JPH03212097A - Building management system - Google Patents

Abstract

PURPOSE:To apply monitor control to an installation equipment in a room and to monitor the state of the inside of the room even in each room by using an infrared-ray remote controller and plural controllers arranged in the room and sending and receiving various data via an infrared-ray transmitter-receiver arranged on a ceiling in the room. CONSTITUTION:A central management unit 1 and plural controllers 5-8 send and receive various data and a central management unit 1 manages centralizingly the installation equipments connected to the controllers 5-8. An infrared-ray remote controller 14 and plural controllers 5-8 arranged in the room send and receive various data via an infrared-ray transmitter-receive 12 arranged on a ceiling in the room. Thus, it is possible to apply monitor control to the installation equipments even in each room and monitors the state in the inside of the room.

Description

[Detailed Description of the Invention] <Industrial Application Field> This invention is applicable to a building that controls and monitors equipment such as lighting fixtures and air conditioners placed in a building, as well as monitors the indoor conditions of each room in the building. Regarding management systems.

<Conventional technology> In conventional building management systems, a central control unit placed in a control room in a building serves as a master station, and multiple controllers placed in each room in the building act as slave stations. There is a system that controls and monitors a plurality of equipment connected to each controller and monitors indoor conditions by transmitting and receiving various data between the device and each controller.

FIG. 4 is a diagram showing the indoor arrangement of a conventional building management system, in which a central management device (40) is connected to a plurality of controllers (
42> to (44) are connected, and each controller (42) to (44) is connected to a lighting device (43),
A plurality of equipment such as an air conditioner (44) and various sensors (47) related to disaster prevention such as a gas sensor and a smoke sensor are connected. Control switches (48) and (49) provided on the walls of the room are connected to a controller for lighting equipment (42) and a controller for an air conditioner (43) via control lines (50).

In the above building management system, the building manager operates the central pipe W (40) to select equipment in a predetermined room, such as a lighting fixture (45), from among a plurality of equipment. By issuing ON/OFF commands, the controller (4) is transmitted from the central management device (40) via the transmission line (41)
2), an ON/OFF command signal is supplied to the lighting fixture (45), and the controller (42) can control ON/OFF of the lighting fixture (45) according to the command signal. Since the results of the control from the controller (42) are sent back to the central management device (40), the status of the equipment can be monitored.

In addition, the controller (44) to which the various sensors (47) related to disaster prevention such as the gas sensor and smoke sensor are connected, or the central management device (40) transmits data created based on the detection signals from each sensor in a predetermined format. The central management device (40) can monitor the status of each room.

Furthermore, a control switch (48
), the controller (42) in response to the operation of (49).

(43) turned on the lighting equipment (45) and air conditioner (46),
Even in the case of OFF control, the controller (42),
(43) transmits the control results to the central management device (40).

According to the above building management system, the building manager can monitor and control the equipment in the building while staying in the management room, so there is no need to go to the installation location of the equipment and open/close switches, etc. Furthermore, since the indoor conditions can be constantly monitored based on the detection signals from the various sensors (47), it is possible to quickly take action in the event of a gas leak, fire, etc. occurring in each room.

<Problem to be solved by the invention> However, there is a case where a person wants to adopt equipment compatible with the above building management system not only in the management room but also in each tenant, and to monitor and control the equipment installed in each tenant individually. I have a request. Furthermore, in tenants having multiple rooms, there is a demand for monitoring the state of each room based on detection signals from various sensors (47). In order to meet this request, tenants should also be provided with a remote control device similar to the central management device (40), and the remote control device and controller (42)
) to (44) must be connected by a transmission line (41).

However, the installation positions of the controllers (42) to (44) are placed on the ceiling or the floor of the room, and it is difficult to connect the plurality of controllers (42) to (44) and the remote control device installed in each tenant. To make the connection, it is necessary to run wiring under the floor or from under the floor along the inside of the wall to the ceiling, which poses the problem of requiring a great deal of labor.

