KR101515603B1 - Plant network system - Google Patents

Abstract

The present invention relates to a plant network system which comprises: a plurality of field nodes installed to a plant facility to investigate the status of the plant facility and transmit investigated data based on an IP address through wireless local area network; one or more field network gateway to receive and transmit data sent from the field nodes; one or more backhaul field network gateways connected to a backbone network based on the IP address to convert the data received from the field network gateways into data appropriate for the backbone network, and transmit the data through the backbone network; and a plant server connected to the backbone network to receive the data from the field network gateways or the backhaul network gateways, and process, save, and analyze the received data.

Description

Plant network system [0001]

The present invention relates to a plant network system utilizing the Internet of Things (IoT) technology.

The biggest issue of plant management is to prevent accidents from occurring or to reduce them to the minimum extent possible. To do this, you need to quickly and easily communicate the plant facilities and process status to your personnel and help you make the right decisions.

Currently, process automation control and measurement systems such as Supervisory Control and Data Acquisition (SCAD), Distributed Control System (DCS), and Programmable Logic Controller (PLC) are widely used for safe plant operation management .

Conventional process automatic control and measurement systems are centralized, and the centralized method lacks interoperability with other systems and networks, uses specialized solutions for each company, and requires a skilled operator for operation management . Also, since the conventional process automatic control and measurement systems are based on a wired communication method, it is difficult to apply to a place where human hands are difficult to reach and maintenance cost is high.

SUMMARY OF THE INVENTION The present invention provides a plant network system that can monitor and control various safety problems that may occur in plant facilities and increase process efficiency by using plant equipment and devices composed of IoT will be.

According to another aspect of the present invention, there is provided a plant network system. The plant network system has a unique IP address, a plurality of field nodes installed in the plant facility to grasp the state of the plant facility and transmit information obtained through the short-range wireless communication based on the IP address, a unique IP address At least one field network gateway for receiving and transmitting information transmitted from the plurality of field nodes, having a unique IP address, connected to a backbone network based on an IP address, and received from the at least one field network gateway At least one backhaul network gateway connected to the backbone network, the at least one backbone network gateway transmitting data from the at least one field network gateway or the at least one backhaul network gateway to the at least one backhaul network gateway, Receiving information Processing the received information, a storage, analysis plant servers.

According to another aspect of the present invention, there is provided a plant network system. The plant network system has a unique IP address, a plurality of field nodes installed in the plant facility to grasp the state of the plant facility and transmit information obtained through the short-range wireless communication based on the IP address, a unique IP address At least one field network gateway connected to a backbone network based on an IP address, for receiving information transmitted from the plurality of field nodes, converting the received information into data corresponding to the backbone network, and transmitting the data through the backbone network, And a plant server connected to the backbone network and receiving information from the at least one field network gateway and processing, storing, and analyzing the received information.

In the above, the state of the plant facility is temperature, humidity, flow rate, pressure, valve position, conductivity, bending degree, noxious gas detection, tilt degree,

Wherein the plurality of field nodes and the at least one field network gateway form a field network, wherein the plurality of field nodes form at least one network in the form of a mesh topology or a star topology, The one field network gateway manages one network formed by the plurality of field nodes.

The plurality of field nodes use one of industrial protocols such as ISA100.11a, Wireless HART (Universal Asynchronous Receiver Transmitter), Profibus, Fieldbus, etc. as a stack.

Wherein one of the plurality of field nodes is installed in a box curvert and transmits information on the temperature and the water level of the box culvert to the field network gateway together with its own IP address, Is connected to the valve drain port, and transmits information on whether or not the valve drain port is out of gas to the field network gateway together with its IP address, and the other field node is installed in the buried pipe, To the field network gateway with its own IP address, and another field node is installed in the piping rack to measure at least one of vibration, inclination, member deformation, and wind direction velocity And transmits the measured result information to the field network gateway together with its own IP address.

