JP2007010198A - Air conditioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent operation of an air conditioner from being affected by communication failure in general-purpose network, while enjoying the benefits by internal communication of the air conditioner through the general-purpose network. <P>SOLUTION: This air conditioning system comprises the air conditioner and control means 11, 13, 21, 23, 26. The air conditioner has first communicating portions 14-16, 24, 25 and second communicating portions 14-16, 24, 25. The second communicating portions 14-16, 24, 25 communicate with the first communicating portions 14-16, 24, 25 through the general-purpose network 1. The control means 11, 13, 21, 23, 26 control the air conditioner under consideration of quality of service (QoS) of the general-purpose network 1. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an air conditioning system, and more particularly, to an air conditioning system including an air conditioner that internally communicates via a general-purpose network.

As the air conditioner, there is a separate type air conditioner having an outdoor unit and an indoor unit. In addition, a central management device that centrally manages outdoor units and indoor units may be connected to the outdoor units and indoor units. Thus, when a plurality of devices constitute one air conditioner, the plurality of devices cooperate with each other while exchanging control data with each other, thereby air-conditioning a predetermined space as a whole. Such internal communication of the air conditioner is often performed via a dedicated line. However, as disclosed in Patent Document 1, it may be performed via a general-purpose network such as a local area network (hereinafter referred to as LAN). In Patent Document 1, by sharing wiring between an air conditioner and an OA device such as a personal computer (hereinafter referred to as a PC), the installation work of the air conditioner can be simplified by reducing the number of wires, or the air conditioner can be easily managed. It is possible to do.
JP 2004-3852 A

  However, when the air conditioner internally communicates via a general-purpose network such as a LAN, it is a device connected to the general-purpose network and other than the devices constituting the air-conditioner as compared to the case where internal communication is performed via a dedicated line. Due to the influence of other devices, congestion easily occurs in the network. In such a case, a communication failure easily occurs in the network, and the communication failure that occurs in the network affects the internal communication of the air conditioner, and as a result, the normal operation of the air conditioner may be hindered.

  The subject of this invention is suppressing the influence which the communication failure in a general purpose network exerts on the operation | movement of an air conditioner, enjoying the benefit by which the internal communication of an air conditioner is made via a general purpose network.

  The air conditioning system according to the first invention includes an air conditioner and control means. The air conditioner includes a first communication unit and a second communication unit. The second communication unit communicates with the first communication unit via a general-purpose network. The control means controls the air conditioner in consideration of the quality of service (QoS) of the general-purpose network. The “general-purpose network” means a network that can connect not only the devices configuring the air-conditioning apparatus but also devices other than the devices configuring the air-conditioning apparatus, that is, a general-purpose network.

  In this air conditioning system, communication between the first communication unit and the second communication unit of the air conditioner, that is, internal communication of the air conditioner is performed via a general-purpose network. Furthermore, in this air conditioning system, the service quality of the general-purpose network is taken into account when the air conditioner is controlled. Thereby, the influence which the communication failure in a general purpose network exerts on the operation | movement of an air conditioner can be suppressed, enjoying the benefit by which the internal communication of an air conditioner is made via a general purpose network.

The air conditioning system according to the second invention is the air conditioning system according to the first invention, wherein the control means secures a communication band for communication between the first communication unit and the second communication unit in the general-purpose network. .
In this air conditioning system, a communication band for internal communication of the air conditioner is secured in the general-purpose network. Thereby, in this air conditioning system, the service quality about the internal communication of an air conditioner is maintained. Therefore, it becomes easy to avoid the occurrence of an abnormality in the operation of the air conditioner due to an abnormality in the internal communication of the air conditioner.

An air conditioning system according to a third aspect is the air conditioning system according to the second aspect, wherein the control means preferentially transfers data transmitted and received between the first communication unit and the second communication unit in the general-purpose network. To do.
In this air conditioning system, data internally communicated in the air conditioner is preferentially transferred in the general-purpose network. This makes it possible to secure a communication band for internal communication of the air conditioner.

  An air conditioning system according to a fourth aspect is the air conditioning system according to the third aspect, wherein the control means defines a plurality of cues. A priority is assigned to each of the plurality of queues. The control means stores data transferred via the general-purpose network in any one of a plurality of queues. Data transmitted / received between the first communication unit and the second communication unit is stored in a queue having a high assigned priority among a plurality of queues. The control means schedules a plurality of queues according to the assigned priority.