This invention was made in view of the above-mentioned problems, and allows each tenant to individually control and monitor equipment in the tenant and monitor the status of each room, as well as to control and monitor equipment between multiple remote control devices and controllers in the building. The purpose is to provide a building management system that eliminates the need for wiring.

Means for Solving the Problems> A building management system of the present invention to achieve the above object connects a plurality of controllers to a central management device located in a management room via a transmission path, and connects the central management device and the central management device. In a building management system that sends and receives various data to and from multiple controllers and centrally manages equipment connected to the controllers using a central management device, an infrared remote control device is placed in each room, and the above-mentioned remote control device is installed on the ceiling of each room. An infrared transmitting/receiving device inserted into the transmission path is arranged, and various sensors for detecting indoor conditions are connected to the infrared transmitting/receiving device, and various data are transmitted between the infrared remote control device and the controller via the infrared transmitting/receiving device. It is characterized by transmitting and receiving signals to manage the equipment placed in each room, and also transmits detection signals from various sensors from the infrared transmitting/receiving device to the central management device.

<Function> With the building management system with the above configuration, various data are sent and received between the central management device and multiple controllers, and when equipment connected to the controller is centrally managed by the central management device, it is possible to Various types of data (data for controlling equipment, data as a result of control, data detected by various sensors) are sent via an infrared remote control device and multiple controllers placed in the room, and an infrared transmitting/receiving device placed on the ceiling of the room. etc.), it is possible to monitor and control indoor equipment and monitor the indoor status in each room. In addition, since the infrared remote control device and the infrared transmitting/receiving device transmit and receive various data using infrared rays as a medium, it is possible to control equipment without operating the control switch installed on the wall. There is no need to wire between the controller and the controller.

<Example> Hereinafter, embodiments will be described in detail with reference to the accompanying drawings showing examples.

FIG. 1 is a schematic block diagram showing one embodiment of the building management system of the present invention, in which a central management device (1) is connected to a main controller (3 ) is connected to the main controller (3) via the second transmission line (4) to various controllers (5) to (8).
is connected. The controllers (5) to (8) include lighting equipment (9), air conditioner 00), blinds (11
), and an infrared transmitting/receiving device (12) attached to the ceiling of the room. Various sensors (13) are connected to the infrared transmitting/receiving device (12), including indoor environment sensors such as temperature sensors and humidity sensors, disaster prevention sensors such as gas sensors and smoke sensors, and crime prevention sensors such as human body sensors. There is. Then, an infrared transmitting/receiving device (12) and various data (
An infrared remote control device (14) for transmitting and receiving data (data for controlling equipment, data resulting from control, data detected by various sensors (13), etc.) is placed in each room.

FIG. 2 is a diagram showing the indoor layout of the building management system shown in FIG.
), an infrared transmitting/receiving device (12) is attached at every fixed span, and the above-mentioned various sensors (13) are connected to the infrared transmitting/receiving device (12). The infrared transmitting/receiving device (12) is connected to a second transmission path (4) via an infrared transmitting/receiving device controller (3).
), the above-mentioned infrared transmitter/receiver controller (8), a lighting fixture controller (51) installed in the ceiling, an air conditioner controller (6), a blind controller (7), and a main controller (3) are connected to form a network. Each of the controllers (5) to (7) has a lighting fixture (9) and an air conditioner 00 installed in each room.
), blind (11〉) is connected.

On each desk (16) in the tenant are the W (12) made by the infrared transmitting/receiving unit, the lighting equipment (9) installed in each room of the tenant using infrared modulated light as a medium, and the air conditioner 001.
, an infrared remote control device (14) for transmitting control data for remote control of the blind (11) is installed, and an infrared remote control device (14') having both transmission and reception functions is connected to a personal computer (17). It is placed in a closed condition. The infrared remote control device (14') connected to the personal computer (17) is also an intelligent interface, and transmits infrared modulated light modulated based on control data input from the personal computer (17) to the infrared transmitting/receiving device (12). At the same time, control result data and data detected by various sensors (13) are restored from the infrared modulated light emitted from the infrared transmitting/receiving device (12) and supplied to the personal computer (17).

