JP7008476B2 - Indoor environment adjustment system, server, indoor environment adjustment method and program - Google Patents

Description

The present invention relates to a technique for adjusting an indoor environmental condition.

Various techniques have been conventionally proposed for adjusting the indoor environmental condition (for example, Patent Document 1). Patent Document 1 discloses a ventilation system for improving the air quality in a building by ventilating the building without wasting energy.

In this ventilation system, an individual measuring instrument measures the air quality inside and outside the building, and the control device operates the ventilation equipment when the air quality outside the building is better than the air quality inside the building. In addition, the control device predicts whether contaminated air with an abnormal air quality will reach the building based on the measurement results of multiple distributed measuring instruments distributed around the building. If the arrival of contaminated air is predicted, the ventilation equipment will be stopped regardless of the measurement results of the individual measuring instruments.

Japanese Unexamined Patent Publication No. 2014-222116

By the way, in a general house having a plurality of rooms, air flows out or flows from one to the other through a gap between the rooms or a gap between the doors of the rooms. The flow rate and direction of air through such gaps are the specifications of the house, for example, the area of the entire house, the floor plan, the area of each room, the airtightness of the door and the airtightness between the rooms, the heat insulation specifications of the walls and windows, etc. Is greatly affected by.

Therefore, in order to accurately adjust the indoor environmental condition, not only the indoor and outdoor environmental conditions (in other words, the inside and outside of the house) but also the information on the specifications of the house are taken into consideration, and the ventilation device and the air conditioner are used. Etc. need to be controlled.

On the other hand, in order to perform the above control, advanced airflow analysis calculation is required, and it is difficult for a general control device installed in each house to collectively perform such control. It can be said that.

The present invention has been made to solve the above problems, and to provide an indoor environment adjustment system or the like that can accurately adjust an indoor environment state even if a control device having a low processing capacity is used. The purpose.

In order to achieve the above object, the indoor environment adjustment system according to the present invention is
Equipped with a control device and a server
The control device is
Information receiving means for accepting input of housing information related to housing specifications,
An information transmission means for transmitting the housing information to the server, and
A state data transmitting means for transmitting state data including the environmental state in the room of the house and the operating state of the adjusting device for adjusting the environmental state in the room to the server.
A control instruction data receiving means for receiving control instruction data for controlling the adjusting device from the server, and a control instruction data receiving means.
A control means for controlling the adjusting device based on the control instruction data is provided.
The server
An information receiving means for receiving the housing information from the control device, and
A state data receiving means for receiving the state data from the control device, and
A prediction means for predicting the environmental state of the room after a predetermined time based on the housing information and the state data, and
A control content determining means for determining the control content of the adjusting device based on the prediction result of the predicting means, and a control content determining means.
A control instruction data transmission means for transmitting the control instruction data generated based on the determined control content to the control device is provided .
The predicting means generates a plurality of state patterns in which the operating states of the adjusting device are different from each other based on the received state data, and operates the adjusting device for a predetermined time with the contents indicated by each state pattern. The environmental state of the room is predicted by using the housing information and the environmental state of the room included in the state data.
The control content determining means selects one prediction result from the prediction results corresponding to each of the plurality of state patterns based on a predetermined selection condition, and adjusts the state pattern corresponding to the selected prediction result. It is decided as the control content of .

According to the present invention, it is possible to accurately adjust the environmental condition in the room even if a control device having a low processing capacity is used.

The figure which shows the structure of the indoor environment adjustment system which concerns on embodiment of this invention. The figure for demonstrating the duct and the damper of the air-conditioning system provided in the indoor environment adjustment system which concerns on this embodiment. A block diagram showing a hardware configuration of a control device according to this embodiment. A block diagram showing a functional configuration of a control device according to this embodiment. Block diagram showing the hardware configuration of the server according to this embodiment Block diagram showing the functional configuration of the server according to this embodiment A flowchart showing the procedure of the indoor environment adjustment process executed by the indoor environment adjustment system according to the present embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a diagram showing a configuration of an indoor environment adjustment system 1 according to an embodiment of the present invention. The indoor environment adjustment system 1 is a system for appropriately adjusting the indoor environmental state in the house H as desired by the user. The indoor environment adjustment system 1 includes a control device 2, an operation terminal 3, a ventilation device 4, an air conditioning system 5, indoor environment sensors 6a to 6d, an outdoor environment sensor 7, a router 8, and a server 9. ..

The control device 2 is installed at an appropriate place in the house H, and can perform wireless communication with the ventilation device 4 and the air conditioning system 5 via a wireless network (not shown) constructed in the house H. Further, the control device 2 is connected to the router 8 which is a broadband router by a LAN (Local Area Network) cable, and can communicate with the remote server 9 via the Internet.

