JP2012198841A - Field network system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a field network system in which a PLC and an I/O input/output unit are connected through a field network and energy conservation is achieved.SOLUTION: A field network system 100 of the present invention includes: a PLC 1; and an I/O input/output unit 2 connected to the PLC 1 through a field network 11 and to which field equipment 4 is connected. The PLC 1 transmits an electric power operation signal to the I/O input/output unit 2, and the I/O input/output unit 2 performs on/off control of an electric supply source in the I/O input/output unit 2 according to the electric power operation signal.

Description

  The present invention relates to a field network system including a programmable logic controller and an I / O input / output unit connected to the programmable logic controller via a field network.

  Monitoring and control systems such as instrumentation are installed in factories and plants. The monitoring control system employs a method in which an I / O input / output unit and a programmable logic controller are arranged in a concentrated manner in an electrical room or the like and wired. Here, input / output connections with a number of field devices are made in the I / O input / output unit. The programmable logic controller controls input / output signals to / from field devices via the I / O input / output unit.

  Further, in recent years, a shift from the above method to a method in which only a programmable controller is installed in an electrical room and an I / O input / output unit is installed near a field device (so-called wiring-saving method) is progressing. In the wire-saving method, the programmable logic controller and the I / O input / output unit are connected via a field network. The programmable logic controller and the I / O input / output unit communicate with each other by transmission using a digital communication protocol.

  FIG. 5 shows a schematic configuration of a field network system according to the wire-saving method.

  As shown in FIG. 5, a programmable logic controller (hereinafter referred to as PLC) 1 and an I / O input / output unit 2 are communicably connected via a field network 11 (where I / O input is connected). On the output unit 2 side, the field network 11 is connected to the terminal section 12). Further, the field device 4 is directly connected to the terminal portion 16 disposed in the I / O input / output unit 2.

  Further, a controller power source 5 for operating the PLC 1 is connected to the PLC 1. On the other hand, on the I / O input / output unit 2 side, the terminal unit 14 is connected to the I / O unit power source 6, and the terminal unit 19 is connected to the field device power source 7.

  The I / O unit power supply 6 operates the I / O input / output unit 2 (more specifically, the I / O unit power supply 6 is disposed in the I / O input / output unit 2 and is connected to each other via the bus 20. Circuit 8, I / O circuit 9, and internal circuit CPU 10. The field device power supply 7 is a power source for operating the field device 4, and the power is supplied to the field device 4 via the I / O input / output unit 2.

  In the configuration shown in FIG. 5, the signal from the field device 4 is transmitted to the PLC 1 via the I / O input / output unit 2 and the field network 11, and the PLC 1 transmits the data transmitted from the field device 4 and the own device. A control signal is generated using a set program. Then, the PLC 1 transmits the control signal to the field device 4 via the field network 11 and the I / O input / output unit 2. The field device 4 performs measurement and control operation based on the control signal.

  In the field network system shown in FIG. 5, it is necessary to install a plurality of power supplies 5, 6, and 7. Thus, for example, as in Patent Document 1, an apparatus that can connect a field device to a field network without increasing the equipment cost and work load has been proposed.

JP 2002-124997 A

  The technique shown in FIG. 5 has a problem that power must be constantly supplied to the I / O input / output unit 2 and the field device 4 while a monitoring control system such as instrumentation is operating. It was.

  Therefore, an object of the present invention is to provide a field network system capable of saving energy in a field network system in which a PLC and an I / O input / output unit are connected via a field network.

  In order to achieve the above object, a field network system according to the present invention includes a controller, and an I / O unit connected to the controller via the field network and connected to a field device, The controller transmits a power operation signal to the I / O unit, and the I / O unit controls on / off of the power supply in the I / O unit according to the power operation signal.

  A field network system according to the present invention includes a controller and an I / O unit connected to the controller via a field network and connected to a field device. The controller is connected to the I / O unit. In response to the power operation signal, the I / O unit controls on / off of the power supply in the I / O unit according to the power operation signal.