As mentioned above, the reason why the infrared transmitting/receiving device (12) is arranged on the ceiling of each room at every predetermined span is because the layout design of the tenant at the time of construction of the building was for each span (-span is approximately 3.5 mm).
3m x 3.3m), and also focused on the fact that tenant layout changes after a building is constructed are based on a combination of multiple spans, and is intended to facilitate layout changes at the design stage or after the design. .

FIG. 3 is a block diagram of the infrared remote control device and the infrared transmitting/receiving device (12).
4) (14') is a first memory (18) that encodes and stores equipment names, control details, etc., and a second memory (18) that stores network protocols.
19), a third memory (20) for storing the protocol of the personal computer (17), a liquid crystal panel (21) for displaying the name of equipment and its code, control details and its code, and an operator. A key panel (22) for specifying equipment, equipment, and control details, and a computer (17).
), or in response to key operations, the controller (
5) - (8) In addition to generating control data in which addresses, control contents, error correction codes, etc. are formatted based on network protocols, control result data from the infrared transmitting/receiving device (12) and various sensors are generated. A CPU (23) that formats the data detected by (13) based on the protocol of the personal computer (17), an infrared oscillation element (24) that outputs infrared light modulated with control data, and an infrared transmitting/receiving device. It has an infrared sensor (25) that photoelectrically converts infrared modulated light emitted from (12), and a personal computer connection interface (2B).

The error correction code is used to prevent the infrared transmitting/receiving device (12) from erroneously reading data due to being affected by light from the lighting equipment (9) or the sun.

The infrared remote control device (14) that is not connected to the computer (17) uses infrared rays emitted from the third memory (20) that stores the protocol of the computer (17) and the infrared transmitting/receiving device (12). Is it possible to remove the infrared sensor (22) that photoelectrically converts modulated light and make it only for reception? Considering compatibility, changes in tenant layout, etc., all infrared remote control devices should have the same configuration. It is preferable that the third memory (20) stores a protocol depending on the type of the personal computer (17) to be connected. In addition, a first memory (18), a key panel (22), a CPU (23), an infrared oscillation element (2
4) It is possible to make it into a handy type by making it compact.

The computer (II) has an infrared remote control device (14')
It displays the control status of equipment in each room in the tenant and the environment of each room based on data from 11), programs to adjust the drive of the air conditioner 00), and programs to turn off the lighting equipment (9), lower the blinds (II), stop the operation of the air conditioner 00), etc. after the workday is over. Remote control device (
14), which stores complex control programs that cannot be done with 14).

The infrared transmitting/receiving device (12) includes a data receiving section (27),
It has a data converter (28), a data transmitter (29), an interface (3a), and a control result display panel (31).

The data reception N (27) is an infrared remote control device (
The infrared modulated light emitted from the controller 14) is received and used as an error correction code to accurately restore control data consisting of addresses, control details, etc. of the controllers (5) to q). The data converter (28) formats the data input from the data receiver (27) and the detection data input from the various sensors (13) and outputs the formatted data to the interface (30).
0) is formatted and output to the data transmitter (29). The data transmitter (29) irradiates the infrared remote control devices (14) and (14') with infrared modulated light that is modulated based on the formatted control result data and detection data. The control result display panel (31) displays control results based on control result data. As the display panel (31), for example, a plurality of light emitting diodes are lined up,
It is used to display the control result (adjusted temperature) of the air conditioner (GO) or to display ON-OFF of the lighting equipment (9) at the light emitting position. Furthermore, as the data converter (28), it is possible to use a device that outputs the data restored by the data receiver (27) or the response signal input via the interface (30) as is to the interface (30). It is.

