JP7329332B2 - AIR CONDITIONING SYSTEM AND CONTROL METHOD OF AIR CONDITIONING SYSTEM - Google Patents

Description

The present invention relates to an air conditioning system that uses a plurality of indoor units to adjust the temperature of a large indoor space.

2. Description of the Related Art In an air conditioning system installed in a place such as an office, a plurality of indoor units are arranged in one room in order to air-condition a large indoor space. Then, each indoor unit performs cooling operation or heating operation, so that the entire indoor space is adjusted to a comfortable room temperature.
In such an air conditioning system, the temperature of the space is detected by the temperature sensor of the indoor unit, and control is performed based on the detected temperature so as to equalize the temperature of the entire space. Furthermore, there is also known a system in which presence or absence of a person is detected by a human sensor, and control is performed based on the detection result.

Patent Literature 1 describes detecting movement of people in each air-conditioned area and air-conditioning each air-conditioned area based on the detection result. Thereby, in patent document 1, the reduction of consumption energy is aimed at.

In addition, there is a technique called zoning air conditioning, in which cold or hot heat is sufficiently heat-exchanged in a target zone and then flowed to the outside. By using this technology, the outflow of air-conditioning heat to the outside of the target zone is reduced, making it possible to operate with the air-conditioning load of only the target zone.

JP 2014-240729 A

Indoor units for zoning air conditioning and indoor units not for zoning air conditioning are sometimes installed together. This is because, for example, it may not be possible to install an indoor unit for zoning air conditioning in a part of the indoor space due to the layout of the building, etc. This is because indoor units that are not for air conditioning are installed. Specifically, since the indoor unit for zoning air conditioning is separated from the air outlet, it is necessary to pass a duct. However, due to the layout of the building, etc., there are places where it is difficult to pass the ducts. Indoor units for zoning air conditioning cannot be installed in this location.

When the indoor units for zoning air conditioning and the indoor units for non-zoning air conditioning are installed together, if conventional control is applied, the air blown out by the indoor units not for zoning air conditioning will It invades the machine's target zone. Then, the indoor unit for zoning air conditioning will process even the load of the zone in which the indoor unit for non-zoning air conditioning is installed. As a result, the energy saving performance of the indoor unit for zoning air conditioning is impaired.

An object of the present invention is to improve energy saving performance when indoor units for zoning air conditioning and indoor units not for zoning air conditioning are installed together.

The air conditioning system according to the present invention is
An air conditioning system that air-conditions a space divided into multiple zones,
It includes a first indoor unit that is an indoor unit for zoning air conditioning that blows air toward the center of the zone, and a second indoor unit that is not an indoor unit for zoning air conditioning, and is installed corresponding to each of the plurality of zones. a plurality of indoor units that are
A control device for controlling indoor units installed in each of the plurality of zones when the target zone changes from an existing zone in which a person exists to an absent zone in which no person exists. and a control device that performs different control depending on whether the indoor unit is the first indoor unit or the second indoor unit.

In this invention, when the target zone changes from the present zone to the absent zone, the indoor unit provided in the target zone is the first indoor unit for zoning air conditioning, and the indoor unit for zoning air conditioning is Different control is performed depending on whether it is the second indoor unit or the second indoor unit that is not. This makes it possible to improve energy saving performance when indoor units for zoning air conditioning and indoor units not for zoning air conditioning are installed together.

2 is an explanatory diagram of a space 200 in which the air conditioning system 100 according to Embodiment 1 is installed; FIG. 1 is a configuration diagram of an air conditioning system 100 according to Embodiment 1. FIG. 2 is a configuration diagram of a first indoor unit 110 and a second indoor unit 120 according to Embodiment 1. FIG. 2 is a configuration diagram of a control device 133 according to Embodiment 1. FIG. 10 is a flow chart showing control when the zone 201 changes from a presence zone in which a person exists to an absent zone in which no person exists.