The control device 2 periodically transmits state data including the latest indoor and outdoor environmental states of the house H and the latest operating states of the ventilation device 4 and the air conditioning system 5. Further, the control device 2 periodically receives the control instruction data sent from the server 9, and controls the ventilation device 4 and the air conditioning system 5 based on the received control instruction data. The details of the control device 2 will be described later.

The operation terminal 3 includes an input device such as a push button, a touch panel, and a touch pad, a display device such as an organic EL display and a liquid crystal display, and a communication interface, for example, a personal computer, a smartphone, a tablet terminal, or a wall-mounted type. It is a smart device such as a remote controller. The operation terminal 3 communicates with the control device 2 in accordance with well-known communication standards such as Wi-Fi (registered trademark), Wi-SUN (registered trademark), and wired LAN. The operation terminal 3 receives an operation from the user and transmits information indicating the accepted operation content to the control device 2. Further, the operation terminal 3 receives the information transmitted from the control device 2 to be presented to the user, and displays the received information. In this way, the operation terminal 3 plays a role as an interface with the user (so-called user interface).

The ventilation device 4 is an example of the adjusting device according to the present invention. The ventilation device 4 is installed at an appropriate place in the house H, and includes a communication interface, a fan motor control unit, a fan motor, and a shutter inside a rectangular parallelepiped housing (not shown). The communication interface communicates with the control device 2 via the above wireless network. This wireless network is, for example, a network according to ECHONET Lite.

The fan motor control unit includes a CPU (Central Processing Unit), ROM (Read Only Memory), RAM (Random Access Memory), etc., and is referred to as control data from the control device 2 received by the communication interface (hereinafter referred to as ventilation control data). .) Controls the drive of the fan motor. The ventilation control data includes information indicating the start, change or stop of the drive of the fan motor, and information indicating the rotation speed. The fan motor control unit rotates the stopped fan motor at the specified rotation speed or changes the rotation speed of the fan motor to the specified rotation speed based on the above information included in the ventilation control data. Or stop driving the fan motor during driving (ie, rotating). When the fan motor rotates, the area around the ventilation device 4 in the house H is ventilated.

The shutter opens and closes based on the above ventilation control data received by the communication interface. Specifically, when the ventilation control data from the control device 2 indicates the start of driving of the fan motor, the shutter opens, while when the data indicates that the driving of the fan motor is stopped, the shutter opens. close. When the shutter is opened, the air passage between the outside and the inside of the house H is opened via the ventilation device 4. On the other hand, when the shutter is closed, this air passage is blocked.

The air conditioning system 5 is an example of the adjusting device according to the present invention. The air conditioning system 5 includes an air conditioner 50, a duct 51, and dampers 52a to 52d, and operates based on the control data from the control device 2, thereby air-conditioning each room in the house H, that is, the air temperature. And / or adjust the humidity. Although not shown, the air conditioner 50 includes an indoor unit and an outdoor unit. The indoor unit and the outdoor unit are connected so as to be able to communicate with each other via a communication line, and are also connected by a refrigerant pipe for circulating a refrigerant.

The indoor unit includes a fan, a heat exchanger, and a first control board. The outdoor unit includes a compressor, a condenser, an expansion valve, an evaporator, and a second control board. Both the first control board and the second control board include a CPU, a ROM, a ROM, and a readable / writable non-volatile semiconductor memory such as an EEPROM (Electrically Erasable Programmable Read-Only Memory) or a flash memory.

Further, the air conditioner 50 includes a communication interface (not shown) for wirelessly communicating with the control device 2 via the above-mentioned wireless network. This communication interface is provided on either the first control board of the indoor unit or the second control board of the outdoor unit.

In the present embodiment, the indoor unit of the air conditioner 50 is installed close to the ventilation device 4 so that the air ventilated by the operation of the ventilation device 4 can be sucked. Specifically, the indoor unit adjusts the temperature and / or humidity of the sucked ambient air, and sends the adjusted air to the air-conditioned area via the duct 51 connecting the adjusted air.

As shown in FIG. 2, the duct 51 is branched into a plurality of branch paths in order to guide the air supplied from the air conditioner 50 (specifically, the indoor unit) to each room (rooms A to D). The end of each branch is connected to an air outlet provided on the ceiling of each room. Further, the duct 51 is provided with dampers 52a to 52d corresponding to each branch path. The dampers 52a to 52d are electric air valves for distributing the air supplied from the air conditioner 50 to the rooms A to D, respectively, and the opening degree thereof is the control data from the control device 2 (hereinafter, dampers). It is adjusted according to the control data).