  In this air conditioning system, a plurality of queues are defined, and data transferred via the general-purpose network is stored in one of the plurality of queues. A priority is assigned to each of the plurality of queues. At this time, among the data transferred through the general-purpose network, data that is internally communicated in the air conditioner is stored in a queue having a high priority. Further, in this air conditioning system, a plurality of queues are scheduled according to the assigned priority. Thereby, it is possible to preferentially transfer data internally communicated in the air conditioner within the general-purpose network.

An air conditioning system according to a fifth aspect of the present invention is the air conditioning system according to the first aspect of the present invention, wherein the control means measures the service quality of the general-purpose network and is used for operation control of the air conditioner based on the measured service quality. Correct the parameters.
In this air conditioning system, the service quality of the general-purpose network is measured, and parameters used for operation control of the air conditioner are corrected based on the measured service quality. As a result, even when the service quality of the general-purpose network deteriorates, it is possible to control the operation of the air conditioner more safely, etc., and to prevent abnormalities in the operation of the air conditioner due to abnormal internal communication of the air conditioner Easy to do.

  In the air conditioning system according to the first aspect of the invention, communication between the first communication unit and the second communication unit of the air conditioner, that is, internal communication of the air conditioner is performed via a general-purpose network. Furthermore, in this air conditioning system, the service quality of the general-purpose network is taken into account when the air conditioner is controlled. Thereby, the influence which the communication failure in a general purpose network exerts on the operation | movement of an air conditioner can be suppressed, enjoying the benefit by which the internal communication of an air conditioner is made via a general purpose network.

In the air conditioning system according to the second aspect of the invention, a communication band for internal communication of the air conditioner is secured in the general-purpose network. Thereby, in this air conditioning system, the service quality about the internal communication of an air conditioner is maintained. Therefore, it becomes easy to avoid the occurrence of an abnormality in the operation of the air conditioner due to an abnormality in the internal communication of the air conditioner.
In the air conditioning system according to the third aspect of the invention, data internally communicated in the air conditioner is preferentially transferred in the general-purpose network. This makes it possible to secure a communication band for internal communication of the air conditioner.

  In the air conditioning system according to the fourth aspect of the present invention, a plurality of queues are defined, and data transferred via the general-purpose network is stored in any of the plurality of queues. A priority is assigned to each of the plurality of queues. At this time, among the data transferred through the general-purpose network, data that is internally communicated in the air conditioner is stored in a queue having a high priority. Further, in this air conditioning system, a plurality of queues are scheduled according to the assigned priority. Thereby, it is possible to preferentially transfer data internally communicated in the air conditioner within the general-purpose network.

  In the air conditioning system according to the fifth aspect of the invention, the service quality of the general-purpose network is measured, and the parameters used for operation control of the air conditioner are corrected based on the measured service quality. As a result, even when the service quality of the general-purpose network deteriorates, it is possible to control the operation of the air conditioner more safely, etc., and to prevent abnormalities in the operation of the air conditioner due to abnormal internal communication of the air conditioner Easy to do.

Hereinafter, an air conditioning system according to the present invention will be described with reference to the drawings.
FIG. 1 shows a local area network (hereinafter, LAN) 1 in which an air conditioning system according to the present invention is introduced. The LAN 1 is a network compliant with Ethernet (registered trademark) and includes a first segment 10 and a second segment 20. The first segment 10 and the second segment 20 are connected to each other via a first router 11 and a second router 21 included therein. The first segment 10 is connected to the Internet 30 via the first router 11, and the second router 21 is connected to the Internet 30 via the second segment 20.

The air conditioning system according to the present invention includes air conditioners 14 to 16, 24, and 25 and devices 11, 13, 21, 23, and 26 that control the operations of the air conditioners 14 to 16, 24, and 25.
(First segment)
The first segment 10 includes devices 11 to 17. The first router 11 has ports P13c and P21, and is connected to the first QoS probe 13 via the port P13c and to the outside of the first segment 10 via the port P21. The first QoS probe 13 has ports P11, P12a, and P12b, and is connected to the first router 11 through the port P11 and to the first switching hub 12 through the ports P12a and 12b. The first switching hub 12 has ports P13a, P13b, P14,..., P17, and is connected to the first QoS probe 13 via the ports P13a, P13b and the remaining ports P14,. The indoor units 14 and 15, the air conditioning centralized controller 16, and the personal computer (hereinafter referred to as PC) 17 are sequentially connected. At this time, the port P13a of the first switching hub 12 is connected to the port P12b of the first QoS probe 13, and the port P13b of the first switching hub 12 is connected to the port P12a of the first QoS probe 13.