Wherein the at least one field network gateway has a function of preferentially transmitting higher priority information based on a priority among information received from the plurality of field nodes, Lt; RTI ID = 0.0 > information < / RTI >

According to the embodiment of the present invention, not only a simple plant automation control system but also a plant optimization and an accident prediction service through real-time monitoring data can be performed, and all the devices, systems and applications in the plant can be linked with the Internet, Make it instantly visible.

1 is a configuration diagram of a plant network system according to a first embodiment of the present invention.
2 is a configuration diagram of a plant network system according to a second embodiment of the present invention.
3 is a configuration diagram of a plant network system according to a third embodiment of the present invention.
4 is a block diagram of a field network gateway according to an embodiment of the present invention.
5 is a block diagram of a backhaul network gateway according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Now, a plant network system according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a configuration diagram of a plant network system according to a first embodiment of the present invention. 1, the plant network system according to the first embodiment of the present invention includes a plurality of field nodes (FD) 100, at least one field network gateway (FNG) 200, At least one backhaul network gateway (BNG) 300, and a plant server 400.

Each of the plurality of field nodes 100 is attached to various types of plant equipment, plant equipment, and infrastructure equipment (e.g., pipe racks) to identify conditions such as temperature, humidity, flow rate, pressure, valve position, conductivity, And transmits the information to the field network gateway 200 through short-range wireless communication. Hereinafter, various types of plant equipment, plant equipment, and infrastructure equipment are collectively referred to as plant facilities.

At this time, the area where the field node 100 is installed, that is, the plant area, exceeds the short-range wireless communication range, so that the plurality of field nodes 100 form a network in the form of a mesh type topology or star topology. A field node (that is, a legacy field node) 100 constituting a legacy network is included in a plurality of field nodes 100 when an existing network, i.e., a legacy network, exists in the plant facility.

At least one mesh topology formed by a plurality of field nodes 100, or a network in the form of a star portal, and / or a legacy network. A field node having a distance from the field network gateway 200 to a field network gateway 200 out of a plurality of field nodes 100 forming a network transmits information to the field network gateway 200 using another field node connected to the network Or receive.

In the case of transmitting and receiving information using another field node connected to the network, the plant server 400 should be able to identify the information sender and the plant server 400 should be able to identify the information receiver. In addition, for systematic and smooth plant management, it is necessary to be able to identify the location where the field node 100 is installed and the type of the plant facility. For this purpose, each field node 100 has a unique IP (Internet Protocol) address as identification information for identifying a location and / or a type of equipment, and is connected to a neighboring field node based on an IP address, And is connected to the network gateway 200 to perform information transmission. Various industrial protocols such as ISA100.11a, Wireless HART (Universal Asynchronous Receiver Transmitter), Profibus, and Fieldbus can be applied to the stack of the field node 100 at this time.

Here, a brief example of a plant facility and its use in which the field node 100 is installed will be described.

The field node 100 is installed in a box curvert. If steam piping passes through the box culvert, water may rush inside the box culvert due to rain, which can affect the mixture moving rapidly through other piping and piping. Therefore, the field node 100 installed in the box culvert has a sensor capable of measuring water temperature, water level, and the like, and transmits information about water temperature and water level measured by the sensor to the field network gateway 200 together with its own IP address send.

The field node 100 is installed in the valve drain port, and detects whether or not the noxious gas leaks through the valve drain port. The field node 100 installed in the valve drain port has a gas sensing sensor for sensing a small amount of gas and transmits information about the gas outflow measured by the sensor to the field network gateway 200 together with its own IP address . The field node 100 is installed in the buried pipe to diagnose the degree of corrosion of the buried pipe. The field node 100 measures a potential difference by applying a current to the buried pipeline, and determines the degree of corrosion and the degree of corrosion according to the potential difference, and transmits it to the field network gateway 200 together with its own IP address.