Embodiment 1.
*** Configuration description ***
A space 200 in which an air conditioning system 100 according to Embodiment 1 is installed will be described with reference to FIG.
In FIG. 1, space 200 indicates an office. The office indicated by the space 200 is grouped into Group E, Group F, Group G, and Group H according to the content of work, and fixtures for each group are arranged.

The superior seat 311E is for the superior of Group E, the superior seat 311F is for the superior of Group F, the superior seat 311G is for the superior of Group G, and the superior seat 311H is for the superior of Group G. This is the seat of the superior of Group H. In addition, the person in charge seat 312A and the person in charge seat 312E are seats for the person in charge of the group E, the person in charge seat 312F is the seat for the person in charge in the group F, and the person in charge seat 312C and the person in charge seat 312G are the seat for the person in charge of the group G. A person in charge seat 312H is a seat for the person in charge of Group H. Each agent seat 312 has seats for six agents. As a general rule, superiors and persons in charge are seated at their own desks.
A meeting space 313B and a meeting space 313D are provided in addition to the manager's seat 311 and the person in charge seat 312 . The meeting space 313B and the meeting space 313D are occupied only during meetings.
The office is accessed through doors 314A and 314D. A space between the manager's seat 311, the person in charge's seat 312, and the meeting space 313 is used as an aisle.

The configuration of the air conditioning system 100 according to Embodiment 1 will be described with reference to FIG.
The air conditioning system 100 is installed in a large commercial building such as an office building, and performs indoor air conditioning. The air conditioning system 100 air-conditions a space 200 divided into a plurality of zones 201 . In FIG. 2, space 200 is divided into eight zones, zone 201A through zone 201H. That is, the eight zones from zone 201A to zone 201H are the air conditioning target areas of the air conditioning system 100 . Each zone 201 is, for example, a rectangular area with a side of about 7.2 m (meters).
Although the boundaries of each zone are indicated by dotted lines in FIG. 2, there are no walls at the boundaries of each zone.

A staff seat 312A is arranged in the zone 201A. A meeting space 313B is arranged in the zone 201B. A staff seat 312C is arranged in the zone 201C. A meeting space 313D is arranged in the zone 201D. A superior seat 311E and a staff seat 312E are arranged in the zone 201E. A senior seat 311F and a staff seat 312F are arranged in the zone 201F. A senior seat 311G and a staff seat 312G are arranged in the zone 201G. A superior seat 311H and a staff seat 312H are arranged in the zone 201H.

The air conditioning system 100 includes a plurality of indoor units including a first indoor unit 110 that is an indoor unit for zoning air conditioning and a second indoor unit 120 that is not an indoor unit for zoning air conditioning. Each indoor unit is installed corresponding to each of a plurality of zones. In FIG. 2, the first indoor unit 110 is installed in the zone 201A, the zone 201C, the zone 201E, the zone 201F, the zone 201G, and the zone 201H where the chief seat 311 or the person in charge seat 312 is located. Second indoor units 120 are installed in zone 201B and zone 201D where meeting space 313 is located.
It should be noted that the size of each zone 201 need not be the same.

The configurations of the first indoor unit 110 and the second indoor unit 120 according to Embodiment 1 will be described with reference to FIG.
In FIG. 3, two zones 201 are shown, zone 201A and zone 201B. In FIG. 3, dashed arrows indicate the blowing wind direction.

The first indoor unit 110 for zoning air-conditioning is an indoor unit in which cold or hot heat is sufficiently heat-exchanged in the target zone 201 and then flowed to the outside. Specifically, the first indoor unit 110 is provided with an air outlet 111 at the end of the target zone 201 and with an air inlet 112 at the center of the target zone 201. is an indoor unit that blows air toward the center of the zone 201 of . That is, the first indoor unit 110 is an indoor unit that blows air from the air outlet 111 toward the air inlet 112 . That is, the first indoor unit 110 is an indoor unit that blows air toward the inside of the target zone 201 . By blowing air in this way, it is possible to selectively thermally regulate the zone 201 of interest.
Note that the outlet 111 may be installed at a position slightly closer to the center than the end of the target zone 201 . Here, when the zone 201 is a rectangular area with one side of 7.2 m, the outlet 111 is installed within a range of 3.6 m from the inlet 112 .
In Embodiment 1, the first indoor unit 110 is a ceiling-embedded indoor unit.