(Second segment)
The second segment 20 includes devices 21 to 27. The second router 21 has ports P23c and P11, and is connected to the second QoS probe 23 via the port P23c and to the outside of the second segment 20 via the port P21. The second QoS probe 23 has ports P21, P22a and P22b, and is connected to the second router 21 via the port P21 and to the second switching hub 22 via the ports P22a and 22b. The second switching hub 22 has ports P23a, P23b, P24,..., P27, and is connected to the second QoS probe 23 through the ports P23a, P23b and the remaining ports P24,. The outdoor unit 24, the central management device 25, the QoS management device 26, and the PC 27 are connected in this order. At this time, the port P23a of the second switching hub 22 is connected to the port P22b of the second QoS probe 23, and the port P23b of the second switching hub 22 is connected to the port P22a of the second QoS probe 23.

(packet)
Devices 11 to 17 and 21 to 27 exist in the LAN 1, and these devices 11 to 17 and 21 to 27 can transmit and receive data to each other in a packet format via the LAN 1. The air conditioners 14 to 16, 24, and 25 transmit and receive data to each other in a packet format via the LAN 1. Although not shown in FIG. 1, network devices other than the PCs 17 and 27 are connected to the switching hubs 12 and 22. The PCs 17 and 27 and these network devices transmit / receive data to / from each other in packet format via the LAN 1 and also transmit / receive data to / from devices in the Internet 30 in packet format.

  FIG. 2 shows a packet 80 transmitted and received by the devices 11 to 17 and 21 to 27. The packet 80 includes a destination IP address 81, a transmission source IP address 82, and data 83. For example, when control data is transmitted from the outdoor unit 24 to the indoor unit 14, the destination IP address 81 is the IP address of the indoor unit 14, the transmission source IP address 82 is the IP address of the outdoor unit 24, and data 83 Is control data from the outdoor unit 24 to the indoor unit 14.

(Air conditioner)
The air conditioners 14 to 16, 24, 25 include the outdoor unit 24, the indoor units 14, 15, the air conditioning centralized controller 16 for the user to centrally manage the operation of the indoor units 14, 15, and the outdoor unit 24. And a central management device 25 that centrally manages the operations of the indoor units 14 and 15.
As shown in FIG. 3, the indoor units 14 and 15 and the outdoor unit 24 form a refrigerant circuit through which the refrigerant flows together with the refrigerant communication pipe 6, and cool or heat the indoor air in which the indoor units 14 and 15 are installed. .

[Indoor unit]
With reference to FIG. 3, the structure of the indoor units 14 and 15 is demonstrated.
The indoor units 14 and 15 are connected to the outdoor unit 24 via the refrigerant communication pipe 6. Since the indoor unit 14 and the indoor unit 15 have the same configuration, only the configuration of the indoor unit 14 will be described here, and each part 51 to 57 of the indoor unit 15 corresponds to each part 41 to 47 of the indoor unit 14. As a thing, description of the indoor unit 15 is abbreviate | omitted.

  The indoor unit 14 includes an expansion valve 41, an indoor heat exchanger 42, an indoor fan 43, and an indoor side control unit 47. The expansion valve 41 is connected to the liquid side of the indoor heat exchanger 42 and adjusts the flow rate of the refrigerant. The indoor heat exchanger 42 functions as a refrigerant evaporator during cooling operation to cool indoor air, and functions as a refrigerant condenser during heating operation to heat indoor air. The indoor fan 43 supplies the indoor air in which the indoor unit 14 is installed to the indoor heat exchanger 42.

The indoor unit 14 is provided with sensors 44 to 46. The liquid side temperature sensor 44 is provided on the liquid side of the indoor heat exchanger 42 and detects the temperature of the refrigerant. The gas side temperature sensor 45 is provided on the gas side of the indoor heat exchanger 42 and detects the temperature of the refrigerant. The indoor temperature sensor 46 detects the temperature of the room where the indoor unit 14 is installed.
The indoor control unit 47 is connected to the port P14 of the first switching hub 12. As a result, the indoor control unit 47 can communicate with the air conditioning centralized controller 16, the outdoor unit 24, and the central management device 25 via the LAN 1, and control data can be transmitted between these devices 16, 24, 25. Send and receive in packet format. The indoor control unit 47 is connected to the sensors 44 to 46 and receives various measurement amounts detected by the sensors 44 to 46. The control data transmitted / received between the devices 16, 24, and 25 includes various measurement amounts from the sensors 44 to 46. Furthermore, the indoor side control unit 47 is connected to the expansion valve 41 and the indoor fan 43 and adjusts the opening degree of the expansion valve 41 and the air volume of the indoor fan 43 based on control data from the devices 16, 24, and 25.

