JP2010010939A - Remote monitoring control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a remote monitoring control system by which the degree of freedom in an installation position of a sensing means is made high and an environment in a control area can be controlled into a desired state on the basis of the measurement data of the sensing means. <P>SOLUTION: A terminal unit 3 for data input acquires the measurement data of illuminance from a built-in sensing element 33 or an external device 7, and returns the acquired measurement data to a transmission unit 1 according to always-on polling from the transmission unit 1 to an address of a self-unit. A terminal unit 4 for management collects the measurement data to be returned from the terminal unit 3 for data input to the transmission unit 1 to perform unitary management, creates a control instruction of an environment controller 6 based on pieces of installation position information on the sensing element 33 and the environment controller 6 and the collected measurement data, and transmits the created control instruction to the transmission unit 1 as monitoring data. The transmission unit 1 transmits a multiple transmission signal including the control instruction transmitted from the terminal unit 4 for management to a corresponding terminal unit 2 for control to control the environment controller 6. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a remote monitoring control system.

  Conventionally, there has been provided an autonomous distributed control system that controls an environmental control device that controls the surrounding environment based on a sensing result of a sensing unit that measures a physical quantity to be controlled.

  FIG. 7 is a schematic block diagram of a sensor-equipped control unit (hereinafter abbreviated as a control unit) 100 that controls the operation of an environmental control device 110 such as a lighting fixture based on illuminance measurement data in a target area. The control unit 100 includes a sensing element 101 that measures the illuminance of a target area, and a sensor input interface unit (hereinafter referred to as a sensor input I / F unit) 102 to which measurement data of the sensing element 101 is input. And a setting input / output interface unit (hereinafter referred to as a setting input / output I / F unit) 103 to which various setting information (for example, measurement unit) is input from an external setting device (not shown). Control data is output to the storage unit 104 that stores various types of information such as setting information and the environment control device 110. Control output interface unit (hereinafter, the control output I / F section) composed of the 105, an arithmetic unit 106 which performs overall control.

  In the control unit 100, measurement data (illuminance information) of the sensing element 101 included in the unit is input to the calculation unit 106 via the sensor input I / F unit 102, and is independently processed by the calculation unit 106. A dimming control signal (for example, a duty signal) is sent to the environmental control device 110 via the control output I / F unit 105 so that the light output of the environmental control device 110 becomes a desired dimming output based on the illuminance information later. And the light output of the environmental control device 110 was controlled. Instead of outputting the dimming control signal to the environment control device 110, the calculation unit 106 of the control unit 100 compares the measurement data of the sensing element 101 with a predetermined threshold value, and if it is brighter than the threshold value, the environment control device In addition to outputting a control signal for turning off 110, some output a control signal for turning on the environmental control device 110 if it is equal to or less than a threshold value.

In addition, although the above control system is an autonomous decentralized control system, a plurality of slave units equipped with brightness sensors and a plurality of lighting fixtures are connected to the master unit, and the operations of each slave unit are concentrated from the master unit. An illumination control system that has been controlled has also been provided (see, for example, Patent Document 1). In this lighting control system, the master unit collects brightness sensor measurement data from each slave unit, and centrally controls each slave unit based on the measurement data, and each slave unit is under centralized control by the master unit, Based on the measurement data of the brightness sensor provided by the self, the light output of the lighting fixture provided by the self is centrally controlled.
JP 2003-59654 A

  Since the former control system described above is an autonomous distributed control system in which control is completed between the control unit 100 and the environmental control device 110, the same configuration as shown in FIGS. When the two control units 100a and 100b are arranged adjacent to each other, the sensing elements 101a and 10b included in the own device are measured under the influence of the light output of the environmental control device 110 controlled by another control unit. Data could be inaccurate. Here, as shown in FIG. 8A, in the control units 100a and 100b that respectively control the illumination areas B1 and B2, the measurement areas A1 and A2 of the sensing elements 101a and 101b included in the control units 100a and 100b If it is set in the lighting areas B1 and B2 under the jurisdiction of the machine, the measurement data of the sensing elements 101a and 101b is affected by the illuminance in the lighting areas B2 and B1 under the jurisdiction of the other control units 100b and 100a. There is nothing. On the other hand, as shown in FIG. 8B, when the measurement area A1 of the sensing element 101a provided in the control unit 100a that controls the illumination area B1 partially includes the illumination area B2, the measurement of the sensing element 101a is performed. The data is affected by the illuminance of the illumination area B2 controlled by the other control unit 100b, and the illuminance of the illumination area B1 may be too bright or too dark compared to the case where there is no interference. There is a possibility that the illuminance in the illumination area B1 cannot be controlled to a desired illuminance.

  As described above, when a plurality of control units 100 are arranged adjacent to each other, control is performed so that the detection area of the sensing element 101 included in each control unit 100 does not overlap with an illumination area controlled by another control unit 100. It was necessary to strictly manage the installation position of the unit 100 (sensing element 101).

