JP7496674B2 - Facility equipment system and facility equipment control method - Google Patents

Description

The present invention relates to an equipment system and an equipment control method.

Traditionally, in facility equipment systems in which multiple facility equipment such as air conditioners and lighting devices are connected, a configuration using a dedicated wired network has been widely adopted.

In such equipment systems, configurations that allow a user to operate one or more desired equipment devices via a mobile terminal, such as that disclosed in Patent Document 1, are well known, and configurations in which information obtained from wireless sensors that detect temperature, humidity, illuminance, various gas concentrations, and the presence or absence of people is used to control each equipment device are also well known.

International Publication No. 2018/146724

As described above, when using a mobile terminal as a user interface or using the detection results of wireless sensors, etc. to control each piece of equipment, conventional equipment systems generally adopt a configuration in which an equipment controller that controls each piece of equipment communicates data with wireless terminals such as mobile terminals and wireless sensors.

As a result, the facility equipment controller must be equipped with a wired communication interface corresponding to the wired network in the facility equipment system, as well as a separate wireless communication interface for wireless communication with wireless terminals. In addition, this requires complex processing such as timing adjustment between networks and control arbitration, resulting in increased development costs.

The present invention has been made to solve the above problems, and aims to provide an equipment system etc. that can realize the control of equipment using wireless terminals without the need for the equipment controller to be equipped with a separate communication interface for communicating with wireless terminals.

In order to achieve the above object, the facility equipment system according to the present invention comprises:
A privately-operated wireless base station that ensures low latency performance in at least a fifth generation mobile communication system;
Equipment and
A portable terminal carried by a user;
An equipment controller;
an environmental sensor for detecting an environmental condition related to an environment in which the facility equipment is installed;
The mobile terminal includes:
an operation receiving means for receiving an operation related to the facility device from the user;
an environmental information acquiring means for acquiring environmental information indicating the detected environmental state from the environmental sensor by communicating with the environmental sensor via a short-range wireless network conforming to a short-range wireless standard;
an operation information transmitting means for transmitting operation information indicating the received operation to the facility equipment controller via a private wireless network established based on the private wireless base station;
an environmental information transmission means for transmitting the acquired environmental information to the facility equipment controller via the private wireless network,
The facility equipment controller includes:
an operation information receiving means for receiving the operation information transmitted from the mobile terminal via the private wireless network;
an environmental information receiving means for receiving the environmental information transmitted from the mobile terminal via the private wireless network;
An equipment control means for controlling the equipment based on the received operation information and the received environmental information,
The system further includes a management server for managing the location of the facility equipment,
The mobile terminal includes:
a communication switching means for switching from communication via a wide area wireless network provided by a telecommunications carrier to communication via the private wireless network when the mobile station moves from outside an area of the private wireless network to within the area of the private wireless network, and for switching from communication via the private wireless network to communication via the wide area wireless network when the mobile station moves from within the area of the private wireless network to outside the area of the private wireless network;
an identification information acquiring means for acquiring identification information of the facility equipment from the facility equipment by communicating with the facility equipment via the private wireless network when a time elapsed since communication via the wide area wireless network is switched to communication via the private wireless network exceeds a predetermined time;
a location information acquisition means for receiving a GPS signal and acquiring location information when the identification information of the facility equipment is acquired by the identification information acquisition means;
The device further includes a location information transmitting means for transmitting, when communication is switched from communication via the private wireless network to communication via the wide area wireless network, location information in which the acquired identification information and the acquired position information are stored to the management server via the wide area wireless network .

According to the present invention, the facility equipment controller does not need to be equipped with a separate communication interface for communicating with wireless terminals such as mobile terminals and environmental sensors, and it is possible to control the facility equipment using wireless terminals.

FIG. 1 is a diagram showing an overall configuration of an equipment system according to a first embodiment of the present invention; FIG. 1 is a block diagram showing a hardware configuration of a mobile terminal according to a first embodiment; FIG. 1 is a block diagram showing a hardware configuration of an equipment controller according to a first embodiment. FIG. 1 is a block diagram showing the functional configurations of a mobile terminal and an equipment controller in a first embodiment; A flowchart showing the procedure of information transmission processing executed by the mobile terminal according to the first embodiment. A flowchart showing the procedure of device control processing executed by the facility device controller of the first embodiment. FIG. 1 is a diagram showing an overall configuration of an equipment system according to a second embodiment of the present invention; FIG. 11 is a block diagram showing a hardware configuration of a management server according to a second embodiment. FIG. 11 is a block diagram showing a hardware configuration of a mobile terminal according to a second embodiment. FIG. 11 is a block diagram showing a functional configuration of a mobile terminal according to a second embodiment. FIG. 13 is a diagram showing an overall configuration of an equipment system according to a third embodiment of the present invention; FIG. 13 is a block diagram showing a hardware configuration of a mobile terminal according to a third embodiment. FIG. 13 is a block diagram showing the functional configurations of a mobile terminal and an equipment controller in a third embodiment. FIG. 13 is a diagram showing an overall configuration of an equipment system according to a fourth embodiment of the present invention; FIG. 13 is a block diagram showing a hardware configuration of a mobile terminal according to a fourth embodiment. FIG. 13 is a block diagram showing a functional configuration of a mobile terminal according to a fourth embodiment.

The following describes in detail the embodiments of the present invention with reference to the drawings.