〔Outdoor unit〕
Next, the configuration of the outdoor unit 24 will be described with reference to FIG.
The outdoor unit 24 is connected to the indoor units 14 and 15 via the refrigerant communication pipe 6.
The outdoor unit 24 includes a compressor 61, a four-way switching valve 62, an outdoor heat exchanger 63, an outdoor fan 64, and an outdoor control unit 65. The compressor 61 is a variable speed compressor driven by an inverter-controlled motor 61a, and compresses the refrigerant. The four-way switching valve 62 is connected to the gas side of the outdoor heat exchanger 63 and to the discharge side of the compressor 61, and switches the direction of refrigerant flow. The four-way switching valve 62 is in a state indicated by a solid line during cooling operation, and is in a state indicated by a broken line during heating operation. The outdoor heat exchanger 63 functions as a refrigerant condenser during the cooling operation, and functions as a refrigerant evaporator during the heating operation. The outdoor fan 64 supplies outdoor air to the outdoor heat exchanger 63.

  The outdoor unit 24 is provided with sensors 70 to 76. The heat exchanger temperature sensor 70 detects the temperature of the refrigerant flowing in the outdoor heat exchanger 63. The liquid side temperature sensor 71 is provided on the liquid side of the outdoor heat exchanger 63 and detects the temperature of the refrigerant. The suction temperature sensor 72 detects the temperature of the suction pipe of the compressor 61. The discharge temperature sensor 73 detects the temperature of the discharge pipe of the compressor 61. The outside air temperature sensor 74 detects the temperature of outside air in the vicinity of the outdoor unit 24 installed. The discharge pressure sensor 75 detects the discharge pressure (that is, high pressure) of the compressor 61. The suction pressure sensor 76 detects the suction pressure (that is, the low pressure) of the compressor 61.

  The outdoor side control unit 65 is connected to the port P24 of the second switching hub 22. As a result, the outdoor control unit 65 can communicate with the indoor units 14 and 15, the air conditioning centralized controller 16 and the central management device 25 via the LAN 1, and control is performed between these devices 14 to 16 and 25. Send and receive data in packet format. The outdoor control unit 65 is connected to the sensors 70 to 76 and receives various measurement amounts detected by the sensors 70 to 76. The control data transmitted and received between the devices 14 to 16 and 25 includes various measurement amounts from the sensors 70 to 76. Furthermore, the outdoor side control unit 65 is connected to the motor 61a of the compressor 61, the four-way switching valve 62, and the outdoor fan 64, and based on control data from the devices 14 to 16 and 25, the motor 61a of the compressor 61 is controlled. The rotational speed, the switching direction of the four-way switching valve 62 and the air volume of the outdoor fan 64 are adjusted.

[Air conditioning centralized controller]
The air conditioning centralized controller 16 is connected to the port P16 of the first switching hub 12. As a result, the air conditioning centralized controller 16 can communicate with the indoor units 14 and 15, the outdoor unit 24 and the central management device 25 via the LAN 1, and controls between these devices 14, 15, 24 and 25. Send and receive data in packet format.

  The air conditioning centralized controller 16 has an input device (not shown), and a user can input an operation command for the indoor units 14 and 15 to the air conditioning centralized controller 16 via the input device. The inputted operation command is transmitted in the packet format as control data to the indoor units 14 and 15, the outdoor unit 24 or the central management device 25 via the LAN 1. The operation command input to the air conditioning centralized controller 16 by the user includes a command to start or stop the operation of the indoor units 14 and 15, a command to register or change the set temperature of the indoor units 14 and 15, and the indoor units 14 and 15. A command for reserving the driving time is included. As described above, the air conditioning centralized controller 16 serves as an interface when the user centrally manages the operation of the indoor units 14 and 15.

[Central management device]
The central management device 25 is connected to the port P25 of the second switching hub 22. As a result, the central management device 25 can communicate with the indoor units 14 and 15, the air conditioning centralized controller 16 and the outdoor unit 24 via the LAN 1, and control data can be transmitted between these devices 14 to 16 and 24. Send and receive in packet format. The control data includes various measurement amounts from the sensors 44 to 46, 54 to 56, and 70 to 76 installed in the indoor units 14 and 15 or the outdoor unit 24.