  However, due to structural limitations of the building where the control unit 100 is installed, the measurement area A1 of the sensing element 101a included in the control unit 100a may overlap with the illumination area B2 under the control of the other control unit 100b. For example, as shown in FIG. 9B, the height of the ceiling 120 on which the control unit 100a (sensing element 101a) overseeing the illumination area B1 is installed, and the control unit 100b (sensing element 101b) overseeing the illumination area B2 are installed. When the height of the ceiling 121 is different, as shown in FIG. 9A, the sensing element 101a at the higher position has a wider detection area than the sensing element 101b at the lower position (A1). > A2) Since the control area B2 of the other control unit 100b is included in the measurement area A1 due to restrictions on the installation position of the control unit 100a, the output of the sensing element 101a is affected by the illuminance of the control area B2. Thus, the illuminance in the measurement area A1 cannot be controlled to the desired illuminance. There was a potential.

  In the latter lighting control system described above, a function for dimming the lighting fixture is provided in the slave unit that is centrally controlled by the master unit, and a circuit that outputs a dimming control signal including a duty signal to the lighting fixture, for example. However, there is a problem that heat generation by the dimming function is large and the circuit scale is large. For this reason, since the slave unit becomes large and a large space is required to install the slave unit, there is a problem that the installation location of the slave unit, that is, the sensing element for measuring illuminance data is restricted.

  The present invention has been made in view of the above problems, and its object is to provide a high degree of freedom in the installation position of the sensing means and to control the environment in the control area based on the measurement data of the sensing means. An object of the present invention is to provide a remote monitoring control system capable of controlling to a desired state.

  In order to achieve the above object, the invention of claim 1 is directed to a transmission unit, a control terminal for controlling the operation of an environment control device for controlling the surrounding environment based on a control command, and a corresponding environment control device. One or more data input terminals for obtaining measurement data from a sensing means for measuring a physical quantity to be controlled in a measurement area provided in the control area, and storage means for storing installation position information of the environmental control device and the sensing means Control instructions for the environmental control equipment to be managed based on the collected measurement data and the installation position information stored in the storage means, collecting the measurement data from one or more data input terminals Is connected to the control terminal for creating the transmission terminal via a two-wire transmission line, and a separate address is assigned to the control terminal and the data input terminal. Multiplex transmission signal including an address is transmitted from the data terminal, the control terminal and the data input terminal are individually accessed, and the data input terminal during the reply waiting period provided for the multiplex transmission signal from the transmission unit. When the management terminal acquires the measurement data sent back from the transmission unit to the transmission unit, the management terminal transmits a control command created based on the acquired measurement data to the transmission unit as monitoring data. A multiplex transmission signal including a control command transmitted from a terminal is transmitted to a corresponding control terminal.

  According to a second aspect of the present invention, in the first aspect of the invention, the data input terminal includes a sensing means.

  According to a third aspect of the present invention, in the first aspect of the present invention, the data input terminal includes an interface circuit for connecting an external sensing means, and the measurement data is received from the sensing means via the interface circuit. It is characterized by acquiring.

  The invention according to claim 4 is the invention according to any one of claims 1 to 3, wherein the storage means of the management terminal is provided with the address information of the control terminal and the data input terminal, and the installation of each terminal. Control-related information including judgment information for optimizing the control contents of the environmental control equipment based on the measurement data for each area divided into the position information and the control area is stored, and is transmitted and received via the transmission line. When the measurement data returned to the transmission unit from the data input terminal is collected together with the address of the data input terminal by monitoring the transmission signal, the collected measurement data is stored in the storage means in association with the address. In addition, a control command for the corresponding environmental control device is created based on the control-related information stored in the storage means and the collected measurement data.

  According to a fifth aspect of the present invention, in the invention according to any one of the first to fourth aspects, an operation switch address associated with the address of the data input terminal is set separately from the address in the control terminal. When the transmission unit acquires the measurement data as monitoring data from the data input terminal, the measurement data is transmitted to the operation switch address associated with the address of the data input terminal, and the control terminal When the measurement data addressed to the operation switch address is received, the operation of the corresponding environmental control device is controlled based on the measurement data.

  According to a sixth aspect of the present invention, in any one of the first to fifth aspects of the present invention, a data display terminal provided with a display means is connected to a transmission unit via a transmission line, and the transmission unit is for data input. When the control data for displaying the measurement data returned from the terminal is transmitted to the data display terminal, the data display terminal displays the measurement data on the display means.

  According to the first aspect of the present invention, the measurement data acquired by the data input terminal is collected and centrally managed by the management terminal, and the collected measurement data and the sensing means and environment control device stored in the storage means Control instructions for controlling the environmental control equipment to be managed are created based on the installation location information of the remote control equipment, so compared to the case where a sensing means is provided for each individual control terminal, the surrounding environmental control equipment Even when the measurement data changes depending on the operation state, it is not easily affected, the environment in the control area can be controlled to a desired state, and the environment in the control area can be controlled to a uniform state. Furthermore, a data input terminal is provided separately from the control terminal for controlling the environmental control equipment, and the data input terminal is not provided with a function for controlling the environmental control equipment. Since the terminal can be made small, there is an effect that the degree of freedom of the installation position of the data input terminal is improved.

  According to the invention of claim 2, since the data input terminal itself includes the sensing means, it is possible to save the labor of installing the sensing means separately from the data input terminal and to save the construction.

  According to the invention of claim 3, since the sensing means is provided separately from the data input terminal, when the required performance of the sensing part is high, special sensing ability is required, or existing sensing There is an advantage that it is easy to cope with the case where it is desired to use the means, and there is also an advantage that the sensing means can be easily exchanged according to changes in the usage or environment of use.

  According to the invention of claim 4, the storage means of the management terminal includes a determination condition for optimizing the control content of the environmental control device based on the measurement data for each area divided into the control areas. Since the related information is stored, the operation of the environmental control device in each area can be controlled more finely as long as the area to be controlled is subdivided. Therefore, since excessive operation of the environmental control device can be suppressed, energy saving can be achieved as the entire system.

  According to the invention of claim 5, when the control terminal receives the measurement data addressed to its own operation switch address transmitted from the transmission unit, the control terminal controls the operation of the corresponding environmental control device based on the measurement data. Therefore, the control terminal itself can control the operation of the environment control device based on the measurement data.

  According to the invention of claim 6, since the measurement data acquired by the data input terminal is displayed on the display means of the data display terminal, the environment data can be notified by informing the user of the measurement data of the sensing means. The user can be urged to manually control the control device, and therefore the user can manually control the environment control device while confirming the display on the display means, for example, when it is desired to finely adjust the physical quantity to be controlled.

  Embodiments of the present invention will be described below with reference to FIGS. In the following embodiments, a remote monitoring control system that performs dimming control of a lighting apparatus that is an environmental control device based on measurement data of a brightness sensor as a sensing unit will be described as an example. The present invention is not limited to a brightness sensor or a lighting fixture, but is a system that controls the output of an air conditioning control device that is an environmental control device based on measurement data of a sensing means such as a temperature sensor or a humidity sensor. May be applied.

  FIG. 1 is a schematic system configuration diagram of a remote monitoring control system, in which a transmission unit 1, a control terminal 2, a data input terminal 3, a management terminal 4, and a data display terminal 5 are shown. Are connected via a two-wire transmission line Ls. Here, a unique address is assigned to the control terminal 2, the data input terminal 3, and the data display terminal 5, and the transmission unit 1 individually connects each of the terminals 2, 3, and 5 according to the address. It has recognized. In FIG. 1, only one control terminal 2, data input terminal 3, and data display terminal 5 are connected to each other for simplicity of illustration. Needless to say, a plurality of terminals 2, 3, and 5 may be connected in accordance with the number.

  The control terminal 2 is a terminal that controls the operation of the environment control device 6 such as a lighting fixture that controls ambient brightness based on a control command, and is connected to the transmission unit 1 via the transmission line Ls. Various settings such as an address between a transmission signal input / output interface unit (hereinafter referred to as a transmission signal input / output I / F unit) 21 for transmitting and receiving transmission signals and an external setting device (not shown). A setting input / output interface unit (hereinafter referred to as a setting input / output I / F unit) 22 for transmitting and receiving information, and a control output interface unit (hereinafter referred to as a dimming control signal) to the environment control device 6 It is called a control output I / F unit.) 23, a storage unit 24 for storing various types of information including setting information such as addresses, and an arithmetic unit 25 that is composed of a microcomputer and performs overall control. Have

  The data input terminal 3 is a terminal for acquiring measurement data from a sensing means for measuring brightness in a measurement area provided in a control area of the corresponding environmental control device 6, and via a transmission line Ls. A setting signal input / output unit for transmitting / receiving various setting information such as an address between a transmission signal input / output I / F unit 31 for transmitting / receiving a transmission signal to / from the transmission unit 1 and an external setting device (not shown). The I / F unit 32, a sensing element 33 that includes an illuminance sensor such as a photodiode, for example, and measures the illuminance in the measurement area, and the analog output (for example, voltage value) of the sensing element 33 is converted to a digital value with a predetermined number of bits. A sensor input interface section (hereinafter referred to as a sensor input I / F section) 34 that captures after A / D conversion and the data input terminal 3 are provided separately and brightness. An external device 7 having sensing means for detection is connected, and an external signal input interface unit (hereinafter referred to as an external device) that takes an analog output (for example, voltage value) of the external device 7 and converts it into a digital value of a predetermined number of bits. The signal input I / F unit is called a signal input I / F unit.) 35, a storage unit 36 that stores various information including setting information such as an address, and an arithmetic unit 37 that includes a microcomputer and performs overall control are provided as main components. ing. In the data input terminal 3, the physical quantity (analog value) to be controlled measured by the sensing element 33 or the external device 7 included in the terminal 3 is converted into a digital quantity and transmitted to the transmission unit 1. However, the resolution is sufficiently high, and the digital information is quantized so that a continuous numerical value (digital amount) can be regarded as an analog amount.

  The management terminal 4 is connected between a transmission signal input / output I / F unit 41 for transmitting / receiving a transmission signal to / from the transmission unit 1 via the transmission line Ls and an external setting device (not shown). , The address of the control terminal 2, the data input terminal 3 and the data display terminal 5, the installation position information of the sensing element 33, the external device 7 and the environmental control device 6, the sensing element 33 and the data display terminal 5 Control-related information including information indicating the type (unit) of measurement data sent to and received from and a judgment condition for optimizing the control content of the environmental control device based on the measurement data for each area divided into control areas The setting input / output I / F unit 42 for transmitting / receiving various setting information such as information, and various setting information input via the setting input / output I / F unit 42 are stored, and the collected measurement data is input as data. Terminal device 3 The main components are a storage unit 43 that stores time information acquired from a clocking means using a less and a built-in oscillator or a synchronous input terminal of an external clock, and an arithmetic unit 44 that is composed of a microcomputer and performs overall control. I have.

  In the management terminal 4, the measurement data returned from the data input terminal 3 in response to the constant polling from the transmission unit 1 or the state change notification from the data input terminal 3 is sent to the transmission unit 1. A plurality of data input terminals are monitored by monitoring the measurement data transmitted or by monitoring the control content transmitted from the transmission unit 1 to the output terminal (the control terminal 2 and the data display terminal 5). The measurement data from 3 is collected and centrally managed, and a control command for the environmental control device 6 to be managed is created based on the collected measurement data. Therefore, no address is set in the management terminal 4 itself, and only the addresses of the terminal devices 2, 3, 5 to be monitored are set in the storage unit 43.

  A personal computer or the like is preferably used as an external device for setting various setting information in the management terminal 4. If the management terminal 4 has a Web server function, a personal computer equipped with a Web browser is used. Various setting information can be set from a setting Web screen displayed on the screen of a personal computer connected to the management terminal 4, and the management terminal can be set from a personal computer connected to the management terminal 4 Various setting information may be set by uploading the setting file to the device 4, and the setting operation can be easily performed even when the setting contents are complicated. Further, when the external device takes in the measurement data stored in the storage unit 43 in association with the time information from the management terminal device 4, the past history of the measurement data can be viewed or the measurement data can be processed. It becomes possible.

  The data display terminal 5 is a terminal for displaying the measurement data of the sensing element 33 and the external device 7, and is a transmission signal input / output for transmitting / receiving a transmission signal to / from the transmission unit 1 via the transmission line Ls. Input / output I / F unit 52 for transferring various setting information such as an address between I / F unit 51 and an external setting device (not shown), and input from arithmetic unit 55 described later A display output interface unit (display output I / F unit) 53 that outputs a display signal to the display 8 based on the display information, a storage unit 54 that stores various information including setting information such as an address, and a microcomputer And a calculation unit 55 that performs overall control.

  By the way, as described above, the remote monitoring control system of the present embodiment is used for dimming control of a plurality of lighting fixtures (environment control devices 6) based on measurement data of an illuminance sensor. The arrangement of the data input terminals 3a and 3b and the environment control device 6 each having the sensing element 33 is shown in FIG. The plurality of environmental control devices 6 are arranged on the ceiling of a room 200 (for example, a office room in an office building) surrounded by walls 201 on all sides. A wall 202a on one surface of the room 200 (a wall located on the upper side in FIG. 2) is provided with a window 202. In a time zone in which daylight exists, a wall closer to the window 202 is brighter, and the wall on the opposite side of the window 202 is provided. The side closer to 201b is darker. The plurality of environmental control devices 6 (lighting fixtures) are arranged in eight rows in the vertical direction in FIG. 2, and four environmental control devices 6 are arranged in each row. . From the window 202 side, the environmental control devices 6 in the first and second rows are the control group G1, the environmental control devices 6 in the third and fourth rows are the control group G2, and the environmental controls in the fifth and sixth rows. The devices 6 are grouped into a control group G3, the environmental control devices 6 in the seventh and eighth rows are grouped into a control group G4, and the environmental control devices 6 in the control groups G1 to G4 are respectively connected via separate dimming signal lines L1. Are connected to the corresponding control terminals 2a to 2d. On the ceiling of the room 200, the data input terminal 3a is installed so that the measurement area A1 of the sensing element 33 is included in the control area of the control group G1, and the sensing element is in the control area of the control group G4. The data input terminal 3b is installed so as to include 33 measurement areas A2. The transmission unit 1, the control terminals 2a to 2d, and the management terminal 4 are installed in the distribution board 300, and the data input terminals 3a and 3b installed in the room 200 and the distribution board. The control terminals 2a to 2d, the management terminal 4 and the transmission unit 1 installed in 300 are connected via a transmission line Ls.

  Here, transmission / reception of data by the remote monitoring control system will be described below. The transmission unit 1 sends a time division multiplexed transmission signal (hereinafter referred to as a transmission signal) Vs having the format shown in FIG. 5A to the transmission line Ls. That is, the start pulse ST indicating the start of signal transmission, the mode data MD indicating the signal mode, the address data AD for individually calling the terminals 2, 3 and 5, and the control for controlling the load (environment control device 6 etc.) Bipolar (± 24V) time-division multiplexed signal comprising data CD, error correction code CS such as checksum data for detecting transmission error, and signal return period WT for setting a return period from terminals 2, 3 and 5 Thus, data is transmitted by pulse width modulation (see FIG. 5A). In this system, the operation power supply in each of the terminals 2, 3, 4 and 5 is obtained by rectifying the transmission signal Vs having a double pole by each of the terminals 2, 3, 4 and 5.

  In each of the terminals 2, 3 and 5, when the address included in the address data AD of the transmission signal Vs received via the transmission line Ls matches the preset address, the control data CD of the transmission signal Vs And monitoring data is returned as a current mode signal (a signal transmitted by short-circuiting the signal lines Ls via an appropriate low impedance) in synchronization with the signal return period WT of the transmission signal Vs. It has become.

  When data is transmitted from the transmission unit 1 to the desired terminals 2, 3 and 5, the transmission signal Vs having the mode data MD as the control mode and the address of the desired terminals 2, 3 and 5 as the address data AD. When the transmission signal Vs is sent to the transmission line Ls, the terminals 2, 3, and 5 that match the address data AD receive the control data CD, and return a signal with a parity bit added to the control data CD. Reply to period WT. The transmission unit 1 confirms that the control data CD has been transmitted to the desired terminals 2, 3, and 5 by matching the transmitted signal with the received signal in the signal return period WT. The control terminal 2 and the data display terminal 5 perform control operations and display operations according to the received control data CD.

  On the other hand, the transmission unit 1 always sends the transmission signal Vs at regular time intervals to the dummy address or to the addresses of all the connected terminals as the mode data MD in the dummy mode or as the constant polling. When the terminals 2, 3 and 5 try to transmit some information to the transmission unit 1, an interrupt as shown in FIG. 5B is made in synchronization with the start pulse ST of the transmission signal Vs in the dummy mode or polling. A signal Vi is generated. At this time, the terminals 2, 3 and 5 set an interrupt flag to prepare for subsequent information exchange with the transmission unit 1. When the transmission unit 1 receives the interrupt signal Vi, the mode data MD is set to the interrupt polling mode, and the upper half of the address data AD (the upper 4 bits if the address data AD is 8 bits) is sequentially increased. The transmission signal Vs is sent out. In the terminals 2, 3, and 5 that have generated the interrupt signal Vi, when the upper 4 bits of the address data AD included in the transmission signal Vs in the interrupt polling mode match the upper 4 bits of the preset address. The lower half of the address is returned to the transmission unit 1 during the signal return period WT. In this way, the transmission unit 1 searches for 16 terminals 2, 3, and 5 that have generated the interrupt signal Vi one by one, so that the terminals 2, 3, and 5 can be found in a relatively short time. When the transmission unit 1 acquires the addresses of the terminals 2, 3 and 5 that have generated the interrupt signal Vi, the mode data MD is set to the monitoring mode, and the transmission signal Vs having the address acquired from the address data AD is transmitted to the transmission line Ls. On the other hand, the terminals 2, 3 and 5 return information to be transmitted in the signal return period WT. Finally, the transmission unit 1 sends a signal instructing an interrupt reset to the terminals 2, 3 and 5 that have generated the interrupt signal Vi, and cancels the interrupt flags of the terminals 2, 3 and 5.

  As described above, information transmission from the terminals 2, 3, and 5 to the transmission unit 1 is performed four times from the transmission unit 1 to the terminals 2, 3, and 5 (dummy mode, interrupt polling mode, Completed by monitoring mode, interrupt reset). When the transmission unit 1 wants to know the desired operating state of the terminals 2, 3 and 5, it is only necessary to send a transmission signal using the mode data MD as monitoring data.

  Next, in this system, the management terminal 4 collects the measurement data from the data input terminals 3a and 3b and centrally manages them, and the control data is sent to the control terminals 2a to 2d based on the collected measurement data. The operation | movement which transmits and controls the environmental control apparatus 6 by each terminal device 2a-2d is demonstrated below. In addition, although data is transmitted / received between the transmission unit 1 and each terminal according to the above-mentioned transmission processing, in order to simplify the explanation below, transmission processing between the transmission unit 1 and the terminal is described. Simplify the description.

  The transmission unit 1 always performs a steady polling operation. When polling is performed on the addresses of the data input terminals 3a and 3b, the data input terminals 3a and 3b are connected to the sensing element 33 or an external device. The illuminance measurement data acquired from the device 7 is returned to the transmission unit 1 during the signal return period WT of the transmission signal Vs as monitoring data. As described above, the data input terminals 3a and 3b return the measurement data acquired from the sensing element 33 or the external device 7 to the transmission unit 1 in response to the constant polling from the transmission unit 1 to the address of the own device. Therefore, the load on the transmission unit 1 can be reduced as compared with the case where the data input terminals 3a and 3b generate an interrupt signal and return the measurement data to the transmission unit 1 through the above interrupt processing. An increase in communication traffic can also be suppressed. The data input terminals 3a and 3b generate an interrupt signal Vi in synchronization with the start pulse ST of the transmission signal Vs when there is a change in measurement data acquired from the sensing element 33 or the external device 7. The measurement data may be returned to the transmission unit 1 after the interruption process.

  When the transmission unit 1 receives the measurement data from the data input terminals 3a and 3b while constantly polling the address of each terminal, a correspondence relationship is set in advance with the data input terminals 3a and 3b. Control data for displaying measurement data is transmitted to the data display terminal 5. At this time, in the data display terminal 5 of the transmission destination, the transmission signal input / output I / F unit 51 receives the control data transmitted by the transmission signal, and the calculation unit 55 outputs the display data based on the control data. Display information is output to the I / F unit 53, and measurement data and information indicating the measurement location (for example, the address of the sensing element 33) are displayed on the display unit 8. FIG. 4A shows an example of the display screen of the data display terminal 5. The display 8 comprising a liquid crystal display arranged at the front center of the terminal has two data input terminals 3a and 3b. The measurement data of the illuminance measured by the sensing element 33 is displayed together with the addresses assigned to the terminals 3a and 3b. In the illustrated example, the measurement data of the terminal 3a whose address is “00-1” is 1, 016 (lx) and the measurement data of the terminal 3b whose address is “00-2” are displayed as 985 (lx). In FIG. 4, 81 and 82 are display switching operation buttons, 83 is a receiving window for receiving a setting signal made up of an optical signal such as an infrared ray transmitted from an external device, and 84 is for displaying an operation. It is an indicator lamp which consists of LED.

  Here, in the management terminal 4, the transmission signal input / output I / F unit 41 monitors the transmission signal transmitted / received via the transmission line Ls, and the address included in the transmission signal is the terminal to be monitored. When the addresses coincide with the addresses 2a to 2d, 3a, 3b, and 5, they are output to the calculation unit 44. That is, the calculation unit 44 transmits the measurement data returned from the data input terminals 3a and 3b according to the constant polling from the transmission unit 1 or the state change notification from the data input terminals 3a and 3b. A plurality of data input terminals by monitoring measurement data transmitted to 1 or monitoring control contents transmitted from the transmission unit 1 to the control terminals 2a to 2d and the data display terminal 5 The measurement data from 3a and 3b are collected, and the collected measurement data is stored in the storage unit 43 together with the time information for centralized management, and the environmental control devices 6 of the groups G1 to G4 by the control terminals 2a to 2d. Understand the control status of

  The storage unit 43 of the management terminal 4 stores the installation position information of the sensing element 33 and the external device 7 and the installation position information of the environmental control device 6, and the calculation unit 44 stores the data input terminals 3a and 3b. The control data of the environmental control device 6 is set for each area divided from the control area after comparing the measurement data acquired from the above with the installation position of the sensing element 33 or the external device 7 that measured these measurement data. By optimizing according to the determination conditions, optimal control data is created for each of the control groups G1 to G4. In the construction example of FIG. 2, one data input terminal 3a is arranged in the control area of the control group G1 near the window (the brightest side when daylight is present), and the other data input terminal 3b is Since it is arranged in the control area of the control group G4 farthest from the window 202 (the darkest side when daylight exists), the calculation unit 44 of the management terminal 4 uses the illuminance data at both ends of light and dark. The necessary illuminance can be easily obtained by calculation in the environmental control devices 6 belonging to the intermediate control groups G2 and G3, and the necessary dimming rate (control data) can be inevitably obtained. Then, when the control unit 44 of the management terminal 4 obtains the control data of the environmental control devices 6 of the control groups G1 to G4, the control data to the control terminals 2a to 2d is transmitted to the transmission unit 1. .

  When receiving the control data transmitted from the management terminal 4, the transmission unit 1 creates control data to be transmitted to the corresponding control terminals 2a to 2d, and transmits the transmission signal Vs including the control data to the transmission line Ls. The control data is transmitted to the corresponding control terminals 2a to 2d, and the control terminals 2a to 2d perform dimming control of the environment control devices 6 of the control groups G1 to G4. The control terminals 2a to 2d are configured to cause the transmission unit 1 to return monitoring data indicating an operation state (the dimming level of the environmental control device 6). Based on the monitoring data, the transmission unit 1 creates control data for displaying the operation state (dimming level) of the control group on the corresponding data display terminal 5, and a transmission signal including the control data. Is transmitted to the transmission line Ls. In the data display terminal 5, the calculation unit 55 outputs display information to the display 8 based on the control data received by the transmission signal input / output I / F unit 51. Since the addresses (01-1 to 4) assigned to the control groups G1 to G4 and their operation states (duty ratios of dimming signals) are displayed on the display screen of the display 8 (see FIG. 4B). Based on the display of the data display terminal 5, it is possible to grasp the operating state of each control group G1 to G4. As described above, the display 8 of the data display terminal 5 displays the illuminance data acquired by the data input terminals 3a and 3b, the dimming states (dimming levels) of the control groups G1 to G4, and the like. Therefore, when the measurement data collected from the data input terminals 3a and 3b is displayed so that the user can visually recognize it, manual control by the user is promoted, or the user wants to adjust more finely according to the usage situation For example, it is possible to make a determination after confirming the measurement data displayed on the data display terminal 5.

  In this system, the measurement data acquired from the sensing element 33 or the external device 7 is centralized and managed by the management terminal 4 that can overlook the entire system, and the measurement data of each sensing element 33 or the external device 7 is Since it is possible to give optimal control data for each control group G1 to G4 to be controlled after comparing with the installation position information of the sensing element 33 or the external device 7, a plurality of illumination control devices with illuminance sensors are installed. Since there is no possibility that the illumination light of other instruments interferes with the measurement data of the illuminance sensor as in the case, there is an effect that higher-quality environmental control becomes possible.

  The management terminal 4 acquires measurement data from the data input terminals 3a and 3b arranged in the control areas (control groups G1 and G4) at both ends of the light and dark, and performs intermediate control based on the acquired measurement data. Since the illuminance is calculated in the areas (control groups G2 and G3), there is an advantage that the number of sensing means for measuring illuminance data is smaller than the number of control groups to be controlled. For example, in the installation example of FIG. 3, only one data input terminal 3 is installed at a substantially central position of the room 200 so that the measurement area A3 extends over the control areas of the control groups G2 and G3. Is input to the sensing element 33 of the data input terminal 3 in a state where the illumination light and the external light of the two sections (control groups G2 and G3) are superimposed. Here, in order to appropriately derive the control data of each control group G1 to G4, the control output of the environmental control device 6 of each control group G1 to G4 is obtained in the storage unit 43 of the management terminal 4 The relationship with the illuminance is set in advance, and the calculation unit 44 controls the control state of the environmental control device 6 of each control group G1 to G4 and the actual illuminance data (external light and illumination light measured by the sensing element 33). After the external light quantity is obtained based on the above, the necessary light quantity is obtained within the control area of each control group G1 to G4, and the control data of the environmental control device 6 is calculated for each control group G1 to G4. As described above, in this embodiment, the management terminal 4 determines the control state of each environmental control device 6 by performing the optimal control process based on the measurement data collected from the data input terminal 3. Therefore, even when there are few input points of measurement data, the environment in the control area can be controlled with the same accuracy without degrading the quality of control. For example, in the system shown in FIG. 3, four control groups G1 to G4 can be controlled. The environmental control device 6 can be controlled based on the detection data of the sensing element 33 acquired by one terminal 3 for data input.

  In addition, the data input terminals 3a and 3b installed on the ceiling of the room 200 only have a function of acquiring measurement data from the sensing means (the sensing element 33 or the external device 7 included in the own device). Since the terminals 3a and 3b are not provided with a dimming function unlike the conventional control system, the terminals 3a and 3b are small in size and can reduce heat generation. is there. Furthermore, since the data input terminals 3a and 3b do not have a dimming function, but only have the sensing element 33 or the external signal input I / F unit 35 of the external device 7, the product life is extended. There is an advantage that the frequency of performing the maintenance work in the room 200 having poor workability such as the office room is reduced, and the maintenance work of the control terminals 2a to 2d with the dimming function is performed in the distribution board 300. Therefore, there is an advantage that the workability of maintenance is improved as compared with the case where the light control device is installed on the ceiling as in the conventional system.

  In the present embodiment, the calculation unit 44 of the management terminal 4 has a process judgment function for optimum control, and determines the control output of each environmental control device 6 using the optimum control logic. There is also an advantage that it is possible to cope with the situation peculiar to the site to be controlled relatively easily only by adjusting. For example, in the case of data input terminals 3a and 3b equipped with a sensing element 33 for detecting illuminance, measurement between terminals is performed under various conditions such as ceiling height, distance from a window, and direction due to physical restrictions on the installation location. Even if there is a difference in the data, the conventional control system has no means for conditioning each terminal, and the dimming output level is uniformly determined using the illuminance information of the representative extracted position (terminal). However, if the optimization unit provided in the calculation unit 44 is used and the illumination area to be controlled is subdivided, by detecting the necessary illuminance in each subdivided area, areas that are brighter than necessary and illuminance can be obtained. It is possible to finely adjust the illuminance in the entire illumination area by eliminating the shortage area, and as a result, necessary illuminance can be ensured while reducing energy consumption.

  Further, when this system controls a blind device or an air conditioner having a function of adjusting a louver angle in addition to a lighting fixture, the management terminal 4 uses illuminance data collected from the data input terminals 3a and 3b. When an excessive illuminance level due to direct sunlight is detected, the control of reducing the energy consumption by suppressing the dimming output of the environmental control device 6 composed of a lighting fixture will reduce the power consumption by the lighting fixture. However, since the indoor temperature rises due to the incidence of direct sunlight and the power consumption of the air conditioner increases accordingly, it may be considered that the power consumption increases on the whole system. Therefore, when the management terminal 4 detects an excessive illuminance level due to direct sunlight, the louver angle is adjusted by the blind device before the indoor temperature rises due to the incidence of direct sunlight, so that A control method of reducing the amount of incident light and increasing the output of the environmental control device 6 including the lighting device by the amount that becomes dark due to the decrease in outside light is also conceivable. The power consumption can be reduced. As described above, the calculation unit 44 of the management terminal 4 can employ an optimization control method that takes into account the performance of the on-site equipment (environmental control device 6 or sensing element 33), and the sensing element 33. Alternatively, higher-order processing can be performed by using a device that detects different types of physical quantities (analog numerical information) as the external device 7 and combining a plurality of types of analog numerical information. For example, when the calculation unit 44 of the management terminal 4 obtains time information and uses it together when performing dimming control, it is input and used. Since it can be calculated, control prediction and planning can also be performed.

  Further, in the above-described system, since the data input terminal 3 itself includes the sensing element 33, it is possible to save the trouble of installing the sensing element separately from the data input terminal 3 and to obtain the matching of the installation location. In some cases, saving construction can be realized. As shown in FIG. 6, external devices 7a and 7b equipped with illuminance sensors are installed on the ceiling of the room 200, and the data input terminals 3a and 3b and the external devices 7a and 7b installed in the distribution board 300 are installed. May be connected via the communication lines L2 and L3, respectively, and the data input terminals 3a and 3b may take in illuminance measurement data from the corresponding external devices 7a and 7b, respectively. As described above, since the external device 7 (sensing means) provided with the illuminance sensor is provided separately from the data input terminal 3, when the required performance of the sensing portion is high or special sensing capability is required. If you want to use existing sensing means to link with existing sensing means, there is an advantage that it can be easily handled, and the sensing means can be easily replaced according to changes in usage and usage environment. In terms of price, the use of an external sensor may be inexpensive.

  Further, since the data input terminal 3 includes an external signal input I / F unit 35 for capturing an external signal, an external device 7 having no sensing function is connected to the external device 7 and the system. It also functions as an input interface when linking with. For example, the dimming control signal from another dimming system is acquired by the data input terminal 3 and returned to the transmission unit 1, so that the dimming control of the environment control device 6 is performed by the corresponding control terminal 2. If so, the maximum wiring length of the dimming control signal can be extended.

  Further, in the above-described embodiment, the management terminal 4 collects measurement data from the data input terminals 3a and 3b and centrally manages the data, and based on the collected measurement data, the control terminal 4a to 2d are connected to the control terminals 2a to 2d. While creating the control data, each of the control terminals 2a to 2d receives the control data transmitted from the transmission unit 1 to control the environment control device 6, but for the control terminals 2a to 2d, In addition to the address as the control terminal, an operation switch address associated with the address of the data input terminal 3 may be set. In this case, when the transmission unit 1 acquires the measurement data as the monitoring data from the data input terminals 3a and 3b, the measurement data is sent to the operation switch address associated with the address of the data input terminals 3a and 3b. Therefore, the control terminals 2a to 2d can obtain the measurement data by receiving the measurement data addressed to their own operation switch addresses, and the control terminals 2a to 2d themselves can perform measurement. The operation of the corresponding environment control device 6 can be controlled based on the data.

1 is a system configuration diagram of a remote monitoring control system of an embodiment. It is explanatory drawing explaining the example of arrangement | positioning same as the above. It is explanatory drawing explaining the other example of arrangement | positioning same as the above. (A) (b) is explanatory drawing of the display content of the data display terminal used for the same as the above. (A) and (b) are waveform diagrams of transmission signals used in the above. It is explanatory drawing explaining another example of arrangement | positioning same as the above. It is a schematic block diagram of the conventional control apparatus with a sensing function. (A) (b) is a layout for demonstrating operation | movement same as the above. (A) is the layout for demonstrating operation | movement same as the above, (b) is explanatory drawing explaining a construction state.

Explanation of symbols

1 Transmission Unit 2 Control Terminal 3 Data Input Terminal 4 Management Terminal 6 Environmental Control Equipment 7 External Equipment (Sensing Means)
33 Sensing element (sensing means)
43 Storage unit (storage means)
Ls transmission line

Claims (6)

Measure the physical quantity to be controlled in the measurement unit provided in the control area of the corresponding environmental control device and the control terminal that controls the operation of the transmission unit, the environmental control device that controls the surrounding environment based on the control command One or more data input terminals that acquire measurement data from the sensing means, and storage means that stores the location information of the environmental control device and the sensing means. The measurement is performed from one or more data input terminals. A two-wire transmission line that collects and centrally manages data, and creates a control command for the environmental control device to be managed based on the collected measurement data and the installation position information stored in the storage means Connected through
A separate address is assigned to the control terminal and the data input terminal, and a multiplex transmission signal including the address is transmitted from the transmission unit to individually access the control terminal and the data input terminal. When the management terminal acquires the measurement data returned from the data input terminal to the transmission unit during the reply waiting period provided in the multiplex transmission signal from the transmission unit, the management terminal is based on the acquired measurement data. The generated control command is transmitted to the transmission unit as monitoring data, and the transmission unit transmits a multiplexed transmission signal including the control command transmitted from the management terminal to the corresponding control terminal. Supervisory control system.   The remote monitoring control system according to claim 1, wherein the data input terminal comprises the sensing means.   2. The data input terminal includes an interface circuit for connecting the sensing means provided outside, and acquires measurement data from the sensing means through the interface circuit. Remote monitoring control system.   In the storage means of the management terminal, the address information of the control terminal and the data input terminal, the installation position information of each terminal, and the control contents of the environmental control device for each area divided within the control area are stored. Control-related information including judgment conditions for optimization based on measurement data is stored and sent back from the data input terminal to the transmission unit by monitoring multiple transmission signals sent and received via the transmission line When the measurement data is collected together with the address of the data input terminal, the collected measurement data is stored in the storage means in association with the address, and based on the control related information stored in the storage means and the collected measurement data. The remote monitoring control system according to any one of claims 1 to 3, wherein a control command for a corresponding environmental control device is created.   In the control terminal, an operation switch address associated with the address of the data input terminal is set separately from the address, and the transmission unit acquires measurement data as monitoring data from the data input terminal. Then, the measurement data is transmitted to the operation switch address associated with the address of the data input terminal, and when the control terminal receives the measurement data addressed to its own operation switch address, The remote monitoring control system according to any one of claims 1 to 4, wherein the operation of the corresponding environmental control device is controlled.   A data display terminal having a display means is connected to the transmission unit via a transmission line, and the transmission unit transmits control data for displaying the measurement data returned from the data input terminal to the data display terminal. The remote monitoring control system according to any one of claims 1 to 5, wherein the data display terminal displays the measurement data on the display means.

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