JP2018155461A - Air conditioning management device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning system, an air conditioning management device, and an air conditioning management method capable of enhancing safety when a flammable refrigerant leaks.
An air conditioning management device includes a storage unit capable of storing information about a plurality of air conditioning target spaces, indoor units and refrigerant leak detectors corresponding to the spaces as air conditioning target space information, and the refrigerant leak detection detecting a refrigerant leak. An acquisition unit that acquires refrigerant leakage information from the air conditioner, a determination unit that determines an air-conditioning target space where the refrigerant has leaked from the refrigerant leakage information and the air-conditioning target space information, and an air-conditioning target for which the determination unit determines that the refrigerant has leaked An air conditioning control unit that instructs the indoor unit corresponding to the space to operate the blower included in the indoor unit.
[Selection] Figure 3

Description

  Embodiments described herein relate generally to an air conditioning management device.

  Conventionally, many non-flammable R410A refrigerants have been used in air conditioners. R410A refrigerant has a property of having a high global warming potential (hereinafter referred to as GWP), although the ozone depletion coefficient is zero. Therefore, in recent years, refrigerant conversion to a low GWP refrigerant has been promoted against the background of global warming prevention. However, many low GWP refrigerants are flammable refrigerants and require attention to refrigerant leakage. In particular, in an air conditioner called a multi-air conditioner in which a plurality of indoor units are connected to one or a plurality of outdoor units, the amount of refrigerant filling becomes large. Flammable concentrations may be reached, and safety measures are being considered.

As one of safety functions when a flammable refrigerant leaks, a function of agitating the leaked refrigerant by operating a blower as in Patent Document 1 has been proposed.
However, the air conditioning system as described above manages an air conditioner of one refrigerant system formed by one outdoor unit and a plurality of indoor units, and simultaneously manages a plurality of refrigerant systems at the same time. It wasn't.

JP, 2006-197006, A

  The problem to be solved by the present invention is to provide an air conditioning management device that can enhance safety when a flammable refrigerant leaks.

  To achieve the above object, an air conditioning management device according to an embodiment includes an outdoor unit that includes a compressor and an indoor unit that includes a blower, and at least one of which is filled with a combustible refrigerant. It is an air-conditioning management apparatus used for an air-conditioning system provided with an air conditioner and a refrigerant leakage detector that detects refrigerant leakage into a plurality of air-conditioning target spaces that are air-conditioned by an indoor unit. The air conditioning management device includes a plurality of air conditioning target spaces, a storage unit capable of storing information on indoor units and refrigerant leak detectors corresponding to the spaces as air conditioning target space information, and the refrigerant leak detector that detects refrigerant leakage. Corresponding to the acquisition unit that acquires refrigerant leakage information, the determination unit that determines the air-conditioning target space where the refrigerant leaked from the refrigerant leakage information and the air-conditioning target space information, and the air-conditioning target space that the determination unit determined that the refrigerant leaked An air conditioning control unit that instructs the indoor unit to operate the blower included in the indoor unit.

1 is an overall view showing an air conditioning system using an air conditioning management device of a first embodiment. It is a block diagram which shows the structure of the air conditioning system using the air-conditioning management apparatus of 1st Embodiment. It is a flowchart when the refrigerant | coolant of the air-conditioning management apparatus of 1st Embodiment leaks. It is a flowchart when the refrigerant | coolant of the air-conditioning management apparatus of 2nd Embodiment leaks. It is the figure which showed the setting value for every form in the air blower of an indoor unit when a refrigerant | coolant leaked, and the wind direction change machine which the memory | storage part of the air-conditioning management apparatus of 2nd Embodiment memorize | stored.

Hereinafter, embodiments for carrying out the invention will be described.
(First embodiment)
An air conditioning management apparatus 100 according to the first embodiment will be described with reference to FIGS. 1 to 3. FIG. 1 is an overall view of the air conditioning system 1. FIG. 2 shows the configuration of the air conditioning system 1, the communication system, and the refrigerant system.

