JP5846892B2 - Centralized control device for air conditioning system - Google Patents

Description

  The present invention relates to a centralized management apparatus for an air conditioning system that collects information on operation control and power consumption of a plurality of air conditioners.

  The conventional air conditioning system automates the trial operation that checks the connection status of the piping between the outdoor unit and the air conditioning terminal, and automatically switches between cooling and heating when operating in the trial operation mode. Have been proposed (see, for example, Patent Document 1).

Japanese Patent Laid-Open No. 10-246492 (pages 5-7, FIG. 1)

A plurality of air conditioners in the air conditioning system consisting of (indoor unit and chamber outboard motor), between a central control device and a plurality of air conditioners are connected by a communication line such as transmission line, monitor multiple air conditioners・ Controlled. In addition, a meter that measures the amount of power consumed by one or more air conditioners is installed, and the measured value of this meter is collected in a centralized management device for energy saving control and electricity billing support, etc. Used for.

  In general, such a wiring connection between a meter and an air conditioner is different from a communication line between the central control device and a plurality of air conditioners and a communication line between the central control device and the measurement meter. They are connected by wiring (sensor wiring). Therefore, in order to confirm that the wiring connection between the meter and the air conditioner is the desired connection, a person must visually check the connection state of the wiring, or operate the air conditioner through a test run. A person has confirmed by visually comparing the operating state with the measured value of the meter. In such a connection check that is visually performed by a person, there are problems that a check error due to human error occurs and that the work load of the checker is increased.

  In the technique described in Patent Document 1, the connection state of the refrigerant pipe is inspected as an automated test operation to confirm that the operation of the air conditioner can be performed correctly. There was a problem that connection confirmation could not be automated.

  The present invention has been made to solve the above-described problems, and provides a centralized management device for an air conditioning system capable of automating connection confirmation between an air conditioner and a meter.

A centralized management apparatus for an air conditioning system according to the present invention is a centralized management apparatus for an air conditioning system that collects information on operation control and electric energy of a plurality of air conditioners, and is a part of the plurality of air conditioners There are wired respectively connected, a plurality of meter for measuring wiring connected electric energy of the air conditioner, respectively, and the data collecting unit for collecting respective information amount of power, for each of the meter, is hardwired A storage unit that stores connection information associated with the air conditioner, and an incorrect connection that detects an incorrect connection of the wiring connection between the meter and the air conditioner based on the information on the electric energy and the connection information A detection unit, and a control unit that performs operation control of the plurality of air conditioners, and the erroneous connection detection unit is measured by each of the plurality of meters when all of the plurality of air conditioners are stopped. At a given time It takes the amount of power, and standby power of the air conditioner, which is hardwired to each meter, in all operating conditions of the plurality of air conditioners, power in a predetermined time measured by each of the plurality of metering It amounts, and the operating time of the power of the air conditioner, which is hardwired to each meter, the controller, based on the connection information, the operation state before Symbol air conditioner wherein associated with each meter, sequentially for each meter, switch to the stop state and the operating state, as a unit the air conditioner associated with the said meter, mixed with the air conditioner in a stopped state, and the air conditioner in an operating state And the erroneous connection detection unit is configured so that the control unit determines the amount of electric power in the predetermined time measured by the respective meters in the mixed state, the standby electric energy, and the operating electric energy. In the set operating state of the air conditioner Compared with Flip, and detects an erroneous connection of the wiring connection between the meter and the air conditioner.

  This invention compares the amount of electric power measured by a meter with the amount of electric power during standby or the amount of electric power during operation according to the operating state of the air conditioner, thereby connecting the wiring between the meter and the air conditioner. Therefore, the connection confirmation between the air conditioner and the meter can be automated.

It is a figure which shows the structure and communication wiring of the air conditioning system in Embodiment 1. FIG. It is a figure which shows the wiring connection between the air conditioning machine and meter in Embodiment 1. FIG. 1 is a diagram illustrating a configuration of a centralized management device according to Embodiment 1. FIG. 3 is a flowchart showing a standby power amount measurement algorithm in the first embodiment. It is a figure which shows an example of the collection information in the measurement algorithm of standby electric energy. 3 is a flowchart illustrating an operation power amount measurement algorithm in the first embodiment. It is a figure which shows an example of the collection information in the measurement algorithm of an operating electric energy. 3 is a flowchart showing a connection error detection algorithm in the first embodiment. 6 is a diagram illustrating a data configuration of connection information in Embodiment 1. FIG. It is a figure which shows an example of the temporary data at the time of the connection normal in a connection error detection algorithm. It is a figure which shows an example of the temporary data at the time of the connection abnormality in a connection error detection algorithm.

