JP2018044751A - Electric device control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To inexpensively realize ventilation depending on air quality.SOLUTION: An electric device control system (40) is provided with a measurement data acquisition unit (452) that acquires measurement data of an environmental parameter from an external server via a network, a sensor unit (66) that measures air quality information in a compartmentalized space, a storage unit (42) that stores the acquired measurement data, and an outside air intake control unit (454) that controls an outside air intake in a ventilating device that ventilates air in the compartmentalized space on the basis of the measurement data stored in the storage unit (42) and the air quality information in the compartmentalized space.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an electric equipment control system.

When operating an air conditioner etc., the system which ventilates according to air quality is known.
For example, in Patent Document 1 below, “a plurality of environmental control devices 5, a measurement unit 11 that measures any two or more environmental parameters of temperature, humidity, and air quality” are set for each environmental parameter, and at least an upper limit is set. A threshold table 14 storing a first appropriate range having values, a priority table 16 storing priorities between a plurality of environmental parameters, and set for each environmental parameter, and each environmental control device 5 and each environmental control device 5 Referring to the device selection table 18, the threshold table 14, the priority table 16, and the device selection table 18 that store the relationship between the implementation effect level and the control method of the environment control device 5, a plurality of environment control devices And a device control unit 17 that selects any one of the environmental control devices 5 among the five ”(see abstract).

JP 2014-240733 A

However, according to the technique disclosed in Patent Document 1, the measurement unit 11 needs to be provided with a sensor for each environmental parameter such as temperature, humidity, air quality, and the like. .
This invention is made | formed in view of the situation mentioned above, and it aims at providing the electrical equipment control system which can implement | achieve ventilation according to air quality at low cost.

  In order to solve the above problems, an electrical equipment control system of the present invention measures a measurement data acquisition unit that acquires measurement data of environmental parameters from an external server and measures air quality information in a partitioned space via a network. Based on the sensor unit, the storage unit storing the acquired measurement data, the measurement data stored in the storage unit, and the air quality information in the partitioned space. And an outside air intake amount control unit that controls an outside air intake amount in a ventilation device that ventilates air.

  According to the electrical equipment control system of the present invention, ventilation according to air quality can be realized at low cost.

1 is a block diagram of an air conditioning system according to a first embodiment of the present invention. It is a block diagram of (a) an air conditioner, (b) a control device, (c) a ventilation device, and (d) an air purifier in the first embodiment. It is a control sequence figure in a 1st embodiment. It is a block diagram of the air-conditioning system by 2nd Embodiment of this invention. It is a perspective view of the indoor unit in 2nd Embodiment. It is a perspective view of the other indoor unit in 2nd Embodiment. It is a block diagram of the air conditioning system by 3rd Embodiment of this invention. It is a block diagram of the air-conditioning system by 5th Embodiment of this invention.

[First Embodiment]
<Overall Configuration of First Embodiment>
FIG. 1 is a block diagram of an air conditioning system S1 according to the first embodiment of the present invention.
In the example of FIG. 1, the air conditioning system S <b> 1 is installed in a four-story building 100, and the building 100 has a plurality of partitioned spaces 101 to 104. This partitioned space is, for example, a room, an elevator hall, or a corridor. In addition, the air conditioning system S1 includes a sensor group 15, an air conditioner 20, a control device 40, a ventilation device 50, an air cleaner 60 provided in each partitioned space 101 to 103, and a mutual space between them. A LAN (Local Area Network) 12 and a router 10 are connected. The air conditioner 20 includes an outdoor unit 21 disposed outside and an indoor unit 22 disposed indoors. The router 10 serves as a gateway that connects, for example, a WAN (Wide Area Network) 5 that is the Internet and a LAN 12.

  The sensor group 15 has a plurality of sensors that measure environmental parameters of the outside air. Here, the environmental parameters include an air pollution state and a weather state. “Air pollution state” means, for example, sulfur dioxide concentration, nitric oxide concentration, nitrogen dioxide concentration, nitrogen oxide concentration, carbon monoxide concentration, photochemical oxidant concentration, non-methane hydrocarbon concentration, methane concentration, total carbonization Hydrogen concentration, suspended particulate matter (particulate matter of 10 μm or less of suspended dust), PM2.5 (particulate matter suspended in the atmosphere, whose particle size is 2.5 μm) Concentration of particles collected after removing particles having a larger particle size using a sizing device that can be separated at a rate of 50%, suspended dust concentration, and the like.

The above-mentioned “floating dust” includes soot (generated by burning oil, coal, etc.), soil particles (yellow sand, etc.), sea salt particles (generated from the sea surface), tire wear dust (generated by rubber tire wear), plant There are types such as particles (pollen etc.) and animal particles (mold spores etc.), and the concentration may be measured for each type. The weather condition refers to wind direction, wind speed, temperature, relative humidity, and the like.
However, the sensor group 15 need not measure all the environmental parameters described above. That is, the environmental parameters measured by the sensor group 15 may be some of the environmental parameters described above, or may not be measured at all. That is, the sensor group 15 itself may not be provided. Environmental parameters that cannot be measured by the sensor group 15 (no sensors are provided) can be acquired via the WAN 5 as described later.

