KR20180006128A - Remote monitoring system for generation farms, and Remote monitoring server - Google Patents

Abstract

The present invention relates to a monitoring server for monitoring a field power complex in real time. The server comprises: a communication unit for receiving state data of the field power complex from a DCS server; a database for storing abnormal situation data of the field power complex and solution data on an abnormal situation by corresponding each other; and a control unit for receiving the state data, and determining whether a situation is abnormal. The control unit extracts the solution data of the database when a situation of the field power complex is determined as the abnormal situation.

Description

[0001] The present invention relates to a remote monitoring system and a remote monitoring server,

A monitoring server for real-time monitoring of a field power plant, comprising: a communication unit for receiving state data of a field power plant from a DCS server; a database for storing abnormality data of the field power plant and solution data for an abnormal situation; And a control unit for receiving the state data and determining whether there is an abnormal situation, and the control unit extracts the solution data of the database when the field power generation complex is judged as an abnormal situation.

A power plant is a place to produce electricity, which is produced by rotating a turbine using energy sources such as water / oil / coal / natural gas / geothermal, and through a generator connected to the turbine shaft. Electricity is an indispensable being in modern society, and it is essential for human life, so power plants are important equipments in any country.

In addition, there is not only one power plant, and many of the power plants are formed into a single farm, thereby maximizing the production efficiency of electric energy. Since a power plant will generate electricity by bundling multiple power plants into a single plant, the power plant should include an integrated monitoring server to control multiple power plants.

In particular, the technology to install and operate a power plant is a technology with advanced know-how in developed countries, and it is not possible to install and operate a power plant in a country where electricity is rapidly needed, such as in developing countries. Therefore, in advanced countries, power plants are installed and operated in developing countries instead of seeking to profit from the costs.

In this case, it is not necessary to monitor a power plant or a power plant installed in a developing country near a power plant, and it is possible to remotely control the power plant in a country where the power plant is installed It is possible to efficiently manage and diagnose the power generation plant in which the power plant and the power plant are installed.

Referring to FIG. 1, a conventional power generation complex remote monitoring system is described. The location and operational data of the power generation complex including a plurality of power plants can be collected by a power plant server and transmitted to a data collection server and transmitted to the monitoring server through the personal server.

However, systems and methods for real-time monitoring of power plants and power generation complexes between countries and countries have the disadvantage of not being able to quickly deliver disturbances and accidents to managers and engineers in the event of a failure or abnormal situation in a power plant installed overseas There is a need to quickly recognize and take action when a fault occurs or an abnormal situation occurs.

On the other hand, in the case of the conventional monitoring method, monitoring was performed by a method of inquiring data in a data collection server installed in a power plant. In this case, since the amount of operation data of the power plant transmitted and received between the data collection server and the remote monitoring server collecting data at the power plant is limited, the monitored operation data of the power plant is processed and converted into a standard suitable for the remote monitoring server Respectively. There is a problem that there is a limitation in monitoring detailed information required by the remote monitoring server and specific state information of the power plant.

On the other hand, in the case of large-scale power plant EPC projects, the project will go through a period of 30 to 40 months with a large scale (about a trillion won). In the case of a power plant, if the construction period is advanced, the power generation period can be pulled, so that the profit from the power generation will increase, and if the construction period is delayed, there will be a disruption in the electric power production, Therefore, it is very important for the contractor to carry out the construction and commissioning in the designated goal in the case of the contractor, because the delayed payment per day is charged to the contractor over the target period, and the delayed payment per day is about 1 billion won do. In particular, when a power plant is constructed overseas, it takes a lot of time and cost, so it is difficult to strictly observe the progress period.

On the other hand, the commissioning process is carried out after the construction. In the construction, the commissioning phase starts without any margin due to various reasons such as the change of the drawing, the delay of the material transportation, heavy rains. In the commissioning, It becomes very important when considering. Such commissioning is highly dependent on experience, and if a commissioning problem occurs, the technical commissioning expert is dispatched to the field as an advisor to proceed with trouble shooting.

As described above, the present invention provides a power generation complex remote monitoring system in which, when the monitoring server and the power generation complex are located at different places, the monitoring server can monitor concrete state information of the power plant in real time after remote connection to the data collection server .

The technical problem to be solved by the present invention is not limited to the above-mentioned technical problems, and various technical problems can be included within the scope of what is well known to a person skilled in the art from the following description.