Communication between the control device 2 and each damper 52 is performed according to a well-known wireless LAN standard such as Echonet Lite or Wi-Fi (registered trademark). In the damper control data, the opening degree of the damper 52 is set from 0 to 6, and the larger the value, the larger the opening degree. When the opening degree is set to 0, the damper 52 is fully closed and the corresponding room is not air-conditioned.

The indoor environment sensors 6a to 6d are installed on the ceiling or wall of the rooms A to D, respectively, and measure the environmental state of each room. The environmental state measured by each indoor environment sensor 6 includes, for example, air temperature, humidity, dust concentration, and VOC (volatile organic compounds) concentration. Each indoor environment sensor 6 is provided with a communication interface, and data including measurement results (hereinafter referred to as indoor environment data) is periodically (for example, every minute) transmitted to the control device 2. Communication between the control device 2 and each indoor environment sensor 6 is performed in accordance with a well-known wireless LAN standard such as Echonet Lite or Wi-Fi (registered trademark).

The outdoor environment sensor 7 is installed on the roof of the house H and measures the outdoor environmental condition. The environmental state measured by the outdoor environment sensor 7 includes, for example, air temperature, humidity, dust concentration, wind direction, and wind speed. The outdoor environment sensor 7 is provided with a communication interface, and data including measurement results (hereinafter referred to as outdoor environment data) is periodically (for example, every minute) transmitted to the control device 2. Communication between the control device 2 and the outdoor environment sensor 7 is performed in accordance with a well-known wireless LAN standard such as Echonet Lite or Wi-Fi (registered trademark).

As shown in FIG. 3, the control device 2 includes a CPU 20, a communication interface 21, a ROM 22, a RAM 23, and a secondary storage device 24. These components are connected to each other via the bus 25. The CPU 20 controls the control device 2 in an integrated manner. The details of the function of the control device 2 realized by the CPU 20 will be described later.

The communication interface 21 includes a ventilation device 4, an air conditioning system 5 (air conditioner 50, dampers 52a to 52d), indoor environment sensors 6a to 6d, one or more network cards for wireless communication with the outdoor environment sensor 7, and an operation terminal. A network card for wireless communication or wired communication with 3 and a network card for communication with the server 9 via the router 8 are provided.

The ROM 22 stores a plurality of firmwares and data and the like used when executing these firmwares. The RAM 23 is used as a work area of the CPU 20.

The secondary storage device 24 is composed of a readable / writable non-volatile semiconductor memory such as an EEPROM and a flash memory, an HDD (Hard Disk Drive), and the like. The secondary storage device 24 stores a program for adjusting the indoor environment state (hereinafter referred to as an indoor environment adjustment program) and data used when the indoor environment adjustment program is executed.

FIG. 4 is a block diagram showing a functional configuration of the control device 2. The control device 2 functionally includes a user interface unit 200, an environmental data collection unit 201, a data transmission unit 202, an information transmission unit 203, a data reception unit 204, and a control unit 205. These functional units are realized by the CPU 20 executing an indoor environment adjustment program stored in the secondary storage device 24.

The user interface unit 200 is an example of the information receiving means according to the present invention. The user interface unit 200 performs user interface processing via the operation terminal 3. That is, the user interface unit 200 receives an input operation by a user such as a resident of the house H via the operation terminal 3. In the present embodiment, the user inputs the housing information and the request information via the operation terminal 3. Details of housing information and request information will be described later. Further, the user interface unit 200 transmits information to be presented to the user, for example, monitoring screen information for monitoring the environmental state of each room to the operation terminal 3.

The environment data collection unit 201 periodically (for example, every minute) sends each indoor environment data from each of the indoor environment sensors 6a to 6d, and the outdoor environment sensor 7 periodically (for example, every minute). The outdoor environment data sent to the user is received, and the received indoor environment data and the outdoor environment data are stored in the state history DB stored in the secondary storage device 24. The state history DB is a database in which the history of the environmental state of each room, the history of the outdoor environmental state, the history of the operating state of the ventilation device 4, and the history of the operating state of the air conditioning system 5 are stored.

The data transmission unit 202 is an example of the state data transmission means according to the present invention. The data transmission unit 202 periodically (for example, every 10 minutes) transmits status data to the server 9. The state data includes the latest states read from the state history DB, that is, the latest environmental states of the rooms A to D and the outdoors, and the latest operating states of the ventilation device 4 and the air conditioning system 5.