  In each of the partitioned spaces 101 to 103 in the building 100, a suction port 34 that exhausts air in each partitioned space and an outlet 32 that blows out air are provided. Air sucked from the suction port 34 is supplied to the ventilation device 50 through the exhaust duct 36. The ventilation device 50 is, for example, a total heat exchanger, and exhausts air collected through the exhaust duct 36 to the outside of the building 100 and sucks outside air. At that time, heat exchange is performed between the exhausted air and the outside air. Then, the sucked outside air is supplied to the indoor unit 22 of the air conditioner 20. The ventilation device 50 is, for example, a ventilation fan.

  In the air conditioner 20, the refrigerant is circulated between the outdoor unit 21 and the indoor unit 22, and the outdoor unit 21 heats or cools the refrigerant by exchanging heat with the outside air. The indoor unit 22 heats or cools the air supplied from the ventilation device 50 with a refrigerant, and discharges the air from the outlet 32 of each partitioned space via the intake duct 30. The plurality of air purifiers 60 are disposed in each partitioned space, and purify while circulating the air in each partitioned space.

  In addition to the air conditioning system S1, other air conditioning systems S2 to Sn are connected to the WAN 5. These air-conditioning systems S2 to Sn are provided as air-conditioning systems such as buildings and factories, agricultural houses, and the like, similar to the air-conditioning system S1 of this embodiment. Specific examples thereof will be described later in other embodiments. The server 1 is a computer for managing the air conditioning systems S1 to Sn, and inputs and outputs various data to and from the air conditioning systems S1 to Sn. The servers 2, 3, and 4 are computers that provide the above-described various environmental parameters, that is, measurement data such as weather, air pollution, pollen, and yellow sand. The servers 2, 3, and 4 may be operated by the Japan Meteorological Agency, the Ministry of the Environment, a data provider, or the like. The server 1 collects environmental parameter measurement data from the servers 2, 3 and 4, and supplies the collected measurement data to the air conditioning systems S1 to Sn.

  The air conditioning system S <b> 1 may acquire measurement data of the sensor group 15 or may acquire it from the server 1 in order to acquire environmental parameters. In order to configure the air conditioning system S1 at a low cost, it is preferable to apply a relatively inexpensive sensor group 15. However, when an inexpensive sensor is applied, the measurement data acquired from the sensor group 15 may be inferior in reliability. On the other hand, the measurement data provided from the servers 2, 3, and 4 via the server 1 is often measured by a high-performance sensor and is generally said to have high reliability.

  However, for example, when the building 100 is adjacent to the cedar forest, the pollen concentration around the building 100 in the season when the cedar pollen is scattered is provided from the server 1 using the measurement data of the sensor group 15. May be more accurate than measured data. Similarly, when construction work is performed in the vicinity of the building 100, the amount of suspended dust around the building 100 may be accurate as measured by the sensor group 15. As described above, the measurement data provided from the server 1 and the measurement data that can be acquired from the sensor group 15 are preferably used depending on the situation. Further, the measurement data measured by the sensor group 15 is transmitted to the server 1 via the control device 40 and the router 10. The transmitted measurement data is distributed particularly to the other air conditioning systems S2 to Sn provided in the vicinity of the air conditioning system S1.

<Configuration of Each Part of First Embodiment>
Next, the structure of each part of this embodiment is demonstrated.
FIG. 2A is a block diagram of the air conditioner 20. As illustrated, the air conditioner 20 includes a communication unit 24, a storage unit 25, a control unit 26, and a refrigeration cycle 28. The communication unit 24 communicates with the control device 40 via the LAN 12. The storage unit 25 stores various data used for the operation of the air conditioner 20. Further, the control unit 26 controls the refrigeration cycle 28 based on these data, and performs heating, cooling, and dehumidifying operations.

  FIG. 2B is a block diagram of the control device 40. As illustrated, the control device 40 includes a storage unit 42, a WAN communication unit 44, a control unit 45, and a LAN communication unit 46. The WAN communication unit 44 communicates with the server 1 via the router 10 and the WAN 5. The LAN communication unit 46 communicates with various devices connected to the LAN 12. The storage unit 42 stores measurement data of various environmental parameters acquired from the server 1 or the sensor group 15. Further, the control unit 45 controls the air conditioner 20, the ventilation device 50, the air purifier 60, and the like based on the measurement data stored in the storage unit 42. The measurement data acquisition unit 452 and the outside air intake amount control unit 454 in the control unit 45 will be described later.