(Embodiment 1)
1 is a diagram showing an overall configuration of a facility equipment system 1 according to a first embodiment of the present invention. The facility equipment system 1 is a system for controlling and managing a plurality of facility equipment 3 installed in a building such as an office building, a commercial building, a factory, or the like.

The facility equipment system 1 includes a privately-operated wireless base station 2, a plurality of facility equipment 3, a mobile terminal 4, a facility equipment controller 5, an environmental sensor 6, and a biosensor 7. The privately-operated wireless base station 2 is an example of a privately-operated wireless base station according to the present invention. The privately-operated wireless base station 2 is a privately-operated wireless base station intended for use within the building or within a site including the building (hereinafter referred to as a privately-operated wireless network area). In detail, the privately-operated wireless base station 2 is a wireless base station for enabling wireless communication under 5G (fifth generation mobile communication system) specifications within this privately-operated wireless network area, and is a wireless base station for so-called local 5G.

Each facility device 3 is an example of facility device according to the present invention, such as lighting equipment and air conditioning equipment. Each facility device 3 has a communication interface for wireless communication with other devices (specifically, the facility device controller 5) via a private wireless network (in other words, a local 5G network) established based on the private wireless base station 2. Each facility device 3 may be connected to the private wireless network by an external communication adapter, enabling wireless communication with the facility device controller 5.

The mobile terminal 4 is an example of a mobile terminal according to the present invention. The mobile terminal 4 is an electronic device carried by a user, such as a smartphone or a tablet terminal. As shown in FIG. 2, the mobile terminal 4 includes a user interface 40, a first communication interface 41, a second communication interface 42, a CPU (Central Processing Unit) 43, a ROM (Read Only Memory) 44, a RAM (Random Access Memory) 45, and a secondary storage device 46. These components are connected to each other via a bus 47.

The user interface 40 includes a display device such as a liquid crystal display or an organic EL display, and an input device such as a push button, a touch panel, or a touch pad. Under the control of the CPU 43, the user interface 40 displays various screens and the like in response to user operations, and also accepts operation inputs from the user and sends signals related to the accepted operations to the CPU 43.

The first communication interface 41 is hardware for wirelessly communicating with other devices via the above-mentioned private wireless network. The second communication interface 42 is hardware for wirelessly communicating with other devices via a short-range wireless network conforming to a predetermined short-range wireless standard, such as Wi-Fi (registered trademark) or BLE (Bluetooth (registered trademark) Low Energy).

The CPU 43 provides overall control over the mobile terminal 4. The ROM 44 stores multiple pieces of firmware and data used when these pieces of firmware are executed. The RAM 45 is used as a working area for the CPU 43.

The secondary storage device 46 is configured to include a readable/writable non-volatile semiconductor memory such as an EEPROM (Electrically Erasable Programmable Read-Only Memory) or a flash memory. The secondary storage device 46 stores various programs including application programs (hereinafter referred to as operation apps) for operating each piece of equipment 3, and data used when these programs are executed. The functions of the mobile terminal 4 will be described in detail later.

The equipment controller 5 is an example of an equipment controller according to the present invention. The equipment controller 5 is connected to each equipment 3 and the mobile terminal 4 via a private wireless network so as to be able to communicate with each equipment 3, and is a device that controls each equipment 3 based on each piece of information, described below, received from the mobile terminal 4.

As shown in FIG. 3, the facility equipment controller 5 includes a communication interface 50, a CPU 51, a ROM 52, a RAM 53, and a secondary storage device 54. These components are interconnected via a bus 55.

The communication interface 50 is hardware for wireless communication with other devices via a private wireless network. The CPU 51 controls the facility equipment controller 5 in an integrated manner. The ROM 52 stores multiple pieces of firmware and data used when these pieces of firmware are executed. The RAM 53 is used as a working area for the CPU 51.

The secondary storage device 54 is composed of a readable/writable non-volatile semiconductor memory such as an EEPROM or a flash memory, a hard disk drive (HDD), etc. The secondary storage device 54 stores various programs including programs for controlling each piece of equipment 3 (hereinafter referred to as equipment control programs), and data used when these programs are executed. The functions of the equipment controller 5 will be described in detail later.

The environmental sensor 6 is an example of an environmental sensor according to the present invention. The environmental sensor 6 is a sensor that detects the environmental state related to the environment in which the equipment 3 is installed. The environmental state includes, for example, air temperature, humidity, illuminance, various gas concentrations, the presence or absence of people, etc. The environmental sensor 6 includes, although none are shown, a sensor circuit, a communication interface, a CPU, a ROM, a RAM, a readable and writable non-volatile semiconductor memory such as an EEPROM or a flash memory, and a primary or secondary battery.

The environmental sensor 6 detects the environmental state at regular intervals and transmits environmental information indicating the detected environmental state to the mobile terminal 4 via the short-range wireless network.

The biosensor 7 is an example of a biosensor according to the present invention. The biosensor 7 is a body-worn (e.g., wristband-type) device that detects biometric data of a user carrying the mobile terminal 4. The biometric data includes body temperature, heart rate, sweat rate, and the like. Although none of these are shown, the biosensor 7 includes a sensor circuit, a communication interface, a CPU, a ROM, a RAM, a readable and writable non-volatile semiconductor memory such as an EEPROM or a flash memory, and a primary or secondary battery.