The field node 100 is installed in the piping rack. The field node installed in the piping rack measures and measures vibrations, inclination, member deformation, wind direction velocity, and the like, and transmits the measured information to the field network gateway 200 together with the IP address do. In this case, one field node 100 can measure vibration, inclination, member deformation, wind direction velocity, and the like. However, the field node for measuring vibration, the field node for measuring inclination, the field node for measuring member deformation, And a field node for measuring the flow rate of the fuel.

Each of the field network gateways 200 has a unique IP address and includes a plurality of field nodes 100 (including legacy field nodes) forming a network (e.g., a mesh network, a star network, a legacy network, And an application layer for transferring information between the field node 100 (including a legacy field node) and the plant server 400 between the backhaul network gateway 300 and the backhaul network gateway 300. That is, the field network gateway 200 transmits the information transmitted from each field node 100 to the backhaul network gateway 300 or the plant server 400 and receives information from the backhaul network gateway 300 or the plant server 400 (Including the IP address of the field node) to the corresponding field node 100.

Hereinafter, the field network gateway 200 will be described in more detail with reference to FIG. 4 is a block diagram of a field network gateway according to an embodiment of the present invention. 4, the field network gateway 200 according to the embodiment of the present invention includes a first communication unit 210a, a second communication unit 210b, a control unit 220, a data processing unit 230, a power source unit 240 And a storage unit 260, and may further include a transmission control unit 250.

The first communication unit 210a has a unique first IP address and enables data transmission / reception with the field node 100 through short-range wireless communication with the field node 100. [ The first communication unit uses one of protocols such as ISA100.11a, Wireless HART (Universal Asynchronous Receiver Transmitter), Profibus, Fieldbus, and Wi-Fi.

The second communication unit 210b has a unique first IP address and enables data transmission / reception with the backhaul network gateway 300. [ The second communication unit 210b uses one of WLAN, high speed downlink packet access (HSDPA), long term evolution (LTE) protocol, RS-232 protocol, and RS485 protocol.

The third communication unit 210c has a unique first IP address and connects to the backbone network to enable data transmission / reception with the plant server 400. [ The third communication unit 210c uses one of WLAN, HSDPA, LTE and Ethernet protocols.

The control unit 220 controls the overall operation of the field network gateway 200 and the data processing unit 230 temporarily stores the data received from the field nodes 100 in the storage unit 260, To the protocol of the backhaul network or to the data of the protocol conforming to the backbone network so as to be transmitted to the backhaul network gateway 300 or the plant server 400. [

The power supply unit 240 supplies power to each configuration of the field network gateway 200. The storage unit 260 stores information received from each field node 100 temporarily or stores information required by the field network gateway 200.

The transmission control unit 250 allows priority information to be preferentially transmitted based on the priority among the information received from the field node 100. [ At this time, the priority information is recorded in the information transmitted from the field node 100, i.e., the data field in the packet. Data acquired from the plant is closely related to plant operations such as accidents, process failures, and shutdowns, so it is necessary to prioritize data transfer according to urgency.

Priority information is classified into classes 1 to N, for example, as shown in Table 1 below.

class 1 Facilities and information that need urgent action class 2 (Short) equipment requiring periodic maintenance class 3 Facilities requiring long (periodic) management  ... class N Simple data collection for the future

As shown in Table 1, class 1 has the highest priority, and the higher the number of classes, the lower the priority. c1ass1 is information of the information transmitted from the field node 100 installed in the facility where the emergency action is required or the information transmitted from the field node 100 that requires urgent action such as the detection of the contaminated gas, Load, shut down or information related to an accident and process failure).

class 2 is information transmitted from the field node 100 installed in the facility that manages in a short time period, class 3 is the information transmitted from the field node 100 installed in the facility managing the long time period, The lower class N is information that is not currently used but is to be used in the future among the information transmitted from the field node 100.

The field network is formed by at least one field network gateway (200) and a plurality of field nodes (100).