In FIG. 3, the first indoor unit 110 is provided with outlets 111a to 111d near four sides of a rectangular target zone 201A. A suction port 112 is provided in the center of the target zone 201A. Air is blown out toward the suction port 112 from the outlets 111a to 111d.
Note that the outlets 111 may not be provided in the vicinity of each of the four sides. For example, there may be three outlets 111, and the outlets 111 may be provided only near three of the four sides. Also, the outlets 111 may be provided at each of the four corners of the rectangular target zone 201A.

The second indoor unit 120 that is not for zoning air conditioning is an indoor unit that does not blow air like the first indoor unit 110 for zoning air conditioning. For example, the second indoor unit 120 is an indoor unit that blows air outward from the center of the target zone 201 . In Embodiment 1, the second indoor unit 120 is a four-way ceiling cassette type indoor unit.
In FIG. 3, the second indoor unit 120 is provided with four outlets 121a to 121d immediately outside the suction port 122 provided in the center. Then, air is blown out from the outlets 121a to 121d toward the outside of the target zone 201B.

Each first indoor unit 110 and each second indoor unit 120 is provided with a human sensor 131 . The human sensor 131 detects whether or not a person exists in the zone 201 where the first indoor unit 110 or the second indoor unit 120 is installed. A specific example of the human sensor 131 is an infrared sensor.
Accordingly, each of the first indoor units 110 and each of the second indoor units 120 can determine whether or not a person exists in the zone 201 in which it is installed, using the human sensor 131 installed therein. Therefore, it is not necessary to link information indicating that the human sensor 131 and the first indoor unit 110 or the second indoor unit 120 are in the same zone 201, and the installation work can be reduced.
Note that the method of detecting whether or not a person exists in each zone 201 is not limited to the method using the human sensor 131 . For example, it is possible to detect whether or not a person exists in each zone 201 by detecting whether or not a computer installed in each zone 201 is operated by a keyboard.

Each first indoor unit 110 and each second indoor unit 120 is provided with a temperature sensor 132 near the inlet 112 or the inlet 122 . Temperature sensor 132 detects the temperature of the air drawn into inlet 112 or inlet 122 .

Each first indoor unit 110 and each second indoor unit 120 is provided with a control device 133 . The control device 133 controls at least one of the first indoor unit 110 or the second indoor unit 120 and the outdoor unit connected to the first indoor unit 110 or the second indoor unit 120 .

The configuration of the control device 133 according to the first embodiment will be described with reference to FIG.
The control device 133 is a computer such as a microcomputer. The control device 133 includes a measurement section 141 , a calculation section 142 , a control section 143 and a storage section 144 .
The measurement unit 141 acquires information such as the result detected by the human sensor 131 and the temperature detected by the temperature sensor 132 . The computing unit 142 computes various operating parameters based on the information acquired by the measuring unit 141 . The control unit 143 controls at least one of the first indoor unit 110 and the outdoor unit connected to the first indoor unit 110 according to the operating parameters calculated by the calculation unit 142 . The storage unit 144 stores information necessary for control. As a specific example, the storage unit 144 of the first indoor unit 110 stores type information indicating that the first indoor unit 110 is for zoning air conditioning. The storage unit 144 of the second indoor unit 120 stores type information indicating that the second indoor unit 120 is not for zoning air conditioning. The storage unit 144 of the first indoor unit 110 and the second indoor unit 120 includes both the first indoor unit 110 for zoning air conditioning and the second indoor unit 120 not for zoning air conditioning. I remember that.

***Description of operation***
The operation of the air conditioning system 100 according to Embodiment 1 will be described.
The operation of the air conditioning system 100 according to Embodiment 1 corresponds to the control method of the air conditioning system 100 according to Embodiment 1.