The air conditioning system 1 according to the first embodiment includes a plurality of air conditioners 2-1 and 2-2 each having a refrigeration cycle apparatus, a plurality of refrigerant leak detectors 3-1 to 3-6, and air conditioning management. Device 100.
Hereinafter, when the air conditioners 2-1 and 2-2 are not distinguished, they are referred to as an air conditioner 2. Hereinafter, the refrigerant leak detectors 3-1 to 3-6 are referred to as the refrigerant leak detector 3 when they are not distinguished.

The air conditioner 2 includes outdoor units 2A-1 to 2A-3 installed outdoors and indoor units 2B-1 to 2B-6 installed indoors. In the air conditioner 2-1, one outdoor unit 2A-1 and two indoor units 2B-1 and 2B-2 are connected via a refrigerant pipe to form a first refrigerant system R-1. To do. The air conditioner 2-2 includes two outdoor units 2A-2 and 2A-3 and four indoor units 2B-3, 2B-4, 2B-5, and 2B-6 via refrigerant piping. Connected to form a second refrigerant system R-2.
Each air conditioner 2 is filled with a slightly flammable refrigerant having a flammability rank of A2L or higher, for example, R32 refrigerant. One of the air conditioners 2 may be filled with the R32 refrigerant, and the other may be filled with the conventional R410A refrigerant.

Remote controllers 2C-1 to 2C-5 and refrigerant leakage detectors 3-1 to 3-6 are connected to the indoor units 2B-1 to 2B-6.
Hereinafter, when the outdoor units 2A-1 to 2A-3 are not distinguished, they are referred to as outdoor units 2A. Hereinafter, when the indoor units 2B-1 to 2B-6 are not distinguished, they are referred to as indoor units 2B. Hereinafter, when the remote controllers 2C-1 to 2C-5 are not distinguished, they are referred to as a remote controller 2C.

  Between the air conditioning management device 100 and the outdoor unit 2A, between the outdoor unit 2A and the indoor unit 2B, between the indoor unit 2B and the refrigerant leak detector 3, and between the indoor unit 2B and the remote controller 2C The communication line 4 is used for communication via each device. Further, between the air conditioning management device 100 and the outdoor unit 2A, between the outdoor unit 2A and the indoor unit 2B, between the indoor unit 2B and the refrigerant leakage detector 3, and between the indoor unit 2B and the remote controller 2C. Communication via a network may be performed regardless of wired or wireless. The network includes, for example, a WAN (Wide Area Network), a VPN (Virtual Private Network), a LAN (Local Area Network), and the like.

  Each outdoor unit 2A communicates with a compressor 12 that circulates the refrigerant in the refrigerant system R, an outdoor heat exchanger (not shown) that exchanges heat between the refrigerant and outdoor air, and the air conditioning management device 100 and the indoor unit 2B. The communication part 11 to perform and the outdoor unit control part 13 are provided. The outdoor unit control unit 13 includes compressor control means 14.

  As shown in FIG. 2, each indoor unit 2B includes a blower 22 that circulates indoor air, an indoor heat exchanger (not shown) that exchanges heat between the refrigerant and the indoor air, and a wind direction of air blown from the indoor unit. Is provided with a wind direction changing machine 23, a communication unit 21, and an indoor unit control unit 24. The wind direction change machine 23 is an apparatus which changes a wind direction by changing the inclination of the louver etc. which were provided in the blower outlet of the indoor unit 2B, for example. The indoor unit control unit 24 further includes a blower control unit 25 that controls operation / stop of the blower 22 and the number of rotations, and a wind direction control unit 26 that controls the wind direction change unit 23 to change the wind direction. The wind direction control means 26 instructs the wind direction changing machine 23 to change the wind direction, and the received wind direction changing machine 23 changes the inclination of the louver or the like to change the wind direction. Note that some louvers are not provided depending on the form of the indoor unit 2B, and the indoor unit 2B having such a form does not include the wind direction changing unit 23 and the wind direction control means 26.

  Each remote controller 2 </ b> C includes an operation unit 32, an operation display unit 33, and a communication unit 31. The user can use the remote controller 2C to perform operations related to the operation of the indoor units 2B connected thereto, such as operation / stop, change of set temperature, change of wind direction, change of air volume, change of operation mode, etc. it can.