  The central management device 25 controls the operation of the indoor units 14 and 15 and the outdoor unit 24 based on the control data received from the indoor units 14 and 15 and the outdoor unit 24. For example, the central management device 25 determines whether or not the temperature of the discharge pipe of the compressor 61 detected by the sensor 73 is higher than the threshold value T1, and if it is determined that the temperature is high, the amount of refrigerant flowing through the refrigerant circuit By determining the opening degree of the expansion valves 41 and 51 so as to increase, the superheat degree SH accompanying the freezing operation of the indoor units 14 and 15 and the outdoor unit 24 is controlled. The determined value is transmitted to the indoor units 14 and 15 via the LAN 1 as control data in a packet format.

  In addition, the operation control by the central management device 25 includes detection of occurrence of abnormality in the indoor units 14 and 15 and the outdoor unit 24. For example, in the internal communication of the air conditioners 14 to 16, 24, and 25, when the timeout time T3 is set and the packet 80 does not arrive even after the timeout time T3 has elapsed from the time when the packet 80 should be received, The central management device 25 detects the occurrence of an abnormality.

  Further, the operation control by the central management device 25 includes protection control for the indoor units 14 and 15 and the outdoor unit 24. The central management device 25 monitors the occurrence or sign of abnormality in the indoor units 14 and 15 and the outdoor unit 24, and when the occurrence or sign of abnormality is detected, protection control of the indoor units 14 and 15 and the outdoor unit 24 is performed. I do. For example, the central management device 25 prevents the temperature of the refrigerant at the outlet of the evaporator (the indoor heat exchangers 42 and 52 during the cooling operation and the outdoor heat exchanger 63 during the heating operation) from being lower than the threshold T2 as protection control. The air volume of the indoor fans 43 and 53 or the frequency of the motor 61a of the compressor 61 is determined so that the high pressure does not become higher than the threshold P2 so that the low pressure does not become lower than the threshold P1. The determined value is transmitted as control data in a packet format to the indoor units 14 and 15 or the outdoor unit 24 via the LAN 1.

(First router)
The first router 11 has ports P13c and P21. The first router 11 is connected to the first QoS probe 13 via the port P13c, and is connected to the outside of the first segment 10 via the port P21.
The first router 11 routes the packet 80 from the devices 13 to 17 to the outside of the first segment 10, that is, the Internet 30 and the second segment, and outside the first segment 10, that is, the Internet 30 and the second segment. Is routed to devices 13-17. At this time, the first router 11 secures a communication band for internal communication of the air conditioners 14 to 16, 24, and 25 in the LAN 1 as described below.

[Securing communication bandwidth by priority control]
FIG. 4 shows a conceptual diagram of how the packet 80 is routed in the first router 11. The arrow in the figure indicates the direction in which the packet 80 is transferred.
In the first router 11, three queues C1 to C3 are defined. These three queues C1 to C3 are assigned priority levels of three levels of high, medium, and low, respectively. When the packet 80 routed through the first router 11 arrives at the first router 11, the packet 80 is sequentially transmitted from the first router 11 through steps S41 to S43.

  In step S41, the queues C1 to C3 in which the packet 80 is to be stored are determined according to a predetermined condition stored in advance in a memory built in the first router 11. At this time, if both the destination IP address 81 and the source IP address 82 of the packet 80 match one of the IP addresses of the devices 14 to 16, 24, and 25 constituting the air conditioner, the packet 80 It is determined to be stored in the queue C1.

Next, in step S42, the packet 80 is stored in one of the three queues C1 to C3 according to the determination in step S41. The packet 80 waits in the queues C1 to C3 until it is taken out in step S43.
Next, in step S43, the packets 80 are continuously extracted from the three queues C1 to C3. At this time, the three queues C1 to C3 are scheduled according to the assigned three levels of priority, and the queue from which the packet 80 is to be extracted next is determined among the three queues C1 to C3. Specifically, the queue from which the packet 80 is to be extracted next is determined so that the packet 80 is not extracted from the lower priority queue until the higher priority queue becomes empty.

  As described above, in the first router 11, the packet 80 internally communicated in the air conditioners 14 to 16, 24, and 25 is stored in the queue C1 having the highest priority among the three queues C1 to C3. The packet 80 is routed without delay by the routing of the packet 80. Therefore, apparently, a communication band for internal communication of the air conditioners 14 to 16, 24, 25 is secured in the LAN 1.