  FIG. 2C is a block diagram of the ventilation device 50. As illustrated, the ventilation device 50 includes a communication unit 52, a storage unit 54, a control unit 55, and a heat exchange unit 56. The heat exchange unit 56 takes in outside air while exchanging heat, and discharges the inside air to the outside. The communication unit 52 communicates with the control device 40 via the LAN 12 and receives a command value such as an outside air intake amount in the heat exchange unit 56 from the control device 40. The storage unit 54 stores the amount of outside air taken in from the control device 40. The control unit 55 controls the heat exchange unit 56 and the like based on the designated outside air intake amount and the like.

FIG. 2D is a block diagram of the air cleaner 60. As illustrated, the air purifier 60 includes a communication unit 61, a storage unit 62, a control unit 64, a measurement unit 65, a plurality of sensor units 66, and an air purification unit 68. The plurality of sensor units 66 are sensors such as temperature, humidity, and carbon dioxide concentration in the partitioned spaces 101 to 103 in which the air purifier 60 is installed, and the measurement unit 65 determines the output values of these sensors. Based on this, measurement data of air quality information in a partitioned space such as temperature, humidity, and carbon dioxide concentration is measured.
In FIG. 2D, the sensor unit 66 is installed in the air cleaner 60. However, the sensor unit 66 may be installed other than the air purifier 60. For example, the outlet 32, the suction inlet 34, the indoor unit 22, etc. of the indoor unit in the divided spaces 101-103 can be considered.

  The storage unit 62 stores measured measurement data and the like. The air purifying unit 68 purifies while circulating the air in the compartments 101 to 103 in which the air purifier 60 is installed. The communication unit 61 communicates with the control device 40 via the LAN 12 and transmits measurement data from the sensor unit 66 to the control device 40. The control unit 64 controls the air purification unit 68 and the like based on a command from the control device 40.

Each of the control units 26, 42, 55, and 64 shown in FIGS. 2A to 2D is a general unit such as a CPU (Central Processing Unit), a RAM (Random Access Memory), and a ROM (Read Only Memory). A computer hardware is provided, and a ROM stores a control program executed by the CPU, various data, and the like.
In FIG. 2B, the inside of the control unit 45 shows functions realized by a control program or the like as blocks. That is, the control unit 45 includes a measurement data acquisition unit 452 and an outside air intake amount control unit 454. These functions will be described later together with the operation.

<Operation of First Embodiment>
FIG. 3 is a control sequence diagram of the first embodiment.
In step S102, the server 1 confirms with the servers 2, 3, and 4 whether or not the latest data (latest measurement data) of various environmental parameters exists. If the latest data exists, the server 1 downloads the latest data in step S104. Note that these steps S102 and S104 are periodically repeated every predetermined time.

Moreover, the measurement data acquisition part 452 (refer FIG.2 (b)) of the control apparatus 40 of air conditioning system S1 performs data confirmation with respect to the server 1 in step S106. That is, for each environmental parameter, a data confirmation message for inquiring whether or not the latest data exists is transmitted.
Upon receiving this data confirmation message, the server 1 transmits a position information confirmation message to the control device 40 in step S108. This position information confirmation message is a message for inquiring the position information of the air conditioning system S1.

  When receiving the position information confirmation message, the control device 40 returns position information (for example, latitude and longitude) of the air conditioning system S1 to the server 1 in step S110. When the server 1 receives the position information of the air conditioning system S1, the server 1 checks whether or not the latest data corresponding to the air conditioning system S1 exists.

  If the corresponding latest data exists, the server 1 transmits the latest data to the control device 40 in step S112. On the other hand, if the corresponding latest data does not exist, a message to that effect is transmitted to the control device 40. Here, “latest data” includes one piece of position information, that is, one corresponding to the position information of the air conditioning system S1, and one corresponding to a plurality of pieces of position information.

  For example, it is assumed that the server 1 stores measurement data of environmental parameters in units of prefectures. In the above step S101, if the position information indicating “Tokyo” is transmitted to the server 1 as the position information of the air conditioning system S1 from the control device 40 of the air conditioning system S1, the server 1 is the latest of “Tokyo”. Data can be transmitted to the control device 40 in step S112. In this case, the control device 40 stores the received latest data in the storage unit 42.

  Further, the server 1 can transmit a plurality of latest data corresponding to various prefectures to the control device 40 together with the position information (for example, data specifying the prefectures). In this case, the control device 40 that has received the latest data selects any of the latest data (for example, the latest data corresponding to the prefecture in which the building 100 is installed) and stores the selected data in the storage unit 42. In the above-described example, the control device 40 has acquired the latest environmental parameter data via the server 1, but the control device 40 directly accesses the servers 2, 3, and 4, and You can also get the latest data from For example, in the normal state, the control device 40 acquires the latest data from the server 1, and when a failure occurs in the server 1, the control device 40 directly acquires the latest data from the servers 2, 3, 4. Also good.