Each refrigerant leak detector 3 includes a refrigerant detector 42 and a communication unit 41. The refrigerant detector 42 detects the leaked refrigerant.
In the present embodiment, two refrigerant leakage detectors 3 are provided in the air-conditioning target spaces X, Y, and Z, respectively, and are connected via the communication line 4 to the indoor unit 2B installed within a predetermined range. In addition, when attaching the indoor unit 2B to a position where the height from the floor of the air-conditioning target space is 1.5 m or more, the range within a radius of 10 m from each indoor unit 2B, the height of the indoor unit 2B being less than 1.5 m In the case where the refrigerant leak detector 3 is installed, it is desirable to install the refrigerant leak detector 3 within a radius of 5 m from each indoor unit 2B.
Moreover, since the refrigerant is heavier than air and tends to accumulate below the air-conditioning target space when leaked, each refrigerant leak detector 3 is preferably installed at a position close to the floor surface.

The air conditioning management device 100 includes a communication unit 51, an input unit 52, a display unit 53, and the following units (1) to (4) as main functions. These operations are realized, for example, when a processor provided in the air conditioning management device 100 executes a computer program stored in a memory.
(1) A storage unit 54 that stores, as air-conditioning target space information, the air-conditioning target space input by the operation of the input unit 52 and the information about the indoor unit 2B and the refrigerant leak detector 3 corresponding to the space.
(2) An acquisition unit 55 that acquires refrigerant leakage information from the refrigerant leakage detector 3 that has detected refrigerant leakage.
(3) A determination unit 56 that determines the air-conditioning target space where the refrigerant has leaked from the refrigerant leakage information and the air-conditioning target space information. The determination unit 56 includes an indoor unit determination unit 57 and a space determination unit 58.
(4) The air conditioning control unit 59 that instructs the indoor unit 2B corresponding to the air conditioning target space determined by the determination unit 56 to operate the blower 22 included in the indoor unit 2B.

The air-conditioning management apparatus 100 may be provided with various functions such as monitoring the operation status of each air conditioner 2 and schedule control, or may be specialized for centralized control when refrigerant leaks.
The air conditioning management device 100 may manage the indoor units 2B-2, 2B-4, and 2B-52B-6 in groups. For example, in the case of a commercial facility, a plurality of groups and levels can be set like floor / tenant / area / remote control system. The group setting is input by the administrator or the like using the input unit 52 of the air conditioning management device 100 as necessary, so that the group setting information such as the group and the hierarchy setting and the air conditioning target space information are registered / stored in the storage unit 54. It can be memorized.
Note that the air conditioning target space information is a means for specifying the indoor unit 2B installed around the refrigerant leak detector 3 when the refrigerant leak detector 3 detects the refrigerant leak. Alternatively, it may be set individually as a category different from the group setting.
Here, the space set as the air-conditioning target space is not limited to a room or the like that is completely partitioned by a wall or a ceiling, but may be a space that is partially released such as a tenant of a commercial facility.
Hereinafter, in this embodiment, a case where “tenant”, which is a part of group setting, is set as an air-conditioning target space will be described.

  In the air conditioning management device 100 of the present embodiment, the air-conditioning target spaces X, Y, and Z are registered in the storage unit as the lowermost group “tenant X”, “tenant Y”, and “tenant Z”, respectively, and the lowermost group The area including “tenant X” is registered as the middle layer group “area S”, and the area including the lowest layer group “tenant Y” and “tenant Z” is registered as the middle layer group “area T”. The floor including “area S” and “area T” is registered as the uppermost group “floor F”.

  Next, the operation when refrigerant leakage occurs in any of the air-conditioning target spaces X, Y, Z of the air conditioning system 1 according to the first embodiment will be described.

  First, an example of the flow of refrigerant leak detection control executed by the air conditioner 2 will be described. When the refrigerant leak occurs and the refrigerant detector 42 of the refrigerant leak detector 3 detects the refrigerant, the refrigerant leak detector 3 controls the air conditioning through the indoor units 2B and the communication units 21 and 11 of the outdoor unit 2A of the same communication system. The refrigerant leakage information is sent to the apparatus 100. At that time, each indoor unit 2B that has received the refrigerant leakage information controls the blower 22 by the indoor unit control unit 24 to start operation, and each outdoor unit 2A is controlled by the outdoor unit control unit 13 to be operated by the compressor 12. Stop.