First, the basic operation of the air conditioning system 100 according to Embodiment 1 will be described.
In the air conditioning system 100, a user selects an operation mode such as a cooling operation, a heating operation, and a fan operation.
When the operation mode is the cooling operation, the air sucked from the suction port 112 of each first indoor unit 110 is cooled, blown out from the blowout port 111, and sucked from the suction port 122 of each second indoor unit 120. The cooled air is cooled and blown out from the outlet 121 . When the operation mode is the heating operation, the air sucked from the suction port 112 of each first indoor unit 110 is heated, blown out from the blowout port 111, and sucked from the suction port 122 of each second indoor unit 120. The heated air is heated and blown out from the outlet 121 . When the operation mode is the fan operation, the air sucked from the suction port 112 of each first indoor unit 110 is blown out from the blowout port 111 as it is, and the air sucked from the suction port 122 of each second indoor unit 120 is blown out. The air is blown out from the outlet 121 as it is.
At this time, for each zone 201, the control device 133 of the indoor unit installed in the target zone 201 determines whether the temperature of the target zone 201 has reached the set temperature and whether there is a person in the target zone 201. Operation control is performed based on the information such as Specifically, the controller 133 controls operating parameters such as thermo ON/OFF, set temperature, air volume, and wind direction. Note that "thermo-on" is an operation in which the outdoor unit is operated, and "thermo-off" is an operation in which the outdoor unit is not operated. That is, when the thermostat is turned off, even if the operation mode is the cooling operation or the heating operation, the state is the same as that of the fan operation.

Referring to FIG. 5, the control when zone 201 changes from a presence zone in which a person exists to an absence zone in which no person exists will be described.
The processing shown in FIG. 5 is periodically executed by the control device 133 of each first indoor unit 110 and each second indoor unit 120 .

(Step S1: detection processing)
The measurement unit 141 of the control device 133 acquires the detection result of the human sensor 131 . The detection result of the human sensor 131 indicates whether or not a person exists in the target zone 201 . The measurement unit 141 writes the detection result of the human sensor 131 to the storage unit 144 .

(Step S2: Change determination processing)
The control unit 143 of the control device 133 reads out the detection result acquired in step S1 from the storage unit 144 .
If the detection result indicates that a person exists, the control unit 143 advances the process to step S3. On the other hand, when the detection result indicates that there is no person, the control unit 143 advances the process to step S4.

(Step S3: Reference value setting process)
The control unit 143 of the control device 133 sets various operating parameters as reference values. Here, the reference value is a value calculated by the calculation unit 142 based on information such as the temperature detected by the temperature sensor 132 .

(Step S4: type determination processing)
The control unit 143 of the control device 133 refers to the type information stored in the storage unit 144 and determines whether the indoor unit is the first indoor unit 110 for zoning air conditioning or the second indoor unit 120 not for zoning air conditioning. Determine if there is
If the indoor unit is the first indoor unit 110 for zoning air conditioning, the control unit 143 advances the process to step S5. On the other hand, if the indoor unit is the second indoor unit 120 that is not for zoning air conditioning, the control unit 143 advances the process to step S6.

(Step S5: first control process)
A control unit 143 of the control device 133 controls operation parameters such as thermo ON/OFF and set temperature. Specifically, the control unit 143 performs control to change from thermo-on to thermo-off, control to raise the set temperature during cooling operation, and lower the set temperature during heating operation, and the like. That is, since there is no person in the target zone 201, the control unit 143 performs control to reduce power consumption.

(Step S6: second control process)
The control unit 143 of the control device 133 controls at least one of the operating parameters of the blowing volume and the wind direction. Specifically, the control unit 143 performs at least one of control to change the operating parameter of the air blow volume to a set value that reduces the air blow volume and control to change the operating parameter of the wind direction to a set value that makes the wind direction closer to the bottom. control. The airflow operating parameters are, for example, the fan notch and the number of air plenums. For example, when there are three levels of air blow volume settings, the control unit 143 changes the set value of the air volume to one level lower. In addition, the control unit 143 changes the operating parameter of the wind direction so that it is as straight down as possible.
Note that the control unit 143 may control at least one of the operation parameters of the airflow rate and the airflow direction, as well as control the operation parameters such as the thermo ON/OFF and the set temperature.

That is, when the target zone 201 changes from the present zone to the absent zone, the control device 133 determines whether the indoor units installed in the target zone 201 are the first indoor unit 110 or the second indoor unit. 120 or 120, different control is performed. Specifically, when the indoor unit is the first indoor unit 110, the control device 133 performs control to reduce power consumption. At least one of the operating parameters of air volume and wind direction is controlled.
Further, when the target zone 201 changes from the absent zone to the present zone, the control device 133 returns the operating parameters of the indoor units installed in the target zone 201 to the reference values.

*** Effect of Embodiment 1 ***
As described above, the air conditioning system 100 according to Embodiment 1 targets each zone 201, and when the target zone 201 changes from the present zone to the absent zone, the indoor unit installed in the target zone 201 , different control is performed depending on whether the indoor unit is the first indoor unit 110 or the second indoor unit 120 . In particular, when the indoor unit is the second indoor unit 120, the air-conditioning system 100 according to Embodiment 1 performs control to change the operating parameter of the air blow volume to a set value that reduces the air blow volume, and controls the operation of the wind direction. At least one of control to change the parameter to a set value that is close to the bottom is performed.
Thereby, when the first indoor unit 110 for zoning air conditioning and the second indoor unit 120 not for zoning air conditioning are installed together, it is possible to improve the energy saving performance.

A specific description will be given with reference to FIG.
When the target zone 201 changes from the present zone to the absent zone, regardless of whether the indoor unit is the first indoor unit 110 or the second indoor unit 120, change to thermo-off and change the set temperature. Suppose that control is performed to reduce power consumption. Here, it is assumed that the thermostat is turned off.
The first indoor unit 110 for zoning air conditioning installed in the zone 201A controls the airflow so that the cold or hot heat is sufficiently heat-exchanged in the target zone 201A and then flows outside. That is, the first indoor unit 110 controls the airflow so as to adjust the temperature only in the target zone 201A.
Assume that the zone 201B becomes an absent zone at this time. Then, the second indoor unit 120 installed in zone 201B is changed to thermo-off. When the second indoor unit 120 is changed to thermo-off, the air sucked from the suction port 122 is blown out as it is from the outlets 121a to 121d toward the outside of the target zone 201B. As a result, air in zone 201B flows to zone 201A. Since the second indoor unit 120 is thermo-off, the air in the zone 201B is not temperature-controlled. In other words, the airflow control by the first indoor unit 110 is disturbed, and the air conditioning load of the zone 201B is applied to the zone 201A.

It is conceivable that the first indoor unit 110 is installed in the zone 201 where people are present most of the time, and the second indoor unit 120 is installed in the zone 201 where there are times when no people are present. Specifically, as shown in FIG. 2, in an office, the first indoor unit 110 is installed in the employee's own seat zone, and the second indoor unit 120 is installed in the meeting zone where the meeting space is located. It is conceivable that As a result, when there is no person in the meeting zone, it is possible to control the meeting zone so as to reduce power consumption while efficiently adjusting the temperature only in the user's seat zone.
In such a case, by controlling the air conditioning system 100 according to Embodiment 1, it is possible to improve the energy saving performance.

***Other Configurations***
<Modification 1>
In Embodiment 1, control is performed by the controller 133 provided in each first indoor unit 110 and each second indoor unit 120 . However, the air conditioning system 100 includes a control device that controls all the first indoor units 110 and all the second indoor units 120, and the control device controls the indoor units to operate as the first indoor units 110 and the second indoor units 120. Different control may be performed depending on which one. Further, control may be performed by the control device 133 provided in each of the first indoor units 110 and each of the second indoor units 120 according to instructions from this control device.