The backhaul network gateway 300 has a unique IP address and transmits information received from the field network gateway 200 to the plant server 400 or transmits information received from the plant server 400 to the field network gateway 200 ). One backhaul network gateway 300 takes charge of one field network gateway 200 or a plurality of field network gateways 200. If there are a plurality of backhaul network gateways 300, each backhaul network gateway 300 is connected to each other to form a backhaul network.

The backhaul network gateway 300 will now be described in more detail with reference to FIG. 5 is a block diagram of a backhaul network gateway according to an embodiment of the present invention. 5, the backhaul network gateway 300 includes a field network communication unit 310, a backhaul network communication unit 320, a plant communication unit 330, a control unit 340, a data management unit 350, a power supply unit 360, And includes a driver 370 and a storage unit 380.

The field network communication unit 310 has a unique second IP address and enables data transmission / reception with the field network gateway 200. The field network communication unit 310 uses one of protocols such as ISA100.11a, Wireless HART (Universal Asynchronous Receiver Transmitter), Profibus, Fieldbus, Wi-Fi, and the like.

The backhaul network communication unit 320 has a unique second IP address and enables data transmission / reception with another backhaul network gateway forming a backhaul network. The backhaul network communication unit 320 uses, for example, one of WLAN, HSDPA and LTE protocols.

The plant communication unit 330 has a unique second IP address and connects to the backbone network to enable data transmission / reception with the plant server 400. The plant communication unit 330 uses one of WLAN, HSDPA, LTE, and Ethernet protocols.

The control unit 340 controls each configuration of the backhaul network gateway 300 to control the overall operation of the backhaul network gateway 300.

The data management unit 350 converts the data received from the field network gateway 200 and provides the data to the plant server 400. The data management unit 350 converts the data received from the plant server 400 and transmits the converted data to the field node 200 through the field network gateway 200. [ (100). The data management unit 350 enables data compatibility between the protocol used by the field network communication unit 310 and the protocol used by the backhaul network communication unit 320. Here, the field network may be composed of a plurality of networks, and each of the plurality of networks may use a different protocol. The data management unit 350 performs data conversion corresponding to these different types of protocols.

The power supply unit 360 supplies power to each configuration of the backhaul network gateway 300. The driver 370 is a serial communication module that converts an output signal into a serial signal and transmits the serial signal to one of the communication units 310 to 330, for example, a USART (Unversal Synchronous and Asynchronous serial Receiver and Transmitter). The storage unit 380 stores information received from each field network gateway 200 temporarily or stores information required by the backhaul network gateway 300.

Finally, the plant server 400 processes, stores, analyzes information received from the field network or backhaul network, and controls each field node 100. The plant server 400 may be one or a plurality of plant servers. The plant server 400 provides not only a mobile device but also a CCTV, a vehicle, a tag carried by a person, navigation, and the like to provide a plant service required by the corresponding device. That is, the plant server 400 uses the information received from the field network (i.e., the field node and the field network gateway) and the backhaul network (i.e., the backhaul network gateway) to manage plant assets, worker location management, , Data forecasting / analysis, and device control management. The results of these activities are communicated through communication with mobile devices, CCTV, vehicles, navigation, and tags to provide asset tracking services, plant operations and worker management services, real- Real-time video image management service, data analysis and accident prediction service.

Hereinafter, a plant network system according to a second embodiment of the present invention will be described with reference to FIG. 2 is a configuration diagram of a plant network system according to a second embodiment of the present invention.

2, the plant network system according to the second embodiment of the present invention includes a plurality of field nodes (FDs) 100, at least one field network gateway 200 and a plant server 400, .

The plant network system according to the second embodiment of the present invention is configured not to use the backhaul network gateway 300 but to directly transmit data to and receive data from the plant server 400 by connecting to the backbone network at the field network gate 200 . Accordingly, the field network gateway 200 does not have the second communication unit 210b that performs communication with the backhaul network gateway 300. [

Hereinafter, a plant network system according to a third embodiment of the present invention will be described with reference to FIG. 3 is a configuration diagram of a plant network system according to a third embodiment of the present invention.

3, the plant network system according to the third embodiment of the present invention includes a plurality of field nodes (FD) 100, a field network gateway 200, and a plant server 400 .

The plant network system according to the third embodiment of the present invention can not manage the entire field nodes 100 installed in the plant area using one field network gateway 200 without using the backhaul network gateway 300, And is different from the first and second embodiments of the invention.

In other words, data is transmitted / received to / from the plant server 400 by directly connecting to the backbone network in the field network gate 200, and management of two or more networks (subnetworks) formed by the plurality of field nodes 100 )do.

The embodiments of the present invention described above are not only implemented by the apparatus and method but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, The embodiments can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

100: field node 200: field network gateway
300: Backhaul network gateway 400: Plant server
210a to 210c: first to third communication units 220 and 340:
230: data processing section 240, 360: power source section
250: transmission control unit 260, 380:
310 field network communication unit 320 backhaul network communication unit
330: Plant communication unit 350: Data management unit
370: Driver

Claims (8)

A plurality of field nodes having a unique IP address and installed in a plant facility to grasp the status of the plant facility and transmit information obtained through the short range wireless communication based on the IP address,
At least one field network gateway having a unique IP address for receiving and transmitting information transmitted from the plurality of field nodes,
At least one backhaul network having a unique IP address and being connected to a backbone network based on an IP address to convert information received from the at least one field network gateway into data corresponding to a backbone network, Gateway, and
And a plant server connected to the backbone network and receiving information from the at least one field network gateway or the at least one backhaul network gateway and processing, storing, and analyzing the received information,
Wherein the plurality of field nodes comprise a plurality of legacy field nodes pre-installed in the plant facility to form a legacy network. A plurality of field nodes having a unique IP address and installed in a plant facility to grasp the status of the plant facility and transmit information obtained through the short range wireless communication based on the IP address,
The IP network having a unique IP address and being connected to the backbone network based on the IP address, receiving information transmitted from the plurality of field nodes, converting the received information into data corresponding to the backbone network, One field network gateway, and
And a plant server connected to the backbone network for receiving information from the at least one field network gateway and processing, storing and analyzing the received information,
Wherein the plurality of field nodes comprise a plurality of legacy field nodes pre-installed in the plant facility to form a legacy network. 3. The method according to claim 1 or 2,
Wherein the state of the plant facility is a temperature, a humidity, a flow rate, a pressure, a valve position, a conductivity, a bending degree, a noxious gas detection, a tilt degree, and a corrosion degree. 3. The method according to claim 1 or 2,
Wherein the plurality of field nodes and the at least one field network gateway form a field network, wherein the plurality of field nodes form at least one network in the form of a mesh topology or a star topology, And one network formed by the plurality of field nodes. 5. The method of claim 4,
Wherein the plurality of field nodes use one of industrial protocols such as ISA100.11a, Wireless HART (Universal Asynchronous Receiver Transmitter), Profibus, Fieldbus, etc. as the stack. The method of claim 5,
Wherein one of the plurality of field nodes is installed in a box curvert and transmits information on the temperature and the water level of the box culvert to the field network gateway together with its own IP address, Is connected to the valve drain port, and transmits information on whether or not the valve drain port is out of gas to the field network gateway together with its IP address, and the other field node is installed in the buried pipe, To the field network gateway with its own IP address, and another field node is installed in the piping rack to measure at least one of vibration, inclination, member deformation, and wind direction velocity And transmits the measured information to the field network gateway together with its own IP address. System. 3. The method according to claim 1 or 2,
Wherein the at least one field network gateway has a function of preferentially transmitting higher priority information based on a priority among information received from the plurality of field nodes, Lt; RTI ID = 0.0 > of: < / RTI > delete

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