  Next, an example of the flow of control operations executed in the air conditioning management device 100 will be described with reference to FIG. FIG. 3 is a flowchart illustrating an example of the air conditioning management device 100. When the air conditioning management device 100 receives the refrigerant leakage information at the communication unit 51 (step S0), the information is sent to the acquisition unit 55, and the determination unit 56 detects the refrigerant leakage based on the data in the acquisition unit 55 and the storage unit 54. It is determined whether the generated air conditioning target space can be specified (step S1). When it can be specified, it is determined whether there is another indoor unit 2B other than the indoor unit 2B in which refrigerant leakage has occurred in the corresponding air conditioning target space (step S2). When it is determined that there is no other indoor unit 2B, the control operation is terminated. When it is determined that there is another indoor unit 2B, it is determined whether the indoor unit 2B is of another refrigerant system R. (Step S3) When it is determined that the refrigerant system R is another refrigerant system R, the air conditioning control unit 59 stops the compressor 12 of the outdoor unit 2A of the refrigerant system R, and among the indoor units 2B of the refrigerant system R, An instruction to operate the blower 22 of the indoor unit 2B installed in the air-conditioning target space determined to be leaking refrigerant is sent from the communication unit 51 to the corresponding outdoor unit 2A and the indoor unit 2B via the communication line 4 ( Step S4). Hereinafter, the instruction to stop the compressor 12 and operate the blower 22 is referred to as refrigerant leakage control. If it is determined in step S3 that the refrigerant system R is not another refrigerant system R, that is, the indoor units 2B corresponding to the same air-conditioning target space are the same refrigerant system R, an instruction to operate the blower 22 only for the corresponding indoor unit 2B. (Step S5). If the air-conditioning target space cannot be specified in step S1, it is determined whether there is group setting control at the time of refrigerant leakage (step S6). The determination of the group setting control is to determine whether or not group setting information stored in advance in the storage unit is registered. When it is determined that there is group setting control, refrigerant leakage control is sent to all the outdoor units 2A and indoor units 2B in the group setting (step S7). If there is no group setting control at the time of leakage detection, an instruction for refrigerant leakage control is sent to all the outdoor units 2A and indoor units 2B managed by the air conditioning management device 100 (step S8), and the operation is terminated.

  In the air conditioner 2 to which the refrigerant leakage control is sent from the air conditioning management device 100, the outdoor unit 2A stops the compressor 12, and the indoor unit 2B operates the blower. The refrigerant leakage control operation is continued until an administrator or the like stops it.

  For example, a case where refrigerant leakage occurs in the indoor unit 2B-2 or in the vicinity thereof will be described with reference to FIG. At this time, when the refrigerant leak detector 3-3 detects the refrigerant, the refrigerant leak information is sent to the indoor unit 2B-2 via the communication line 4. The indoor unit 2B-2 that has received the refrigerant leakage information immediately operates the blower 22 of the own unit, and simultaneously sends the refrigerant leakage information to the outdoor unit 2A-1 via the communication line 4. The outdoor unit 2A-1 receives the refrigerant leakage information, stops the operation of the compressor 12 of the own unit, and sends the refrigerant leakage information to the air conditioning management device 100 via the communication line 4. The air conditioning management device 100 identifies the air conditioning target space “tenant Y” and the refrigerant system R-1 of the indoor unit 2B-2 that has received the refrigerant leak information from the refrigerant leak detector 3-3, and is the same as the indoor unit 2B-2. The refrigerant system R-2 of the other indoor unit 2B-4 in the air conditioning target space “tenant Y” is specified.