  Therefore, on / off of the power supply to the I / O unit and the field device can be controlled by the signal from the controller in accordance with the operation state of the plant or facility. Thereby, in the field network system according to the present invention, energy saving can be achieved.

1 is a diagram showing a schematic configuration of a field network system 100 according to the present invention. 2 is a block diagram illustrating an internal configuration of an I / O input / output unit 2 according to Embodiment 1. FIG. 3 is a block diagram showing an internal processing function of the I / O input / output unit 2 according to Embodiment 1. FIG. It is a figure which shows the conceptual structure of the field network transmission information 31 which concerns on Embodiment 2. FIG. It is a block diagram which shows schematic structure of the field network system which concerns on a wiring-saving system.

  Hereinafter, the present invention will be specifically described with reference to the drawings showing embodiments thereof.

<Embodiment 1>
FIG. 1 is a diagram showing a schematic configuration of a field network system 100 according to the present invention.

  As shown in FIG. 1, a field network system 100 includes a PLC (programmable logic controller) 1, a plurality of I / O input / output units 2, a plurality of field devices 4, a controller power supply 5, and a plurality of I / O unit power supplies 5. , And a plurality of field device power supplies 7. The field network system 100 is installed in a factory or the like for instrumentation purposes.

  The PLC 1 is installed on a distribution board in an electrical room, each field device 4 is installed at each site in the factory, and each I / O input / output unit 2 is installed at each site near the field device 4. The PLC 1 and each I / O input / output unit 2 are connected via a field network 11, and bidirectional communication using a predetermined protocol is performed between the PLC 1 and each I / O input / output unit 2. Is done.

  A controller power supply 5 is connected to the PLC 1. Accordingly, the PLC 1 is driven by receiving power from the controller power supply 5.

  Each I / O input / output unit 2 is connected to an I / O unit power source 6 and a field device power source 7. Each I / O input / output unit 2 is driven by receiving power from an I / O unit power supply 6 connected to the I / O input / output unit 2. Each I / O input / output unit 2 is connected to at least one field device 4 disposed nearby. Each field device 4 supplies power from the field device power supply 7 connected to the I / O input / output unit 2 via the I / O input / output unit 2 to which the field device 4 is connected. To drive.

  Here, the controller power supply 5 and the I / O unit power supply 6 each supply power of about 100V. On the other hand, the field device power supply 7 supplies power of about 24V.

  A predetermined measurement operation, a predetermined control operation, and the like are performed at each field device 4 and each site in the factory. Data output from the field device 4 is transmitted to the PLC 1 via the I / O input / output unit 2 and the field network 11. The PLC 1 manages data transmitted from the field device 4 and generates a predetermined control signal using the data and a program set in the own device 1. Then, the PLC 1 outputs this control signal to a predetermined field device 4. The control signal is transmitted to the predetermined field device 4 via the field network 11 and the predetermined I / O input / output unit 2, and the predetermined field device 4 that has received the control signal receives a predetermined signal according to the control signal. A measurement operation or a predetermined control operation is executed.

  FIG. 2 and FIG. 3 are diagrams showing an internal schematic configuration of each I / O input / output unit 2. FIG. 2 is a diagram showing a state of the power supply in the I / O input / output unit 2. On the other hand, FIG. 3 is a diagram showing internal processing functions in the I / O input / output unit 2.

  Here, each of the plurality of I / O input / output units 2 has the same internal configuration as the configuration shown in FIGS. 2 and 3, and performs the same operation as that described later.

  As shown in FIG. 3, a communication circuit 8, an I / O circuit 9, and an internal circuit CPU 10 are disposed in the I / O input / output unit 2. The communication circuit 8, the I / O circuit 9 and the internal circuit CPU 10 are connected to each other via the internal bus 20. As a result, the I / O circuit 9 and the internal circuit CPU 10 can communicate with each other via the internal bus 20.