As described above, when the control device 40 acquires the latest data, the control device 40 executes the data rank process in step S114. This is a process of ranking the latest data for each environmental parameter. For example, the following ranks are given to sulfur dioxide according to the concentration.
Rank 1: 0.000 to 0.020 ppm
Rank 2: 0.021 to 0.040 ppm
Rank 3: 0.041-0.100 ppm
Rank 4: 0.101 to 0.120 ppm
Rank 5: 0.121 to 0.150 ppm
Rank 6: 0.151 ppm or more

  The control device 40 similarly ranks other environmental parameters. Any method may be employed as the ranking method, but in this embodiment, the lowest value of rank 4 (0.101 ppm in the example of sulfur dioxide) is unified so as to be the lowest value exceeding the environmental standard value. doing. As described above, when the rank of each environmental parameter is determined, the storage unit 42 of the control device 40 stores a rank table that associates each environmental parameter item with the rank (not shown).

  When the data rank process ends, in step S116, the control device 40 transmits a carbon dioxide concentration confirmation message to the air purifier 60 in each of the partitioned spaces 101 to 103. When receiving the carbon dioxide concentration confirmation message, the air purifier 60 transmits the measurement data of the carbon dioxide concentration to the control device 40 in step S118. Next, the control apparatus 40 performs a ventilation control process in step S120. This is a process of determining the outside air intake amount in the air cleaner 60. The contents of the processing are as follows.

(Case A) When the rank of any environmental parameter is “4” or more:
If the rank of at least one environmental parameter stored in the storage unit 42 is “4” or more, the environmental reference value is not satisfied for the environmental parameter.
In this case, the outside air intake amount control unit 454 of the control device 40 determines the outside air intake amount as small as possible while keeping the carbon dioxide concentration below a predetermined reference concentration (1000 ppm). This is to prevent contaminated outside air from entering the room as much as possible while suppressing the carbon dioxide concentration below the reference concentration.

(Case B) When the ranks of all environmental parameters are “3” or less:
If the ranks of all the environmental parameters stored in the storage unit 42 are “3” or less, the environmental reference values are satisfied for all the environmental parameters. In this case, the outside air intake amount control unit 454 determines the outside air intake amount according to the temperatures of the partitioned spaces 101 to 103.
First, if the temperature of each compartment 101-103 is a predetermined temperature range (for example, 18 degreeC or more and less than 25 degreeC), possibility that the air conditioner 20 is drive | operating is low and is operating temporarily. In many cases, the load is low. Therefore, in such a case, the outside air intake amount control unit 454 determines the outside air intake amount so as to introduce more outside air into the room than in the case A.

  In addition, when the ranks of all the environmental parameters are “3” or less and the temperatures of the partitioned spaces 101 to 103 are not in the above temperature range (for example, less than 18 ° C. or 25 ° C. or more), the outside air As in the case A, the intake amount control unit 454 determines the external air intake amount as small as possible while keeping the carbon dioxide concentration below the reference concentration (1000 ppm). This is because the air conditioner 20 is likely to be operated if the temperature of each of the divided spaces 101 to 103 is less than 18 ° C. or 25 ° C. or more, and therefore the power consumption of the air conditioner 20 is as low as possible. It is for suppressing.

  Next, in step S122, the control device 40 transmits the determined outside air intake amount to the ventilation device 50. Thereby, the control part 55 (refer FIG.2 (c)) of the ventilation apparatus 50 controls the heat exchange part 56 so that the specified external air intake amount may be implement | achieved.

<Effects of First Embodiment>
As described above, the electric equipment control system (40) of the present embodiment is partitioned with the measurement data acquisition unit (452) that acquires the measurement data of the environmental parameters from the external server (1) via the network. A sensor unit (66) for measuring the air quality information in the space, a storage unit (42) for storing the acquired measurement data, measurement data stored in the storage unit (42), and a partitioned space ( 101-103) based on the air quality information, the outside air intake amount control unit (454) controls the outside air intake amount in the ventilator (50) for ventilating the air in the partitioned spaces (101-103). And).
Thereby, the measurement data acquired via the network can be utilized, and the operation according to the air quality can be realized at low cost.

Further, the measurement data acquisition unit (452) transmits the position information of the ventilation device (50) to the server (1) and receives the measurement data corresponding to the transmitted position information from the server (1). Can do.
Thereby, suitable measurement data according to the position of the ventilator (50) can be acquired.

Moreover, even if the server (1) transmits the measurement data at the plurality of measurement points together with the position information of the plurality of measurement points to the measurement data acquisition unit (452), the measurement data acquisition unit (452) Based on the positional information, any measurement data is selected and stored in the storage unit (42).
Also by this, the appropriate measurement data according to the position of the ventilator (50) can be stored.