(Second router)
The second router 21 has the same configuration as the first router 11. Therefore, the ports P13c and P21, the first QoS probe 13, the first switching hub 12, the first segment 10, the second segment 20, and the packets 80 from the devices 13 to 17 in the description of the first router 11 are respectively connected to the ports P23c and P11. The second router 21 is not described as corresponding to the packet 80 from the second QoS probe 23, the second switching hub 22, the second segment 20, the first segment 10, and the devices 23 to 27.

(First QoS probe)
The first QoS probe 13 has three ports P11, P12a and P12b, and is connected to the first router 11 via the port P11 and to the first switching hub 12 via the ports P12a and P12b. At this time, the port P12a is connected to the port P13b of the first switching hub 12, and the port P12b is connected to the port P13a of the first switching hub 12.

  A packet 80 passing between the first router 11 and the first switching hub 12 is taken into the first QoS probe 13 through one of the port P11 and the port P12a, and is sent from the first QoS probe 13 through the other. . The first QoS probe 13 is a packet that is internally communicated in the air conditioners 14 to 16, 24, and 25 among all the packets 80 that pass through the first QoS probe 13 from when the packet 80 is taken in to when it is transmitted. Capture 80. The captured packet 80 is subjected to predetermined processing in the first QoS probe 13, and is then sent as a packet 80a to the QoS management device 26 via the port P12b.

  In the memory built in the first QoS probe 13, the IP addresses of the devices 14 to 16, 24, and 25 are stored as filtering conditions for capturing only the packet 80 that is internally communicated in the air conditioners 14 to 16, 24, and 25. It is remembered. The first QoS probe 13 refers to the filtering condition, and both the destination IP address 81 and the source IP address 82 of the packet 80 passing through the first QoS probe 13 are the IP addresses of the devices 14 to 16, 24, 25. It is determined whether or not it matches either one. If they match, the packet 80 is captured. If they do not match, do nothing.

  If they match, as shown in FIG. 5 (a), a packet 80a is newly created by adding a time stamp to a bit extracted from a predetermined position from the captured packet 80. The packet 80a includes a destination IP address 81a, a source IP address 82a, and data 83a. The data 83a includes a time stamp 84a and a bit 85a at a predetermined position extracted from the captured packet 80. In this case, the destination IP address 81a is the IP address of the QoS management device 26, and the source IP address 82a is the IP address of the first QoS probe 13.

(Second QoS probe)
The second QoS probe 23 has three ports P21, P22a and P22b, and is connected to the second router 21 via the port P21 and to the second switching hub 22 via the ports P22a and P22b. At this time, the port P22a is connected to the port P23b of the second switching hub 22, and the port P22b is connected to the port P23a of the second switching hub 22.

  The packet 80 passing between the second router 21 and the second switching hub 22 is taken into the second QoS probe 23 via one of the port P21 and the port P22a, and is sent from the second QoS probe 23 via the other. . The second QoS probe 23 is a packet that is internally communicated in the air conditioners 14 to 16, 24, and 25 among all the packets 80 that pass through the second QoS probe 23 between the time when the packet 80 is captured and the time when the packet 80 is transmitted. Capture 80. The captured packet 80 is subjected to predetermined processing in the second QoS probe 23 and then sent to the QoS management device 26 as a packet 80b through the port P22b.

  In the memory built in the second QoS probe 23, the IP addresses of the devices 14 to 16, 24 and 25 are used as filtering conditions for capturing only the packet 80 internally communicated in the air conditioners 14 to 16, 24 and 25. It is remembered. The second QoS probe 23 refers to the filtering condition, and both the destination IP address 81 and the source IP address 82 of the packet 80 passing through the second QoS probe 23 are the IP addresses of the devices 14 to 16, 24, 25. It is determined whether or not it matches either one. If they match, the packet 80 is captured. If they do not match, do nothing.

  If they match, as shown in FIG. 5 (b), a packet 80b is newly created by adding a time stamp to the extracted bit 80 extracted from the packet 80. The packet 80b includes a destination IP address 81b, a source IP address 82b, and data 83b. The data 83b includes a time stamp 84b and a bit 85b at a predetermined position extracted from the captured packet 80. In this case, the destination IP address 81b is the IP address of the QoS management device 26, and the source IP address 82b is the IP address of the second QoS probe 23.

