JP6790794B2 - Air conditioning controller - Google Patents

Description

The present invention relates to an air conditioning controller that controls an air conditioning system.

When multiple air conditioners are installed in the building and each unit is operated independently, if all the air conditioners are started at the same time at the start of daily operation, the power consumption will exceed the peak power consumption of the contracted power. There is a risk of causing a power outage by temporarily exceeding the supply capacity. In order to prevent such a situation, in the invention described in Patent Document 1 (Japanese Patent Laid-Open No. 11-159837), a plurality of air conditioners are started at different times to prevent an excessive current from flowing to the power supply line. ing.

On the other hand, although it is possible to avoid simultaneous activation by shifting the activation timing of a plurality of air conditioners, delaying the activation may impair user comfort.

An object of the present invention is to provide an air conditioning control device capable of starting an air conditioning operation without impairing the comfort of the user.

The air conditioning control device according to the first aspect of the present invention includes a plurality of indoor units installed in the air conditioning target space, a plurality of compressors corresponding to each indoor unit, and a person detection unit that detects the presence or absence of a person in the air conditioning target space. It is an air conditioning control device that controls an air conditioning system including the above, and is provided with a control unit that controls the start-up of a compressor. When there is a command to operate a plurality of indoor units at the same time, the control unit shifts the start time of the compressor corresponding to each indoor unit based on the detection result by the human detection unit.

In this air-conditioning controller, since a plurality of compressors are started at different times, it is possible to prevent the concentration of power consumption at one time. Further, since the indoor unit in the space where the person is present can be preferentially operated based on the detection result by the person detection unit, it is possible to avoid giving discomfort to the user of the space.

The air-conditioning control device according to the second aspect of the present invention is the air-conditioning control device according to the first aspect, and the control unit preferentially operates an indoor unit belonging to a space in which a person is detected in the air-conditioning target space. Let me.

In this air-conditioning control device, the indoor unit in the space where the person is present can be preferentially operated based on the detection result by the person detection unit, so that it is possible to avoid giving discomfort to the user in the space.

The air-conditioning control device according to the third aspect of the present invention is the air-conditioning control device according to the first aspect, and a person detection unit is installed in each of a plurality of indoor units. The control unit gives priority to the operation of the indoor unit that detects a person.

In this air conditioning controller, when a plurality of indoor units are installed in a room with a person, the indoor unit located far from the person is in a position where the person can be detected rather than starting operation. When the indoor unit starts operation, the surrounding space of the person can be made quick and comfortable.

The air-conditioning control device according to the fourth aspect of the present invention is the air-conditioning control device according to the first aspect, and a communication control unit is further installed in each of the plurality of indoor units. The control unit sets in advance the time to start the compressor corresponding to each indoor unit when an operation start command is given to a plurality of indoor units at the same time, and periodically transmits the compressor to the communication control unit. Keep it.

In this air conditioning controller, even if the air conditioning system is stopped due to some trouble and each indoor unit is instructed to start operation at the same time, each indoor unit is notified in advance of the start time, so all The situation where the compressors are started all at once is prevented. As a result, it is possible to prevent the concentration of power consumption at one time.

In the air conditioning control device according to the first aspect of the present invention, since the plurality of compressors are started at different times, it is possible to prevent the power consumption from being concentrated at one time. Further, since the indoor unit in the space where the person is present can be preferentially operated based on the detection result by the person detection unit, it is possible to avoid giving discomfort to the user of the space.

In the air-conditioning control device according to the second aspect of the present invention, the indoor unit in the space where the person is present can be preferentially operated based on the detection result by the person detection unit, which causes discomfort to the user of the space. Giving is avoided.

In the air conditioning control device according to the third aspect of the present invention, when a plurality of indoor units are installed in a room with a person, the indoor unit located far from the person detects the person rather than starting the operation. It is possible to make the person's surrounding space quicker and more comfortable when the indoor unit in a position where it can be started to operate.

In the air conditioning control device according to the fourth aspect of the present invention, even if the air conditioning system is stopped due to some trouble and each indoor unit is instructed to start operation at the same time, each indoor unit has a start time in advance. Since it is reported, the situation where all the compressors are started at the same time is prevented. As a result, it is possible to prevent the concentration of power consumption at one time.

A plan view of a building in which multiple air conditioners that make up an air conditioning system are installed. FIG. 1A is a cross-sectional view taken along the line XX of the building shown in FIG. 1A. The block diagram which shows the structure of the control system of an air conditioning system. Configuration diagram of the air conditioner. The block diagram which shows the control part of an air conditioner. The operation flowchart of the centralized control unit. The operation flowchart of the centralized control unit in the 1st situation. The operation flowchart of the centralized control part in the 2nd situation. The operation flowchart of the centralized control unit in the third situation (step S31 to step S39, step S40). An operation flowchart of the centralized control unit in the third situation (steps S41 to S47). The operation flowchart of the centralized control unit in the third situation (steps S51 to S59).

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention.

(1) Outline of Air Conditioning System FIG. 1A is a plan view of a building in which a plurality of air conditioners 10A to 10U constituting the air conditioning system are installed. Further, FIG. 1B is a cross-sectional view taken along line XX of the building shown in FIG. 1A.

In FIGS. 1A and 1B, each of the plurality of air conditioners 10A to 10U is an air conditioner in which an indoor unit, which is a user-side unit installed on the ceiling, and a heat source-side unit arranged behind the ceiling are integrated. .. Since such an integrated specific structure is disclosed in, for example, Japanese Patent Application Laid-Open No. 9-324928, the description of the specific structure is omitted here.

The plurality of indoor units 21A to 21U are installed on the ceiling of the building, and the heat source side units 11A to 11U corresponding to each indoor unit are arranged in the attic space CS.

When the indoor units 21A to 21U are collectively referred to, it is expressed as "indoor unit 21", and when the heat source side units 11A to 11U are collectively referred to, it is expressed as "heat source side unit 11".

In this air conditioning system, indoor units 21 to be arranged for each room which is an air conditioning target space are determined. For example, indoor units 21A to 21C of air conditioners 10A to 10C are arranged in the first room R1.