The operation of the building management system having the above configuration is as follows.

A person in the tenant or multiple infrared remote control devices (1
In step 4), operate the key panel (22) of one of the infrared remote control devices (14) to specify equipment, control details, etc. The CPU of the infrared remote control device (14) (
23) reads the addresses and control contents of the controllers (5) to (7) from the first memory (18) in response to the above specifications, and generates control data in which these are formatted based on the network protocol. The infrared transmitter/receiver (
12).

Next, the data receiving section (2) of the infrared transmitting/receiving device (12)
7) photoelectrically converts the infrared modulated light emitted from the infrared remote control device (14), restores the control data based on the error correction code, and converts the format of this by the data converter (28), or It is output as is to the infrared transmitter/receiver controller (8).

An infrared transmitting/receiving device controller (8) organizes control data with duplicate contents sent from a plurality of infrared transmitting/receiving devices (12) and sends it to a second transmission path (4).

The control data is then sequentially supplied to the controllers (5) to (7) through the second transmission path (4). If the controller (5) to σ) includes its own address in the control data, it controls the equipment connected to itself based on the control content, and includes the control result with the other party (the control data The control result data with the address of the infrared transmitting/receiving device controller that sent the data is sent to the second transmission path (4).

The control result data sent to the second transmission path (4) is transmitted to the main controller (3) and the infrared transmitter/receiver controller (
8), and the control result data supplied to the main controller (3) is supplied to the central management device (1) via the first transmission path (2). Further, the control result data supplied to the infrared transmitting/receiving device controller (8) is taken into the infrared transmitting/receiving device (12) that has received the infrared modulated light for remote control.

The infrared transmitting/receiving device 1 (12) displays the control results on the control result display panel (31). This control result display panel (31) can notify the operator that a predetermined equipment has been controlled.

In addition, when the work start time or work end time arrives, the computer (17) can be used to turn on the lighting equipment (9), roll up the blinds (11), adjust the temperature of the air conditioner (00), etc. at the scheduled time. The necessary control data is manually input.

According to this control data, the infrared remote control device (14')
The infrared modulated light is formatted based on a network protocol and further modulated with the formatted signal, and is irradiated to the infrared transmitting/receiving device (12).

The infrared transmitter/receiver (12) formats the received control data and sends them to the second transmission path (4) via the infrared transmitter/receiver controller (8).

Based on the supplied control data, the controllers (5) to (7) turn on the lighting fixture (9) and turn on the blind (1).
1), and controls the temperature adjustment of the air conditioner 00), and transmits control result data to the infrared transmitting/receiving device (12) that transmitted the control data.

The data converter (28) of the infrared transmitter/receiver (12) formats the transmitted control result data and outputs it to the data transmitter (29). The data transmitter (29) irradiates the infrared remote control device (14') with infrared rays modulated based on the formatted control result data.

The infrared remote control device (14') is an infrared transmitting/receiving device (
Control results are extracted from the infrared modulated light emitted from the computer (12), formatted based on the protocol of the personal computer (17), and output to the personal computer (17).

The personal computer (17) checks based on the control result data whether or not the control corresponding to the control data transmitted by itself has been performed, and if the control corresponding to the control data has been performed,
Stop remote control. Furthermore, if control corresponding to the control data is not being performed, the control data is sent again.

Although the equipment is remotely controlled and monitored as described above,
Gas detection signals, smoke detection signals, and human body detection signals after the scheduled time are transmitted from various sensors (13) to an infrared transmitting/receiving device (12).
If the infrared transmitter/receiver (12) formats the detection signal and supplies it to the data transmitter (29) of the infrared transmitter/receiver (12) and the infrared transmitter/receiver controller (8).