(QoS management device)
The QoS management device 26 has the same configuration as that of a normal PC, and manages the service quality of the LAN 1 by executing the processes according to steps S61 to S65 described below according to a built-in program. Operates as a device.
In step S61, the QoS management device 26 receives the packets 80a and 80b from the first QoS probe 13 and the second QoS probe 23.

  Next, in step S <b> 62, the QoS management device 26 determines the delay of the packet 80 transmitted / received between the devices 14 to 16 included in the first segment 10 and the devices 24 and 25 included in the second segment 20. . The QoS management device 26 compares the time stamp 84a included in the packet 80a with the time stamp 84b included in the packet 80b, thereby delaying the packet 80 transmitted / received between the devices 14-16 and the devices 24, 25. It is determined whether or not.

  Next, in step S <b> 63, the QoS management device 26 determines the loss of the packet 80 transmitted / received between the devices 14 to 16 and the devices 24 and 25. The QoS management device 26 compares the bit 85a included in the packet 80a with the bit 85b included in the packet 80b, so that the packet 80 transmitted / received between the devices 14 to 16 and the devices 24 and 25 is lost. It is determined whether or not.

  Next, in Step S64, when it is determined that the packet 80 is delayed or lost in Step S62 or Step S63, the QoS management device 26 operates the indoor units 14 and 15 and the outdoor unit 24 by the central management device 25. The values of parameters T1 to T3, P1, and P2 used for control are determined. At this time, the values of the parameters T1 to T3, P1, and P2 are determined so that the operations of the indoor units 14 and 15 and the outdoor unit 24 can be controlled more safely. Specifically, the values of the parameters T1 to T3, P1, and P2 are set so that the threshold value T1 is smaller, the threshold value T2 is larger, the threshold value P1 is larger, the threshold value P2 is smaller, and the timeout time T3 is shorter. It is determined.

Next, in step S65, the QoS management device 25 creates a command for correcting the values of the parameters T1 to T3, P1, and P2 used for operation control to the values determined in step S64. The QoS management device 26 transmits the created command as control data to the central management device 25 in the packet format via the LAN 1.
As described above, the QoS management device 26 uses the delay and loss of the packet 80 transmitted and received between the devices 14 to 16 and the devices 24 and 25, so that the quality of service for the internal communication of the air conditioners 14 to 16, 24, and 25 is improved. In the case where the air pressure drops, the operations of the indoor units 14 and 15 and the outdoor unit 24 are controlled more safely. Thereby, in the indoor units 14 and 15 and the outdoor unit 24, it becomes difficult to generate | occur | produce the abnormality resulting from the fall of the service quality about the internal communication of the air conditioners 14-16, 24, and 25. FIG.

<Features>
In the above embodiment, the air conditioners 14 to 16, 24, and 25 perform internal communication via the LAN 1. In addition to the air conditioners 14 to 16, 24, and 25, the PC 17 and 27 are connected to the LAN 1 and are also connected to the Internet 30, so the air conditioners 14 to 16, 24, and 25 are internally communicated. Communication failure may occur. Even in such an environment, in the above embodiment, since the service quality of the internal communication of the air conditioners 14 to 16, 24, and 25 is managed, the normal operation of the air conditioners 14 to 16, 24, and 25 is performed. Easy to maintain.

<Modification>
(1)
In the said embodiment, although the 1st router 11 or the 2nd router 21 has secured the communication band for the internal communication of the air conditioners 14-16, 24, 25 in LAN1, such control is 1st. It may be performed in the switching hub 12 or the second switching hub 22. Further, for example, a dedicated bandwidth control device may be provided between the first router 11 and the first switching hub 12 or between the second router 21 and the second switching hub 22.

(2)
In the above embodiment, in the first router 11 or the second router 21, the communication band for internal communication of the air conditioners 14 to 16, 24, 25 is secured by the priority control method, but class-based queuing (CBQ) ) Method may be secured. In this case, in the first router 11, for example, the communication band is secured by the following steps S51 to S53. The same applies to the second router 12.

[Securing communication bandwidth by CBQ]
In the first router 11, three queues C1 to C3 are defined. The three queues C1 to C3 correspond to the three classes A1 to A3, respectively, and a bandwidth is allocated to each of the three classes A1 to A3 at a predetermined ratio.
In step S51, the packet 80 routed through the first router 11 is classified into one of the three classes A1 to A3 according to a predetermined condition stored in advance in a memory built in the first router 11. At this time, the packet 80 internally communicated in the air conditioners 14 to 16, 24, and 25 is classified into a specific class A1 among the three classes A1 to A3. In the class A1, the packets 80 other than the packet 80 internally communicated in the air conditioners 14 to 16, 24, and 25 are not classified.