The information transmission unit 203 is an example of the information transmission means according to the present invention. The information transmission unit 203 irregularly transmits the housing information and the request information to the server 9. The housing information is information on the specifications of the house H, for example, the area of the entire house H, the floor plan, the height of the room, the area of each room, the airtightness of the door and the airtightness between the rooms, and the heat insulation of the wall and the window. Specifications etc. are included. In addition, information regarding the installation position of the ventilation device 4, information regarding the position of the air outlet of each room, and the like may be included in the housing information. The housing information is transmitted to the server 9 by the information transmission unit 203 when it is newly input by the user via the operation terminal 3 and when it is updated.

Further, the request information is information indicating a user's request for environmental adjustment, and includes, for example, a request for comfort, a request for adjustment speed, and the like. The request information is transmitted to the server 9 by the information transmission unit 203 when it is newly input by the user via the operation terminal 3 and when it is updated.

The data receiving unit 204 is an example of the control instruction data receiving means according to the present invention. The data receiving unit 204 receives control instruction data sent periodically (for example, every 10 minutes) from the server 9. The control instruction data includes ventilation instruction information indicating the control content for the ventilation device 4 and air conditioning instruction information indicating the control content for the air conditioning system 5. The ventilation instruction information includes information indicating the start, change or stop of the drive of the fan motor, and information indicating the rotation speed. Further, the air conditioning instruction information includes information indicating the opening degree of each damper 52. The data receiving unit 204 updates the state history DB based on the ventilation instruction information and the air conditioning instruction information extracted from the control instruction data, and supplies the ventilation instruction information and the air conditioning instruction information to the control unit 205.

The control unit 205 is an example of the control means according to the present invention. The control unit 205 generates ventilation control data for controlling the ventilation device 4 based on the ventilation instruction information supplied from the data reception unit 204, and transmits the ventilation control data to the ventilation device 4. Further, the control unit 205 generates each damper control data for controlling each of the dampers 52a to 52d of the air conditioning system 5 based on the air conditioning instruction information supplied from the data receiving unit 204, and transmits the damper control data to each damper 52. do.

Subsequently, the server 9 will be described. The server 9 is a so-called cloud server managed by the manufacturer or sales company of the control device 2. As shown in FIG. 5, the server 9 includes a CPU 90, a communication interface 91, a ROM 92, a RAM 93, and a secondary storage device 94. These components are connected to each other via a bus 95. The CPU 90 controls the server 9 in an integrated manner. The performance of the CPU 90 is higher than that of the CPU 20 of the control device 2. Details of the functions of the server 9 realized by the CPU 90 will be described later.

The communication interface 91 is an interface for connecting to the Internet and communicating with other devices such as the control device 2.

The ROM 92 stores a plurality of firmwares and data used when executing these firmwares. The RAM 93 is used as a work area of the CPU 90.

The secondary storage device 94 is a large-capacity storage device composed of a readable / writable non-volatile semiconductor memory such as an EEPROM and a flash memory, an HDD, and the like. As shown in FIG. 5, the customer DB 940 is stored in the secondary storage device 94. The customer DB 940 is a database in which information managed for each user who purchased the control device 2, that is, for each customer (hereinafter referred to as customer information) is registered as many as the number of customers. In addition, the secondary storage device 94 stores a program for providing a remote control service to each customer (hereinafter referred to as a remote control program) and data used when the remote control program is executed.

Functionally, as shown in FIG. 6, the server 9 includes a weather data acquisition unit 900, a state data reception unit 901, a housing information reception unit 902, a request information reception unit 903, and an environmental state prediction unit 904. A control content determination unit 905 and a control instruction data transmission unit 906 are provided. These functional units are realized by the CPU 90 executing a remote control program stored in the secondary storage device 94.

The meteorological data acquisition unit 900 periodically (for example, every 10 minutes) acquires meteorological data corresponding to each customer's residential area from the meteorological service provider server 10 by communication. The meteorological service provider server 10 is a server managed by the meteorological service provider and is connected to the Internet. The meteorological data includes averaged environmental conditions (for example, air temperature, humidity, dust concentration, wind direction, wind speed, etc.) in the area designated by the meteorological data acquisition unit 900. The meteorological data acquisition unit 900 stores the acquired meteorological data corresponding to the residential area of each customer in the customer information corresponding to the customer in the customer DB 940.

The state data receiving unit 901 is an example of the state data receiving means according to the present invention. The state data receiving unit 901 receives the state data sent periodically (for example, every 10 minutes) from the control device 2 of each customer, and the received state data is used as the customer information corresponding to the customer in the customer DB 940. Store.