  Next, the air-conditioning management apparatus 100 sends an instruction to stop the compressor 12 to the outdoor units 2A-2 and 2A-3 and an instruction to operate the blower 22 to the indoor unit 2B-4 via the communication line 4. The outdoor units 2A-2, 2A-3 and the indoor unit 2B-4 receive instructions from the air conditioning management device 100 at the respective communication units 11, 21, and the outdoor units 2A-2, 2A-3 are connected to the outdoor unit control unit 13. The compressor control means 14 controls the compressor 12 and stops the compressor 12. In the indoor unit 2B-4, the blower control means 25 of the indoor unit control unit 24 controls the blower 22 to start operation. Further, among the indoor units 2B of the respective refrigerant systems R, those installed in the air-conditioning target spaces “tenant X” and “tenant Z” where the refrigerant does not leak are used to stop the compressor 12 of the outdoor unit 2A. Accordingly, the indoor unit 2B is also stopped.

As another example, a case where refrigerant leakage occurs in the indoor unit 2B-5 or in the vicinity thereof will be described. At this time, the refrigerant leak detector 3-5 detects the refrigerant. When the refrigerant leak detector 3-5 sends the refrigerant leak information, the indoor unit 2B-5 operates the blower 22, and the compressors 12 of the outdoor units 2A-2 and 2A-3 are stopped. The air conditioning management device 100 identifies the air conditioning target space “tenant Z” and the refrigerant system R-2 of the indoor unit 2B-5, and the refrigerant system of the indoor unit 2B-6 in the same space “tenant Z” as the indoor unit 2B-5. R-2 is specified.
At this time, since the refrigerant system of the indoor unit 2B corresponding to the air-conditioning target space “tenant Z” is only R-2, the air-conditioning management apparatus 100 sends an instruction to operate the blower 22 only to the indoor unit 2B-6. The indoor unit 2B-6 receives an instruction from the air conditioning management device 100 through the communication unit 21, and the blower control means 25 of the indoor unit control unit 24 controls the blower 22 to start operation.

  When the air conditioning management apparatus 100 cannot identify the air conditioning target space “tenant Z” of the indoor unit 2B-5 and it can be determined that there is a group setting of “area T”, the indoor unit 2B- The compressors 12 of the outdoor units 2A-1, 2A-2, 2A-3 that are the refrigerant systems R-1, R-2 of 2, 2B-4, 2B-6 are stopped, and the indoor unit 2B- The blower 22 of 2, 2B-4, 2B-6 is operated.

  When it cannot be determined that there is a group setting, the compressors 12 of all the outdoor units 2A under the control of the air conditioning management device 100 are stopped, and the blowers 22 of all the indoor units 2B are operated.

(Second Embodiment)
The air-conditioning management apparatus 100 of 2nd Embodiment is demonstrated with reference to FIG. Elements that are the same as or similar to those in the first embodiment are assigned the same reference numerals, and redundant descriptions are omitted as appropriate.
The storage unit 54 provided in the air conditioning management device 100 according to the second embodiment further includes, as the air conditioning target space information, the form information of the indoor unit 2B corresponding to the air conditioning target space and the blower provided in the indoor unit 2B corresponding to the refrigerant leak. The setting value of the rotational speed of 22 and the wind direction of the wind direction changing machine 23 is stored. The determination unit 56 determines the air-conditioning target space where the refrigerant has leaked, the indoor unit 2B corresponding to the space, and the form of the indoor unit 2B. The air-conditioning control unit 59 sets the air directions of the blower 22 and the air-direction changing device 23 provided in the indoor unit 2B corresponding to the air-conditioning target space where the refrigerant has leaked based on the set values stored in the storage unit 54. The operation is instructed to perform the operation at the time of refrigerant leakage control.

  FIG. 4 is a flowchart illustrating an example of a flow of refrigerant leakage countermeasure control executed by the air conditioning management device 100 according to the second embodiment. The air-conditioning management apparatus 100 determines the configuration of the indoor unit 2B before sending the refrigerant leakage control instruction to the air conditioner 2 (steps S4a, S5a, S7a, S8a). Thereafter, an instruction for refrigerant leakage control corresponding to the form of each indoor unit 2B is sent (steps S4, S5, S7, S8). Here, the air-conditioning management apparatus 100 is provided in the outdoor unit 2A with the start of operation of the blower 22 of each indoor unit 2B and the rotation speed of the blower 22, the wind direction (louver change) of the wind direction changer 23, and the outdoor unit 2A according to the refrigerant leakage control instruction. Send instructions to control the compressor shutdown. FIG. 5 shows the set values of the rotational speed of the blower 22 and the wind direction of the wind direction changer 23 for each form of each indoor unit 2B.