According to an aspect of the present invention, there is provided a monitoring server for real-time monitoring of a field power plant, comprising: a communication unit for receiving state data of a field power plant from a DCS server; And a control unit for receiving the state data and determining whether there is an abnormal situation, wherein the control unit determines that the field power generation complex is abnormal , And extracts the solution data of the database.

In addition, the remote monitoring server according to an embodiment of the present invention is characterized in that, when the controller generates an abnormal situation in the DCS server, the controller updates the abnormal occurrence data in the database.

In the remote monitoring server according to an embodiment of the present invention, when the abnormal situation occurs, the control unit checks whether there is an abnormal situation stored in the database.

In addition, the remote monitoring server according to an embodiment of the present invention is characterized in that when the abnormal situation occurs, the controller analyzes an abnormal situation and extracts an optimal problem solving expert from a database.

At this time, the remote monitoring server according to an embodiment of the present invention may be configured such that the control unit determines at least one of a current project schedule status of the DCS server, a equipment status of the field power generation complex, a problem solving expert list stored in the database, And extracts by considering any one of them.

In addition, the remote monitoring server according to an embodiment of the present invention is characterized in that the control unit transmits the user terminal information of the problem solving expert to the DCS server to authenticate the connection of the user terminal to the DCS server .

According to an aspect of the present invention, there is provided a remote monitoring system for real-time monitoring of a field power generation complex, comprising: a DCS server for acquiring state data of a field power generation complex; A DCS firewall allowing only an authenticated connection among external connections attempting to connect to the DCS server, and a monitoring server for monitoring the DCS server in real time from outside, wherein the DCS server and the monitoring server are connected to a VPN (Virtual Private Network) .

The power generation complex remote monitoring system according to an embodiment of the present invention further includes a router connecting the network between the DCS server and the monitoring server.

At this time, the power generation complex remote monitoring system according to an embodiment of the present invention is characterized in that only the authenticated connection is allowed during the external connection in which the router is connected to the DCS server.

In addition, the power generation complex remote monitoring system according to an embodiment of the present invention further includes a first VPN terminal connected to the monitoring server side, and a second VPN terminal connected to the DCS server side.

Further, the power generation complex remote monitoring system according to an embodiment of the present invention is characterized in that the DCS server allows remote control of the monitoring server when the monitoring server succeeds in connecting to the DCS server .

Further, the power generation complex remote monitoring system according to an embodiment of the present invention is characterized in that the DCS firewall registers an address of a port connectable to the DCS server.

At this time, the power generation complex remote monitoring system according to an embodiment of the present invention is characterized in that the DCS firewall includes at least one of an IP address, a subnet mask address, and a default gateway address for each port.

In addition, the power generation complex remote monitoring system according to an embodiment of the present invention compares the external connection address with the address of the stored port when the DCS firewall attempts external connection to the DCS server. .

In addition, the power plant remote monitoring system according to an embodiment of the present invention is characterized in that the field power plant includes at least two field generators, and the plant remote monitoring system is connected to the field generators, And further comprising:

At this time, the power generation complex remote monitoring system according to an embodiment of the present invention is characterized in that the DCS server acquires state data for each of the two or more field generators.

In addition, the power generation complex remote monitoring system according to an embodiment of the present invention is characterized in that the monitoring server includes a database storing data related to the DCS server.

The power generation complex remote monitoring system of the present invention monitors a specific state information of a power plant in real time by remote accessing a DCS server installed on the site and a monitoring server for remotely monitoring the power generation complex by VPN connection.

Further, the power generation complex remote monitoring system of the present invention further includes a router, and allows only authenticated connections using the security function built in the router. In addition, the DCS firewall is used to protect the DCS server and, as a result, double security is used to prevent unauthorized external connections.

In addition, the power generation complex remote monitoring system of the present invention enables a manager to monitor the operation state of a power plant at a remote place in real time without having to visit a local area when a power plant is installed overseas or at a remote place, The recovery time can be shortened by prompt response.

Further, since the power generation complex remote monitoring system of the present invention can easily check the operation history of the engine and the power generation facility from a remote place, it is easy to grasp the cause of the malfunction of the engine and the power generation facility, .

Further, in the power generation complex remote monitoring system of the present invention, when an abnormal situation occurs in the test run phase, similar cases are extracted from the database and information for cause and solution of the abnormal situation is promptly provided to the field trial operator, You can connect the best experts. At this time, the power generation complex remote monitoring system categorizes similar cases and assigns weights to confirm similarity.