The biosensor 7 detects biometric data at regular intervals and transmits biometric information indicating the detected biometric data to the mobile terminal 4 via the short-range wireless network.

Next, the functions of the mobile terminal 4 and the facility equipment controller 5 will be described in detail. FIG. 4 is a block diagram showing the functional configuration of the mobile terminal 4 and the facility equipment controller 5. As shown in FIG. 4, the mobile terminal 4 includes an operation reception unit 400, an operation information transmission unit 401, an environmental information acquisition unit 402, an environmental information transmission unit 403, a biometric information acquisition unit 404, and a biometric information transmission unit 405. These functional units of the mobile terminal 4 are realized by the CPU 43 of the mobile terminal 4 executing the above-mentioned operation app stored in the secondary storage device 46.

The facility equipment controller 5 includes an operation information receiving unit 500, an environmental information receiving unit 501, a biometric information receiving unit 502, and an equipment control unit 503. These functional units of the facility equipment controller 5 are realized by the CPU 51 of the facility equipment controller 5 executing the above-mentioned equipment control program stored in the secondary storage device 54.

In the mobile terminal 4, the operation reception unit 400 is an example of an operation reception means according to the present invention, and receives operations related to the equipment 3 from the user. In detail, the operation reception unit 400 displays an equipment operation screen (not shown), and receives input from the user via the equipment operation screen, such as the designation of the equipment 3 to be operated and the contents of the operation instructions for the designated equipment 3. The operation information transmission unit 401 is an example of an operation information transmission means according to the present invention, and transmits operation information indicating the operation received from the user to the equipment controller 5 via the private wireless network.

The environmental information acquisition unit 402 is an example of an environmental information acquisition means according to the present invention, and communicates with the environmental sensor 6 via a short-range wireless network to acquire environmental information indicating the environmental state detected by the environmental sensor 6. The environmental information transmission unit 403 is an example of an environmental information transmission means according to the present invention, and transmits the environmental information acquired by the environmental information acquisition unit 402 to the facility equipment controller 5 via a private wireless network.

The biometric information acquisition unit 404 is an example of a biometric information acquisition means according to the present invention, and communicates with the biometric sensor 7 via a short-range wireless network to acquire biometric information indicating the biometric data detected by the biometric sensor 7. The biometric information transmission unit 405 is an example of a biometric information transmission means according to the present invention, and transmits the biometric information acquired by the biometric information acquisition unit 404 to the facility equipment controller 5 via a private wireless network.

In the facility equipment controller 5, the operation information receiving unit 500 is an example of an operation information receiving means according to the present invention, and receives operation information transmitted from the mobile terminal 4 via a private wireless network. The environmental information receiving unit 501 is an example of an environmental information receiving means according to the present invention, and receives environmental information transmitted from the mobile terminal 4 via a private wireless network. The biometric information receiving unit 502 is an example of a biometric information receiving means according to the present invention, and receives biometric information transmitted from the mobile terminal 4 via a private wireless network.

The device control unit 503 is an example of a device control means according to the present invention. The device control unit 503 controls the facility device 3 based on the operation information received by the operation information receiving unit 500.

In detail, the equipment control unit 503 generates control commands for controlling the specified equipment 3 individually based on the operation information, and transmits each generated control command to each equipment 3 via the private wireless network. For example, if the equipment 3 is a lighting device and the operation information received by the operation information receiving unit 500 is to turn on all equipment 3 simultaneously, the equipment control unit 503 generates control commands for each equipment 3 individually to instruct it to turn on, and transmits each generated control command to each equipment 3 via the private wireless network.

The equipment control unit 503 also controls the facility equipment 3 based on the environmental information received by the environmental information receiving unit 501.

In detail, the equipment control unit 503 generates control commands for controlling all the equipment 3 individually based on the environmental information, and transmits each generated control command to each equipment 3 via the private wireless network. For example, if the equipment 3 is an air conditioner, and the environmental information received by the environmental information receiving unit 501 includes the air temperature in the building, the equipment control unit 503 generates control commands for each equipment 3 individually based on the air temperature, and transmits each generated control command to each equipment 3 via the private wireless network. Alternatively, if the equipment 3 is a lighting device, and the environmental information received by the environmental information receiving unit 501 includes the illuminance in the building, the equipment control unit 503 generates control commands for each equipment 3 individually based on the illuminance, and transmits each generated control command to each equipment 3 via the private wireless network.

The device control unit 503 also controls the facility device 3 based on the biometric information received by the biometric information receiving unit 502.

In detail, the equipment control unit 503 generates control commands for controlling all equipment 3 individually based on the biometric information, and transmits each generated control command to each equipment 3 via the private wireless network. For example, if the equipment 3 is an air conditioning device and the biometric information received by the biometric information receiving unit 502 includes the user's body temperature, the equipment control unit 503 generates control commands for each equipment 3 individually based on the body temperature, and transmits each generated control command to each equipment 3 via the private wireless network.

Figure 5 is a flowchart showing the procedure of the information transmission process executed by the mobile terminal 4. The information transmission process is started when the CPU 43 of the mobile terminal 4 starts an operation app stored in the secondary storage device 46.

When the environmental information transmitted from the environmental sensor 6 is acquired by communication via a short-range wireless network (step S101; YES), the mobile terminal 4 transmits the acquired environmental information to the facility equipment controller 5 via the private wireless network (step S102). Then, the process returns to step S101.

If the biometric information transmitted from the biometric sensor 7 is acquired by communication via a short-range wireless network (step S103; YES) instead of acquiring environmental information (step S101; NO), the mobile terminal 4 transmits the acquired biometric information to the facility equipment controller 5 via the private wireless network (step S104). Then, the process returns to step S101.

If neither environmental information nor biological information is acquired (step S101; NO and step S103; NO) but an operation related to the equipment 3 is received from the user (step S105; YES), the mobile terminal 4 transmits operation information indicating the operation received from the user to the equipment controller 5 via the private wireless network (step S106). If NO in step S105 or after step S106, the process returns to step S101.

Figure 6 is a flowchart showing the procedure of the equipment control process executed by the facility equipment controller 5. The equipment control process is started by the CPU 51 of the facility equipment controller 5 starting an equipment control program stored in the secondary storage device 54.

When the environmental information transmitted from the mobile terminal 4 is received via the private wireless network (step S201; YES), the equipment controller 5 generates control commands for controlling all the equipment 3 individually based on the received environmental information, and transmits each generated control command to each equipment 3 via the private wireless network (step S202). Then, the process returns to step S201.

When receiving biometric information transmitted from the mobile terminal 4 via the private wireless network (step S203; YES) rather than receiving environmental information (step S201; NO), the equipment controller 5 generates control commands for controlling all equipment 3 individually based on the received biometric information, and transmits each generated control command to each equipment 3 via the private wireless network (step S204). Then, the process returns to step S201.

If neither environmental information nor biological information is received (step S201; NO and step S203; NO) but operation information transmitted from the mobile terminal 4 is received via the private wireless network (step S205; YES), the equipment controller 5 generates control commands for controlling the designated equipment 3 individually based on the received operation information, and transmits each generated control command to each designated equipment 3 via the private wireless network (step S206). After NO in step S205 or step S206, the process returns to step S201.

As described above, according to the facility equipment system 1 of the first embodiment, a private wireless network that is a local 5G network is constructed by the private wireless base station 2, and the facility equipment controller 5 communicates with each facility equipment 3 and the mobile terminal 4 via the private wireless network. The facility equipment controller 5 receives operation information based on user operation, environmental information based on the detection result of the environmental sensor 6, and biological information based on the detection result of the biological sensor 7 from the mobile terminal 4 via the private wireless network, and controls the facility equipment 3 based on the received information.

In this way, information from wireless terminals can be utilized, enabling control of highly functional facility equipment 3. Furthermore, the facility equipment controller 5 does not need to be equipped with a separate communication interface for communicating with wireless terminals such as the environmental sensor 6 and biosensor 7, eliminating the need for cumbersome processing such as timing adjustment between networks and control arbitration, thereby reducing development costs.

In addition, in the facility equipment system 1, the facility equipment controller 5 communicates with each facility equipment 3 individually. However, with 5G, the end-to-end delay time is low, at less than 1 ms. Therefore, even if a user simultaneously operates 100 lighting devices via a mobile terminal 4, for example, control is completed in 0.1 seconds, and the user does not feel uncomfortable.

(Embodiment 2)
Next, a second embodiment of the present invention will be described. In the following description, components that are the same as those in the first embodiment are given the same reference numerals, and the description thereof will be omitted.

Figure 7 is a diagram showing the overall configuration of an equipment system 1A according to embodiment 2 of the present invention. The equipment system 1A includes a private wireless base station 2, a plurality of equipment devices 3, a mobile terminal 4A, an equipment controller 5, an environmental sensor 6, a biosensor 7, a wide-area wireless base station 8, and a management server 9.

The wide-area wireless base station 8 is a wireless base station installed by a telecommunications business operator known as a carrier, and enables wide-area wireless communication that covers the area of the privately-operated wireless network. For example, the wide-area wireless base station 8 enables wireless communication according to specifications such as 3G (third generation mobile communication system), LTE (Long Term Evolution), 4G (fourth generation mobile communication system), and 5G. Hereinafter, a wireless network constructed based on the wide-area wireless base station 8 is referred to as a wide-area wireless network.

The management server 9 is an example of a management server according to the present invention. The management server 9 is a server computer installed and operated by a manufacturer, a sales company, an affiliated company, etc. of the equipment 3, and is connected to the wide area wireless network. As shown in FIG. 8, the management server 9 comprises a communication interface 90, a CPU 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 communication interface 90 is hardware for wireless communication with other devices via the wide area wireless network. The CPU 91 controls the management server 9 in an integrated manner. The ROM 92 stores multiple pieces of firmware and data used when these pieces of firmware are executed. The RAM 93 is used as a working area for the CPU 91.

The secondary storage device 94 is composed of a readable/writable non-volatile semiconductor memory such as an EEPROM or a flash memory, a HDD, etc. The secondary storage device 94 stores various programs, including a program for managing the location of each piece of equipment 3, and data used when these programs are executed.

The mobile terminal 4A is an example of a mobile terminal according to the present invention. Like the mobile terminal 4 of the first embodiment, the mobile terminal 4A is an electronic device carried by a user, such as a smartphone or a tablet terminal. As shown in FIG. 9, the mobile terminal 4A includes a user interface 40, a first communication interface 41, a second communication interface 42, a CPU 43, a ROM 44, a RAM 45, a secondary storage device 46, a third communication interface 48, and a GPS signal receiving circuit 49. These components are connected to each other via a bus 47.