  The internal circuit CPU 10 obtains information from each field device 4 via the internal bus 20 and the I / O circuit 9. In the internal circuit CPU 10, the information obtained from the field device 4 is converted into field network data and written to the communication circuit 8 via the internal bus 20. The communication circuit 8 transmits the written data to the field network 11 connected to the terminal unit 12 based on a predetermined communication protocol.

  The communication circuit 8 also has a function of writing information output from the PLC 1 via the field network 11 to the internal circuit CPU 10 via the internal bus 20. In the internal circuit CPU 10, the information obtained from the PLC 1 is converted into field device data and written to the I / O circuit 9 via the internal bus 20. The I / O circuit 9 transmits the written data to the field device 4 connected to the terminal unit 16.

  As shown in FIG. 2, the I / O input / output unit 2 is provided with a plurality of terminal portions 12, 14, 16, and 19. The communication circuit 8 is connected to the field network 11 via the terminal unit 12. The terminal unit 14 is connected to the I / O unit power source 6, and the terminal unit 19 is directly connected to the field device power source 7. Further, each terminal unit 16 is connected to the field device 4.

  As shown in FIG. 2, a switch 21 is provided in the I / O input / output unit 2, and is connected to the I / O input / output unit 2 in the I / O circuit 9. Corresponding to the field devices 4, switches 23 are respectively provided.

  The switch 21 controls on / off of a power supply supplied to a circuit disposed in the I / O input / output unit 2. Specifically, as can be seen from FIG. 2, when the switch 21 is in the ON state, the communication circuit 8, the I / O circuit 9, and the internal circuit CPU 10 are each connected to the I / O unit power supply 6. Supply power is supplied via the terminal portion 14. On the other hand, as can be seen from FIG. 2, when the switch 21 is in the OFF state, the supply power from the I / O unit power supply 6 is supplied to the communication circuit 8 only through the terminal portion 14. . That is, the power supplied from the I / O unit power supply 6 to the I / O circuit 9 and the internal circuit CPU 10 is supplied via the switch 21 (note that the I / O unit power supply 6 to the communication circuit 8 is supplied from the I / O unit power supply 6. Is supplied without going through the switch 21). Therefore, when the switch 21 is in the OFF state, the supply power from the I / O unit power supply 6 is not supplied to each of the I / O circuit 9 and the internal circuit CPU10.

  The ON / OFF control of the switch 21 is performed according to a power supply operation signal transmitted from the PLC 1. Specifically, the communication circuit 8 in the I / O input / output unit 2 receives the power operation signal. The communication circuit 8 controls on / off of the power supply supplied to the circuits 9 and 10 disposed in the I / O input / output unit 2 in accordance with the received power operation signal (that is, the switch 21 A control signal (which controls ON / OFF) is transmitted to the switch 21. According to the control signal, ON / OFF switching of the switch 21 is performed.

  Here, as described above, even if the switch 21 is switched ON / OFF, the power supplied from the I / O unit power supply 9 is always supplied to the communication circuit 8. That is, the communication circuit 8 follows the power supply operation signal with respect to its own circuit (that is, the communication circuit 8 provided in the I / O input / output unit 2 for controlling communication with the PLC 1). Does not control on / off of the power supply. Thereby, the I / O input / output unit 2 can continue communication with the PLC 1 even when the other internal circuits 9 and 10 are in the OFF state.

  Each switch 23 disposed in the I / O circuit 9 is supplied from the field device power supply 7 supplied to the field device 4 connected to the switch 23 in the I / O input / output unit 2. Control on / off of power supply. Specifically, as can be seen from FIG. 2, when the switch 23 is in the ON state, the supply power from the field device power supply 7 is supplied to the terminal device to the field device 4 connected to the switch 23. 19, supplied via the I / O circuit 9 and the terminal unit 16. On the other hand, as can be seen from FIG. 2, when the switch 23 is in the OFF state, the supply power from the field device power supply 7 is not supplied to the field device 4 connected to the switch 23.