The housing information receiving unit 902 is an example of the information receiving means according to the present invention. The housing information receiving unit 902 receives the housing information sent irregularly from the control device 2 of each customer, and stores the received housing information in the customer information corresponding to the customer in the customer DB 940. The request information receiving unit 903 receives the request information sent irregularly from the control device 2 of each customer, and stores the received request information in the customer information corresponding to the customer in the customer DB 940.

The environmental state prediction unit 904 is an example of the prediction means according to the present invention. The environmental state prediction unit 904 periodically (for example, every 10 minutes) analyzes the air flow for each customer based on the content of the customer information corresponding to the customer in the customer DB 940, and performs an air flow analysis to the indoor environment of the customer's house H. , That is, the environmental condition of each room is predicted.

Specifically, the environmental state prediction unit 904 first generates a state pattern X indicating the current operating state of the ventilation device 4 and the air conditioning system 5 based on the state data included in the customer information. The state pattern X includes the current rotation speed of the fan motor (for example, 30 rps (rotation / sec)) and the current opening degree of each damper 52 (for example, 2). Next, the environmental state prediction unit 904 generates the operating state of the ventilation device 4 in the state pattern X, that is, the state pattern Y in which the rotation speed of the fan motor is changed. The rotation speed of the fan motor in the state pattern Y is, for example, 25 rps (rotation / second). Further, the environmental state prediction unit 904 generates the operating state of the air conditioning system 50 in the state pattern X, that is, the state pattern Z in which the opening degree of each damper 52 is changed. The opening degree of each damper 52 in the state pattern Z is, for example, 3.

The environmental state prediction unit 904 is a ventilation device for each of a plurality of state patterns X, Y, Z having different contents generated as described above, for a time T (for example, 10 minutes) predetermined by the contents indicated by the state patterns. Predict the environmental state of each room (rooms A to D) when 4 and the air conditioning system 5 are operated. Specifically, the environmental state prediction unit 904 is based on the content of the state pattern, the housing information included in the customer information of the customer, the weather data, and the environmental state of each room and the outdoors included in the state data. , Predict the environmental condition after time T of each room. At that time, the environmental condition prediction unit 904 simplified from the housing information, for example, "a room of 100 m ³ and a room of 50 m ³ are combined in a state where ventilation of 10 m ³ / h is possible". You may generate a model and use the generated model to predict environmental conditions. The environmental state prediction unit 904 predicts the temperature / humidity distribution, the dust distribution, and the like as the environmental state after the time T of each room.

The control content determination unit 905 is an example of the control content determination means according to the present invention. The control content determination unit 905 selects the most appropriate prediction result from the prediction results corresponding to each of the state patterns X, Y, and Z. The selection conditions at that time include basic conditions such as that the indoor air temperature and humidity meet general comfort standards, that the room meets general air purification standards, and the user based on the request information. Preference conditions and are included. The preference conditions include specifying the adjustment speed (eg, "slow", "normal", "fast", etc.) and the degree of comfort (eg, "strong", "normal", "weak", etc.). Is included.

The control content determination unit 905 determines a state pattern corresponding to the selected most appropriate prediction result as the control content, and notifies the control instruction data transmission unit 906 of the determined control content. When the state pattern X is determined as the control content, it means that it is the same as the control content of the ventilation device 4 and the air conditioning system 5 in the current state data.

The control instruction data transmission unit 906 is an example of the control instruction data transmission means according to the present invention. The control instruction data transmission unit 906 generates control instruction data based on the control content notified by the control content determination unit 905, and transmits the generated control instruction data to the control device 2.

FIG. 7 is a flowchart showing the procedure of the indoor environment adjustment process executed by the control device 2 and the server 9 in the indoor environment adjustment system 1. This indoor environment adjustment process is repeatedly executed at the timing (for example, every 10 minutes) when the control device 2 transmits the state data to the server 9.

In step S101, the control device 2 transmits state data including the environmental state of each room in the house H, the outdoor environmental state, the operating state of the ventilation device 4, and the operating state of the air conditioning system 5 to the server 9. do.

In step S102, the server 9 updates the customer information corresponding to the customer in the customer DB 940 based on the received state data from the control device 2. In step S103, the server 9 generates a plurality of state patterns X, Y, Z having different contents based on the received state data.

In step S104, the server 9 predicts the environmental state of each room after the time T (for example, 10 minutes) in each of the plurality of state patterns X, Y, and Z based on the customer information corresponding to the customer. In step S105, the server 9 determines one state pattern as the control content from the plurality of state patterns X, Y, Z.