The detection data supplied to the infrared transmitting/receiving device controller (controller) is transmitted in the order of second transmission path (4) - raw controller (3) -> first transmission path (1) - central management device (1). It is also transmitted from the transmitting/receiving device controller (L2) to another infrared transmitting/receiving device (L2).

Then, the infrared rays modulated by the detection data from all the infrared transmitting/receiving devices 12) are transmitted to the infrared remote control device (14) (
14'). The infrared remote control device (14') supplies detection data to the personal computer (17).

The computer (17) generates an alarm sound based on the detection data, and also displays the details of the abnormality in the detected room (gas leak, fire, etc.).
theft, etc.).

The generation of the above-mentioned alarm sound and the display of the details of the detected abnormality in the room are also performed in the central management device (1).

According to this embodiment described above, the infrared remote control device (14
) and the controllers (5) to (7) using infrared rays as a medium to control the equipment, eliminating the need for a switch in the room. Therefore, there is no need for wiring between the switch and the controller.

In addition, the infrared transmitting/receiving devices (12) are arranged on the ceiling of each room at predetermined spans, so if it is necessary to change the layout of the tenant, the infrared receiving devices (12)
) can be freely laid out based on a predetermined span without changing the mounting position.

Furthermore, since the control results are displayed on the control result display panel (31) of the infrared transmitting/receiving device (12), it is possible to know the status of the air conditioner 00) etc. that are located in a position that is not visible to the person operating the remote control.

In addition, by using the infrared remote control device (14') to mutually convert the network protocol and the protocol of the personal computer (17), there is no need to create a special remote control device that follows the network protocol. Since a general-purpose computer can be used, costs can be reduced.

Note that the present invention is not limited to the above-mentioned embodiments. For example, in addition to the above-mentioned lighting equipment (9), air conditioner 00), and blinds (11), an electronic lock may be installed in the central management unit (1).
) and a personal computer (17), and all infrared transmitting/receiving devices (12) are equipped with sound generators, so that when gas, smoke, or human body detection signals are input from the sensor, It is possible to notify that fact, and various other design changes can be made within the scope of not changing the gist of the invention.

<Effects of the Invention> According to the present invention described above, an infrared remote control device and a plurality of controllers placed indoors can transmit various data (for controlling equipment) via an infrared transmitting/receiving device placed on the ceiling of the room. data, control result data, data detected by various sensors, etc.), it is possible to monitor and control indoor equipment and monitor the indoor status in each room. In addition, since the infrared remote control device and the infrared transmitting/receiving device send and receive various data using infrared rays as a medium, equipment can be controlled without operating the control switch installed on the wall. This has the effect of eliminating the need for wiring between the two.

[Brief explanation of drawings]

FIG. 1 is a schematic block diagram showing one embodiment of the building management system of the present invention, FIG. 2 is a diagram showing the indoor layout of the building management system shown in FIG. 1, and FIG. 3 is an infrared remote control device, A block diagram of an infrared transmitting/receiving device. FIG. 4 is a diagram showing the indoor layout of a conventional building management system. (1) Central management device, (5) Lighting equipment controller, (6) Air conditioner controller, (7) Blind controller, (8) Infrared transmitter/receiver controller, (12)...Infrared transmitting/receiving device, (13)...Various sensors, (14) (1
4')...Infrared remote control device, (17)...PC

Claims (1)

[Claims] 1. Send information to the central control device located in the control room. Connect multiple controllers via feed path central management unit and multiple controllers Send and receive various data and control centrally manage equipment connected to the controller. Building management system centrally managed at An infrared remote control device is installed in each room. The above transmission is installed on the ceiling of each room. An infrared transmitting and receiving device inserted into the road is placed In addition, the infrared transmitting and receiving device Various sensors are connected to detect the via the infrared transmitting and receiving device mentioned above. with an infrared remote control device and a controller. Send and receive various data with Managing equipment placed indoors In both cases, the infrared transceiver is connected to the central management unit. It is possible to send detection signals from various sensors to A building management system featuring: