KR101552785B1 - real time monitoring system self-healing way and system - Google Patents

Abstract

The present invention relates to an automatic restoration system for real-time monitoring, and more particularly, A surveillance & reboot system unit for receiving power from the power source to monitor in real time, determining if a failure or an error occurs, and rebooting; A monitoring unit receiving power from the power source and displaying real-time data collection and utilization of collected data for monitoring the operation of the ship in an efficient manner; And a general equipment unit for transmitting information to the monitoring unit in real time, wherein the data transmission status is checked and controlled between the server and the client.
An automatic restoration system and method for a real-time monitoring system continuously checks the state of communication with a server by an operation program at a client end, and transmits data on whether the data communication success or failure between the server and the client is failed by a real-time monitoring and rebooting controller. Based on this data, the monitoring & rebooting system unit can manage the power of the monitoring unit.

Description

Technical Field [0001] The present invention relates to an automatic recovery method and system for a real-time monitoring system,

The present invention relates to an automatic recovery method and system for a real-time monitoring system, and more particularly, to an automatic recovery system that controls a power unit of a monitoring unit by checking the data transmission state between a server and a client in real time.

Also, the present invention relates to an automatic restoration system and method for a real-time monitoring system in which a controller of a monitor & reboot system unit performs reloading of a monitoring unit in the event of a data processing trouble, and the system of the monitoring unit re- .

Manufacturers, such as ships, consider how to operate properly under efficient planning in production. To do this, real-time data collection of various systems related to manufacturing and utilization of collected data should be well done. First, a real-time monitoring system is required for data collection and the measured data must be transmitted to the server reliably through communication.

 The various equipment in the ship should be transmitted to the server as a client, the measurement data should be continuously transmitted over a certain period of time, and the server should receive and process necessary data for each system for planning, results, judgment and prediction. Various real-time monitoring systems are developed and applied to industrial sites in accordance with various equipment and systems.

Large-scale real-time monitoring systems can lead to an increase in communication data between server and client, and many systems are overloaded and decentralized, resulting in various errors. In particular, it is important to recover the lost communication data due to a sudden drop of the client elements to a minimum time for bringing additional effects to the related system.

However, it is inefficient for management to manage clients on a one-to-one basis, with distributed client systems scattered across a wide range of production sites. Continuous monitoring of clients on the server and on- It takes a human part.

The monitoring system of these manufacturing industries has a lot of emphasis on safety through field test and construction and operation, so additional monitoring and restoration systems are insufficient and additional components for automation management are needed.

Accordingly, various problems arise, such as an increase in communication data due to the expansion of the system, an increase in management factors through system identification, and a quick response in case of an accident.

As the size of the system increases and the number of objects to be monitored increases, communication data between the server and the client increases, and there are factors causing overload and error while processing various data. In order to prevent such an overload, it is necessary to construct a plurality of further improved systems, thereby generating additional economic factors.

In addition, in managing the monitoring systems distributed in various workplaces, an additional factor of inefficiency arises ineffective management part.

If both the server and the client have a problem with the device itself, they are first rebooted and reloaded. In this post-management, the server side can be checked by continuous monitoring and alarm through IDC operation. The processing of the client's confirmation and action takes an excessive amount of time to lose data and return to the system, which also results in a loss due to economic factors in the manufacturing industry. In addition, there are many ineffective factors to be manually handled in many cases, such as returning to the actual site only by rebooting the additional system.

Korean Registered Patent No. 10-2010-002456 (Fault restoration system and method of financial automation equipment: disclosed on September 27, 2011) Korean Registered Patent No. 10-2013-0039828 (Remote Management System of Intelligent Equipment with Network Automatic Recovery Function: Registered on Mar. 13, 2013)

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above problems, and it is an automatic recovery system by controlling the power source of the client terminal by checking the data transmission state between the server and the client in real time.

In addition, the controller of the real-time monitoring & rebooting system unit is related to an automatic restoration system and method for a real-time monitoring system for rebooting the monitoring system by automatically rebooting the down phenomenon caused by an overload of the client system.

In order to achieve the above object, the present invention includes a power supply unit for supplying power, a monitoring & rebooting system unit for receiving power from the power supply, monitoring in real time, determining if a failure or an error occurs, and rebooting

And a monitoring unit for displaying real-time data collection and utilization of the collected data through monitor for efficiently managing operation of the ship by receiving power from the power source, and a general equipment unit for transmitting information to the monitoring unit in real time .

The monitoring and rebooting system includes a relay switch A and a relay switch B that receive and transmit signals from the monitoring unit and includes a controller for receiving a signal of the two relay switches and transmitting a reboot signal of the program.

The monitoring unit includes a measurement system for receiving signals from the power supply unit and measuring signals and errors of the general equipment, an operation program for supplying and receiving signals to and receiving power from the relay switch A, And a communication module included for communication between the general equipment and the monitoring and rebooting system.

In addition, the failure and error condition includes one of a case where abnormal communication is received, a case where communication is unsuccessful, and a case where communication can not be received for a certain period of time in the communication from the monitoring to the controller.