According to the air conditioning management device 100 of at least one embodiment described above, the air conditioners 2 of the plurality of refrigerant systems R are simultaneously controlled, and the blowers 22 of all the indoor units 2B in the air conditioning target space where refrigerant leakage is detected. And stir the leaked refrigerant. As a result, it is possible to prevent the leaked refrigerant from locally reaching the flammable concentration and to enhance the safety when the refrigerant leaks.
Further, the air in the air-conditioning target space can be further agitated by changing the rotational speed of the blower 22 of the indoor unit 2B and the wind direction of the wind direction changer 23. This further prevents the leaked refrigerant from reaching the flammable concentration, thereby ensuring higher safety.

Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention.
For example, the communication connection relationship with the air conditioning management device 100, the outdoor unit 2A, the indoor unit 2B, the refrigerant leak detector 3, and the remote controller 2C shown in the above embodiment is not limited to the above embodiment, and is appropriately connected. May be replaced.
Moreover, although the refrigerant | coolant leak detector 3 used what was connected to the indoor unit 2B in the said embodiment, it communicates with the air-conditioning management apparatus 100 directly from the refrigerant | coolant leak detector 3 provided not only in this but indoors. May be.
Moreover, in the said embodiment, although the rotation speed of the air blower 22 of the indoor unit 2B and the wind direction of the wind direction change machine 23 had the setting corresponding to refrigerant | coolant leakage, it can be changed suitably according to the form etc. of the air-conditioning object space. Also good.
These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the invention described in the claims and their equivalents, as well as included in the scope and gist of the invention.

  DESCRIPTION OF SYMBOLS 1 ... Air conditioning system, 2,2-1,2-2 ... Air conditioning apparatus, 2A, 2A-1 to 2A-3 ... Outdoor unit, 2B, 2B-1 to 2B-6 ... Indoor unit, 2C, 2C-1 ˜2C-5, remote control, 3,3-1 to 3-6, refrigerant leak detector, 4 communication line, 100 air conditioning management device, 12 compressor, 22 blower, 54 storage unit, 55 acquisition , 56... Judgment unit, 59... Air conditioning control unit, R, R-1, R-2... Refrigerant system, X, Y, Z.

Claims (3)

A plurality of air conditioners each composed of an outdoor unit equipped with a compressor and an indoor unit equipped with a blower, at least one being filled with a combustible refrigerant;
A refrigerant leakage detector for detecting leakage of the refrigerant to a plurality of air-conditioning target air-conditioned by the indoor unit;
An air conditioning management device used in an air conditioning system comprising:
A storage unit capable of storing information on the plurality of air-conditioning target spaces, the indoor units corresponding to the spaces, and the refrigerant leak detector as air-conditioning target space information;
An acquisition unit for acquiring refrigerant leakage information from the refrigerant leak detector that has detected refrigerant leakage;
A determination unit that determines an air-conditioning target space in which a refrigerant has leaked from the refrigerant leakage information and the air-conditioning target space information;
An air-conditioning control unit that instructs the operation of the blower included in the indoor unit with respect to the indoor unit corresponding to the air-conditioning target space in which the refrigerant is determined to have leaked by the determination unit;
An air conditioning management device.   The air conditioning control unit is in operation of the outdoor unit that the outdoor unit includes with respect to all the outdoor units of the air conditioner including the indoor unit corresponding to the air conditioning target space in which the refrigerant is determined to have been leaked by the determination unit. The air conditioning management device according to claim 1, wherein the air conditioning management device instructs to stop the compressor.   The air conditioning control unit instructs the operation of the blower included in the indoor unit to all the indoor units managed by the air conditioning management device when the determination unit cannot determine the air conditioning target space where the refrigerant has leaked. The air-conditioning management apparatus according to claim 1 or 2.

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