Next, in step S52, the packet 80 is stored in one of the three queues C1 to C3 based on the classification in step S51. Specifically, the packet 80 is stored in a queue corresponding to the class classified in step S51. The packet 80 waits in the queues C1 to C3 until it is taken out in step 543.
Next, in step S53, the packets 80 are continuously extracted from the three queues C1 to C3. At this time, the three queues C1 to C3 are scheduled according to the bandwidths allocated to the classes A1 to A3 corresponding thereto.

In this case, since a dedicated communication band is always secured for routing of the packet 80 internally communicated in the air conditioners 14 to 16, 24, and 25, a service for internal communication of the air conditioners 14 to 16, 24, and 25 is provided. Quality is unlikely to deteriorate.
(3)
In the above embodiment, the QoS probes 12 and 22 capture only the packet 80 internally communicated in the air conditioners 14 to 16, 24 and 25, but other than the internal communication of the air conditioners 14 to 16, 24 and 25. A packet 80 related to communication may also be captured. In this case, the QoS management device 26 manages the service quality of the entire LAN 1 and the Internet 30. Therefore, before the service quality of the internal communication of the air conditioners 14 to 16, 24, 25 is deteriorated, it is possible to detect the deterioration of the service quality of the entire LAN 1 or the Internet 30 that may be the cause, and more safely. The operations of the air conditioners 14 to 16, 24, and 25 can be controlled.

(4)
The operation control by the central management device 25 in the embodiment may be performed in devices other than the central management device 25. For example, it may be performed in the outdoor side control unit 65 of the outdoor unit 24.

  The present invention has the effect that it is possible to suppress the influence of the communication failure in the general-purpose network on the operation of the air-conditioning apparatus while enjoying the benefits of the internal communication of the air-conditioning apparatus being made via the general-purpose network. It is useful as an air conditioning system including an air conditioner that performs internal communication via a general-purpose network.

The figure which shows the structure of LAN in which the air conditioning system which concerns on this invention was introduced. The figure which shows the data structure of a packet. The figure which shows the structure of an outdoor unit and an indoor unit. The conceptual diagram which shows a mode that a packet is routed. (A) The figure which shows the data structure of the packet produced with the 1st QoS probe. (B) The figure which shows the data structure of the packet produced with the 2nd QoS probe.

Explanation of symbols

1 LAN
11 First router 13 First QoS probe 14, 15 Indoor unit 16 Air conditioning centralized controller 21 Second router 23 Second QoS probe 24 Indoor unit 25 Central management unit 26 QoS management unit 47, 57 Indoor side control unit 65 Outdoor side control unit 80 Packet C1 to C3 Queues P1, P2, T1 to T2 Threshold value T3 Timeout period

Claims (5)

A first communication unit (16, 25, 47, 57, 65) and a second communication unit (16, 25) that communicates with the first communication unit (16, 25, 47, 57, 65) via the general-purpose network (1). 25, 47, 57, 65),
Control means (11, 13, 21, 23, 26) for controlling the air conditioner in consideration of the quality of service (QoS) of the general-purpose network (1);
An air conditioning system. The control means (11, 21) includes the first communication unit (16, 25, 47, 57, 65) and the second communication unit (16, 25, 47, 57, 65) in the general-purpose network (1). ) Secure communication bandwidth for communication with
The air conditioning system according to claim 1. The control means (11, 21) is transmitted and received between the first communication unit (16, 25, 47, 57, 65) and the second communication unit (16, 25, 47, 57, 65). Data (80) is preferentially transferred in the general network (1);
The air conditioning system according to claim 2. The control means (11, 21)
Define a plurality of queues (C1 to C3) each assigned a priority,
Data (80) transmitted and received between the first communication unit (16, 25, 47, 57, 65) and the second communication unit (16, 25, 47, 57, 65) is sent to the plurality of queues ( Data (80) transferred via the general-purpose network (1) is stored in the queues (C1 to C3) so as to be stored in the queue (C1) having a higher assigned priority among the C1 to C3). ) Stored in one of
Scheduling the plurality of queues (C1-C3) according to the assigned priority;
The air conditioning system according to claim 3. The control means (13, 23, 26)
Measuring the quality of service of the general network (1);
Based on the measured service quality, the parameters (T1 to T3, P1, P2) used for operation control of the air conditioner are corrected.
The air conditioning system according to claim 1.

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