In step S106, the server 9 generates control instruction data based on the determined control content, and transmits the generated control instruction data to the control device 2.

In step S107, the control device 2 controls the ventilation device 4 and the air conditioning system 5 based on the received control instruction data from the server 9.

As described above, in the indoor environment adjustment system 1 according to the embodiment of the present invention, the housing information, the weather data, the indoor and outdoor environmental conditions, the ventilation device 4, and the air conditioning system, which are information on the specifications of the house H, are used. Based on the operating state of 5, the indoor environmental state after time T is predicted, and the control contents of the ventilation device 4 and the air conditioning system 5 are determined based on the predicted result. Therefore, it is possible to accurately maintain the room in the environmental state desired by the user.

Further, since the process of predicting the indoor environmental state after the time T is executed by the server 9 having a high processing capacity equipped with the high-performance CPU 90, even a computer having a low processing capacity can be used as the control device 2. It will be possible to make it work.

Further, the server 9 generates a plurality of state patterns having different contents based on the current operating states of the ventilation device 4 and the air conditioning system 5, and predicts the indoor environmental state after the time T for each state pattern. Then, the server 9 selects the most appropriate prediction result from the prediction results corresponding to each state pattern, and determines the state pattern corresponding to the selected prediction result as the control content of the ventilation device 4 and the air conditioning system 5. Therefore, more appropriate control contents can be derived.

The present invention is not limited to the above embodiment, and various modifications can be made without departing from the gist of the present invention.

In the above embodiment, the ventilation device 4 and the air conditioner 50 are installed in the house H one by one, and the adjusted air is conveyed to each room by the duct 51 connected to the indoor unit of the air conditioner 50. It is not limited to such a configuration. For example, a mechanical ventilation device and an air conditioner (indoor unit) may be installed in each room whose environmental condition is to be adjusted. Further, the configuration of the indoor environment adjustment system 1 may include a radiant cooling / heating device, a floor heating device, an air purifying device, a humidifying device, and the like.

Further, the environmental state measured by the indoor environment sensors 6a to 6d may include the number of occupants, the amount of exercise of the occupants, the amount of solar radiation, and the like. Further, the request information may include information regarding the priority items of the environment in each room and the time zone for adjusting the environment based on the priority items, which are set in advance by the user. Priority items include, for example, hot / cold comfort, air cleanliness, low noise, low airflow, and the like. Further, the request information may include a request for the degree of air purification (for example, "strong", "normal", "weak", etc.) and a request for power saving (for example, a 20% reduction in electricity bill). Further, the user may be able to select from a plurality of request information prepared in advance according to the billing amount. Further, the control device 2 transmits information such as the name, model number, and performance limit value of the adjusting device (ventilation device 4, air conditioning system 5, etc.) to the server 9, and the server 9 adjusts by taking such information into consideration. The control content of the device may be determined.

Further, the server 9 predicts the indoor environmental condition based on the housing information, the indoor environmental condition, and the operating condition of the ventilation device 4 and the air conditioning system 5 without using the weather data and the outdoor environmental condition. You may. Further, the server 9 may repeatedly execute a series of processes by the environment state prediction unit 904 and the control content determination unit 905 a plurality of times. In this case, for example, in the second loop, the environment state prediction unit 904 has different contents based on the state pattern obtained by the control content determination unit 905 in the first loop, that is, the state pattern determined as the control content. Generate multiple state patterns X, Y, Z. However, the change width is reduced each time the loop is repeated. By doing so, it is possible to determine a more appropriate control content.

Further, the server 9 may acquire the housing information corresponding to the housing H by communicating with another server (not shown) managed by the sales company of the housing H or the like.

Further, when the control device 2 cannot communicate with the server 9, or when the user instructs the self-sustaining control, the ventilation device 4 is based on the measurement results of the indoor environment sensors 6a to 6d and the outdoor environment sensor 7. And the air conditioning system 5 can be controlled.

Further, the user can access the control device 2 from inside and outside the house H via the operation terminal 3 and instruct the control contents of the ventilation device 4 and the air conditioning system 5. In this case, the control device 2 notifies the server 9 that the manual control by the user has been performed. Upon receiving such a notification, the server 9 stops the remote control of the control device 2 for a certain period of time (for example, one hour). As a result, it is possible to prevent an unintended change in the environmental state of the user and reduce the processing load of the server 9.

Further, the server 9 may provide each customer with a service different from the adjustment of the indoor environment state based on the customer information of each customer registered in the customer DB 940. For example, the server 9 may have a function of determining the value of the house H of each customer based on the customer information of each customer and providing the determination result to each customer via the control device 2. Specifically, the server 9 determines the value of the house H from the house information, the history of the environmental state of each room, and the history of the operating state of the ventilation device 4 and the air conditioning system 5. For example, in a house H that maintains good humidity for a long period of time, it can be predicted that the generation of mold is suppressed as compared with a normal house, and this is one of the factors for determining the value of the house H. Can be adopted. Further, in the house H where the energy for obtaining the same air-conditioning effect (cooling effect or heating effect) is increasing, it can be predicted that the heat insulating property and the airtightness are lowered with the aging, and the value of the house H is high. Can be adopted as one of the factors in determining.

Further, since the deterioration of the heat insulating material and the airtightness is assumed to be the deterioration of the heat insulating material, the sash, etc., the server 9 proposes the maintenance to the customer or the reform proposal via the control device 2. May be done.

Alternatively, the sales company of the house H or the like may be able to provide the above-mentioned service. In this case, the server 9 may transmit information indicating the result of determining the value of the house H of each customer to the server managed by the sales company of the house H (hereinafter referred to as the server A). Information for determining the value of the house H (for example, information including the house information, the history of the environmental state of each room, the history of the operating state of the ventilation device 4 and the air conditioning system 5 and the like) may be transmitted. The server 9 may transmit the above information to the server A only when the customer of the house H has obtained consent in advance via the control device 2, or when the server A requests the information. In addition, the above information may be transmitted to the server A only when the customer is confirmed via the control device 2 and consent is obtained.

In the above embodiment, in the control device 2, each functional unit (see FIG. 4) of the control device 2 is realized by executing the indoor environment adjustment program stored in the secondary storage device 24 by the CPU 20. .. Further, in the server 9, each functional unit (see FIG. 6) of the server 9 is realized by executing the remote control program stored in the secondary storage device 94 by the CPU 90.

However, all or part of the functional parts of the control device 2 may be realized by dedicated hardware. Similarly, all or part of the functional parts of the server 9 may be realized by dedicated hardware. The dedicated hardware is, for example, a single circuit, a composite circuit, a programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a combination thereof.

The above-mentioned indoor environment adjustment program or remote control program includes a CD-ROM (Compact Disc Read Only Memory), a DVD (Digital Versatile Disc), a magneto-optical disc (Magneto-Optical Disc), and a USB (Universal Serial Bus) memory. It is also possible to store and distribute it in a computer-readable recording medium such as a memory card or an HDD. Then, by installing the indoor environment adjustment program or the remote control program distributed in this way on a specific or general-purpose computer, it is also possible to make the computer function as the control device 2 or the server 9 in the above embodiment. ..

Further, the indoor environment adjustment program or the remote control program is stored in a disk device or the like owned by another server on the Internet, and the indoor environment adjustment program or the remote control program is downloaded from the server to the control device 2 or the server 9. You may do so.

1 Indoor environment adjustment system, 2 Control device, 3 Operation terminal, 4 Ventilation device, 5 Air conditioning system, 6a-6d Indoor environment sensor, 7 Outdoor environment sensor, 8 Router, 9 server, 10 Meteorological operator server, 20, 90 CPU , 21,91 Communication interface, 22,92 ROM, 23,93 RAM, 24,94 Secondary storage device, 50 air conditioner, 51 duct, 52a to 52d damper, 200 user interface section, 201 environment data collection section, 202 data Transmitter, 203 Information transmitter, 204 Data receiver, 205 Control unit, 900 Meteorological data acquisition unit, 901 Status data receiver, 902 Housing information receiver, 903 Request information receiver, 904 Environmental status prediction unit, 905 Control contents Decision unit, 906 control instruction data transmission unit, 940 customer DB

Claims (8)