Embodiment 1 FIG.
FIG. 1 is a diagram illustrating a configuration and communication wiring of an air-conditioning system according to Embodiment 1.
In FIG. 1, the air conditioning system includes a centralized management device 100, one or more outdoor units 200, one or more indoor units 300, and a plurality of meters 400.
One or more indoor units 300 are connected to one outdoor unit 200 by a refrigerant pipe (not shown), and air conditioning is performed by heat absorption and heat dissipation of the refrigerant flowing in the refrigerant pipe.
The outdoor unit 200, the indoor unit 300, and the meter 400 are connected to each other via a communication line such as a transmission line. Thereby, the centralized management apparatus 100 can transmit and receive information individually with all of the devices using identification information such as addresses set in the outdoor unit 200, the indoor unit 300, and the meter 400.
In the following description, when the outdoor unit 200 and the indoor unit 300 are not distinguished, they are referred to as “air conditioners”.
In the present embodiment, the case where the outdoor unit 200 and the indoor unit 300 are provided as air conditioners will be described. However, the present invention is not limited to this, and any facility device such as a ventilation facility that is not connected to the refrigerant pipe may be used. .

FIG. 2 is a diagram illustrating wiring connections between the air conditioner and the meter in the first embodiment.
In FIG. 2, the numerical value in [] of each configuration indicates an address (identification information) used for communication with the central management apparatus 100.
As shown in FIG. 2, one meter 400 is connected to one or more outdoor units 200. One meter 400 is connected to one or more indoor units 300. Note that a plurality of meters 400 are not connected to one air conditioner.
The wiring connection between the meter 400 and the air conditioner (the outdoor unit 200 and the indoor unit 300) is connected regardless of the connection relationship of the refrigerant pipes and the connection relationship of the communication lines. For example, when the indoor unit 300 is installed in a building such as a building, the meter 400 is connected to each indoor unit 300 arranged on the same floor.
Here, it is assumed that one meter 400 is connected so that the power of both the indoor unit 300 and the outdoor unit 200 is not measured. In general, since the outdoor unit 200 and the indoor unit 300 connected to the same refrigerant system are not individually operated, when the measured value of the meter 400 is used for charging an electricity bill, it is difficult to charge the amount of power. .

  The meter 400 is configured by a so-called power meter that integrates the amount of electric power (Wh) consumed by the air conditioner to be measured, and transmits information (count value) of the integrated value of the measured electric energy to the centralized management device 100. .

FIG. 3 is a diagram illustrating the configuration of the centralized management apparatus according to the first embodiment.
In FIG. 3, the centralized management device 100 includes a data transmission / reception unit 110 that transmits / receives data to / from an air conditioner such as the outdoor unit 200 and the indoor unit 300, and the operation state of the air conditioner and the meter 400 using the data transmission / reception unit 110. Facility equipment data collection section 120 that collects information on measurement values, equipment equipment control section 130 that can control at least operation / stop of the air conditioner using the data transmission / reception section 110, and a refrigerant system of the outdoor unit 200 and the indoor unit 300 Equipment connection information storage unit 140 that stores the connection state, meter connection information storage unit 150 that stores a connection state that associates the air conditioners connected to each meter 400, each outdoor unit 200, and each room An operation data information storage unit 160 that records whether or not the machine 300 is in operation, and a measurement data information storage unit 170 that records a measurement value of each meter 400 per certain time. , And a test run result storage unit 180 for recording the test run results, the commissioning unit 190 for performing commissioning for connection confirmation the meter 400.

  The facility equipment control unit 130 can freely operate or stop any air conditioner. In addition, the facility device control unit 130 can transmit a local operation prohibition mode in which operation or stop is not accepted from a local remote controller (not shown) to any air conditioner. Furthermore, the facility equipment control unit 130 can switch the operation mode of any air conditioner to the test operation mode.