The third communication interface 48 is hardware for wireless communication with other devices via the wide area wireless network. The GPS signal receiving circuit 49 is a circuit that receives GPS signals from GPS (Global Positioning System) satellites, calculates latitude and longitude based on the received GPS signals, and outputs them to the CPU 43.

Next, the functions of the mobile terminal 4A will be described in detail. FIG. 10 is a block diagram showing the functional configuration of the mobile terminal 4A. As shown in FIG. 10, the mobile terminal 4A includes an operation reception unit 400, an operation information transmission unit 401, an environmental information acquisition unit 402, an environmental information transmission unit 403, a biometric information acquisition unit 404, a biometric information transmission unit 405, a communication switching unit 406, an identification information acquisition unit 407, a position information acquisition unit 408, and a location information transmission unit 409. These functional units of the mobile terminal 4A are realized by the CPU 43 of the mobile terminal 4A executing an operation app, which is an application program for operating each facility device 3 and is stored in the secondary storage device 46.

The communication switching unit 406 is an example of a communication switching means according to the present invention. The communication switching unit 406 selectively switches between communication via a wide area wireless network (i.e., communication via the third communication interface 48) and communication via a private wireless network (i.e., communication via the first communication interface 41). In detail, when the mobile terminal 4A moves from outside the private wireless network area to within the private wireless network area, the communication switching unit 406 switches from communication via the wide area wireless network to communication via the private wireless network. Also, when the mobile terminal 4A moves from within the private wireless network area to outside the private wireless network area, the communication switching unit 406 switches from communication via the private wireless network to communication via the wide area wireless network.

The identification information acquisition unit 407 is an example of an identification information acquisition means according to the present invention. The identification information acquisition unit 407 acquires the identification information of each equipment device 3 from that equipment device 3. In detail, when the elapsed time since communication via the wide area wireless network is switched to communication via the private wireless network exceeds a predetermined time, the identification information acquisition unit 407 acquires the identification information of each equipment device 3 from that equipment device 3 by communicating with each equipment device 3 via the private wireless network. The identification information of the equipment device 3 includes, for example, the model name, type name, serial number, etc.

The location information acquisition unit 408 is an example of a location information acquisition means according to the present invention. When the identification information of each piece of equipment 3 is acquired by the identification information acquisition unit 407, the location information acquisition unit 408 acquires the latitude and longitude output by the GPS signal receiving circuit 49 as the location information of each piece of equipment 3.

The location information transmission unit 409 is an example of a location information transmission means according to the present invention. When the communication switching unit 406 switches from communication via the private wireless network to communication via the wide area wireless network, the location information transmission unit 409 transmits location information, which contains the identification information of each equipment device acquired by the identification information acquisition unit 407 and the location information acquired by the location information acquisition unit 408, to the management server 9 via the wide area wireless network.

When the management server 9 receives the location information transmitted from the mobile terminal 4A via the wide area wireless network, it stores the received location information in a device management DB (not shown) stored in the secondary storage device 94. The device management DB is a database for managing the location of the sold equipment 3. In the device management DB, device management data that associates identification information with location information for each equipment 3 is registered for each piece of equipment 3 that has been sold.

Such equipment management data can be used, for example, in businesses that provide customers with services related to the traceability of facility equipment 3. Services related to traceability include, for example, notifications of recall information, suggestions for replacing the main unit or parts, notifications of new product information, etc.

As described above, the facility equipment system 1A of the second embodiment provides the same effects as the facility equipment system 1 of the first embodiment, and further makes it possible to manage the location of the facility equipment 3.

In addition, if the equipment controller 5 holds identification information for each equipment device 3, the mobile terminal 4A may obtain the identification information for each equipment device 3 from the equipment controller 5.

(Embodiment 3)
Next, a third embodiment of the present invention will be described. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted.

Figure 11 is a diagram showing the overall configuration of an equipment system 1B according to embodiment 3 of the present invention. The equipment system 1B includes a private wireless base station 2A, multiple equipment devices 3, a mobile terminal 4B, an equipment controller 5A, an environmental sensor 6, a biosensor 7, and multiple repeaters 10.

The private wireless base station 2A is an example of a private wireless base station according to the present invention. Like the private wireless base station 2 of the first embodiment, the private wireless base station 2A is a wireless base station intended for use in a private wireless network area within a building in which the equipment 3 is installed or within a site including the building, and is intended to enable wireless communication under 5G specifications within the private wireless network area.

Furthermore, the private wireless base station 2A is equipped with a gateway device (not shown) that connects the private wireless network and the short-range wireless network. The gateway device is an example of the gateway means according to the present invention.

The mobile terminal 4B is an example of a mobile terminal according to the present invention. Like the mobile terminal 4 of the first embodiment, the mobile terminal 4B is an electronic device carried by a user, such as a smartphone or a tablet terminal. As shown in FIG. 12, the hardware configuration of the mobile terminal 4B differs from that of the mobile terminal 4 (see FIG. 2) only in that the mobile terminal 4B does not include the first communication interface 41. The functional configuration of the mobile terminal 4B will be described later.

The facility equipment controller 5A is an example of a facility equipment controller according to the present invention. The facility equipment controller 5A is communicatively connected to each facility equipment 3 via a private wireless network, and communicatively connected to a mobile terminal 4B, an environmental sensor 6, and a biological sensor 7 via the private wireless network and a short-range wireless network. The facility equipment controller 5A controls each facility equipment 3 based on information received from each of the mobile terminal 4B, the environmental sensor 6, and the biological sensor 7. The hardware configuration of the facility equipment controller 5A is the same as that of the facility equipment controller 5 of embodiment 1 (see FIG. 3). The functional configuration of the facility equipment controller 5A will be described later.

Repeater 10 is an example of a repeater according to the present invention. Repeaters 10 are arranged so as to be scattered at multiple locations in a private wireless network area. Each repeater 10 expands the short-range wireless network by relaying wireless communications that comply with the same short-range wireless standard as in embodiment 1.

Next, the functions of the mobile terminal 4B and the facility equipment controller 5A will be described in detail. FIG. 13 is a block diagram showing the functional configuration of the mobile terminal 4B and the facility equipment controller 5A. As shown in FIG. 13, the mobile terminal 4B includes an operation reception unit 400 and an operation information transmission unit 401A. These functional units of the mobile terminal 4B are realized by the CPU 43 of the mobile terminal 4B executing an operation app, which is an application program for operating each facility equipment 3 and is stored in the secondary storage device 46.

The facility equipment controller 5A also includes an operation information receiving unit 500, an environmental information receiving unit 501A, a biological information receiving unit 502A, and an equipment control unit 503. These functional units of the facility equipment controller 5A are realized by the CPU 51 of the facility equipment controller 5A executing an equipment control program for controlling each facility equipment 3, which is stored in the secondary storage device 54.

In the mobile terminal 4B, the operation reception unit 400 receives operations related to the facility equipment 3 from the user. The operation information transmission unit 401A transmits operation information indicating the operations received from the user to the facility equipment controller 5A via the short-range wireless network.

In the facility equipment controller 5A, the operation information receiving unit 500 receives the operation information transmitted from the mobile terminal 4B via the private wireless network. The environmental information receiving unit 501A is an example of environmental information receiving means according to the present invention, and receives environmental information transmitted from the environmental sensor 6 to the facility equipment controller 5A via the short-range wireless network via the private wireless network. The biometric information receiving unit 502A is an example of biometric information receiving means according to the present invention, and receives biometric information transmitted from the biometric sensor 7 to the facility equipment controller 5A via the short-range wireless network via the private wireless network.

The equipment control unit 503 generates control commands for controlling the specified equipment devices 3 individually based on the operation information, and transmits each generated control command to each specified equipment device 3 via the private wireless network. The equipment control unit 503 also generates control commands for controlling all equipment devices 3 individually based on the environmental information, and transmits each generated control command to each equipment device 3 via the private wireless network. The equipment control unit 503 also generates control commands for controlling all equipment devices 3 individually based on the biometric information, and transmits each generated control command to each equipment device 3 via the private wireless network.

As described above, according to the facility equipment system 1B of the third embodiment, the private wireless base station 2A establishes a private wireless network that is a local 5G network, and connects the private wireless network to a short-range wireless network. The facility equipment controller 5A communicates directly with each facility equipment 3 via the private wireless network, and indirectly with wireless terminals such as the mobile terminal 4B, the environmental sensor 6, and the biosensor 7 via the private wireless network. The facility equipment controller 5A then controls the facility equipment 3 based on information received from each wireless terminal.

In this way, information from the wireless terminal can be utilized, enabling control of highly functional facility equipment 3. Furthermore, the facility equipment controller 5A does not need to be equipped with a separate communication interface for communicating with the wireless terminal, and complicated processes such as timing adjustment between networks and control arbitration are not required, which helps reduce development costs.

Furthermore, since the mobile terminal 4B does not require a communication interface for communicating via a private wireless network, i.e., a communication interface compatible with 5G, it is possible to employ a low-spec electronic device as the mobile terminal 4B.

(Embodiment 4)
Next, a fourth embodiment of the present invention will be described. In the following description, the same components as those in the first to third embodiments are denoted by the same reference numerals, and the description thereof will be omitted.

Figure 14 is a diagram showing the overall configuration of an equipment system 1C according to embodiment 4 of the present invention. The equipment system 1C includes a private wireless base station 2A, multiple equipment devices 3, a mobile terminal 4C, an equipment controller 5A, an environmental sensor 6, a biosensor 7, a wide-area wireless base station 8, a management server 9, and multiple repeaters 10.

The mobile terminal 4C is an example of a mobile terminal according to the present invention. Like the mobile terminals 4, 4A, and 4B of the first to third embodiments, the mobile terminal 4C is an electronic device carried by a user, such as a smartphone or a tablet terminal. As shown in FIG. 15, the hardware configuration of the mobile terminal 4C differs from that of the mobile terminal 4A (see FIG. 9) only in that the mobile terminal 4C does not include the first communication interface 41.

Fig. 16 is a block diagram showing the functional configuration of the mobile terminal 4C. As shown in Fig. 16, the mobile terminal 4C includes an operation reception unit 400, an operation information transmission unit 401A, an identification information acquisition unit 407A, a position information acquisition unit 408, and a location information transmission unit 409A. These functional units of the mobile terminal 4C are realized by the CPU 43 of the mobile terminal 4C executing an operation app, which is an application program for operating each equipment device 3 and is stored in the secondary storage device 46.