Further, the power generation complex remote monitoring system of the present invention can receive the solution to the abnormal situation to the extracted expert, and can remotely receive the TA to solve the problem. Thus, time and cost savings can be achieved through quick and complete troubleshooting.

FIG. 1 is a view showing the configuration of a power generation complex remote monitoring system of the prior art.
2 is a schematic diagram of a power generation complex remote monitoring system according to the present invention.
3 is a block diagram of a remote monitoring server of the power generation complex remote monitoring system of the present invention.
4 is a configuration diagram showing a method for causing a remote monitoring server of the present invention to solve a problem when an abnormal situation occurs.
Fig. 5 is a view showing the configuration of the power generation complex remote monitoring system of the present invention.
6 is a security function of a DCS firewall among power generation complex remote monitoring systems of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a 'remote monitoring system and remote monitoring server' according to the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention. In addition, the matters described in the attached drawings may be different from those actually implemented by the schematic drawings to easily describe the embodiments of the present invention.

In the meantime, each constituent unit described below is only an example for implementing the present invention. Thus, in other implementations of the present invention, other components may be used without departing from the spirit and scope of the present invention.

Also, the expression " comprising " is intended to merely denote that such elements are present as an expression of " open ", and should not be understood to exclude additional elements.

Also, the expressions such as 'first, second', etc. are used only to distinguish between plural configurations, and do not limit the order or other features among the configurations.

In the description of the embodiments, it is to be understood that each layer (film), area, pattern or structure may be referred to as being "on" or "under / under" Quot; includes all that is formed directly or through another layer. The criteria for top / bottom or bottom / bottom of each layer are described with reference to the drawings.

 When a part is "connected" to another part, it includes not only "directly connected" but also "indirectly connected" with another part in between. Also, when an element is referred to as "comprising ", it means that it can include other elements, not excluding other elements unless specifically stated otherwise.

2 is a schematic diagram of a power generation complex remote monitoring system according to the present invention.

Referring to FIG. 2, the power generation complex remote monitoring system 100 of the present invention includes a DCS server 110, a DCS firewall 120, and a monitoring server 130 as a remote monitoring system for real- can do.

The DCS server 110 may obtain status data of the field power plant. Since the power generation complex remote monitoring system of the present invention aggregates various state data generated from a plurality of power plants included in the power generation complex and transmits them to the DCS server, it is possible to maintain / repair the entire power generation complex by monitoring the DCS server from the outside . Therefore, if an abnormal situation occurs or a fault occurs in the power generation complex, it is possible to take real-time measures by monitoring the state data stored in the DCS server from the outside.

In particular, the DCS server can optimize the installation efficiency and maintenance and management of the data center, and can be a general data device capable of storing and browsing data such as CPU, RAM, storage device, and computing device. Such a DCS server is a necessary device when constructing and constructing a power plant.

DCS firewall 120 may only allow authenticated connections of external connections attempting to connect to the DCS server. Firewalls are installed to prevent and isolate network security incidents or problems, to block illegal traffic from outside, and to allow only authorized and authenticated traffic. Therefore, it is possible to perform a role of distinguishing one computer system (server) from the external system, and even if the connection from the outside is restricted, the danger zone can be reduced and it can be an effective security measure.

Also, the DCS firewall of the present invention can be connected to the DCS server through a hub. In particular, the DCS firewall is installed in a DCS server in a program format, so that external traffic connecting to the DCS server can be selected and only valid access can be granted.

In addition, the DCS firewall of the present invention can register an address of a port connectable to the DCS server. Referring to FIG. 4, the DCS firewall of the present invention can set security on a firewall based on a MAC address of communication modules of a DCS server. Therefore, it is possible to allow only access by a specific address among external accesses connected to the DCS server, and it is possible to monitor the specific power plant status of the DCS server from the outside. In addition, a port of a hub connected to the DCS firewall can also be assigned an address, thereby allowing an external connection to connect the address.

At this time, the DCS firewall of the present invention may include at least one of an IP address, a subnet mask address, and a default gateway address for each port. The IP address corresponds to a unique number identifying a device connected to the Internet, and may be implemented in various forms such as IPv4. The subnet mask corresponds to a notation that distinguishes subnetworks and can be used to precisely identify network zones. To further distinguish between IP addresses, you can set and use a subnet mask address.

Referring to FIG. 4, various addresses are stored and registered in the DCS firewall for each port. For example, the DCS firewall can store various addresses such as IP address 175.204.102.xxx, subnet mask address 255.255.255.xxx, and default gateway address 175.204.102.xxx for each port.