  Here, the trial operation mode of the air conditioner is a mode that operates with a constant operation capability. For example, even in an environment where the operating capacity of cooling or heating is excessive or insufficient due to the relationship between the current indoor temperature and the set temperature, it is possible to consume power with a certain operating capacity by setting the test operation mode. It becomes.

The equipment connection information storage unit 140, the meter connection information storage unit 150, the operation data information storage unit 160, the measurement data information storage unit 170, and the test operation result storage unit 180 are configured by an HDD (Hard Disk Drive) or a flash memory. can do.
In addition, the equipment data collection unit 120, the equipment control unit 130, and the test run unit 190 can be realized by hardware such as a circuit device that realizes these functions, or are executed on an arithmetic device such as a microcomputer or a CPU. It can also be realized as software.
The data transmission / reception unit 110 can be configured by a network interface such as a LAN interface.

The equipment data collection unit 120 corresponds to the “data collection unit” in the present invention.
Further, the facility device connection information storage unit 140 corresponds to a “storage unit” in the present invention.
Moreover, the trial run part 190 is corresponded to the "wrong connection detection part" in this invention.
Further, the facility equipment control unit 130 corresponds to a “control unit” in the present invention.

  Next, the operation in the present embodiment will be described in three parts: a standby power amount measurement algorithm, an operating power amount measurement algorithm, and a connection error detection algorithm.

(Standby energy measurement algorithm)
FIG. 4 is a flowchart showing a standby power amount measurement algorithm in the first embodiment.
FIG. 5 is a diagram illustrating an example of collected information in the standby power amount measurement algorithm.
Hereinafter, the standby power amount measurement algorithm will be described with reference to FIG. 5 based on the steps in FIG. 4.

(S101)
The equipment device control unit 130 stops the operations of all outdoor units 200 and all indoor units 300 connected to the meter 400. At this time, the facility equipment control unit 130 transmits an operation prohibit mode to all the outdoor units 200 and all the indoor units 300 to prevent unintended operation.

  In the case of a model in which control such as operation / stop of the outdoor unit 200 cannot be applied, all the indoor units 300 connected to the outdoor unit 200 in the refrigerant system using the information in the equipment connection information storage unit 140 are displayed. The outdoor unit 200 may be stopped by stopping it. Similarly, in the case of a model that cannot control the outdoor unit 200 such as operation / stop, the operation prohibit mode may be transmitted only to the indoor unit 300.

(S102)
Immediately after all the outdoor units 200 and all the indoor units 300 connected to the meter 400 are stopped, the facility equipment data collection unit 120 counts the integrated value (count) of the electric energy measured by each meter 400. Value) information is collected and written to the weighing data information storage unit 170 as temporary data.
For example, as shown in FIG. 5, the integrated value of the electric energy collected in S <b> 102 is written in the measurement data information storage unit 170 as the initial electric energy corresponding to the address of each meter 400.

(S103)
Next, in a state where the outdoor unit 200 and the indoor unit 300 are stopped, a predetermined time elapses, and standby power at the time of stop is consumed. Each meter 400 measures and integrates the amount of power corresponding to the standby power of the air conditioners connected by wiring. The standby power of the outdoor unit 200 includes, for example, power consumption at the crankcase heater and power consumption at the communication base. Further, the standby power of the indoor unit 300 includes power consumption in the communication infrastructure.
Here, the predetermined time to elapse may be any time as long as the minimum count value of the meter 400 is longer than the time assumed to be counted up.
In the following description, the time for the operation to elapse “a certain time” is the same as the certain time here.

(S104)
The facility equipment data collection unit 120 collects information on the integrated value (count value) of the electric energy measured by each meter 400 after a predetermined time has elapsed, and writes it as temporary data in the measurement data information storage unit 170.
For example, as shown in FIG. 5, corresponding to the address of each meter 400, the integrated value of the electric energy collected in S104 is written in the measurement data information storage unit 170 as the electric energy after a lapse of a predetermined time.

(S105)
The trial run unit 190 subtracts the initial power amount collected in S102 from the power amount collected in S104 after the lapse of the fixed time, obtains the power amount in the fixed time for each meter 400 as the standby power amount, and obtains the weighing data. Write to the information storage unit 170.
For example, as shown in FIG. 5, corresponding to the address of each meter 400, the calculation result is written in the weighing data information storage unit 170 as the standby power amount.