Similarly, the indoor units 21E to 21H of the air conditioners 10E to 10H are in the second room R2, the indoor units 21I and 21J of the air conditioners 10I and 10J are in the third room R3, and the air conditioners 10N are in the fourth room R4. The indoor unit 21O of the air conditioner 10O is arranged in the indoor unit 21N and the fifth room R5, and the indoor units 21P to 21U of the air conditioners 10P to 10U are arranged in the sixth room R6.

Further, on the floor FL, indoor units 21D, 21K, 21L and 21M of air conditioners 10D, 10K, 10L and 10M are arranged.

FIG. 2 is a block diagram showing a configuration of a control system of an air conditioning system. In FIG. 2, in the air conditioning system, the centralized control unit 40 may communicate with the communication control unit 50 (see FIG. 4) mounted on each of the plurality of air conditioners 10A to 10U via the communication network 6. it can.

The communication network 6 is composed of a communication line using information and communication technology such as the Internet, an intranet, a LAN (Local, Area, Network), and a VPN (Virtual, Private, Network).

The centralized control unit 40 can cause the air conditioners 10A to 10U to perform various operations by remote control.

Hereinafter, the centralized control unit 40 and the air conditioners 10A to 10U will be described in detail. When the air conditioners 10A to 10U are collectively referred to, the term "air conditioner 10" is used.

(2) Configuration of Air Conditioner 10 FIG. 3 is a configuration diagram of the air conditioner 10. In FIG. 3, the air conditioner 10 is a refrigerating device capable of cooling operation and heating operation, and is connected to a liquid refrigerant for connecting the heat source side unit 11, the indoor unit 21, and the heat source side unit 11 and the indoor unit 21. It is provided with a pipe 2 and a gas refrigerant connecting pipe 3. For example, R32, which is a single refrigerant, is sealed in the refrigerant circuit C of the air conditioner 10.

(2-1) Configuration of Heat Source Side Unit 11 In FIG. 3, the heat source side unit 11 mainly includes a compressor 12, a four-way switching valve 15, a heat source side heat exchanger 13, and an expansion valve 14. Further, the heat source side unit 11 also has a heat source side fan 16.

(2-1-1) Compressor 12
The compressor 12 compresses the low-pressure refrigerant and discharges the compressed high-pressure refrigerant. In the compressor 12, a scroll type, rotary type, or other compression mechanism is driven by the compressor motor 12a. The operating frequency of the compressor motor 12a is changed by the inverter device.

(2-1-2) Heat source side heat exchanger 13
The heat source side heat exchanger 13 is a fin-and-tube heat exchanger. A heat source side fan 16 is installed in the vicinity of the heat source side heat exchanger 13. In the heat source side heat exchanger 13, the air conveyed by the heat source side fan 16 and the refrigerant exchange heat.

(2-1-3) Expansion valve 14
The expansion valve 14 is an electronic expansion valve having a variable opening degree. The expansion valve 14 is arranged on the downstream side of the heat source side heat exchanger 13 in the flow direction of the refrigerant in the refrigerant circuit C during the cooling operation.

During the cooling operation, the opening degree of the expansion valve 14 is adjusted so as to reduce the pressure (that is, the evaporation pressure) at which the refrigerant flowing into the indoor heat exchanger 32 can be evaporated in the indoor heat exchanger 32. Further, during the heating operation, the opening degree of the expansion valve 14 is adjusted so as to reduce the pressure of the refrigerant flowing into the heat source side heat exchanger 13 to a pressure at which the heat source side heat exchanger 13 can evaporate.

(2-1-4) Four-way switching valve 15
The four-way switching valve 15 has ports P1 to P4 from the first to the fourth. In the four-way switching valve 15, the first port P1 is connected to the discharge side of the compressor 12, the second port P2 is connected to the suction side of the compressor 12, and the third port P3 is the gas side of the heat source side heat exchanger 13. It is connected to the end and the fourth port P4 is connected to the gas side closing valve 5.

The four-way switching valve 15 switches between a first state (a state shown by a solid line in FIG. 1) and a second state (a state shown by a broken line in FIG. 1). In the four-way switching valve 15 in the first state, the first port P1 and the third port P3 communicate with each other, and the second port P2 and the fourth port P4 communicate with each other. In the four-way switching valve 15 in the second state, the first port P1 and the fourth port P4 communicate with each other, and the second port P2 and the third port P3 communicate with each other.

(2-1-5) Heat source side fan 16
The heat source side fan 16 is composed of a propeller fan 16a and a motor 16b that drives the propeller fan 16a. The rotation speed of the motor 16b is variable depending on the inverter device.

(2-1-6) Heat source side control unit 41a
As shown in FIG. 3, the heat source side unit 11 is equipped with a heat source side control unit 41a. Further, FIG. 4 is a block diagram showing a control unit 41 of the air conditioner 10. In FIG. 4, the heat source side control unit 41a has a built-in microcomputer 41aa and a memory 41ab. The microcomputer 41aa performs various calculations and gives a command to the device to be controlled. The memory 41ab stores various data.

(2-1-7) Attic temperature sensor 36
The attic temperature sensor 36 detects the temperature of the air flowing into the heat source side unit 11 on the air suction port side of the heat source side unit 11. In the present embodiment, the attic temperature sensor 36 includes a thermistor.

(2-2) Configuration of Indoor Unit 21 The indoor unit 21 has an indoor heat exchanger 32 and an indoor fan 27. Further, the indoor unit 21 is attached with a remote control unit (hereinafter, referred to as "remote controller 42"). The user can set various operation modes of the air conditioner 10 and the like via the remote controller 42.

(2-2-1) Indoor heat exchanger 32
The indoor heat exchanger 32 is a fin-and-tube heat exchanger. An indoor fan 27 is installed in the vicinity of the indoor heat exchanger 32.

The indoor heat exchanger 32 functions as a refrigerant evaporator to cool the indoor air during the cooling operation, and functions as a refrigerant condenser during the heating operation to heat the indoor air.