<Modification 2>
In Embodiment 1, when the zone 201 in which the second indoor unit 120 is installed changes from the present zone to the absent zone, the control unit 143 changes the set value so that the air blow volume decreases. If the state in which the zone 201 in which the second indoor unit 120 is installed is an absent zone continues for a reference time or longer, the control unit 143 may change the set value to further decrease the air blow volume. For example, the control unit 143 changes the set value of the blowing volume to one step lower. As a result, the comfort of the zone 201 in which the second indoor unit 120 is installed is reduced, but the air conditioning load on the surrounding zones 201 is reduced, and energy saving performance can be improved.

<Modification 3>
In Embodiment 1, when the zone 201 in which the second indoor unit 120 is installed changes from the present zone to the absent zone, the control unit 143 changes the set value so that the air blow volume decreases. However, even if the zone 201 in which the second indoor unit 120 is installed is the existing zone, if the first indoor unit 110 installed in another zone 201 is in cooling operation or heating operation, The operating parameter of the second indoor unit 120 may be changed to a set value that reduces the amount of air blown. Further, only when the first indoor unit 110 installed in the zone 201 adjacent to the zone 201 in which the second indoor unit 120 is installed is in the cooling operation or the heating operation, the operation parameter of the second indoor unit 120 is changed. The set value may be changed to a value that reduces the amount of air blown.
Note that when performing this control, the control unit 143 needs to acquire operation mode information from the other first indoor unit 110 . Therefore, as described in Modification 1, this control may be performed by a control device that controls all first indoor units 110 and all second indoor units 120 .

100 air conditioning system, 110 first indoor unit, 111 outlet, 112 inlet, 120 second indoor unit, 121 outlet, 122 inlet, 131 motion sensor, 132 temperature sensor, 133 control device, 141 measurement unit, 142 calculation unit, 143 control unit, 144 storage unit, 200 space, 201 zone, 311 superior seat, 312 person in charge seat, 313 meeting space, 314 door.

Claims (5)

An air conditioning system that air-conditions a space divided into multiple zones,
It includes a first indoor unit that is an indoor unit for zoning air conditioning that blows air toward the center of the zone, and a second indoor unit that is not an indoor unit for zoning air conditioning, and is installed corresponding to each of the plurality of zones. a plurality of indoor units that are
A control device for controlling indoor units installed in each of the plurality of zones when the target zone changes from an existing zone in which a person exists to an absent zone in which no person exists. A control device that performs different control depending on whether the indoor unit is the first indoor unit or the second indoor unit,
The control device, when the indoor unit is the second indoor unit, is an air conditioning system that changes an operating parameter of an air blow volume to a set value that reduces the air blow volume. 2. The control device according to claim 1, wherein, when the state in which the target zone is the non-existent zone continues for a reference time or longer, the control device changes the operating parameter of the air blow volume to a set value that further reduces the air blow volume. air conditioning system. each of the plurality of indoor units includes a human sensor that detects whether or not a person exists in the corresponding zone;
3. The air conditioning system according to claim 1 , wherein the control device detects that the target zone has changed from the present zone to the absent zone based on the result detected by the human sensor. The space is an office in an office,
The plurality of zones includes a seat zone where employees working in the office have their own seats and a meeting zone for holding meetings,
The air conditioning system according to any one of claims 1 to 3 , wherein the first indoor unit is installed in the own seat zone, and the second indoor unit is installed in the meeting zone. A first indoor unit that is an indoor unit for zoning air conditioning that performs air conditioning in a space divided into a plurality of zones and blows air toward the center of the zone, and a second indoor unit that is not an indoor unit for zoning air conditioning. A control method for an air conditioning system comprising a plurality of indoor units installed corresponding to each of the plurality of zones,
With respect to each of the plurality of zones, when the target zone changes from a zone in which a person is present to an absent zone in which no person is present, the indoor unit installed in the target zone is operated as the above. Performing different control depending on whether it is the first indoor unit or the second indoor unit,
A control method for an air conditioning system, wherein, when the indoor unit is the second indoor unit, an operating parameter for air blow volume is changed to a set value that reduces the air blow volume.

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