In addition, the DCS firewall of the present invention can allow external access only when the external connection is attempted by comparing the address of the port with the external connection address and authenticated. For example, when an external connection corresponding to the IP address 175.204.102.xxx is accessed, the DCS firewall of the present invention is judged as a legitimate external connection, and then the external connection is permitted.

The monitoring server 140 allows the DCS server to be monitored in real time from outside. Referring to FIG. 3, the power generation complex remote monitoring system of the present invention can be connected to a DCS server through the Internet at DCs located in various places. As described above, since the power generation plant and the externally connected server are physically located at a remote place, various devices for security are required between the monitoring server and the DCS server.

The monitoring server of the present invention connects to the DCS server and directly monitors and monitors the current status of the DCS server. Conventionally, there is a limitation in monitoring specific state information of a power plant by only inquiring data from a DCS server. However, the power generation complex remote monitoring system of the present invention connects a site and a monitoring site and performs remote access to the DCS server Specific status information of the power plant can be monitored in real time. However, if the monitoring server authenticates that it is an external access suitable for the DCS server, the monitoring server is allowed to remote control the monitoring server when the monitoring server successfully connects to the DCS server. Therefore, after remotely accessing the site DCS server through the Internet, the operation trend of the power plant is analyzed, and the control logic is reviewed, so that experts located at the head office can support the operation of the site in real time.

Also, the monitoring server of the present invention can be applied to field trial operation. However, the monitoring server of the present invention can improve the quality of on-site commissioning by performing real-time trial-and-error (Trouble Shooting). In addition, Communication costs and errors can be reduced. At the headquarters, experts and expert apprentices can also monitor and direct the monitoring server, so it is possible to cultivate the property by expanding indirect experience of trial operation.

The DCS server and the monitoring server of the present invention are connected to a VPN (Virtual Private Network). VPN (Virtual Private Network) is a system that enables private network to be used as a dedicated network for users. It allows the group to define its own network configuration and build up an arbitrary system. In particular, the VPN uses a service that provides a special communication system and a cryptographic technique, so that it will have the same effect as installing the private network while using the general network in the Internet communication between the head office, the branch office, . VPN has advantages such as user's mobility guarantee and convenient network configuration, and transmits / receives data through public network, so it transmits / receives data by using encryption / decryption method of data.

Further, the power generation complex remote monitoring system of the present invention may further include a first VPN terminal connected to the monitoring server side and a second VPN terminal connected to the DCS server side. A VPN function router that can be used for VPN communication is required for VPN communication that connects the first point and the second point to each other. Therefore, the power generation complex remote monitoring system of the present invention includes a DCS server and a monitoring server, .

Meanwhile, the power generation complex remote monitoring system of the present invention may further include a router connecting a network between the DCS server and the monitoring server. A router is a device that relays different networks. It reads the destination address from the transmission information, designates the most appropriate communication path, and transmits it to another communication network. It is a device that is essential for connecting a local area network to a wide area network or connecting the Internet.

Such a router may include security functions as well as relay functions which are functions of the present invention. More specifically, the router may only allow authorized connections of external connections to the DCS server. Accordingly, the power generation complex remote monitoring system of the present invention can establish a dual security system by allowing an authenticated connection by a router as well as a DCS firewall. Therefore, even if any one of the router or the DCS firewall is broken by the hacking, the other security device can prevent the access.

FIG. 3 is a configuration of a remote monitoring server of the power generation complex remote monitoring system of the present invention, and FIG. 4 is a configuration diagram illustrating a method of causing a remote monitoring server of the present invention to solve a problem when an abnormal situation occurs.

Referring to FIG. 3, the monitoring server of the power generation complex remote monitoring system of the present invention may include a database storing data related to the DCS server. When an abnormal situation occurs in the DCS server, the history stored in the database can be referred to for quick response in the future.

The monitoring server 140 of the present invention may include a communication unit 141, a database 142, and a controller 143. The communication unit receives the state data of the field power generation complex from the DCS server. In addition, the database stores the abnormal situation data of the field power plant and the solution data corresponding to the abnormal situation. When the control unit receives the status data and determines whether or not it is abnormal, it extracts the solution data of the database.

More specifically, the power generation complex remote monitoring system of the present invention enables the field generator and the expert located on the ground to deal with the abnormal situation of the field generator. At this time, when the DCS server that detects the state data of the field generators detects the abnormal state, the monitoring server of the present invention updates the abnormal state occurrence data to the database. At this time, the monitoring server stores the abnormality occurrence data and the solution data corresponding to the abnormal situation in the database, and confirms whether or not there is abnormality stored in the database when the abnormality occurs.

At this time, the database of the present invention can categorize and catalog various issues that have arisen by trial operation in a conventional project. At this time, the categorized information can be classified into a problem occurrence symptom, a cause of occurrence of a problem, a processing result, an input cost and a time.

More specifically, the database of the present invention includes project information such as a power generation type (ex. Thermal power or combined power), generating capacity (ex: 600MW, 800MW, 1000MW), boiler type (pulverized coal boiler, down shot boiler, ), Types of turbines (two or more turbines, types 3 and 4, regenerative turbines), types of BOP (balance of plant, heat exchanger, deaerator, condenser, etc.).

In addition, the database of the present invention may include information on a problem occurrence device, a commissioning step, a problem occurrence symptom, and the like as the commissioning abnormal situation information. The commissioning problem solving information may include a cause of the trouble, a processing result, And the like.

In addition, the database unit of the present invention can extract the type of an abnormal situation that is closest to the cause of occurrence when the status data is received. At this time, if there is a case where the problem is solved successfully for the abnormal situation, the case can be extracted as the most optimal solution and the expert who solved the case can be extracted.

On the other hand, when an abnormal situation occurs, the monitoring server of the present invention analyzes an abnormal situation and extracts an optimum problem solving expert from the database. Especially, in the case of construction and commissioning of the power plant, the project period is specified, and in case of problems in the project, it should be dealt with quickly. This means that if the project can not be completed within the specified deadline, it will have to pay a large amount of penalty.

The monitoring server of the present invention can quickly analyze an abnormal situation and then extract an optimal problem solving expert from a database, thereby enabling quick problem solving as compared with the prior art.

For example, if an abnormal situation occurs during the commissioning of a project, the commissioner of the site inputs the commissioning abnormality information through his or her PC or mobile, and the information is combined with the project information entered in DCS at the site, To the monitoring server. In the monitoring server, the information is matched with case-by-case project information and trial-and-error information in the existing database and listed up in order of relevance, and the result is transmitted to the PC or mobile terminal of the field trial operator. At this time, when matching the test abnormal condition information, the matching with high accuracy is induced by changing the weight for each category, and the weight can be designated by the expert or the trial operator in advance.

The commissioner receives the list, identifies cases similar to the problems occurring in the field trial run, and quickly identifies the cause of the anomaly through the cause of the problem in the case. In addition, the commissioner can obtain information on how to solve the problem through the process result. In addition, the commissioner can set up an optimal process management plan through information such as manpower, cost, and period for problem solving.

In addition, the commissioner can additionally receive not only the case list transmitted from the monitoring server but also the case manager information of each case and the commissioning expert information of the corresponding field, and the commissioner of the field can receive the corresponding expert To request a Technical Advisor (TA).

When the commissioner selects a specialist and requests a TA, the monitoring server delivers the project information, the information on the commissioning and the real-time monitoring information, etc. received by the expert's mobile terminal or PC, and the expert who receives the information It is possible to transmit advice for solving the abnormal phenomenon through its own mobile terminal or PC and real-time communication such as remote control is possible.

In particular, the monitoring server of the present invention can extract at least one of the current project schedule status of the DCS server, the equipment status of the field power plant, the list of problem solving experts stored in the database, and the fitness of the abnormal situation. Since the DCS server receives various status data of the field power plant, it can collect various state information such as the degree of thermal power received by the DCS server, the power generation capacity, the turbine type, the duration and progress of the project, And the most appropriate problem solving expert list is extracted.

For example, if the degree of firepower is excessively low in the event of an abnormal situation, the monitoring server of the present invention matches the firepower experts stored in the database and transmits the status to the user terminal of the firepower expert. The thermal experts can diagnose the abnormal situation of the field power plant which has fallen by the user terminal at the user terminal, write a solution to solve the abnormal situation, instruct the engineer located on the site, and solve the problem quickly.

At this time, the monitoring server of the present invention transmits the user terminal information of the problem solving expert to the DCS information to authenticate the connection of the user terminal to the DCS server. If the user terminal of the extracted expert is not allowed to authenticate to the DCS server, the monitoring server of the present invention requests the user terminal to connect to the DCS server for quick problem resolution. The DCS server confirms the expert user terminal and permits the connection. In particular, the expert user terminal directly accesses the DCS server of the present invention, monitors and remotely controls the DCS server, thereby enabling faster problem solving.

Meanwhile, the database of the present invention may include a first database unit for storing abnormal situation data and state data of a power plant, and a second database unit for storing expert personnel and employee information. In this case, the first database unit and the second database unit may be implemented as hardware and transmit / receive data through software, and the first database unit and the second database unit may be implemented by different hardware.

Meanwhile, the field power plant of the power generation complex remote monitoring system of the present invention may include at least two field power generators, and may further include an EWS device connected to each of the field generators to establish a network connection. At this time, the DCS server may obtain state data for each of the two or more field generators.

Referring to FIG. 6, the field power plant may include a plurality of field generators, and each field generator is connected to an EWS device. The EWS device collects and regulates data for each generator, and can have respective gateway addresses and IP addresses. When connecting from outside through a user terminal or a computing device, each IP is assigned to access the IP and gateway of the EWS device. The DCS firewall compares the IP address of the EWS device with the IP address of the user terminal, respectively, so that remote access is possible only when the connection is appropriate.

The embodiments of the present invention described above are disclosed for the purpose of illustration, and the present invention is not limited thereto. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention.

100: Power generation complex remote monitoring system
110: Power generation complex
120: DCS server
130: DCS firewall
140: Monitoring Server
141:
142: Database
143:
150: Ideal situation solving expert

Claims (17)

A monitoring server for real-time monitoring of a field power generation complex,
A communication unit for receiving status data of the field power plant from the DCS server;
A database for storing abnormality data of the field power plant and solution data for abnormality situations;
A controller receiving the status data and determining whether the status data is abnormal;
Lt; / RTI >
Wherein the control unit extracts the solution data of the database when determining that the field power generation complex is an abnormal situation.
The method according to claim 1,
Wherein,
And updates the abnormal situation occurrence data in the database when an abnormal situation occurs in the DCS server.
The method according to claim 1,
Wherein,
And if the abnormal situation occurs, checking whether there is an abnormal situation stored in the database.
The method according to claim 1,
Wherein,
When the abnormal situation occurs, the abnormal situation is analyzed to extract the optimum problem solving expert from the database
Features include a remote monitoring server.
5. The method of claim 4,
Wherein,
Wherein at least one of the current project schedule status of the DCS server, the equipment status of the field power plant, the list of problem solving experts stored in the database, and the fitness of the abnormal situation are taken into consideration.
5. The method of claim 4,
Wherein,
And transmits the user terminal information of the problem solving expert to the DCS server to authenticate the connection of the user terminal to the DCS server.
A remote monitoring system for real-time monitoring of a field power generation complex,
A DCS server for acquiring state data of the field power plant;
A DCS firewall that allows only authenticated connections of external connections attempting to connect to the DCS server;
A monitoring server for monitoring the DCS server in real time;
Lt; / RTI >
Wherein the DCS server and the monitoring server are connected to a VPN (Virtual Private Network).
8. The method of claim 7,
A router connecting a network between the DCS server and the monitoring server;
Further comprising a remote monitoring system.
9. The method of claim 8,
The router includes:
Wherein only authorized connections are allowed during an external connection to the DCS server.
8. The method of claim 7,
A first VPN terminal connected to the monitoring server side;
A second VPN terminal connected to the DCS server;
Further comprising a remote monitoring system.
8. The method of claim 7,
The DCS server,
Wherein the monitoring server permits remote control of the monitoring server when the monitoring server succeeds in connecting to the DCS server.
8. The method of claim 7,
The DCS firewall,
And registers an address of a port connectable to the DCS server.
13. The method of claim 12,
The DCS firewall,
Wherein the network includes at least one of an IP address, a subnet mask address, and a default gateway address for each port.
13. The method of claim 12,
The DCS firewall,
Wherein when the external connection is attempted to the DCS server, the external connection is allowed only when the external connection address is compared with the address of the stored port.
8. The method of claim 7,
Wherein the field power plant includes at least two field generators,
The power plant remote monitoring system comprises:
An EWS device connected to the field generator and connected to the network;
Further comprising a remote monitoring system.
16. The method of claim 15,
The DCS server,
And obtains status data for each of the at least two on-site generators.
The method according to claim 1,
The monitoring server comprises:
A database for storing data associated with the DCS server;
Wherein the remote monitoring system comprises a remote monitoring system.

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