  Here, when a plurality of field devices 4 are connected to one I / O input / output unit 2, a switch 23 is provided for each field device 4 (see FIG. 2). ). That is, the power supplied from the field device power supply 7 to each field device 4 is supplied via each switch 23. Therefore, depending on the ON / OFF operation of each switch 23, it becomes possible to control ON / OFF of the power supply for each field device 4 connected to the switch 23.

  The ON / OFF control of the switch 23 is performed according to a power supply operation signal transmitted from the PLC 1. Specifically, the communication circuit 8 in the I / O input / output unit 2 receives the power operation signal. Then, the communication circuit 8 controls on / off of power supplied to each field device 4 connected to the I / O input / output unit 2 in accordance with the received power operation signal (that is, ON of each switch 23). A control signal for controlling / OFF) is transmitted to each switch 23. According to the control signal, ON / OFF switching of the switch 23 is performed.

  Here, when a plurality of field devices 4 are connected to the I / O input / output unit 2, a switch 23 is provided in the I / O circuit 9 corresponding to each field device 4 as described above. Arranged. Therefore, the power supply operation signal can control the ON / OFF of the power supply for each individual field device 4 (in other words, the communication circuit 8 can control each switch 23 according to the power supply operation signal transmitted from the PLC 1. ON / OFF switching can be controlled).

  Next, the operation of the field network system 100 according to the present embodiment, that is, the operation related to the ON / OFF control of the power supply in the I / O input / output unit 2 will be described.

  First, ON / OFF control of the power supply supplied to the circuits 9 and 10 in the I / O input / output unit 2 will be described.

  In the PLC 1, schedule information related to the plant state is set in advance. It is assumed that the PLC 1 determines that the predetermined I / O input / output unit 2 does not need to be monitored or controlled based on the schedule information based on the plant state or the like.

  In this case, the PLC 1 transmits a power operation signal to the predetermined I / O input / output unit 2 via the field network 11. Here, the power supply operation signal is a signal for requesting the power supply to the circuits 9 and 10 disposed in a predetermined I / O input / output unit 2 to be cut off.

  Then, the communication circuit 8 receives the power operation signal and outputs a switch operation command signal for switching off to the switch 21. Here, the communication circuit 8 directly transmits a switch operation command signal to the switch 21 without going through the internal circuit CPU10.

  The switch 21 that has received the switch operation command signal shifts to the OFF state. As a result, the supply power supplied from the I / O unit power supply 6 to the I / O circuit 9 and the internal circuit CPU 10 can be disconnected inside the predetermined I / O input / output unit 2.

  Here, even if the switch 21 shifts to OFF, the power supplied from the I / O unit power supply 6 continues to be supplied to the communication circuit 8 provided in the predetermined I / O input / output unit 2. . Therefore, the communication circuit 8 can continue bidirectional communication with the PLC 1.

  Now, it is assumed that the PLC 1 determines that the predetermined I / O input / output unit 2 needs to be monitored / controlled based on the plant state or the like based on the set schedule information. In this case, the PLC 1 transmits a power operation signal to the predetermined I / O input / output unit 2 via the field network 11. Here, the power operation signal is a signal for requesting resumption of the power supply to the circuits 9 and 10 disposed inside the predetermined I / O input / output unit 2.

  Here, as described above, the communication circuit 8 is continuously supplied with power from the I / O unit power supply 6 and continues to operate. Accordingly, the communication circuit 8 receives the power supply operation signal and outputs a switch operation command signal for turning on switching to the switch 21. Here, the communication circuit 8 directly transmits a switch operation command signal to the switch 21 without going through the internal circuit CPU10.

  The switch 21 that has received the switch operation command signal shifts to the ON state. Thereby, the supply of the supply power from the I / O unit power supply 6 to the I / O circuit 9 and the internal circuit CPU 10 can be restarted inside the predetermined I / O input / output unit 2.

  Next, ON / OFF control of the power supply supplied to each field device 4 connected to the I / O input / output unit 2 will be described.