(Operating energy measurement algorithm)
FIG. 6 is a flowchart showing a measurement algorithm of the operating electric energy in the first embodiment.
FIG. 7 is a diagram illustrating an example of collected information in the measurement algorithm of the operating electric energy.
Hereinafter, the measurement algorithm of the operating electric energy will be described with reference to FIG. 7 based on the steps in FIG.

(S201)
The equipment device control unit 130 stops the operations of all outdoor units 200 and all indoor units 300 connected to the meter 400. At this time, the facility equipment control unit 130 transmits an operation prohibit mode to all the outdoor units 200 and all the indoor units 300 to prevent unintended operation.
However, if all the outdoor units 200 and all the indoor units 300 have already stopped, such as immediately after the standby power amount measurement algorithm, S201 may not be executed.

(S202)
The equipment data collection unit 120 collects information on the integrated value (count value) of the electric energy measured by each meter 400 and writes it as temporary data in the measurement data information storage unit 170.
For example, as shown in FIG. 7, the integrated value of the electric energy collected in S202 is written in the measurement data information storage unit 170 as the initial electric energy corresponding to the address of each meter 400.

(S203)
The facility equipment control unit 130 causes all outdoor units 200 and all indoor units 300 connected to the meter 400 to operate. At this time, the facility equipment control unit 130 transmits an operation prohibit mode to all the outdoor units 200 and all the indoor units 300 to prevent unintended operation. The facility equipment control unit 130 changes the operation mode of all outdoor units 200 and all indoor units 300 to the test operation mode.

(S204)
Next, in a state where the outdoor unit 200 and the indoor unit 300 are operated, a certain period of time elapses and power during operation is consumed. Each meter 400 measures and integrates the amount of electric power according to the electric power during operation of the air conditioners connected by wiring.
The fixed time to be elapsed is the same time as the fixed time of the standby energy measurement algorithm described above.

(S205)
The facility equipment data collection unit 120 collects information on the integrated value (count value) of the electric energy measured by each meter 400 after a predetermined time has elapsed, and writes it as temporary data in the measurement data information storage unit 170.
For example, as shown in FIG. 7, the integrated value of the electric energy collected in S <b> 204 is written in the measurement data information storage unit 170 as the electric energy after a lapse of a certain time corresponding to the address of each meter 400.

(S206)
The test operation unit 190 subtracts the initial power amount collected in S202 from the power amount collected in S205 after the lapse of a certain time, obtains the power amount in a certain time for each meter 400 as the operating power amount, and obtains the weighing data. Write to the information storage unit 170.
For example, as shown in FIG. 7, corresponding to the address of each meter 400, the calculation result is written in the weighing data information storage unit 170 as the operating power amount.

(Connection error detection algorithm)
FIG. 8 is a flowchart showing a connection error detection algorithm in the first embodiment.
FIG. 9 is a diagram showing a data configuration of connection information in the first embodiment.
FIG. 10 is a diagram illustrating an example of temporary data when the connection is normal in the connection error detection algorithm.
FIG. 11 is a diagram illustrating an example of temporary data at the time of connection abnormality in the connection error detection algorithm.
The connection error detection algorithm will be described below with reference to FIGS. 9 to 11 based on the steps in FIG.

  In the following description, the meter 400 connected to the outdoor unit 200 is referred to as an “outdoor unit meter”, and the meter 400 connected to the indoor unit 300 is referred to as an “indoor unit meter”.

(S301, S302)
S301 corresponds to the above-described standby power amount measurement algorithm.
S302 corresponds to the above-described power consumption measurement algorithm.

(S303)
The facility equipment control unit 130 stops the operation of all the outdoor units 200 connected to the meter 400. At this time, the facility equipment control unit 130 transmits an operation prohibition mode to all the outdoor units 200 to prevent unintended operation.

(S304)
The equipment data collection unit 120 collects information on the integrated value (count value) of the electric energy measured by the outdoor unit meter among the plurality of meters 400 and stores it as temporary data in the measurement data information storage unit 170. Write.
For example, as shown in FIGS. 10 and 11, the integrated value of the electric energy collected in S304 corresponding to the meter 400 at addresses [1] and [3], which is an outdoor unit meter, is used as the initial electric energy. Is written in the weighing data information storage unit 170.