Equipped with a control device and a server
The control device is
Information receiving means for accepting input of housing information related to housing specifications,
An information transmission means for transmitting the housing information to the server, and
A state data transmitting means for transmitting state data including the environmental state in the room of the house and the operating state of the adjusting device for adjusting the environmental state in the room to the server.
A control instruction data receiving means for receiving control instruction data for controlling the adjusting device from the server, and a control instruction data receiving means.
A control means for controlling the adjusting device based on the control instruction data is provided.
The server
An information receiving means for receiving the housing information from the control device, and
A state data receiving means for receiving the state data from the control device, and
A prediction means for predicting the environmental state of the room after a predetermined time based on the housing information and the state data, and
A control content determining means for determining the control content of the adjusting device based on the prediction result of the predicting means, and a control content determining means.
A control instruction data transmission means for transmitting the control instruction data generated based on the determined control content to the control device is provided .
The predicting means generates a plurality of state patterns in which the operating states of the adjusting device are different from each other based on the received state data, and operates the adjusting device for a predetermined time with the contents indicated by each state pattern. The environmental state of the room is predicted by using the housing information and the environmental state of the room included in the state data.
The control content determining means selects one prediction result from the prediction results corresponding to each of the plurality of state patterns based on a predetermined selection condition, and adjusts the state pattern corresponding to the selected prediction result. An indoor environment adjustment system that is determined as the control content of . In the control device
The information receiving means further accepts input of request information indicating a user's request regarding adjustment of an environmental state.
The information transmission means further transmits the request information to the server.
In the server
The indoor environment adjusting system according to claim 1, wherein the control content determining means includes the user's preference condition based on the request information in the selection condition and determines the control content of the adjusting device. The server determines the value of the house based on the house information, the history of the environmental state in the room, and the history of the operating state of the adjusting device, and the result of the determination is determined by the user via the control device. The indoor environment adjustment system according to claim 1 or 2, further comprising a housing value determination means provided to the above. The indoor environment adjustment system according to claim 3, wherein the house value determining means proposes maintenance or remodeling of the house to a user via the control device. When the server has obtained the consent of the user of the house , the information indicating the result of the determination, the house information, the history of the environmental state in the room, and the history of the operating state of the adjusting device The indoor environment adjustment system according to claim 3 or 4 , further comprising a transmission means for transmitting information including the above to another server. Information receiving means for receiving housing information related to housing specifications from the control device,
A state data receiving means for receiving state data including an environmental state in the room of the house and an operating state of the adjusting device for adjusting the environmental state in the room from the control device.
A prediction means for predicting the environmental state of the room after a predetermined time based on the housing information and the state data, and
A control content determining means for determining the control content of the adjusting device based on the prediction result of the predicting means, and a control content determining means.
A control instruction data transmission means for transmitting control instruction data generated based on the determined control content to the control device is provided .
The predicting means generates a plurality of state patterns in which the operating states of the adjusting device are different from each other based on the received state data, and operates the adjusting device for a predetermined time with the contents indicated by each state pattern. The environmental state of the room is predicted by using the housing information and the environmental state of the room included in the state data.
The control content determining means selects one prediction result from the prediction results corresponding to each of the plurality of state patterns based on a predetermined selection condition, and adjusts the state pattern corresponding to the selected prediction result. The server that is determined as the control content of . The control device
Accepts input of housing information regarding housing specifications,
Send the housing information to the server and
State data including the environmental state in the room of the house and the operating state of the adjusting device for adjusting the environmental state in the room is transmitted to the server.
The server
Upon receiving the housing information from the control device,
Upon receiving the state data from the control device,
Based on the housing information and the state data, the environmental state of the room after a predetermined time is predicted.
Based on the predicted result, the control content of the adjusting device is determined.
The control instruction data generated based on the determined control content is transmitted to the control device, and the control instruction data is transmitted to the control device.
The control device
Upon receiving the control instruction data from the server,
The adjusting device is controlled based on the control instruction data, and the adjusting device is controlled .
The server
The above, when a plurality of state patterns in which the operating states of the adjusting device are different from each other are generated based on the received state data, and the adjusting device is operated for the predetermined time with the contents indicated by each state pattern. The indoor environmental state is predicted using the housing information and the indoor environmental state included in the state data.
From the prediction results corresponding to each of the plurality of state patterns, one prediction result is selected based on a predetermined selection condition, and the state pattern corresponding to the selected prediction result is determined as the control content of the adjusting device . How to adjust the indoor environment. Computer,
Information receiving means for receiving housing information related to housing specifications from the control device,
A state data receiving means for receiving state data including an environmental state in the room of the house and an operating state of the adjusting device for adjusting the environmental state in the room from the control device.
A predictive means for predicting the environmental state of the room after a predetermined time based on the house information and the state data.
A control content determining means for determining the control content of the adjusting device based on the prediction result of the predicting means,
A program for functioning as a control instruction data transmission means for transmitting control instruction data generated based on the determined control content to the control device .
The predicting means generates a plurality of state patterns in which the operating states of the adjusting device are different from each other based on the received state data, and operates the adjusting device for a predetermined time with the contents indicated by each state pattern. The environmental state of the room is predicted by using the housing information and the environmental state of the room included in the state data.
The control content determining means selects one prediction result from the prediction results corresponding to each of the plurality of state patterns based on a predetermined selection condition, and adjusts the state pattern corresponding to the selected prediction result. A program that is determined as the control content of .

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