In addition, the outside air intake amount control unit (454) sets the value of the air quality information to a predetermined reference when the measurement data stored in the storage unit (42) satisfies a predetermined air pollution condition (the degree of pollution is high). The ventilator (50) is controlled so as to make the outside air intake amount as small as possible while keeping it below the value. Here, the air pollution conditions are sulfur dioxide concentration, nitrogen monoxide concentration, nitrogen dioxide concentration, nitrogen oxide concentration, carbon monoxide concentration, photochemical oxidant concentration, non-methane hydrocarbon concentration, methane concentration, total hydrocarbon concentration, floating One or a plurality of elements among the particulate matter concentration, PM2.5 concentration, suspended dust concentration, pollen concentration, or yellow sand concentration exceed a predetermined reference value.
Thereby, when the degree of contamination is large, the outside air intake amount can be reduced as much as possible, and deterioration of the indoor environment can be suppressed.

In this embodiment, the outside air intake amount control unit (454) is a partitioned space in which the measurement data stored in the storage unit (42) does not satisfy the air pollution condition (the degree of contamination is small). When the temperature inside is within a predetermined temperature range (18 ° C. to 25 ° C.), a function of increasing the amount of outside air taken in compared with the case where the air pollution condition is satisfied (the degree of contamination is large), and a storage unit If the measurement data stored in (42) does not satisfy the air pollution condition (the degree of pollution is small) and the temperature in the partitioned space is outside the temperature range (18 ° C. to 25 ° C.), air And a function of controlling the ventilator (50) so as to make the outside air intake amount as small as possible while keeping the value of the quality information below a predetermined reference value.
Thereby, when the air conditioner is operated, the power consumption of the air conditioner can be suppressed.

[Second Embodiment]
<Overall Configuration of Second Embodiment>
FIG. 4 is a block diagram of an air conditioning system S2 according to the second embodiment of the present invention.
In FIG. 4, parts corresponding to those in FIGS. 1 to 3 are denoted by the same reference numerals, and the description thereof may be omitted.
The air conditioning system S2 is installed in a small building 110, and the building 110 has partitioned spaces 111 and 112. The air conditioning system S2 includes a sensor group 15, an air conditioner 80, two ventilation devices 50, and two air purifiers 60.

The air conditioner 80 in the present embodiment has one outdoor unit 82 and two indoor units 84A and 84B installed in the partitioned spaces 111 and 112, respectively. Moreover, the ventilation apparatus 50 and the air cleaner 60 are installed in the divided spaces 111 and 112, respectively. The indoor units 84A and 84B have power sources 86A and 86B, respectively. In addition, description of the heat exchanger etc. in the air conditioner 80 is abbreviate | omitted. The indoor unit 84A is equipped with the router 10A and the control device 40, and the power supply 86A applies a predetermined power supply voltage thereto. Further, the router 10B is attached to 84B, and the power supply 86B applies a predetermined power supply voltage to the router 10B.
In the present embodiment, the sensor unit 66 is connected to the air cleaner 60 or the indoor units 84A and 84B.

  The routers 10A and 10B also function as, for example, IEEE 802.11 standard access points. Then, the ventilation device 50 and the air purifier 60 in the partitioned spaces 111 and 112 function as communication terminals conforming to the IEEE 802.11 standard, and wirelessly communicate with the routers 10A and 10B. The routers 10A and 10B and the control device 40 are connected to each other via the LAN 12, and the router 10A is connected to the external WAN 5. Configurations other than those described above are the same as those of the first embodiment (see FIG. 1).

<External configuration of indoor unit 84A>
FIG. 5 is a perspective view of the indoor unit 84A.
The indoor unit 84A is generally called a “ceiling cassette type four-way indoor unit”. The main body 120 of the indoor unit 84A has a shape in which four corners of a square thick plate are cut out into a substantially square shape, and four substantially L-shaped support fittings 122 are formed in the cutout portions of the four corners. Welded. Four suspension bolts (not shown) are embedded in the concrete slab where the indoor unit 84A is installed so as to protrude downward. When the support fitting 122 is inserted through these four suspension bolts and a nut (not shown) is screwed into the suspension bolt, the main body 120 is fixed to the suspension bolt.

  A heat exchanger, a fan, and the like are built in the main body 120 (not shown). A substantially square plate-shaped decorative plate 121 is mounted on the lower surface of the main body 120. A substantially square plate-like air inlet 124 with a slit is mounted at the center of the decorative plate 121. Further, four exhaust ports 126 are formed between each of the four sides of the intake port 124 and the peripheral edge of the decorative plate 121. Thereby, the indoor unit 84A heats or cools the air sucked from the air inlet 124 by a heat exchanger (not shown), and discharges the air into the room through the exhaust ports 126.

  Panels (corner panels) having substantially the same dimensions in a plan view are fitted into the four corners of the decorative plate 121. Two of these panels are the control device 40 and the router 10A described above, and the remaining two are a blank panel 128 and a camera panel 129. The camera panel 129 is equipped with a camera for photographing the room. The decorative plate 121 is provided with a plurality of mounting brackets 130 at the mounting location of the router 10 </ b> A, whereby the router 10 </ b> A is mounted on the decorative plate 121. A similar mounting bracket 130 is also provided at the mounting position of the control device 40, the blank panel 128, and the camera panel 129 (not shown).

