conditioning system is characterized by having an address abnormality notifying unit that notifies that the setting is abnormal. 7. The air conditioning system according to claim 1, wherein, when the outdoor unit functioning as the representative outdoor unit cannot function as the representative outdoor unit, any one of the other outdoor units. An air conditioning system characterized by selecting one outdoor unit as a new representative outdoor unit. 8. The air conditioning system according to claim 2, wherein when the outdoor units communicate with each other, the outdoor unit addresses are used for communication. 9. The air conditioning system according to claim 1, wherein the device that communicates with any of the outdoor units or any of the indoor units via the network is the outdoor unit address. An air conditioning system characterized in that a communication partner is specified using the system address. 10. An outdoor unit that constitutes an air conditioning system in which a plurality of air conditioning devices that constitute a refrigerant circulation system including an indoor unit are installed, and the air conditioning devices are connected via a network, An outdoor unit that functions as a representative outdoor unit that communicates with the indoor unit via the network on behalf of all the outdoor units in cooperation with other outdoor units that form a harmony system. . 11. An outdoor unit that constitutes an air conditioning system in which a plurality of air conditioning devices that constitute a refrigerant circulation system including an indoor unit are installed, and the air conditioning devices are connected via a network, In order to share the communication data transmitted to the representative outdoor unit that communicates with the indoor unit via the network on behalf of all the outdoor units constituting the harmony system,
An outdoor unit that receives the communication data. 12. An outdoor unit that constitutes an air conditioning system in which a plurality of air conditioning devices that constitute a refrigerant circulation system including an indoor unit are installed, and the air conditioning devices are connected via a network, An outdoor unit, wherein an outdoor unit address for identifying a unit and a system address corresponding to the refrigerant circulation system are assigned. 13. The outdoor unit according to claim 12, wherein it is determined whether or not a combination of a refrigerant system address and a device address in the outdoor unit overlaps with a combination of a refrigerant system address and a device address of another outdoor unit. An outdoor unit, comprising: an address duplication determination unit; and an address abnormality notification unit that notifies a setting abnormality state when the duplication occurs. 14. An outdoor unit that constitutes an air conditioning system in which a plurality of air conditioning devices that constitute a refrigerant circulation system including an indoor unit are installed, and the air conditioning devices are connected via a network. An outdoor unit characterized by selecting, as a representative outdoor unit, one of the outdoor units constituting the air conditioning system together with other outdoor units constituting the harmony system.