  Similarly to the above, schedule information related to the plant state is set in the PLC 1 in advance. It is assumed that the PLC 1 determines that the predetermined field device 4 connected to the predetermined I / O input / output unit 2 does not need to be monitored or controlled based on the schedule information due to the plant state or the like.

  In this case, the PLC 1 transmits a power operation signal to the predetermined I / O input / output unit 2 via the field network 11. Here, the power operation signal is a signal for requesting the power supply to the predetermined field device 4 connected to the predetermined I / O input / output unit 2 to be cut off.

  Then, the communication circuit 8 receives the power operation signal and outputs a switch operation command signal for switching off to the predetermined switch 23 that is connected to the predetermined field device 4. Here, the communication circuit 8 directly transmits a switch operation command signal to the predetermined switch 23 without going through the I / O circuit 9.

  The predetermined switch 23 that has received the switch operation command signal shifts to the OFF state. As a result, the supply power supplied from the field device power supply 7 to the predetermined field device 4 can be disconnected inside the predetermined I / O input / output unit 2.

  Here, for the other field devices 4 connected to the predetermined I / O input / output unit 2, a command to cut off the power supply is not output from the PLC 1. Therefore, the command to shift the switching to OFF is not output from the communication circuit 8 to the other switch 23 that is connected to the other field device 4.

  Now, based on the set schedule information, it is assumed that the PLC 1 determines that the predetermined field device 4 connected to the predetermined I / O input / output unit 2 needs to be monitored and controlled depending on the plant state or the like. . In this case, the PLC 1 transmits a power operation signal to the predetermined I / O input / output unit 2 via the field network 11. Here, the power operation signal is a signal for requesting resumption of power supply to a predetermined field device 4 connected to a predetermined I / O input / output unit 2.

  Then, the communication circuit 8 receives the power operation signal and outputs a switch operation command signal for turning on the switching to the predetermined switch 23 connected to the predetermined field device 4. Here, the communication circuit 8 directly transmits a switch operation command signal to the predetermined switch 23 without going through the I / O circuit 9.

  The predetermined switch 23 that has received the switch operation command signal shifts to the ON state. Thereby, the supply of the supply power from the field device power supply 7 to the predetermined field device 7 can be resumed inside the predetermined I / O input / output unit 2.

  The PLC 1 can output a power operation signal for each I / O input / output unit 2 connected to the field network 11. On the basis of the power supply operation signal, on / off of the power supply for the circuits 9 and 10 disposed in the I / O input / output unit 2 can be controlled for each I / O input / output unit 2. Further, on / off of the power supply can be controlled for each field device 4 based on the power operation signal. Here, ON / OFF control of each power supply is executed in each I / O input / output unit 2.

  As described above, in the field network system 100 according to the present embodiment, the PLC 1 transmits a power operation signal to the I / O input / output unit 2 via the field network 11. The I / O input / output unit 2 controls on / off of the power supply in the I / O input / output unit 2 in accordance with the power operation signal.

  For example, the I / O input / output unit 2 controls on / off of the power supply supplied to the circuits 9 and 10 disposed in the I / O input / output unit 2 in accordance with the power operation signal. Here, ON / OFF control of the power supply to the circuits 9 and 10 is possible for each I / O input / output unit 2.

  Therefore, the power supply to the I / O input / output unit 2 can be controlled automatically and remotely, and the I / O input / output unit 2 can save energy by reducing unnecessary power consumption when not necessary. .

  Here, the I / O input / output unit 2 does not control on / off of the power supply according to the power operation signal for the communication circuit 8 disposed in the I / O input / output unit 2.

  Therefore, even in a state where the power supply to the I / O input / output unit 2 is suppressed, the I / O input / output unit 2 can communicate with the PLC 1. Therefore, for example, the power supply to the I / O input / output unit 2 can be restarted by a power operation signal transmitted from the PLC 1.