Here, in the connection information stored in advance in the equipment connection information storage unit 140, the address of one or a plurality of air conditioners that are connected by wiring is associated with the address of each meter 400. For example, in the case of wiring connection between the meter 400 and the air conditioner shown in FIG. 2, the address of the connecting machine is set as shown in FIG.
The equipment data collection unit 120 refers to the connection information, and distinguishes between the outdoor unit meter or the indoor unit meter.

  The connection information may be set using an input device (not shown) provided in the central management apparatus 100, or the connection information stored in the external storage medium is transmitted to the central management apparatus 100. Also good.

(S305)
The facility equipment control unit 130 operates all the outdoor units 200 other than the outdoor unit 200 associated with any outdoor unit meter based on the connection information stored in the meter connection information storage unit 150.
For example, when the meter 400 at the address [1] is selected as an arbitrary meter for the outdoor unit, the outdoor unit 200 other than the outdoor unit 200 (address [A1]) corresponding to the address [1], that is, the address [ The outdoor unit 200 of [A2] and [A3] is operated.

(S306)
After a certain period of time has elapsed, standby power is consumed for the outdoor unit 200 in a stopped state, and power for operation is consumed for the outdoor unit 200 in an operating state. Each outdoor unit meter measures and accumulates the amount of power consumed by the air-conditioner connected by wiring.
The predetermined time to be elapsed is the same time as the fixed time of the standby power amount measurement algorithm and the operating power amount measurement algorithm described above.

(S307)
The equipment data collection unit 120 collects information on the integrated value (count value) of the electric energy measured by each outdoor unit meter after a certain period of time, and stores it in the measurement data information storage unit 170 as temporary data. Write.
For example, as shown in FIG. 10 and FIG. 11, the integrated value of the electric energy collected in S307 corresponding to the addresses [1] and [3] of the outdoor unit meter is used as the electric energy after a lapse of a predetermined time. The data is written in the weighing data information storage unit 170.

(S308)
The test run unit 190 subtracts the initial power amount collected in S304 from the power amount collected in S307 after the lapse of a fixed time, obtains the power amount in a fixed time for each outdoor unit meter as a differential power amount, Write to the data information storage unit 170.
For example, as shown in FIGS. 10 and 11, the calculation result is written in the measurement data information storage unit 170 as the differential power amount corresponding to the addresses [1] and [3] of the outdoor unit meter.

(S309)
The test run unit 190 compares the difference electric energy calculated in S308 with the standby electric energy calculated in S301 for any outdoor unit meter selected in S305.
When the difference power amount and the standby power amount substantially match, it is determined that there is no error in the wiring connection between the arbitrary outdoor unit meter and the air conditioner, and the process proceeds to S310.
For example, in the example shown in FIG. 10, since the difference power amount of the address [1] matches the standby power amount (see FIG. 5), it is determined that there is no error in the wiring connection.

On the other hand, if the difference power amount does not match the standby power amount, it is determined that there is an error in the wiring connection between the arbitrary outdoor meter and the air conditioner, and the process proceeds to S311.
For example, when the outdoor unit 200 having the addresses [A1] and [A2] is connected to the meter 400 having the address [1] shown in FIG. 2, the standby power by the outdoor unit 200 having the stopped address [A1] Then, the operating power by the outdoor unit 200 at the address [A2] which is the operating state is measured. In this case, as in the example shown in FIG. 11, the difference power amount of the address [1] and the standby power amount (see FIG. 5) do not match, so it is determined that there is an error in the wiring connection.

(S310)
Since it is determined in S309 that there is no error in the wiring connection, the test operation unit 190 stores information indicating that there is no error in the wiring connection in the test operation result storage unit 180 for any of the outdoor unit meter selected in S305. The writing and confirmation process is terminated. For example, information such as “normal connection” is set corresponding to the address of the meter 400. Note that the test result information is not limited to this, and may be a flag such as “0” or “1”.

(S311)
Since it is determined in S309 that there is an error in the wiring connection, the test run unit 190 further investigates the outdoor unit meter in which the wiring connection is incorrect.
Specifically, for the outdoor unit meter other than the arbitrary outdoor unit meter selected in S305, the difference power amount calculated in S308 and the operating power amount obtained in S302 are compared.
If the difference power amount and the operating power amount substantially match, it is determined that there is no error in the wiring connection between the outdoor unit meter and the air conditioner, and the process proceeds to S313.

On the other hand, if the difference power amount and the operating power amount do not match, it is determined that there is an error in the wiring connection between the outdoor unit meter and the air conditioner, and the process proceeds to S312.
For example, the outdoor unit 200 of addresses [A1] and [A2] is connected to the meter 400 of address [1] shown in FIG. 2, and the outdoor unit 200 of address [A3] is connected to the meter 400 of address [3]. When only is connected, the meter 400 at the address [3] measures only the operating power by the outdoor unit 200 at the address [A3] in the operating state. In this case, as in the example shown in FIG. 11, the difference power amount at address [3] and the operating power amount (see FIG. 7) do not match, so the wiring connection of meter 400 at address [3] is incorrect. Judge that there is.

(S312)
Since it is determined in S309 and S311 that there is an error in the wiring connection, the test run unit 190 determines that there is an error in the wiring connection for the optional outdoor unit meter compared in S309 and the outdoor unit meter compared in S311. The information indicating that it exists is written in the test run result storage unit 180, and the confirmation ends. For example, information such as “connection abnormality” is set corresponding to each address of the meter 400. Note that the test result information is not limited to this, and may be a flag such as “0” or “1”.

(S313)
The test operation unit 190 determines whether there is an outdoor unit meter that does not compare the amount of power during operation in S311 among the plurality of outdoor unit meters. If there is, the process returns to S311 to repeat the above-described operation. On the other hand, when the survey is completed for all the outdoor unit meters, the confirmation process is terminated.

  By using such a connection error detection algorithm, any outdoor unit meter selected in S305 is sequentially selected and repeated for all outdoor unit meters, so that an outdoor unit meter having an incorrect wiring connection is used. Can confirm all.

  In the above description, the case of confirming the wiring connection between the meter 400 and the outdoor unit 200 has been described, but the wiring connection between the meter 400 and the indoor unit 300 can also be confirmed by the same procedure. it can. That is, by replacing the outdoor unit meter in the connection error detection algorithm with the indoor unit meter, all the indoor unit meters having an incorrect wiring connection can be confirmed.

In the present embodiment, the connection error detection process between the meter 400 and the outdoor unit 200 and the connection error detection process between the meter 400 and the indoor unit 300 have been described separately. Is not limited to this. If each outdoor unit 200 and each indoor unit 300 can be operated individually, the outdoor unit meter and the indoor unit meter may be set to the same connection error detection process.
Further, even when an air conditioner other than the outdoor unit 200 and the indoor unit 300 is provided, such as a ventilation facility, an error in the wiring connection between the air conditioner and the meter 400 can be detected based on the above technical idea. .

As described above, in the present embodiment, based on the connection information, the operation of one or more air conditioners associated with each meter 400 is sequentially set to the stop state and the operating state for each meter 400. The operation of the air conditioner set by the equipment control unit 130 with the electric energy (difference electric energy) in the predetermined time (fixed time) measured by the meter 400 and the standby electric energy or the operating electric energy. In comparison according to the state, an erroneous connection of the wiring connection between the meter 400 and the air conditioner is detected.
For this reason, the misconnection of the wiring connection between the meter 400 and an air conditioner can be detected automatically. Accordingly, it is possible to prevent a confirmation error due to an artificial confirmation error in the trial operation. In addition, it is possible to automatically check the connection when there is no person at night or the like, so that the burden on the checker can be reduced. In addition, it is possible to confirm with a specific numerical value of the electric energy, and the burden on the confirmer can be reduced.

Further, according to the operation state of the air conditioner, the power amount (difference power amount) measured by the meter 400 is compared with the standby power amount or the operating power amount to detect an erroneous connection. Even when the difference in the amount of power between the standby power amount of the air conditioner with high power and the operating power amount of the air conditioner with low operating power is small, the erroneous connection can be detected with high accuracy.
In the case of processing in which each air conditioner is operated sequentially and the air conditioner being operated is associated with the meter by the amount of electric power measured at that time, the air conditioner having a large standby power as described above is used. If air conditioners with low operating power coexist, it is not possible to determine the correspondence, and it is impossible to detect erroneous connections.

In the above description, the operation for detecting the meter 400 having an incorrect wiring connection has been described. However, when an erroneous connection of the meter 400 associated with a plurality of air conditioners is detected, the plurality of air conditioners are detected. Among them, an incorrectly connected air conditioner may be detected.
Specifically, when the test run unit 190 detects an erroneous connection of the meter 400 associated with a plurality of air conditioners, the facility device control unit 130 identifies the plurality of air conditioners associated with the meter 400. Among them, an arbitrary air conditioner is operated and the other air conditioners are stopped.
And if the electric energy (difference electric energy) in the fixed time measured with the meter 400 which detected the misconnection is larger than standby electric energy, the trial run part 190 has an error in the wiring connection of the said arbitrary air conditioners. Judge that there is no. On the other hand, when the electric energy (difference electric energy) substantially matches the standby electric energy, it is determined that there is an error in the wiring connection of the arbitrary air conditioner. Such processing is sequentially performed on all the air conditioners associated with the meter 400 in which the erroneous connection is detected, thereby detecting the misconnected air conditioner among the plurality of air conditioners. be able to.

  In addition, in this Embodiment, although the air conditioning system provided with the outdoor unit 200 and the indoor unit 300 connected with refrigerant | coolant piping was demonstrated, it is not restricted to this, For example, the hot water supply type air conditioner which circulates cold water or warm water You may apply to. In this case, the measurement target of the meter 400 can be the amount of water supplied from the water supply. Even in this case, the erroneous connection of the wiring connection between the meter 400 and the hot water supply type air conditioner can be detected based on the technical idea described above.

  DESCRIPTION OF SYMBOLS 100 Central management apparatus, 110 Data transmission / reception part, 120 Equipment data collection part, 130 Equipment control part, 140 Equipment connection information storage part, 150 Meter connection information storage part, 160 Operation data information storage part, 170 Measurement data information Storage unit, 180 Trial operation result storage unit, 190 Trial operation unit, 200 Outdoor unit, 300 Indoor unit, 400 Meter.

Claims (2)

A central control device for an air conditioning system that collects information on operation control and electric energy of a plurality of air conditioners,
A part of the plurality of air conditioners is connected by wiring , and a data collection unit that collects information on the amount of power from a plurality of meters that respectively measure the amount of power of the air conditioners connected to the wiring ,
For each meter, a storage unit that stores connection information that associates the air-conditioner that is wire-connected, and
Based on the information on the electric energy and the connection information, an erroneous connection detection unit that detects an erroneous connection of the wiring connection between the meter and the air conditioner,
A control unit for controlling the operation of the plurality of air conditioners;
With
The erroneous connection detector is
When all of the plurality of air conditioners are in a stopped state, the amount of power at a predetermined time measured by each of the plurality of meters is set as the standby power amount of the air conditioner connected to each meter,
When all of the plurality of air conditioners are in an operating state, the amount of power at a predetermined time measured by each of the plurality of meters is the amount of power during operation of the air conditioner connected to each meter,
The controller is
Based on the connection information, the operation state of each meter before Symbol air conditioner associated with the sequentially for each meter, switch to the stop state and the operating state, the air conditioner associated with the said meter As a unit, the air conditioner in the stopped state and the air conditioner in the operating state are mixed,
The erroneous connection detector is
The electric energy in the predetermined time measured by each meter in the mixed state, the standby electric energy and the operating electric energy according to the operation state of the air conditioner set by the control unit In comparison, a centralized management device for an air conditioning system, wherein an erroneous connection of a wiring connection between the meter and the air conditioner is detected. The controller is
When the erroneous connection detection unit detects an erroneous connection of the meter that is associated with a plurality of the air conditioners, the operation states of the plurality of air conditioners associated with the meter are sequentially stopped. And switch to the driving state,
The erroneous connection detector is
Of the plurality of air conditioners associated with the meter, based on the amount of power measured by the meter that has detected an incorrect connection and the operation state of the air conditioner set by the control unit The central control device for an air conditioning system according to claim 1, wherein an air-conditioner connected in error is detected.

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