  The above-described components 10A, 40, 128, and 129 have substantially the same shape in plan view. Since the blank panel 128 is a simple plate, it can be removed and another device having substantially the same shape can be attached to the decorative plate 121. For example, a microphone panel with a microphone that collects indoor sound or a lighting panel that illuminates the room may be mounted at the position of the blank panel 128. Further, when the router 10A, the control device 40, or the camera panel 129 is unnecessary, another device having substantially the same shape can be attached to the decorative plate 121 instead of the unnecessary device. As another device, a sensor unit 66 that is a sensor of temperature, humidity, carbon dioxide, or the like can be considered. In addition, the sensor unit 66, the microphone panel, the camera panel 129, and the like can be attached to the four corners of the decorative plate 121 of the indoor unit 84A already installed on the ceiling of the room. Thereby, for example, even when there is no plan to acquire information such as indoor air quality information at the beginning of installation of the indoor unit 84A, information desired to be acquired in the room can be appropriately acquired as necessary.

<External configuration of indoor unit 84B>
FIG. 6 is a perspective view of the indoor unit 84B. The indoor unit 84B is generally called a “ceiling suspended one-way indoor unit”. The main body 140 of the indoor unit 84B has a substantially rectangular parallelepiped shape, and two substantially L-shaped support fittings 142 are welded to the right end portion thereof. Two support fittings 142 are similarly welded to the left side of the main body 140 (not shown).

  Four suspension bolts (not shown) are embedded in the concrete slab where the indoor unit 84B is installed so as to protrude downward. When the support fitting 142 is inserted into the four suspension bolts and a nut (not shown) is screwed into the suspension bolt, the main body 140 is fixed to the suspension bolt. A heat exchanger, a fan, and the like are built in the main body 140 (not shown). In addition, a rectangular plate-like intake port 144 with a slit is mounted on the lower surface of the main body 140. Further, the front surface of the main body 140 is opened, and an exhaust port 146 is formed. As a result, the indoor unit 84B heats or cools the air sucked from the intake port 144 by a heat exchanger (not shown), and discharges the air into the room through the exhaust port 146.

  Openings (not shown) having substantially the same dimensions are formed at the left and right ends of the lower surface of the indoor unit 84B. Blank openings 148 having substantially the same shape and a router 10B are mounted in these openings in plan view. ing. Since the blank panel 148 is a simple plate, it can be removed and another device (for example, a microphone panel or a lighting panel) having substantially the same shape can be mounted on the lower surface of the indoor unit 84B. In addition, when the router 10B is unnecessary, another device having substantially the same shape can be attached to the indoor unit 84B instead of the router 10B. Further, similarly to the indoor unit 84A, a sensor unit 66 that is a sensor of temperature, humidity, carbon dioxide, or the like can be attached. Furthermore, the sensor unit 66, the microphone panel, the camera panel 129, and the like can be attached to the opening of the indoor unit 84B that is already installed indoors.

<Effects of Second Embodiment>
As described above, according to the present embodiment, the same effects as those of the first embodiment can be obtained, and various devices according to applications can be mounted on the indoor units 84A and 84B. In particular, since the indoor units 84A and 84B are generally installed near the ceiling of the partitioned spaces 111 and 112, when the routers 10A and 10B having a wireless communication function are attached to the indoor units 84A and 84B, The indoor ventilation device 50, the air purifier 60, and other communication terminals can be installed within the line-of-sight range of the routers 10A and 10B. Thereby, the advantage that favorable radio | wireless communication quality can be ensured arises.

[Third Embodiment]
FIG. 7 is a block diagram of an air conditioning system S3 according to a third embodiment of the present invention.
In FIG. 7, portions corresponding to the respective portions in FIGS. 1 to 6 are denoted by the same reference numerals, and description thereof may be omitted.
The air conditioning system S3 is installed in the agricultural house 200, and includes an air conditioner 220, an in-house control unit 240, and a portable terminal 250.

  The air conditioner 220 according to the present embodiment includes an outdoor unit 221 installed outside the agricultural house 200 and an indoor unit 222 installed inside the agricultural house 200. The air conditioner 220 incorporates a router 210, and the router 210 is connected to the WAN 5. The router 210 also functions as, for example, an IEEE 802.11 standard access point, and performs wireless communication with the mobile terminal 250, similarly to the routers 10A and 10B of the second embodiment. Therefore, the mobile terminal 250 does not have to be unique to the present embodiment, and a normal mobile phone or the like can be applied.

  Inside the agricultural house 200, an in-house control unit 240 is installed. The in-house control unit 240 detects the indoor temperature and humidity in the agricultural house 200, detects the outdoor temperature and humidity, detects the carbon dioxide concentration, detects nutrient solution information (information on nutrient solution components and quantity, etc.), and sunshine condition Measure and so on. These measurement data are supplied to the server 1. Further, the in-house control unit 240 is configured to control humidity, carbon dioxide concentration, nutrient solution control, window opening / closing control, curtain opening / closing control, equipment, based on a command supplied from the server 1 via the air conditioner 220. Perform maintenance (detection of signs of equipment failure), etc. In addition, the air conditioner 220 performs temperature control and dehumidification control based on the command supplied from the server 1.