  Further, the I / O input / output unit 2 turns on / off the power supply to the field device 4 connected to the I / O input / output unit 2 in the I / O input / output unit 2 in accordance with the power operation signal. OFF is controlled. Here, ON / OFF control of the power supply to the field device 4 is possible for each field device 4.

  Therefore, the power supply to the field device 4 can be controlled by automatic and remote operation, and unnecessary power supply other than when necessary can be reduced in each field device 4. Such power reduction can be finely controlled for each field device 4.

  Here, in each I / O input / output unit 2, the switch 21 may be in the ON state and the switch 23 may be in the ON or OFF state. However, in each I / O input / output unit 2, when the switch 21 is OFF, it is not assumed that the switch 23 is ON. That is, in each I / O input / output unit 2, when the switch 21 is in the OFF state, all the switches 23 are in the OFF state.

<Embodiment 2>
In the field network system according to the present embodiment, each I / O input / output unit 2 notifies the PLC 1 of a state confirmation signal regarding the ON / OFF state of the power supply in the I / O input / output unit. Specifically, it is as follows.

  In each I / O input / output unit 2, the internal circuit CPU 10 acquires data (hereinafter referred to as field device data) transmitted from each field device 4 connected to the I / O input / output unit 2. Then, the communication circuit 8 in the I / O input / output unit 2 outputs field network transmission information including field device data acquired by the internal circuit CPU 10 to the PLC 1.

  In the present embodiment, each I / O input / output unit 2 transmits field network transmission information including the state confirmation signal and field device data to the PLC 1. FIG. 4 is a conceptual configuration diagram of the field network transmission information 31 transmitted by each I / O input / output unit 2.

  As shown in FIG. 4, the field network transmission information 31 includes an I / O input / output unit status 32, a field device status 33, and field device data 34. It can be understood that the I / O input / output unit status 32 and the field device status 33 are the state confirmation signals.

  Here, the I / O input / output unit status 32 indicates a power supply state (ON state or OFF state) to the circuits 9 and 10 in the I / O input / output unit 2 that transmits the field network transmission information 31. In the state where the power supply to the circuits 9 and 10 in the I / O input / output unit 2 is cut off by the operation described in the first embodiment, the I / O input / output unit status 32 indicating “OFF” It is included in the network transmission information 31. On the other hand, when the power supply to the circuits 9 and 10 in the I / O input / output unit 2 is performed by the operation described in the first embodiment, the I / O input / output unit status 32 indicating “ON” is displayed. Included in the field network transmission information 31.

  The field device status 33 indicates a power supply state (ON state or OFF state) to each field device 4 connected to the I / O input / output unit 2 that transmits the field network transmission information 31. Note that there are as many field device statuses 33 in the field network transmission information 31 as there are field devices 4 connected to the I / O input / output unit 2. In the state where the power supply to the field device 4 connected to the I / O input / output unit 2 is cut off by the operation described in the first embodiment, the field device status 33 indicating “OFF” is transmitted to the field network. It is included in the information 31. On the other hand, in the state where the power supply to the field device 4 connected to the I / O input / output unit 2 is performed by the operation described in the first embodiment, the field device status 33 indicating “ON” It is included in the field network transmission information 31.

  The field device data 34 indicates data transmitted from each field device 4 connected to the I / O input / output unit 2 that transmits the field network transmission information 31. The field network transmission information 31 includes field device data 34 as many as the number of field devices 4 connected to the I / O input / output unit 2. The field device data 34 is a physical quantity such as pressure measured by the field device 4, for example.

  The I / O unit status 32 is created by the communication circuit 8 in the I / O input / output unit 2 that transmits the field network transmission information 31. The field device status 33 for each field device 4 and the field device data 34 for each field device 4 are created by the internal circuit CPU 10. The field device status 33 for each field device 4 may be created by the communication circuit 8 (for example, when the switch 21 is in the OFF state, the field device status 33 for each field device 4 is Created by the communication circuit 8).

  The field network transmission information 31 shown in FIG. 4 is created in each I / O input / output unit 2 periodically or in response to a request from the PLC 1 and transmitted to the PLC 1.

  As described above, in this embodiment, each I / O input / output unit 2 sends a status confirmation signal (in FIG. 4, I / O input / output unit status constituting field network transmission information 31 to PLC 1). 32 and field device status 33).

  The PLC 1 can confirm whether or not the power supply to the circuit 9.10 in the I / O input / output unit 2 is accurately controlled based on the power operation signal. Further, the PLC 1 can confirm whether or not the power supply to the field device 4 connected to the I / O input / output unit 2 is accurately controlled based on the power operation signal.

  In the present embodiment, each I / O input / output unit 2 transmits field network transmission information 31 having the configuration shown in FIG. Accordingly, the following determination can be made in the PLC 1.

  For example, when an abnormality occurs in each of the circuits 9 and 10, the field device data 34 included in the field network transmission information 31 indicates “abnormal”. In addition, the field device data 34 included in the field network transmission information 31 indicates “abnormal” even when the power supply to the circuits 9 and 10 is cut off by the operation described in the first embodiment. Become. Therefore, the field network transmission information 31 including the I / O unit status 32 and the field device data 34 at the same time is transmitted to the PLC 1, whereby the field device data 34 indicating “abnormal” is displayed in the PLC 1 in the first embodiment. Thus, it is possible to clearly distinguish and judge whether the power supply to the circuits 9 and 10 is cut off or the failure of the I / O input / output unit 2 itself.

  When an abnormality occurs in the field device 4, the field device data 34 included in the field network transmission information 31 indicates “abnormal”. In addition, the field device data 34 included in the field network transmission information 31 indicates “abnormal” even when the power supply to the field device 4 is cut off by the operation described in the first embodiment. . Therefore, the field network transmission information 31 including the field device status 33 and the field device data 34 at the same time is transmitted to the PLC 1, so that the field device data 34 indicating “abnormal” in the PLC 1 is the operation of the first embodiment. Thus, it is possible to clearly distinguish / determine whether the power supply to the field device 4 is caused by the disconnection or the failure of the field device 4 itself.

1 Programmable logic controller (PLC)
2 I / O input / output unit 4 Field device 5 Controller communication power supply 6 I / O unit power supply 7 Field device power supply 8 Communication circuit 9 I / O circuit 10 Internal circuit CPU
11 Field Network 12, 14, 16, 19 Terminal 20 Internal Bus 21, 23 Switch 31 Field Network Transmission Information 32 I / O Unit Status 33 Field Device Status 34 Field Device Data 100 Field Network System

Claims (8)

A controller,
An I / O unit connected to the controller via a field network and connected to a field device;
The controller is
Send a power operation signal to the I / O unit,
The I / O unit is
According to the power operation signal, on / off of the power supply is controlled in the I / O unit.
A field network system characterized by that. The I / O unit is
According to the power operation signal, to control on / off of the supply power supplied to a circuit disposed in the I / O unit;
The field network system according to claim 1. The I / O unit is
For the communication circuit that controls communication with the controller arranged in the I / O unit, the on / off of the power supply according to the power operation signal is not controlled.
The field network system according to claim 2. The field device includes
Power is supplied from the field device power source via the I / O unit.
The I / O unit is
In accordance with the power operation signal, in the I / O unit, the on / off of the supply power from the field device power supplied to the field device is controlled.
The field network system according to any one of claims 1 to 3, wherein The field device connected to the I / O unit is:
Multiple
The I / O unit is
For each field device to control on / off of the power supply;
The field network system according to claim 4. The I / O unit is
Sending a status confirmation signal regarding the on / off status of the power supply to the controller;
The field network system according to any one of claims 1 to 5, wherein The I / O unit is
Transmitting transmission information comprising the status confirmation signal and data transmitted from the field device to the controller;
The field network system according to claim 6. The I / O unit is
Multiple
The controller is
Transmitting the power operation signal for each I / O unit;
The field network system according to claim 1.

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