JP5401194B2 - Supervisory control device - Google Patents

Description

  The present invention relates to a monitoring control device that monitors and controls equipment such as air conditioners and lighting equipment, and in particular, communicates with a management server and a higher-level network and simultaneously communicates with equipment and a lower-level network. The present invention relates to a monitoring control device.

  Conventionally, in a monitoring control system that controls and monitors equipment such as lighting devices, air conditioners, alarms, and electric locks, a remote monitoring control system that is hierarchized by a plurality of networks with different communication methods has been provided. . The remote monitoring control system includes a monitoring control device that monitors and controls a plurality of facility devices, and is configured so that the management server communicates with the plurality of monitoring control devices. It is designed to be controlled remotely through a centralized system. As one of such remote monitoring and control systems, a local control device that is a monitoring control device and a center server that is a management server are connected via a network, and a remote device that remotely controls facility equipment that is a controlled device by the center server. A control system has been proposed (see Patent Document 1).

  The remote control system of Patent Document 1 has a configuration in which a plurality of local control devices connected to transmission lines for communicating with a plurality of controlled devices are connected to a center server through a network such as the Internet. In this remote control system, when the center server sends a control command to the local control device via the network, the control command is sent from the local control device to the controlled device via the transmission line, and the controlled device executes an operation based on the control command. To do. That is, the center server performs remote control of the operation of the controlled device through the local control device.

  In a remote monitoring control system including such a remote control system, a monitoring control device such as a local control device is connected to a plurality of networks having different communication protocols. Therefore, when performing communication that mediates between the management server and the equipment, the monitoring and control apparatus converts the signal into a signal according to the communication protocol of each network, and performs communication between the management server and the equipment. . Moreover, when connected to a plurality of networks of different communication protocols, such as the monitoring control device, the communication control device is provided with an interface connected to each network.

  Further, as communication control devices connected to a plurality of networks, those connected to a LAN for monitoring and controlling an air conditioner and a LAN for monitoring and controlling a lighting fixture have been proposed (Patent Literature). 2). The communication control device of Patent Document 2 performs communication control with different connected LANs, and has a configuration in which a communication control CPU is provided in order to establish communication between each LAN and a host CPU. ing. In this communication control device, in order to monitor and control the air conditioner or the lighting fixture based on the processing by the host CPU, the LAN control CPU connected to the LAN that communicates with each other is selected by the communication control CPU. The CPU is connected and its communication is established. That is, the communication control device shown in Patent Document 2 has a configuration in which a LAN control CPU connected to a host CPU is selected and connected by a communication control CPU in order to establish communication with a different LAN.

JP 2009-015882 A Japanese Patent Laid-Open No. 09-130874

  In the case of a monitoring control device having a conventional communication control device represented by the communication control device of Patent Document 2, the network is switched by the communication control device, and the monitoring control device performs communication. Therefore, a processing device such as a communication control CPU for switching an interface connected to a communication target network is required, and the device configuration is complicated. In addition, since the communication is performed by selecting one of the plurality of interfaces, the communication by the unselected interface is stopped until the communication is completed, and the time required for the communication is increased. End up.

  In view of such a problem, the present invention is capable of connecting to a plurality of types of networks, and temporarily storing signals from the respective networks and then distributing and processing depending on the transmission source. An object is to provide a control device.

In order to achieve the above object, a monitoring control apparatus of the present invention is a monitoring control apparatus that connects to a plurality of networks using different communication protocols and communicates with each of the plurality of networks, and each of the plurality of networks. A plurality of network processing units for processing signals to be transmitted to and received from, a buffer for temporarily storing signals processed after being received by each of the plurality of network processing units, and a signal received by each of the network processing units The network designation table storing the relationship between the address of the transmission source device and the network to which the device belongs, and the signal temporarily stored in the buffer are read, and then transmitted by referring to the network designation table. Check the network that sent the signal from the address of the original device, and check the And a control unit which processes the signal based on the network communication protocol, the processed signal by said control unit, a data memory unit in which the signal is stored for each network is transmitted, and the buffer, the Common to a plurality of network processing units, and the buffer stores data received by each of the plurality of network processing units in the order of reception, including the transmission source address. .

  In such a monitoring control device, the control unit generates a signal to be transmitted to each of the networks, temporarily stores the generated signal in the buffer, and stores the signal temporarily stored in the buffer. Then, the data is sent to a network processing unit corresponding to the destination network and processed, and then transmitted to the network.

  Further, the network processing unit is connected to a first network processing unit that is connected to a lower network that communicates with the equipment and a second network that is connected to an upper network that communicates with a management server that remotely monitors and controls the equipment. And when the first network processing unit receives a monitoring signal indicating an operation state of the equipment, the second network processing unit is configured to process the monitoring signal with the control unit. While transmitting the monitoring signal to the management server, when the second network processing unit receives a control signal for controlling equipment, the first network processes the control signal after processing the control signal. The control signal may be transmitted from the processing unit to the target equipment.

  According to the present invention, when communicating with a plurality of networks using different communication protocols, a signal received from each network is temporarily stored in a buffer and then sent to the control unit. The control unit refers to the network designation table. Then, the corresponding communication protocol is confirmed from the source address of the signal. Thereby, after the signal received from each network is stored in the buffer at a time, the control unit can perform signal processing corresponding to each network. Therefore, the device configuration of the monitoring control device can be simplified and the size can be reduced.

These are block diagrams which show the internal structure of the monitoring control apparatus of this invention. These are block diagrams which show the structure of the remote monitoring control system provided with the monitoring control apparatus shown in FIG. These are figures which show the structure of the network designation | designated table memorize | stored in the memory of the monitoring control apparatus shown in FIG.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the internal configuration of the monitoring control device of this embodiment. FIG. 2 is a block diagram showing a configuration of a remote monitoring control system including the monitoring control device shown in FIG. As shown in FIG. 1, the monitoring control apparatus will be described by taking as an example a configuration connected to two lower networks, but may be configured to connect to one lower network. It may be configured to connect to two or more lower networks.

  A monitoring control device 1 shown in FIG. 1 includes a connector unit 11a connected to a transmission line L1a of a lower network for monitoring and controlling an air conditioner 3a (see FIG. 2) that is a facility device, and a lighting device 3b that is a facility device. A connector unit 11b connected to a transmission line L1b of a lower network for monitoring and controlling (see FIG. 2), and a host that communicates with a management server 2 (see FIG. 2) that centrally manages the entire remote monitoring and controlling system. A network transmission line L2 and a connector part 12 to be obtained are provided. The monitoring control device 1 transmits and receives signals to and from the network processing units 13a, 13b, and 14 connected to the connector units 11a, 11b, and 12 and the network processing units 13a, 13b, and 14 via the bus line 16, respectively. A memory unit that stores a bus buffer 15 to be performed, a control unit 18 that transmits and receives signals to and from the bus buffer 15 via the bus line 17, and a program for executing a signal processing operation by the control unit 18, a network designation table T1, and the like 19 and data memory units 20a, 20b, and 21 for storing signals processed by the control unit 18.

  The monitoring control device 1 includes a communication block by network processing units 13a, 13b, and 14 connected to a bus line 16 across a bus buffer 15, a control unit 18 connected to the bus line 17, a memory unit 19, In addition, a control block by the data memory units 20a, 20b, and 21 is provided. That is, a signal received by the communication block is given to the bus buffer 15 through the bus line 16, temporarily stored in the bus buffer 15, and then sent to the control block via the bus line 17. On the other hand, a signal transmitted from the communication block is given from the control block to the bus buffer 15 through the bus line 16, temporarily stored in the bus buffer 15, and then transmitted to the communication block through the bus line 16. Sent out.

  The remote monitoring control system shown in FIG. 2 includes a plurality of monitoring control devices 1 having the configuration shown in FIG. 1, a management server 2 that communicates with the plurality of monitoring control devices 1 via the host network NT2, and the monitoring control device 1. Are provided with an air conditioner 3a, a lighting device 3b, an alarm device 3c, and an electric lock 3d, which are equipment devices that communicate with each of the devices via the lower network NT1. A plurality of equipment devices (corresponding to the air conditioner 3a, the lighting device 3b, the alarm device 3c, and the electric lock 3d) are connected to one monitoring control device 1 for each of the lower networks NT1, Monitoring and control is performed by the monitoring control device 1.

  In the remote monitoring and control system shown in FIG. 2, in order to simplify the description, each of the lower networks NT1 is provided with an air conditioner 3a, an illumination device 3b, an alarm device 3c, and an electric lock 3d. For example, for the air conditioner 3a, a control valve that controls the flow rate of hot water or cold water, a fan that discharges hot air or cold air after heat exchange, hot air or cold air flowing through a duct flows into the room And a controller for controlling the opening of the control valve and the damper and the amount of air blown by the fan in order to adjust the room temperature to the set temperature. The controller of the air conditioner 3a is connected to the lower network NT1 and communicates with the monitoring control device 1. Further, for the network NT1 for monitoring and controlling the lighting device 3b, a control terminal device having a relay for turning on / off the lighting device 3b and an operation terminal for receiving an ON / OFF operation of the lighting device 3b are connected.

  In such a remote monitoring control system, the monitoring control device 1 transmits a control signal to facility equipment (corresponding to the air conditioner 3a, the lighting equipment 3b, the alarm device 3c, and the electric lock 3d) connected to the lower network NT1. And while controlling the operation | movement, a signal is received from an installation apparatus and the operation state of the installation apparatus is monitored. At this time, an address is assigned to each of the monitoring control device 1, the air conditioner 3a, the lighting device 3b, the alarm device 3c, and the electric lock 3d connected to the lower network NT1, and a signal transmitted on the lower network NT1. Includes the address of the device as the transmission destination and the address of the device as the transmission source. The addresses assigned to each of the monitoring control device 1, the air conditioner 3a, the lighting device 3b, the alarm device 3c, and the electric lock 3d are set according to a method according to the communication protocol in the lower network NT1.

  In addition, the management server 2 communicates with a plurality of monitoring control devices 1 through the higher level network NT2, so that each equipment device connected to the lower level network NT1 is transmitted by the management server 2 via the monitoring control device 1. Remote monitoring controlled. That is, when the equipment is remotely controlled by the management server 2, a control signal from the management server 2 is transmitted to the monitoring control device 1 through the higher-level network NT2. In addition, the monitoring control device 1 transmits a monitoring signal indicating the operation state of each equipment device to the management server 2 through the upper network NT2. This upper network NT2 uses, for example, the BACnet protocol as a communication protocol to be used. Each of the monitoring control device 1 and the management server 2 connected to the upper network NT2 is assigned an address such as an IP address according to the communication protocol of the upper network NT2. The signal transmitted on the higher level network NT2 also includes the address of the device as the transmission destination and the address of the device as the transmission source.

  That is, in the remote monitoring control system shown in FIG. 2, when the management server 2 generates a control signal for operating a specific equipment device in a predetermined operating state, the control signal is used to monitor and control the equipment device. The data is transmitted to the control device 1 through the upper network NT2. Therefore, the monitoring control device 1 that has received the control signal from the management server 2 performs signal processing on the received control signal, and confirms the equipment to be controlled and the operating state to be controlled. Then, the supervisory control device 1 generates a control signal for setting the equipment to be controlled to the designated operating state, and transmits this control signal to the equipment to be controlled through the lower network NT1. The equipment that has received this control signal is controlled so as to be in the operating state designated by the management server 2.

  On the other hand, when a monitoring signal indicating the operation state is transmitted from the equipment to the monitoring control device 1 through the lower network NT1, the monitoring control device 1 performs signal processing on the received monitoring signal. Check the operating status of equipment. And the monitoring control apparatus 1 produces | generates the monitoring signal which shows the operation state of the confirmed installation apparatus, and transmits this produced | generated monitoring signal with respect to the management server 2 via the high-order network NT2. Therefore, the management server 2 receives the monitoring signal from the monitoring control device 1, analyzes the content of the signal, confirms the operating state of the equipment, and performs remote monitoring of the equipment.

  The operation of the monitoring control device 1 installed to realize the remote monitoring control by the management server 2 will be described below by taking the configuration shown in FIG. 1 as an example. In addition to the program for the signal processing operation according to the communication protocol of each of the lower network and the upper network connected to the connector units 11a, 11b, and 12 in the memory unit 19, the monitoring control device 1 is shown in FIG. The network designation table T1 having such a configuration is stored. The network designation table T1 stored in the memory unit 19 is configured to designate a network to be used for communication with respect to the addresses of the air conditioner 3a and the lighting equipment 3b as the equipment and the address of the management server 2. ing.

  In the network designation table T1 of FIG. 3, the lower network to which the air conditioner 3a is connected is “NT1a”, the lower network to which the lighting device 3b is connected is “NT1b”, and the upper network to which the management server 2 is connected. Is "NT2". In the network designation table T1 of FIG. 3, the addresses of the air conditioners 3a are “A1” to “A3”, the addresses of the lighting equipment 3b are “B1” to “B5”, and the addresses of the management server 2 are “C1”. And Therefore, in the network designation table T1, the lower network “NT1a” to which the air conditioner 3a is connected is associated with the addresses “A1” to “A3”, and the lighting device 3b is associated with the addresses “B1” to “B5”. The lower network “NT1b” to be connected is stored in association with the address “C1” and the upper network “NT2” to which the management server 2 is connected.

  The monitoring control device 1 having such a network designation table T1 is transmitted from the transmission lines L1a, L1b, and L2 connected to the connector units 11a, 11b, and 12 in the network processing units 13a, 13b, and 14, respectively. Receive a signal. Each of the network processing units 13a, 13b, and 14 performs a decoding process on the received signal, and then sends it to the bus buffer 15 via the bus line 16. That is, the bus buffer 15 receives the signals received by the network processing units 13a, 13b, and 14 in the order of reception and temporarily stores them. At this time, the signal sent from each of the network processing units 13a, 13b, and 14 to the bus buffer 15 includes data destined for the control unit 18. Therefore, the signals transmitted from the network processing units 13a, 13b, and 14 and stored in the bus buffer 15 are sequentially transmitted to the control unit 18.

  When the signal to the control unit 18 temporarily stored in the bus buffer 15 is given to the control unit 18 through the bus line 17, the control unit 18 transmits the source address included in the signal sent from the bus buffer 15. Confirm. Then, the control unit 18 refers to the network designation table T1 in the memory unit 19 and recognizes which network the signal from the bus buffer 15 is received through. Then, the control unit 18 reads a program based on the communication protocol corresponding to the recognized network from the memory unit 19, performs signal processing according to the program, and then processes the processed signal to one of the data memory units 20a, 20b, and 21. To store.

  That is, when the transmission source address included in the signal from the bus buffer 15 is any one of “A1” to “A3”, the control unit 18 recognizes that the signal is transmitted from the lower network NT1a. Therefore, signal processing is performed based on the communication protocol in the lower network NT1a, and then stored in the data memory 20a through the bus line 17. Similarly, when the transmission source address is any one of “B1” to “B5”, the control unit 18 performs signal processing based on the communication protocol in the lower network NT1b, and then transmits the data memory through the bus line 17. When the transmission source address is “C1”, the control unit 18 performs signal processing based on the communication protocol in the higher level network NT2, and then stores it in the data memory 21 through the bus line 17. As a result, the control unit 18 performs signal processing for each signal received from each of the lower networks NT1a and NT1b and the upper network NT2, and then distributes the processed signals to the data memories 20a, 20b, and 21. it can.

  When the signal processed by the control unit 18 is a control signal from the higher-order network NT2, the control unit 18 reads the data from the data memory 21 through the bus line 17 again, analyzes the content of the control signal, and performs the air conditioning equipment 3a. And which of the lighting devices 3b is to be controlled. And when it is a control signal with respect to the air conditioner 3a, the control part 18 converts into the control signal for transmitting to lower network NT1a, and sends it out to the bus buffer 15 through the bus line 17. FIG. On the other hand, when the control signal is for the lighting device 3b, the control unit 18 converts the control signal into a control signal for transmission to the lower network NT1b, and sends the control signal to the bus buffer 15 through the bus line 17. In this way, when sending to the bus buffer 15, the control signal transmitted to the lower network NT1a is accompanied with the data destined for the network processing unit 13a, while the control signal transmitted to the lower network NT1b is added to the network processing unit. Data with destination 13b is attached.

  Thereafter, the control signal temporarily stored in the bus buffer 17 is sent to the network processing units 13a and 13b through the bus line 16 in accordance with the data indicating the accompanying transmission destination. That is, the control signal for the air conditioner 3a is converted into a signal according to the communication protocol of the lower network NT1a by the network processing unit 13a, and then transmitted from the connector unit 11a to the transmission line L1a. Thereby, the control signal is transmitted from the monitoring controller 1 to the air conditioner 3a to be controlled through the lower network NT1a. The control signal for the lighting device 3b is converted into a signal according to the communication protocol of the lower network NT1b by the network processing unit 13b, and then transmitted from the connector unit 11b to the transmission line L1b to be controlled. 3b is transmitted through the lower network NT1b. Each control signal includes the address of the air conditioner 3a or lighting device 3b to be controlled as the transmission destination and the address of the monitoring control device 1 as the transmission source as information.

  When the signal processed by the control unit 18 is a monitoring signal from each of the lower networks NT1a and NT1b, the control unit 18 reads the data again from each of the data memories 20a and 20b through the bus line 17. At this time, the control unit 18 analyzes the monitoring signal read from the data memory 20a, thereby confirming the operation state of the air conditioner 3a, and also analyzes the monitoring signal read from the data memory 20b. The operating state of the device 3b is confirmed. And the control part 18 produces | generates the signal for a monitoring which shows each operation state of the air conditioner 3a and the illuminating device 3b, and sends it out to the bus buffer 15 through the bus line 17. FIG. As described above, when the data is transmitted to the bus buffer 15, the monitoring signal is accompanied by data having the network processing unit 14 as a transmission destination.

  Thereafter, the monitoring signal temporarily stored in the bus buffer 17 is sent to the network processing unit 14 through the bus line 16 and converted into a signal according to the communication protocol of the higher level network NT2, and then the connector unit 12 To the transmission line L2. As a result, a monitoring signal indicating the operating state of each facility device is transmitted from the monitoring control device 1 to the management server 2 through the lower network NT2. This monitoring signal includes the address of the management server 2 as a transmission destination and the address of the monitoring control device 1 as a transmission source as information.

  In addition, the monitoring control device 1 causes the memory unit 19 to link the time schedule information for setting the air conditioner 3a of the lower network NT1 and the lighting device 3b of the upper network NT2 to a predetermined operation state at a predetermined time. Interlocking device information indicating the relationship between the facility devices is stored. The control unit 18 refers to the time schedule information or the linked device information in the memory unit 19, and triggers the recognition of the operation of a predetermined time or a predetermined facility device, and determines the facility device operated by this trigger and its operation state. recognize. Then, the control unit 18 generates a control signal for controlling the equipment to be controlled to a predetermined operation state, and sends the control signal to the bus buffer 15 via the bus line 17. When the control signal temporarily stored in the bus buffer 15 is a signal that targets the air conditioner 3a, the control signal is sent to the network processing unit 13a while the signal that targets the lighting device 3b. If there is, it is sent to the network processing unit 13b. Thereafter, the target air conditioner 3a or lighting device 3b is controlled by being transmitted to the transmission lines L1a and L1b of the connectors 11a and 11b or the lower networks NT1a and NT1b, respectively.

DESCRIPTION OF SYMBOLS 1 Monitoring and control apparatus 2 Management server 3a Air conditioner 3b Lighting equipment 3c Alarm 3D Electric lock 11a, 11b Connector part 12 Connector part 13a, 13b Network processing part 14 Network processing part 15 Bus buffer 16, 17 Bus line 18 Control part 19 Memory 20a, 20b Data memory unit 21 Data memory unit

Claims (3)

A monitoring control device that connects to a plurality of networks using different communication protocols and communicates with each of the plurality of networks,
A plurality of network processing units for processing signals transmitted to and received from each of the plurality of networks;
A buffer that temporarily stores signals processed after being received by each of the plurality of network processing units;
A network designation table storing a relationship between an address of a device that is a transmission source of a signal received by each of the network processing units and a network to which the device belongs;
After reading the signal temporarily stored in the buffer, referring to the network designation table, confirm the network to which the signal is transmitted from the address of the transmission source device, and based on the confirmed communication protocol of the network A control unit for processing the signal,
A data memory unit for storing a signal processed by the control unit for each network through which the signal is transmitted;
Equipped with a,
The buffer is common to the plurality of network processing units, and the data received by each of the plurality of network processing units is stored in the buffer in the order received, including the transmission source address. A monitoring control device characterized by that. In claim 1,
The control unit generates a signal to be transmitted to each of the networks, temporarily stores the generated signal in the buffer,
A monitoring control apparatus, wherein the signal temporarily stored in the buffer is transmitted to a network processing unit corresponding to a network serving as a transmission destination, and then transmitted to the network. In claim 2,
A first network processing unit connected to a lower network that communicates with the equipment, and a second network processing unit connected to an upper network that communicates with a management server that remotely monitors and controls the equipment. And
When the first network processing unit receives a monitoring signal indicating an operation state of the equipment, the second network processing unit converts the monitoring signal into the monitoring signal after processing the monitoring signal by the control unit. While sending to the management server
When the second network processing unit receives a control signal for controlling a facility device, the control signal is processed by the control unit and then transmitted from the first network processing unit to the target facility device. A monitoring and control device characterized by:

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