  The server 1 collects information such as agricultural market conditions, currency exchange information, supply chain circulation, and transportation status, and determines an optimal shipping time based on the collected information. Here, the “optimal shipping time” may be determined from various factors such as high yield, high quality, high profits, and energy savings. For example, the optimal shipping time is selected as the shipping time. Good. Then, in order to realize the determined shipping time, the command values such as temperature, humidity, carbon dioxide concentration, nutrient solution type and amount, opening and closing of windows, opening and closing of curtains are controlled in the house via the air conditioner 220. To the unit 240.

  As described above, according to the present embodiment, the server 1 can control the environment in the agricultural house 200 so that the shipment time of agricultural products is matched with the optimal shipping time, so that the yield and quality of crops are improved. Further, energy saving of the agricultural house 200, labor saving of the farmer, and the like can be realized.

[Fourth Embodiment]
Next, an air conditioning system according to a fourth embodiment of the present invention will be described.
The air conditioning system according to the fourth embodiment is applied to a livestock barn. The overall configuration of the fourth embodiment is the same as that of the third embodiment (see FIG. 7).
However, instead of the agricultural house 200 shown in FIG. 7, a livestock barn (not shown) is applied. In this embodiment, the in-house control unit 240 provided in the barn detects the presence or absence of invaders in the barn, detects the indoor temperature and humidity, detects the outdoor temperature and humidity, feed information (feed composition, amount, etc.) Information) and measuring body temperature of livestock. Similar to the third embodiment, these measurement data are supplied to the server 1.

  Further, the in-house control unit 240 controls humidity control, feed control (control of feed composition, amount, etc.) window opening / closing control, curtain opening / closing based on a command supplied from the server 1 via the air conditioner 220. Control, equipment maintenance (detection of equipment failure signs), etc. The air conditioner 220 performs temperature control and dehumidification control in the barn based on the command supplied from the server 1.

  The server 1 collects information such as meat market conditions, currency exchange information, supply chain circulation, transport status, etc., and determines the optimal shipment time of meat based on the collected information. Here, as in the case of the third embodiment, the “optimum shipping time” may be determined from various factors such as high yield, high quality, high profit, and energy saving. The timing when the profit is high should be selected as the shipping time. And like 3rd Embodiment, command values, such as temperature, humidity, composition and quantity of feed, opening and closing of a window, and opening and closing of a curtain, are realized via the air conditioner 220 so as to realize the determined shipping time. This is supplied to the in-house control unit 240.

  As described above, according to the present embodiment, the server 1 can control the environment in the barn so as to match the shipment time of the meat with the optimal shipping time. Energy saving and labor saving of livestock farmers can be realized.

[Fifth Embodiment]
FIG. 8 is a block diagram of an air conditioning system S5 according to the fifth embodiment of the present invention.
In FIG. 8, parts corresponding to those in FIGS. 1 to 7 are denoted by the same reference numerals, and the description thereof may be omitted.
The air conditioning system S5 is applied to a restaurant (for example, a restaurant chain store). In the configuration shown in FIG. 8, the restaurant store 400 is applied instead of the agricultural house 200 and the sensor group 410 is applied instead of the in-house control unit 240 as compared with the third embodiment (FIG. 7). . Other configurations of the present embodiment are the same as those of the third embodiment.

  The sensor group 410 includes various sensors that measure outdoor temperature and humidity, temperature and humidity in the cabin, illuminance, image and sound, and temperature and humidity in the kitchen, illuminance, image and sound. The measurement data of these sensor groups 410 is transmitted to the server 1 via the air conditioner 220.

  The server 1 performs various types of analysis such as quantifying customer satisfaction based on images and sound in the cabin. It also analyzes the movements of store clerk in the kitchen. Based on these analysis results, the server 1 transmits information such as temperature / humidity control in the cabin and kitchen, recipe improvement suggestions, work instructions, and preparation instructions. Among these pieces of information, the instruction content for temperature / humidity control is directly reflected in the operation of the air conditioner 220. Information such as recipe improvement proposals, work instructions, and preparation instructions is displayed via the portable terminal 250.

  According to the present embodiment, it is possible to increase the turnover rate of the customer, improve the quality and make it uniform, and shorten the waiting time. In particular, the present embodiment is useful when the restaurant chain store is expanded overseas. The taste of food and drink varies from country to country, and there may be inconveniences that are difficult for the Japanese to predict in advance. According to this embodiment, since a customer's state can be grasped | ascertained via the sensor group 410, the optimal service according to the actual condition of the area where the restaurant chain restaurant is developed can be provided to the customer. In addition to the restaurant, the air conditioning system S5 may be applied. For example, a convenience store or a supermarket can be considered.