(2-2-2) Indoor fan 27
The indoor fan 27 is a cross flow fan. The indoor fan 27 has a fan 27a and an indoor fan motor unit 27b for rotating the fan 27a.

By operating the indoor fan 27, the indoor unit 21 sucks indoor air into the room, exchanges heat with the refrigerant in the indoor heat exchanger 32, and then supplies the indoor air as supply air. Further, the indoor fan 27 can change the air volume of the air supplied to the indoor heat exchanger 32 within a predetermined air volume range.

(2-2-3) Indoor control unit 41b
As shown in FIG. 1, the indoor unit 21 is equipped with an indoor control unit 41b. Further, as shown in FIG. 4, the indoor control unit 41b has a built-in microcomputer 41ba and a memory 41bb.

The microcomputer 41ba performs various calculations. Further, the memory 41bb stores various data.

Further, the indoor side control unit 41b communicates a control signal or the like with the remote controller 42 for individually operating the indoor unit 21, and further, the indoor side control unit 41b communicates with the heat source side unit 11 via a transmission line. Etc. are communicated.

(2-2-4) Various Sensors The indoor unit 21 is provided with an indoor heat exchange temperature sensor 44 and an indoor temperature sensor 46. The indoor heat exchange temperature sensor 44 is installed at an intermediate position of the indoor heat exchanger 32 and detects the saturation temperature of the refrigerant.

The indoor temperature sensor 46 is provided on the indoor air suction port side of the indoor unit 21. The indoor temperature sensor 46 detects the temperature of the indoor air flowing into the indoor unit 21.

In the present embodiment, the indoor heat exchange temperature sensor 44 and the indoor temperature sensor 46 are composed of a thermistor.

Further, the indoor unit 21 is equipped with a human detection sensor 48. As for the operating principle of the human detection sensor, many technical documents have already been published, and for example, it is described in detail in Japanese Patent No. 5310792, so the description thereof is omitted here.

(2-3) Centralized control unit 40
The centralized control unit 40 can remotely control the operating frequency of the compressor 12, the switching operation of the four-way switching valve 15, the opening degree of the expansion valve 14, and the rotation of the heat source side fan 16 and the indoor fan 27. Therefore, the centralized control unit 40 can also control communication with the outside.

In FIG. 2, the centralized control unit 40 controls each of the air conditioners 10A to 10U via the communication network 6. Each indoor unit 21 of each of the air conditioners 10A to 10U is equipped with a communication control unit 50 (see FIG. 4) so that signals can be transmitted and received to and from the centralized control unit 40.

Further, the centralized control unit 40 has a storage unit 401, a determination unit 403, a communication unit 405, and a command unit 407.

(2-3-1) Storage unit 401
The storage unit 401 stores data between each unit of the centralized control unit 40 and operation information communicated between the centralized control unit 40 and each of the air conditioners 10A to 10U.

(2-3-2) Judgment unit 403
The determination unit 403 determines whether or not the operating state of each of the air conditioners 10A to 10U satisfies the preset operating conditions based on the above operating information.

(2-3-3) Communication unit 405
The communication unit 405 is an interface to the communication network 6, and transmits a signal to the communication network 6 according to a command of the command unit 407, or receives a signal from the communication network 6 and sends a signal to that effect to the command unit 407.

(2-3-4) Command unit 407
The command unit 407 controls the communication unit 405 to receive the operation information transmitted from the air conditioners 10A to 10U, and controls the operation of each unit of the centralized control unit 40 based on the operation information.

(3) Operation of the air conditioner 10 In the air conditioner 10, the four-way switching valve 15 can switch the circulation cycle of the refrigerant to either the circulation cycle during the cooling operation or the circulation cycle during the heating operation.

(3-1) Cooling operation In the cooling operation, the four-way switching valve 15 shown in FIG. 3 is in the state shown by the solid line, and the compressor 12, the indoor fan 27, and the heat source side fan 16 are in the operating state. As a result, in the refrigerant circuit C, a refrigeration cycle is performed in which the heat source side heat exchanger 13 serves as a condenser and the indoor heat exchanger 32 serves as an evaporator.

Specifically, the high-pressure refrigerant compressed by the compressor 12 flows through the heat source side heat exchanger 13 and exchanges heat with air. In the heat source side heat exchanger 13, the high-pressure refrigerant dissipates heat to the air and condenses. The refrigerant condensed by the heat source side heat exchanger 13 is decompressed by the expansion valve 14 while being sent to the indoor heat exchanger 32, and then flows through the indoor heat exchanger 32.

In the indoor unit 21, the indoor air sucked by the indoor fan 27 passes through the indoor heat exchanger 32 and exchanges heat with the refrigerant at that time. In the indoor heat exchanger 32, the refrigerant absorbs heat from the indoor air and evaporates, and at that time, the air is cooled. The air cooled by the indoor heat exchanger 32 is supplied to the indoor space. Further, the refrigerant evaporated in the indoor heat exchanger 32 is sucked into the compressor 12 and compressed again.

(3-2) Heating operation In the heating operation, the four-way switching valve 15 shown in FIG. 1 is in the state shown by the broken line, and the compressor 12, the indoor fan 27, and the heat source side fan 16 are in the operating state. As a result, in the refrigerant circuit C, a refrigeration cycle is performed in which the indoor heat exchanger 32 serves as a condenser and the heat source side heat exchanger 13 serves as an evaporator.

Specifically, the high-pressure refrigerant compressed by the compressor 12 flows through the indoor heat exchanger 32. In the indoor unit 20, the indoor air sucked by the indoor fan 27 passes through the indoor heat exchanger 32 and exchanges heat with the refrigerant at that time. In the indoor heat exchanger 32, the refrigerant dissipates heat to the indoor air and condenses, and the air is heated at that time. The air heated by the indoor heat exchanger 32 is supplied to the indoor space. Further, the refrigerant condensed by the indoor heat exchanger 32 is depressurized by the expansion valve 14 and then flows through the heat source side heat exchanger 13. In the heat source side heat exchanger 13, the refrigerant absorbs heat from the air and evaporates. The refrigerant evaporated in the heat source side heat exchanger 13 is sucked into the compressor 12 and compressed again.

(4) Start Control of Air Conditioner 10 In this air conditioning system, the centralized control unit 40 remotely controls various operations of the plurality of air conditioners 10A to 10U via the control units 41 of the plurality of air conditioners 10A to 10U. ing. The air conditioning control device according to the present invention is composed of a centralized control unit 40 and control units 41 of each of the plurality of air conditioners 10A to 10U.

If all the air conditioners 10A to 10U are started at the same time at the start of daily air conditioning operation, the power consumption may exceed the peak power consumption of the contracted power, or a power outage may be caused by temporarily exceeding the supply capacity. There is a risk of

Therefore, in the air conditioning system according to the present embodiment, when all the air conditioners 10A to 10U are instructed to start operation at the same time, the compressor 12 is based on the detection result by the human detection sensor 48. Control is performed to shift the startup time.

Specifically, the centralized control unit 40 determines whether or not there is a person in each room R1 to R6 (see FIGS. 1A and 1B) from the detection signal of the person detection sensor 48, and determines that there is a person. Priority is given to the air conditioners belonging to the room to start operation.

At that time, it is necessary to assume three situations. First, the first situation is when there are people in all rooms and floors. The second situation is when all rooms and floors are empty. The third situation is a case where a room or floor with people and a room or floor without people are mixed.

The centralized control unit 40 determines which of the first situation, the second situation, and the third situation corresponds to, and starts the operation of each of the air conditioners 10A to 10U in a timely manner according to the situation.

(4-1) Operation of Centralized Control Unit 40 FIG. 5 is an operation flowchart of the centralized control unit 40. The operation will be described below with reference to FIG.

(Step S1)
First, the centralized control unit 40 determines in step S1 whether or not there is a start command for the compressor 12, proceeds to step S2 if there is a start command, and continues to determine whether or not there is a start command if there is no start command. To do.

(Step S2)
Next, in step S2, the centralized control unit 40 determines whether or not the activation command corresponds to simultaneous activation. Here, the simultaneous start means to start the compressors 12 of all the air conditioners 10A to 10U, or to start the compressors 12 of the air conditioners in a predetermined number or more of the rooms.

The centralized control unit 40 proceeds to step S3 when it is determined that it corresponds to the simultaneous start, and proceeds to step S5 when it determines that it does not correspond to the simultaneous start.

(Step S3)
Next, in step S3, the centralized control unit 40 confirms which of the first situation, the second situation, and the third situation is based on the presence status of the person in each room.

(Step S4)
Next, in step S4, the centralized control unit 40 proceeds to step S11 when the occupancy status of the person in each room is the first situation, proceeds to step S21 when the second situation, and when the third situation. The process proceeds to step S31.

(Step S5)
On the other hand, if the centralized control unit 40 determines in step S2 above that it does not correspond to simultaneous activation, the centralized control unit 40 proceeds to step S5 and performs normal activation control.

That is, for example, when only the air conditioners 10A, 10B, and 10C of the first room R1 are started, even if three units are started at the same time, the power consumption may exceed the peak power amount of the contract power. Since there is no risk of causing a power failure by temporarily exceeding the supply capacity, normal start control is performed.

(Step S6)
In step S6, the centralized control unit 40 determines whether or not the compressor 12 of the air conditioner to be activated has completed the activation, and if the activation is completed, the centralized control unit 40 ends the activation control.

(4-2) Operation of the centralized control unit 40 in the first situation Since the first situation is a situation in which there are people in all the rooms R1 to R6 and the floor FL, it is not a situation in which the start of operation of the air conditioner can be postponed. .. Therefore, in preparation for such a situation, the centralized control unit 40 sets in advance an air conditioner that first activates the compressor 12 for each room, and stores it in the storage unit 401.

The numbers in parentheses adjacent to the alphabet enclosed by the frame indicating each air conditioner in FIG. 1A indicate the priority of the air conditioners in each room.

Specifically, the air conditioner 10A in the first room R1, the air conditioner 10E in the second room R2, the air conditioner 10I in the third room R3, the air conditioner 10N in the fourth room R4, and the air conditioner 10O in the fifth room R5. In the sixth room R6, the air conditioner 10P is set as the air conditioner that first activates the compressor 12.

FIG. 6 is an operation flowchart of the centralized control unit 40 in the first situation. The operation will be described below with reference to FIG.

(Step S11)
In step S11, the centralized control unit 40 sets the order of the air conditioners to start the operation under the first situation, so that the first priority air conditioner group for starting the compressor 12 first and the second priority for starting the compressor 12 next. The air conditioner group, the third priority air conditioner group to be started next, and the fourth priority air conditioner group to be started next are specified.

In the present embodiment, as the first priority air conditioner group for first starting the compressor 12, the air conditioner 10A in the first room R1, the air conditioner 10D in the floor FL, the air conditioner 10E in the second room R2, and the third room R3 The air conditioner 10I, the air conditioner 10N in the fourth room R4, the air conditioner 10O in the fifth room R5, and the air conditioner 10P in the sixth room R6 are stored in advance in the storage unit 401.

Similarly, next to the first priority air conditioner group, as the second priority air conditioner group for activating the compressor 12, the air conditioner 10B in the first room R1, the air conditioner 10K in the floor FL, and the air conditioner in the second room R2. The air conditioner 10J in the 10th floor, the third room R3, and the air conditioner 10Q in the sixth room R6 are stored in the storage unit 401.

Further, as the third priority air conditioner group for activating the compressor 12 next to the second priority air conditioner group, the air conditioner 10C in the first room R1, the air conditioner 10L in the floor FL, and the air conditioner 10G in the second room R2. , And the air conditioner 10R of the sixth room R6 are stored in the storage unit 401.

Finally, as the fourth air conditioner group for activating the compressor 12, the air conditioner 10H in the second room R2, the air conditioner 10M in the floor FL, the air conditioners 10S, 10T, and 10U in the sixth room R6 are stored. It is stored in 401.

(Step S12)
In step S12, the centralized control unit 40 activates all the air conditioners 10A, 10D, 10E, 10I, 10N, 10O, and 10P compressors 12 belonging to the first priority air conditioner group.

(Step S13)
In step S13, the centralized control unit 40 determines whether or not all the air conditioners 10A, 10D, 10E, 10I, 10N, 10O, and 10P compressors 12 belonging to the first priority air conditioner group have completed activation. If the startup is completed, the process proceeds to step S14.

(Step S14)
In step S14, the centralized control unit 40 activates all the air conditioners 10B, 10K, 10F, 10J, and 10Q compressors 12 belonging to the second priority air conditioner group.

(Step S15)
In step S15, the centralized control unit 40 determines whether or not all the air conditioners 10B, 10K, 10F, 10J, and 10Q compressors 12 belonging to the second priority air conditioner group have completed the start-up, and the start-up is started. If it is completed, the process proceeds to step S16.

(Step S16)
In step S16, the centralized control unit 40 activates all the air conditioners 10C, 10L, 10G, and 10R compressors 12 belonging to the third priority air conditioner group.

(Step S17)
In step S17, the centralized control unit 40 determines whether or not all the air conditioners 10C, 10L, 10G, and 10R compressors 12 belonging to the third priority air conditioner group have completed the start-up, and the start-up is completed. If so, the process proceeds to step S18.

(Step S18)
In step S10, the centralized control unit 40 activates the compressors 12 of all the air conditioners 10H, 10M, 10S, 10T, and 10U belonging to the fourth priority air conditioner group.

(Step S19)
In step S19, the centralized control unit 40 determines whether or not all the air conditioners 10H, 10M, 10S, 10T, and 10U compressors 12 belonging to the fourth priority air conditioner group have completed the start-up, and the start-up is started. If it is completed, the start control is terminated.

(Action and effect)
As described above, the centralized control unit 40 groups a plurality of air conditioners 10A to 10U into room units and floor units, sets the priority of the air conditioners for activating the compressor 12 for each group, and stores the storage unit 401. I remember in.

Then, in steps S4 to S11, after the compressors 12 of each of the air conditioner groups having the first priority in each group are activated, the plurality of air conditioners 10A to 10U are activated, and then the air conditioners in the second rank are each activated. Since the compressor 12 is started at a different time so as to be started, it is possible to prevent the power consumption from being concentrated at one time.

Further, since at least one air conditioner compressor 12 is activated for each room and starts operation, for example, if a space that is always used by people is set in the space, the air conditioning start time will not be delayed. It also avoids causing discomfort to the users of the space.

(4-3) Operation of the centralized control unit 40 in the second situation In the second situation, since there are no people in all the rooms R1 to R6 and the floor FL, there is a room where the start of operation of the air conditioner can be postponed. is there. Therefore, the centralized control unit 40 can set priorities for each of the floor and the plurality of rooms in advance, and activate the compressor 12 of the air conditioner belonging to the corresponding room according to the priority.

FIG. 7 is an operation flowchart of the centralized control unit 40 in the second situation. The operation will be described below with reference to FIG. 7.

(Step S21)
In step S21, the centralized control unit 40 sets the order of the air conditioners to start the operation under the second situation, so that the first priority space air conditioner group for starting the compressor 12 first and the second for starting the compressor 12 next. The priority space air conditioner group, the third priority space air conditioner group to be started next, and the fourth priority space air conditioner group to be started next are specified.

The numbers in square brackets in the corners of each room and floor in FIG. 1A indicate the order of priority.

In the present embodiment, as the first priority space air conditioner group for first starting the compressor 12, the air conditioners 10I, 10J, 10N and 10O belonging to the third room R3, the fourth room R4 and the fifth room R5 are previously provided. It is stored in the storage unit 401.

Similarly, the air conditioners 10E, 10F, 10G and 10H belonging to the second room R2 are stored in the storage unit 401 as the second priority space air conditioner group for activating the compressor 12 next to the first priority space air conditioner group. It is remembered.

Further, as the third priority space air conditioner group that activates the compressor 12 next to the second priority space air conditioner group, the air conditioners 10A, 10B, 10C, 10D, 10K, and 10L belonging to the first room R1 and the floor FL. And 10M are stored in the storage unit 401.

Finally, as the fourth priority space air conditioner group for activating the compressor 12, the air conditioners 10P, 10Q, 10R, 10S, 10T and 10U of the sixth room R6 are stored in the storage unit 401.

(Step S22)
In step S22, the centralized control unit 40 activates the compressors 12 of all the air conditioners 10I, 10J, 10N and 10O belonging to the first priority space air conditioner group.

(Step S23)
In step S23, the centralized control unit 40 determines whether or not all the air conditioners 10I, 10J, 10N, and 10O compressors 12 belonging to the first priority space air conditioner group have completed the start-up, and the start-up is completed. If so, the process proceeds to step S24.

(Step S24)
In step S24, the centralized control unit 40 activates the compressors 12 of all the air conditioners 10E, 10F, 10G, and 10H belonging to the second priority space air conditioner group.

(Step S25)
In step S25, the centralized control unit 40 determines whether or not all the air conditioners 10E, 10F, 10G, and 10H compressors 12 belonging to the second priority space air conditioner group have completed the start-up, and the start-up is completed. If so, the process proceeds to step S26.

(Step S26)
In step S26, the centralized control unit 40 activates all the air conditioners 10A, 10B, 10C, 10D, 10K, 10L and 10M compressors 12 belonging to the third priority space air conditioner group.

(Step S27)
In step S27, the centralized control unit 40 determines whether or not all the air conditioners 10A, 10B, 10C, 10D, 10K, 10L, and 10M compressors 12 belonging to the third priority space air conditioner group have completed activation. If the startup is completed, the process proceeds to step S28.

(Step S28)
In step S28, the centralized control unit 40 activates the compressors 12 of all the air conditioners 10P, 10Q, 10R, 10S, 10T and 10U belonging to the fourth priority space air conditioner group.

(Step S29)
In step S29, the centralized control unit 40 determines whether or not all the air conditioners 10P, 10Q, 10R, 10S, 10T, and 10U compressors 12 belonging to the fourth priority space air conditioner group have completed startup. If the startup is completed, the startup control is terminated.

(Action and effect)
As described above, the centralized control unit 40 groups a plurality of air conditioners 10A to 10U into room units and floor units, sets priorities for each group, and stores them in the storage unit 401. The air conditioner in step S21 can be specified by the method of "activating the compressor 12 of the air conditioner belonging to the high priority group".

Then, in steps S22 to S29, after the compressors 12 of the air conditioner group having the first priority are activated for the plurality of air conditioners 10A to 10U, the compressors of the air conditioner group having the second highest priority are started. Since the 12 is started at a different time so as to be started, it is possible to prevent the power consumption from being concentrated at one time.

(4-4) Operation of Centralized Traffic Control Unit 40 in Third Situation The third situation is a case where a room or floor with people and a room or floor without people coexist. Complex situations are assumed, such as when there are people in only one room or when there are no people in only one room.

Here, for convenience of explanation, the total number of air conditioners is N, the total number of air conditioners belonging to a room where a person is present is n, and the allowable number of simultaneous start-ups capable of simultaneously starting the compressors 12 of a plurality of air conditioners is α. And.

8, 9 and 10 are operation flowcharts of the centralized control unit 40 in the third situation. The operation will be described below with reference to FIGS. 8 to 10.

(4-4-1) Step S31 to step S38, step S40
(Step S31)
In step S31, the centralized control unit 40 determines whether or not the total n of the air conditioners belonging to the room in which the person is present is larger than the allowable number α for simultaneous start, and when it is determined that “n> α”, the step Proceed to S32.

On the other hand, when the centralized control unit 40 determines that "n> α is not satisfied", the process proceeds to step S40, and in step S40, the compressors 12 of all the air conditioners in the room where the person is present are started all at once.

(Step S32)
In step S32, the centralized control unit 40 selects air conditioners in order of priority from each room in which a person is present until the total number of air conditioners reaches α.

In FIG. 1A, the total number N of the air conditioners is 21, and for example, if there are people in the first room R1, the third room R3, and the sixth room R6, the air conditioners belonging to the room where the people are present The total n is 11 units.

Assuming that the number of air conditioners allowed to be started simultaneously is 7, the air conditioner 10A having the highest priority in the first room R1, the air conditioner 10I having the first priority in the third room R3, and the air conditioner R6 having the first priority in the third room R3. 1st priority air conditioner 10P, 1st room R1 priority 2nd priority air conditioner 10B, 3rd room R3 priority 2nd priority air conditioner 10J, 6th room R6 priority 2nd A total of 6 air conditioners 10Q are selected.

The remaining one is selected from the air conditioners having the third highest priority among the air conditioners belonging to the first room R1, the third room R3, and the sixth room R6. However, since only two air conditioners are originally installed in the third room R3, the air conditioners having the third priority belonging to the first room R1 and the sixth room R6 are actually selected. ..

The centralized control unit 40 sets priorities for all rooms in advance and stores them in the storage unit 401. Specifically, from the one with the highest priority [3rd room R3, 4th room R4, and 1st room]. The order is set to [5 room R5], [2nd room R2], [1st room R1 and floor FL], and [6th room R6].

Therefore, for the remaining one, the air conditioner 10C having the third priority in the first room R1 is selected.

(Step S33)
In step S33, the centralized control unit 40 has the selected first room R1 with the first priority air conditioner 10A, the third room R3 with the first priority air conditioner 10I, and the sixth room R6 with the first priority. 1st place air conditioner 10P, 1st room R1 priority 2nd place air conditioner 10B, 3rd room R3 priority 2nd place air conditioner 10J, 6th room R6 priority 2nd place air conditioner The compressor 12 of the air conditioner 10C having the third priority in 10Q and the first room R1 is activated.

(Step S34)
In step S34, the centralized control unit 40 subtracts [the number of air conditioners α in which the compressor 12 is activated] from [the total number of air conditioners belonging to the room where the person is present n] for the number of air conditioners allowed to start all at once α. It is determined whether or not the value (n−α) is exceeded.

Then, the centralized control unit 40 proceeds to step S35 when it is determined that “α ≧ n−α”, and proceeds to step S51 when it is determined that “α ≧ n−α is not”.

In the explanation by the example, since α = 7> n−α = 11-7 = 4, the process proceeds to step S35.

(Step S35)
In step S35, the centralized control unit 40 operates the air conditioners in order from the air conditioner having the highest priority in each room where the person is present until the total number reaches n-α, except for the air conditioner in which the compressor 12 has already been started. select.

Here, as the remaining four air conditioners, air conditioners 10R, 10S, 10T, and 10U in which the compressor 12 of the sixth room R6 has not been started are selected.

(Step S36)
The centralized control unit 40 activates the compressor 12 of the selected air conditioner in step S36. Here, the compressors 12 of the air conditioners 10R, 10S, 10T and 10U of the sixth room R6 are started. At this point, the compressors 12 of all the air conditioners in the room where the person is present are activated.

(Step S37)
In step S37, the centralized control unit 40 has a value (N) obtained by subtracting [total number of air conditioners belonging to a room with people n] from [total number of air conditioners N] in [allowable number of air conditioners to start all at once α]. -N) is determined whether or not it exceeds.

Then, the centralized control unit 40 proceeds to step S38 when it is determined that “α ≧ Nn”, and proceeds to step S41 when it is determined that “α ≧ Nn is not”.

In the explanation by the example, since α = 7 <Nn = 21-11 = 10, the process proceeds to step S41, which will be described in the columns after step S41.

(Step S38)
In step S38, the centralized control unit 40 activates the compressor 12 for all the air conditioners in each room where no one is present.

This is because the total Nn of the air conditioners in which the compressors 12 are not activated is equal to or less than the allowable number of simultaneous activations α, so that all the target compressors 12 can be activated at once.

(4-4-2) Steps S41 to S47
When proceeding from step S37 to step S41, when proceeding from step S40 to step S41, and when proceeding from step S58 to step S41, the operation after activating the compressors 12 of all the air conditioners in the room where the person is present. Is.

Therefore, after step S41, the operation is to activate the compressor 12 of the air conditioner in the room where no one is present.

(Step S41)
The centralized control unit 40 sets the variable m to 0 in step S41.

(Step S42)
In step S42, the centralized control unit 40 selects air conditioners in order from the air conditioner having the highest priority in each room where no person is present, until the total number of air conditioners reaches α.

For example, in the case where the process proceeds from step S37 to step S41, since Nn = 21-11 = 10, all 10 air conditioners in each room where no person is present are in a stopped state.

Specifically, all the air conditioners in the second room R2, the fourth room R4, the fifth room R5, and the floor FL are targeted.

Since the allowable number of air conditioners for simultaneous activation is 7, the air conditioner 10E having the highest priority in the second room R2, the air conditioner 10N having the highest priority in the fourth room R4, and the fifth room Air conditioner 10O with the highest priority of R5, air conditioner 10D with the highest priority of the floor FL, air conditioner 10F with the second highest priority of the second room R2, and air conditioner with the second highest priority of the floor FL. A total of 6 aircraft 10K will be selected.

The remaining one is selected from the air conditioners having the third highest priority among the air conditioners belonging to the second room R2 or the floor FL.

The centralized control unit 40 sets priorities for all rooms in advance and stores them in the storage unit 401. Specifically, [3rd room R3, 4th room R4 and 5th room R5], [ The order is set to [2nd room R2], [1st room R1 and floor FL], and [6th room R6].

Therefore, for the remaining one, the air conditioner 10G having the third priority of the second room R2, which has a higher priority of the room than the floor FL, is selected.

(Step S43)
In step S43, the centralized control unit 40 has the selected second room R2 with the first priority air conditioner 10E, the fourth room R4 with the first priority air conditioner 10N, and the fifth room R5 with the first priority. 1st air conditioner 10O, 1st floor FL priority 1st air conditioner 10D, 2nd room R2 2nd priority air conditioner 10F, floor FL 2nd priority air conditioner 10K, and 1st The compressor 12 of the air conditioner 10G, which has the third highest priority in the two-room R2, is activated.

(Step S44)
The centralized control unit 40 adds 1 to the variable m in step S44.

(Step S45)
In step S45, the centralized control unit 40 changes the [allowable number of air conditioners to start all at once α] to [the total number of air conditioners N to the total number of air conditioners belonging to the room where people are present n] and [allowable number of air conditioners to start all at once]. It is determined whether or not the value (N−n−α × m) obtained by subtracting [the number multiplied by the variable m] is exceeded.

Here, [the number obtained by multiplying the allowable number of simultaneous start-ups α by the variable m] corresponds to the number of air conditioners in the room where there are no people who have already started the compressor 12.

Then, when the centralized control unit 40 determines that "α ≧ N-n-α × m", the centralized control unit 40 proceeds to step S46, and when it determines that "α ≧ N-n-α × m is not", the centralized control unit 40 proceeds to step S46. Return to S42.

In the explanation by the example, since α = 7 ≧ Nn−α × m = 21-11-7 × 1 = 3, the process proceeds to step S46.

(Step S46)
In step S46, the centralized control unit 40 has a total number of Nn-α × m (=) in order from the air conditioner having the highest priority in each room where no person is present, except for the air conditioner in which the compressor 12 has already been started. 21-11-7 × 1 = 3) Select the air conditioner until the number is reached.

Here, the air conditioner 10L having the third priority on the floor FL, the air conditioner 10H having the fourth priority on the second room R2, and the air conditioner 10M having the fourth priority on the floor FL are selected.

(Step S47)
In step S47, the centralized control unit 40 ranks the selected floor FL with the third priority air conditioner 10L, the second room R2 with the fourth priority air conditioner 10H, and the floor FL with the fourth priority. The compressor 12 of the air conditioner 10M is started.

At this point, the compressors 12 of all the air conditioners in the unoccupied room are activated.

(4-4-3) Steps S51 to S59
The case where the process proceeds from step S34 to step S51 is a case where a plurality of group activations are required in order to activate the compressors 12 of all the air conditioners in the room where the person is present.

Therefore, after step S51, the second and subsequent group activations targeting the compressor 12 of the air conditioner in the room where the person is present.

(Step S51)
The centralized control unit 40 sets the variable s to 1 in step S51.

(Step S52)
In step S52, the centralized control unit 40 operates the air conditioners in order from the air conditioner having the highest priority in each room where people are present, except for the air conditioner 10 which has already started the compressor 12, until the total number of air conditioners reaches α. select. The selection method is performed in the manner of step S32 and step S35.

(Step S53)
In step S53, the centralized control unit 40 activates the compressor 12 of the α-unit air conditioner selected.

(Step S54)
The centralized control unit 40 adds 1 to the variable s in step S54.

(Step S55)
In step S55, the centralized control unit 40 changes the [allowable number of air conditioners to start simultaneously α] from [total n of air conditioners belonging to a room with people] to [the number obtained by multiplying the allowable number of simultaneous start α by the variable s]. It is determined whether or not the value obtained by subtracting (n−α × s) is exceeded.

Here, [the number obtained by multiplying the allowable number of simultaneous start-ups α by the variable s] corresponds to the number of air conditioners in the room in which the person is present who have already started the compressor 12.

Then, the centralized control unit 40 proceeds to step S56 when it is determined that “α ≧ n−α × s”, and returns to step S52 when it is determined that “it is not α ≧ n−α × s”.

(Step S56)
In step S56, the centralized control unit 40 air-conditions in order from the air conditioner having the highest priority in each room where people are present, except for the air conditioner in which the compressor 12 has already been started, until the total number of air conditioners reaches the n−α × s level. Select a machine.

(Step S57)
In step S57, the centralized control unit 40 activates the selected n−α × s compressors 12. At this point, the compressors 12 of all the air conditioners in the room where the person is present are activated.

(Step S58)
In step S58, the centralized control unit 40 has a value (N) obtained by subtracting [total number of air conditioners belonging to a room with people n] from [total number of air conditioners N] by [allowable number of air conditioners to start all at once α]. -N) is determined whether or not it exceeds.

Then, the centralized control unit 40 proceeds to step S59 when it is determined that “α ≧ Nn”, and proceeds to step S41 when it is determined that “α ≧ Nn is not”.

(Step S59)
In step S59, the centralized control unit 40 activates the compressor 12 for all the air conditioners in each room where no one is present.

This is because the total Nn of the air conditioners in which the compressors 12 are not activated is equal to or less than the allowable number of simultaneous activations α, so that all the target compressors 12 can be activated at once (action and effect). )
As described above, the centralized control unit 40 stores the air conditioner in the room where the person is present in advance in the storage unit 401 [priority of the air conditioner for activating the compressor 12]. Select.

Then, after all the air conditioners 10 in the room where the person is present are activated, the air conditioner 10 in the room where there is no person is also stored in the storage unit 401 in advance [of the air conditioner that activates the compressor 12 Select an air conditioner based on [Priority].

In this way, since the compressor of the air conditioner is started at different times, it is possible to prevent the power consumption from being concentrated at one time.

Further, since at least one compressor 12 of the air conditioner is activated and starts operation in each room, the start time of air conditioning is not delayed, and it is possible to avoid giving discomfort to the user of the space.

(5) Features (5-1)
Since the centralized control unit 40 activates the plurality of compressors 12 at different times, it is possible to prevent the power consumption from being concentrated at one time.

(5-2)
Further, since the centralized control unit 40 preferentially operates the air conditioner belonging to the room in which the person is detected based on the detection result by the person detection sensor 48, it may cause discomfort to the user of the room. Avoided.

(6) Modification Example (6-1) First Modification Example In the above embodiment, the compressor 12 of the air conditioner 10 in the room where the person is present has a preset priority with respect to the air conditioner 10 belonging to the room. It is started according to.

However, the present invention is not limited to this, and since the human detection sensor 48 is provided in each indoor unit 21, the compressor 12 corresponding to the indoor unit 21 that has detected a person may be preferentially activated. ..

When a plurality of indoor units 21 (air conditioners 10) are installed in a room, the indoor unit 21 located at a position where the person can be detected rather than the indoor unit 21 located far from the person starts operation. The person who starts driving can make the person's surrounding space quicker and more comfortable.

(6-2) Second Modified Example In the above embodiment, an air conditioner that starts the compressor 12 in order to avoid concentration of power consumption when an operation start command is given to a plurality of air conditioners 10 at the same time. A method of presetting the priority of 10 is adopted.

However, whether or not there are people in the room depends on the day and time, so rather than fixing the priority of the air conditioner 10 that activates the compressor 12, it is based on the actual usage of the room each time. Alternatively, it may be rational to change the priority at regular intervals.

In the second modification, the centralized control unit 40 sets the timing for starting the compressor 12 for each of the air conditioners 10 in preparation for the case where the operation start command is given to the plurality of air conditioners 10 at the same time. It can also be set in advance and periodically transmitted to the communication control unit 50.

Therefore, even if the air conditioning system is stopped due to some trouble and each air conditioner 10 is instructed to start operation at the same time, the start time of each air conditioner 10 is notified in advance, so that all the air conditioners 10 are started. A situation in which the compressors 12 are started all at once is prevented. As a result, it is possible to prevent the concentration of power consumption at one time.

(6-3) Third Modified Example In the above embodiment, the centralized control unit 40 identifies a room in which a person is located based on the detection result of the person detection sensor 48. For example, entry / exit card information of each room is used. The control system / communication system may be changed so as to determine whether or not there is a person in the room. Of course, it is also possible to change so that the determination is made based on the combination of the entry / exit card information and the detection result of the person detection sensor 48.

(7) Others In the above-described embodiment and the above-described modification, the centralized control unit 40 is provided separately from the control units 41 of the air conditioners 10A to 10U. However, the present invention is not limited to this, and any of the air conditioners 10A to 10U may be set as the master unit, and the control unit 41 of the master unit may be set as the centralized control unit.

According to the air-conditioning controller according to the present invention, even if there is a simultaneous start request for the compressors of a plurality of air conditioners, the compressors of the air conditioner group having a high priority to be started are started first. It is possible to avoid the simultaneous start-up of the compressor and prevent the concentration of power consumption.

Therefore, the field of application is not limited to an air conditioner in which the indoor unit, which is the user side unit, and the heat source side unit are integrated, and is also useful for an air conditioner in which the indoor unit and the heat source side unit are separated.

12 Compressor 21 Indoor unit 40 Centralized control unit (control unit)
48 person detection sensor (person detection unit)
50 Communication control unit

Japanese Unexamined Patent Publication No. 11-159837

Claims (4)

A plurality of indoor units (21) installed in the air-conditioned space, a plurality of compressors (12) corresponding to the indoor units (21), and a person detection unit (48) for detecting the presence or absence of a person in the air-conditioned space. ) Is an air conditioning control device that controls the air conditioning system, including
A control unit (40) that controls the activation of the compressor (12) is provided.
The control unit (40)
When there is a command to operate the plurality of indoor units (21) at the same time, the compressor (12) corresponding to each indoor unit (21) is based on the detection result by the human detection unit (48). ) Shift the startup time,
Air conditioning controller. The control unit (40) preferentially operates the indoor unit (21) belonging to the space in which a person is detected in the air-conditioned space.
The air conditioning control device according to claim 1. The person detection unit (48) is installed in each of the plurality of indoor units.
The control unit (40) preferentially operates the indoor unit (21) that has detected a person.
The air conditioning control device according to claim 1. A communication control unit (50) is further installed in each of the plurality of indoor units (21).
The control unit (40) activates the compressor (12) corresponding to each of the indoor units (21) when an operation start command is given to the plurality of indoor units (21) at the same time. The time is set in advance and is periodically transmitted to the communication control unit (50).
The air conditioning control device according to claim 1.

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