The identification information acquisition unit 407A is an example of an identification information acquisition means according to the present invention. The identification information acquisition unit 407A acquires the identification information of each equipment device 3 from that equipment device 3. In detail, when the time that has elapsed since short-range wireless communication became possible exceeds a predetermined time, the identification information acquisition unit 407A acquires the identification information of each equipment device 3 from that equipment device 3 by communicating with each equipment device 3 via the short-range wireless network and the private wireless network. The identification information of the equipment device 3 includes, for example, the model name, type name, serial number, etc.

When the identification information of each piece of equipment 3 is acquired by the identification information acquisition unit 407A, the location information acquisition unit 408 acquires the latitude and longitude output by the GPS signal receiving circuit 49 as the location information of each piece of equipment 3.

The location information transmission unit 409A is an example of a location information transmission means according to the present invention. The location information transmission unit 409A transmits location information, which contains the identification information of each facility device acquired by the identification information acquisition unit 407A and the location information acquired by the location information acquisition unit 408, to the management server 9 via a wide area wireless network.

As described above, the facility equipment system 1C of the fourth embodiment has the same effect as the facility equipment system 1B of the third embodiment, and further makes it possible to manage the location of the facility equipment 3.

In addition, if the equipment controller 5A holds identification information for each equipment device 3, the mobile terminal 4C may obtain the identification information for each equipment device 3 from the equipment controller 5A.

The present invention is not limited to the above-described embodiments, and various modifications are possible without departing from the spirit of the present invention.

For example, the private wireless base station according to the present invention is not limited to a wireless base station for wireless communication according to 5G specifications, but may be a wireless base station that ensures at least low latency performance in 5G.

In addition, in the facility equipment systems 1, 1A, 1B, and 1C, multiple environmental sensors 6 may be installed in a scattered manner within a building in which multiple facility equipment 3 is installed. In this case, the facility equipment controllers 5 and 5A may control each facility equipment 3 based on environmental information from the environmental sensor 6 installed closest to the facility equipment 3.

The equipment controller 5, 5A may also control one or more equipment devices 3 that are installed within a predetermined range (e.g., within 10 m) of a user wearing a biosensor 7 and are located within the private wireless network area, based on biometric information from the biosensor 7.

The technical concept of the present invention can also be applied to a home appliance control system that controls home appliances installed in a home. For example, a home appliance control system can be envisioned in which a home controller, lighting equipment, and a mobile terminal carried by a user are connected to a 5G private wireless network, image information relating to surrounding images captured by the mobile terminal is transmitted to the home controller, and the home controller controls the lighting equipment based on the image information received from the mobile terminal.

In detail, the home controller analyzes the image information received from the mobile terminal, and switches the lighting devices on and off and adjusts the illuminance based on the presence and number of people in the home. In this home appliance control system, the mobile terminal may be indirectly connected to a private wireless network via a short-range wireless network, and image information from the mobile terminal may be transmitted to the home controller via the short-range wireless network and the private wireless network.

In addition, for example, a home appliance control system can be envisioned in which a home controller, an induction heating (IH) cooker, and a camera installed in the kitchen are connected to a private 5G wireless network, image information relating to images of the kitchen taken by the camera is transmitted to the home controller, and the home controller controls the IH cooker based on the image information received from the camera.

In detail, the home controller analyzes the image information received from the camera and estimates the age of people in the kitchen. If a person of a specific age group, such as a small child or elderly person, is in the kitchen, the home controller performs safety control such as locking the operation of the induction cooker. Furthermore, if a person of that specific age group is in the kitchen, the home controller may output electronic sounds or voices to alert the person from an alarm device, AI speaker, etc. In this home appliance control system, the camera may be indirectly connected to a private wireless network via a short-range wireless network, and image information from the camera may be transmitted to the home controller via the short-range wireless network and the private wireless network.

In addition, all or part of the functional units of the mobile terminals 4, 4A, 4B, and 4C and all or part of the functional units of the facility equipment controllers 5 and 5A may be realized by dedicated hardware. The dedicated hardware may be, 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 of these.

In addition, the operation application and device control program in each of the above embodiments can also be stored and distributed on a computer-readable recording medium such as a CD-ROM (Compact Disc Read Only Memory), a DVD (Digital Versatile Disc), a Magneto-Optical Disc, a USB (Universal Serial Bus) memory, a memory card, or a HDD.

In addition, each operation app may be stored in a storage device owned by a server (not shown) on the Internet, and the corresponding operation app may be downloaded from the server to the mobile terminals 4, 4A, 4B, and 4C. Similarly, each device control program may be stored in a storage device owned by a server (not shown) on the Internet, and the corresponding device control program may be downloaded from the server to the facility device controllers 5 and 5A.

1, 1A, 1B, 1C Equipment equipment system, 2, 2A Private wireless base station, 3 Equipment equipment, 4, 4A, 4B, 4C Mobile terminal, 5, 5A Equipment equipment controller, 6 Environmental sensor, 7 Biometric sensor, 8 Wide area wireless base station, 9 Management server, 10 Repeater, 40 User interface, 41 First communication interface, 42 Second communication interface, 43, 51, 91 CPU, 44, 52, 92 ROM, 45, 53, 93 RAM, 46, 54, 94 Secondary storage device, 47, 55, 95 Bus, 48 Third communication interface, 49 GPS signal receiving circuit, 50, 90 Communication interface, 400 Operation reception unit, 401, 401A Operation information transmission unit, 402 Environmental information acquisition unit, 403 Environmental information transmission unit, 404 Biometric information acquisition unit, 405 Biometric information transmission unit, 406 Communication switching unit, 407, 407A Identification information acquisition unit, 408 Position information acquisition unit, 409, 409A Location information transmission unit, 500 Operation information reception unit, 501, 501A Environmental information reception unit, 502, 502A Biometric information reception unit, 503 Device control unit

Claims (4)

A privately-operated wireless base station that ensures low latency performance in at least a fifth generation mobile communication system;
Equipment and
A portable terminal carried by a user;
An equipment controller;
an environmental sensor for detecting an environmental condition related to an environment in which the facility equipment is installed;
The mobile terminal includes:
an operation receiving means for receiving an operation related to the facility device from the user;
an environmental information acquiring means for acquiring environmental information indicating the detected environmental state from the environmental sensor by communicating with the environmental sensor via a short-range wireless network conforming to a short-range wireless standard;
an operation information transmitting means for transmitting operation information indicating the received operation to the facility equipment controller via a private wireless network established based on the private wireless base station;
an environmental information transmission means for transmitting the acquired environmental information to the facility equipment controller via the private wireless network,
The facility equipment controller includes:
an operation information receiving means for receiving the operation information transmitted from the mobile terminal via the private wireless network;
an environmental information receiving means for receiving the environmental information transmitted from the mobile terminal via the private wireless network;
An equipment control means for controlling the equipment based on the received operation information and the received environmental information ,
The system further includes a management server for managing the location of the facility equipment,
The mobile terminal includes:
a communication switching means for switching from communication via a wide area wireless network provided by a telecommunications carrier to communication via the private wireless network when the mobile station moves from outside an area of the private wireless network to within the area of the private wireless network, and for switching from communication via the private wireless network to communication via the wide area wireless network when the mobile station moves from within the area of the private wireless network to outside the area of the private wireless network;
an identification information acquiring means for acquiring identification information of the facility equipment from the facility equipment by communicating with the facility equipment via the private wireless network when a time elapsed since communication via the wide area wireless network is switched to communication via the private wireless network exceeds a predetermined time;
a location information acquisition means for receiving a GPS signal and acquiring location information when the identification information of the facility equipment is acquired by the identification information acquisition means;
a location information transmitting means for transmitting, when communication is switched from communication via the private wireless network to communication via the wide area wireless network, location information in which the acquired identification information and the acquired position information are stored to the management server via the wide area wireless network . A biosensor is attached to the user and detects biometric data of the user.
The mobile terminal includes:
a biometric information acquiring means for acquiring biometric information indicating the detected biometric data from the biometric sensor by communicating with the biometric sensor via the short-range wireless network;
a biometric information transmission means for transmitting the acquired biometric information to the facility equipment controller via the private wireless network,
The facility equipment controller further includes a biological information receiving means for receiving the biological information transmitted from the mobile terminal via the private wireless network,
The facility equipment system according to claim 1 , wherein the equipment control means of the facility equipment controller controls the facility equipment based on the received operation information, the received environmental information, and the received biological information. A mobile terminal carried by a user,
Accepting an operation related to the facility device from the user;
communicate with an environmental sensor that detects an environmental state related to the environment in which the facility device is installed via a short-range wireless network that complies with a short-range wireless standard, and acquire environmental information indicating the detected environmental state from the environmental sensor;
Transmitting operation information indicating the accepted operation to an equipment controller via a private wireless network constructed based on a private wireless base station that ensures low latency performance in at least a fifth generation mobile communication system;
Transmitting the acquired environmental information to the facility equipment controller via the private wireless network;
The facility equipment controller,
receiving the operation information and the environmental information transmitted from the mobile terminal via the private wireless network;
An equipment control method for controlling the equipment based on the received operation information and the received environmental information,
The mobile terminal,
when moving from outside the area of the privately-operated wireless network to within the area of the privately-operated wireless network, switching from communication via a wide-area wireless network provided by a telecommunications carrier to communication via the privately-operated wireless network, and when moving from within the area of the privately-operated wireless network to outside the area of the privately-operated wireless network, switching from communication via the privately-operated wireless network to communication via the wide-area wireless network;
When a time that has elapsed since communication via the wide area wireless network was switched to communication via the private wireless network exceeds a predetermined time, acquiring identification information of the facility equipment from the facility equipment by communicating with the facility equipment via the private wireless network,
When the identification information of the facility equipment is acquired, a GPS signal is received to acquire location information,
when communication is switched from communication via the private wireless network to communication via the wide area wireless network, location information storing the acquired identification information and the acquired position information is transmitted via the wide area wireless network to a management server that manages the location of the facility equipment . The mobile terminal,
a biosensor attached to the user and configured to detect biosensor data of the user, and communicates with the biosensor via the short-range wireless network to obtain biosensor information indicating the detected biosensor data;
Transmitting the acquired biological information to the facility equipment controller via the private wireless network;
The facility equipment controller,
receiving the biometric information transmitted from the mobile terminal via the private wireless network;
The facility equipment control method according to claim 3 , further comprising controlling the facility equipment based on the received operation information, the received environmental information, and the received biological information.

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