[Sixth Embodiment]
Next, an air conditioning system according to a sixth embodiment of the present invention will be described.
The air conditioning system according to the sixth embodiment is mainly applied to schools. The overall configuration of the sixth embodiment is the same as that of the fifth embodiment (see FIG. 8). However, a school building (not shown) is applied instead of the restaurant store 400 shown in FIG. The sensor group 410 in the present embodiment includes various sensors that measure classroom temperature and humidity, classroom carbon dioxide concentration and oxygen concentration, classroom images and sounds, and the like. The measurement data of these sensor groups 410 is transmitted to the server 1 via the air conditioner 220.

  The server 1 analyzes the received voice in the classroom and extracts words related to “bullying”. Moreover, based on the images in the classroom, the problem behavior (violence and the like) of the student is extracted, and the teaching ability of the teacher and the student's willingness to learn are analyzed. The server 1 transmits to the air conditioning system S5 information such as temperature / humidity control in the classroom, information recommending ventilation, information on “bullying” and other problem behaviors of the student, student happiness, and evaluation of the teacher's leadership. . Among these pieces of information, the instruction content for temperature / humidity control is directly reflected in the operation of the air conditioner 220. In addition, information such as student problem behavior information, student happiness, and teacher's instructional evaluation are displayed via the portable terminal 250.

  According to the present embodiment, by optimizing the environment in the school building, the effect of preventing “bullying” by the student, improving the academic ability of the student, improving the teaching ability of the teacher, and improving the happiness of the student. Can be played.

[Modification]
The present invention is not limited to the above-described embodiments, and various modifications can be made. The above-described embodiments are illustrated for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of an embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of an embodiment. Further, it is possible to delete a part of the configuration of each embodiment, or to add or replace another configuration. In addition, the control lines and information lines shown in the figure are those that are considered necessary for the explanation, and not all the control lines and information lines that are necessary on the product are shown. Actually, it may be considered that almost all the components are connected to each other. Examples of possible modifications to the above embodiment are as follows.

(1) Since the hardware such as the control device 40 in each of the above embodiments can be realized by a general computer, the program according to the control sequence diagram shown in FIG. 3 is stored in a storage medium or via a transmission path. You may distribute it.

(2) Although the process according to the control sequence diagram shown in FIG. 3 has been described as a software process using a program in the above embodiment, a part or all of the process is an ASIC (Application Specific Integrated Circuit); IC), or hardware processing using an FPGA (field-programmable gate array) or the like.

1-4 server 40 control device (electric equipment control system)
42 Storage Unit 50 Ventilator 66 Sensor Units 101 to 104, 111, 112 Partitioned Space 452 Measurement Data Acquisition Unit 454 Outside Air Intake Amount Control Unit

Claims (5)

A measurement data acquisition unit that acquires measurement data of environmental parameters from an external server via a network, a sensor unit that measures air quality information in a partitioned space,
A storage unit for storing the acquired measurement data;
Based on the measurement data stored in the storage unit and the air quality information in the partitioned space, the outside air intake for controlling the amount of outside air taken in the ventilation device that ventilates the air in the partitioned space. Load control unit,
An electrical equipment control system comprising: The said measurement data acquisition part transmits the positional information on the said ventilation apparatus with respect to the said server, and receives the measurement data corresponding to the transmitted positional information from the said server. Electrical equipment control system. The server transmits measurement data at a plurality of measurement points together with position information of a plurality of measurement points to the measurement data acquisition unit,
2. The electrical equipment control system according to claim 1, wherein the measurement data acquisition unit selects any of the measurement data based on position information of a plurality of measurement locations and stores the selected measurement data in the storage unit. . When the measurement data stored in the storage unit satisfies a predetermined air pollution condition, the outside air intake amount control unit holds the value of the air quality information below a predetermined reference value while maintaining the outside air intake. Controlling the ventilator so as to minimize the amount of intrusion,
The air pollution conditions are sulfur dioxide concentration, nitric oxide concentration, nitrogen dioxide concentration, nitrogen oxide concentration, carbon monoxide concentration, photochemical oxidant concentration, non-methane hydrocarbon concentration, methane concentration, total hydrocarbon concentration, suspended particulate form The electrical equipment control system according to claim 3, wherein one or a plurality of elements among the substance concentration, the PM2.5 concentration, the suspended dust concentration, the pollen concentration, or the yellow sand concentration exceed a predetermined reference value. . The outside air intake control unit
If the measurement data stored in the storage unit does not satisfy the air pollution condition and the temperature in the partitioned space is within a predetermined temperature range, the outside air intake amount is The ability to make it larger than if the contamination conditions were met,
When the measurement data stored in the storage unit does not satisfy the air pollution condition and the temperature in the partitioned space is outside the temperature range, the value of the air quality information is set as a predetermined reference. A function of controlling the ventilator so as to make the outside air intake amount as small as possible while keeping it below a value;
The electrical equipment control system according to claim 4, comprising:

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