In addition, the operating program of the monitoring unit continuously checks whether the data communication state is successful or not between the general server unit and the monitoring unit, and transmits the data to the controller unit.

A first step of controlling a power of an operating program and a communication module of the monitoring unit by using a relay switch A and a relay switch B, And a second step of rebooting the communication module through the control of the controller when an error occurs.

A third step of rebooting the operating program when an error occurs even after rebooting the communication module of the monitoring unit; and a fourth step of transmitting alarm information to the IDC when an error occurs after the rebooting operation.

Also, when performing the reboot operation of the communication module, when an error occurs, the relay module switches the relay switch B to '0' to turn off the communication module, store the value of B = 0 to BB = B, And rebooting.

,

When an error occurs even after a reboot of the communication module, the operating program turns the relay switch A to a value of '0', turns off the operating program, stores AA = 0 in AA = A, And reboots the operating program.

The automatic restoration method and system for the real-time monitoring system according to the present invention continuously checks the communication state with the server and the data transmission between the server and the client is performed by the monitoring and rebooting controller unit. According to this data, the monitoring & rebooting system unit can manage the power of the monitoring unit.

Also, the data received from the operating program is effective to control the power of the client operating PC, the operating program, and the communication module through the controller.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is an internal block diagram of an automatic recovery method and system for a real-time monitoring system in accordance with an embodiment of the present invention.
2 is a block diagram illustrating a configuration of a communication module and a relay switch B of an automatic restoration method and system for a real-time monitoring system according to an embodiment of the present invention.
3 is a block diagram of an automatic recovery method for a real-time monitoring system according to an embodiment of the present invention, and a configuration of an operating program and a relay switch A of the system.
FIG. 4 is a flowchart illustrating an automatic restoration method and system for automatically performing real-time monitoring and rebooting for a real-time monitoring system of the present invention. FIG.
5 is a block diagram of an automatic recovery system for a real-time monitoring system of the present invention and an automatic recovery system for a system.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an internal block diagram of an automatic restoration method and system for a real-time monitoring system according to an embodiment of the present invention.

1, an automatic restoration method for a real-time monitoring system according to the present invention includes a power supply unit 100 for supplying power, a monitoring & rebooting system unit 200, a monitoring unit 300, a general equipment unit 400, .

The power supply unit 100 is a power supply unit 100 installed at the time of manufacturing a ship and supplies power to a monitoring and rebooting system unit 200, a monitoring unit 300, and a LV equipment unit 400 .

The monitoring and rebooting system unit 200 monitors and reboots the general equipment 400 and the monitoring unit 300 and includes a controller 210, a relay switch A 220 and a relay switch B 230 .

The controller 210 has a feature of processing a signal received from the monitoring unit 300. The controller 210 is included in the monitoring & rebooting system unit 200, monitors the error occurring in the monitoring unit 300, determines whether there is a reboot, and executes rebooting.

The relay switch A 220 and the relay switch B 230 provide a signal to the controller 210 and receive the signal transmitted from the controller 210 to the monitoring unit 300. The relay switch A 220 and the relay switch B 230 connected to the controller 210 are included in the monitoring & rebooting system unit 200.

The monitoring and rebooting system unit 200 includes a relay switch A 220, a relay switch B 230 and a controller 210. The controller 210 checks the delayed time to determine whether or not each time And periodically receives a signal. In this case, when the periodically transmitted signal is disconnected, or an error such as an abnormal signal interval or an abnormal signal transmission occurs, the monitoring unit 300 sends an error of the general equipment 400 to the relay switch B 230 as a signal do. The signal sent from the relay switch B 230 is transmitted to the controller 210 and the controller 210 checks the signal and reboots the communication module 330 of the monitoring unit 300.

Also, when the error is re-transmitted in the above process, the controller 210 transmits a signal to the controller 210 through the relay switch A 220, and the controller 210 checks the signal to check the operation program 320 of the monitoring unit 300 Reboot.

The monitoring unit 300 includes a measurement system 310, an operation program 320, and a communication module 330.

The measurement system 310 is coupled to the power supply unit 100 and receives power from the power supply unit 100. The measurement system 310 receives signals in real time from the general equipment unit 400 and displays the signals on a monitor.

The operation program 320 is connected to the relay switch A 220 of the monitoring & rebooting system unit 200 and is operated by being supplied with or receiving a signal. The operation program 320 provides a signal received from the general facility 400 to the relay switch A 220 and receives a signal from the controller 210 to perform a power reboot.

The communication module 330 is connected to the relay switch B 230 of the monitoring & rebooting system unit 200 and is supplied with or supplied with a signal. The communication module 330 provides a signal received from the general facility 400 to the relay switch B 230 and receives a signal from the controller 210 to perform power rebooting.

The monitoring unit 300 receives a signal from the general equipment unit 400, measures it through the measurement program 310, displays it on a monitor, and transmits a signal to the relay switch A 220 through the operation program 320 And transmits and receives a signal to the relay switch B 230 through the communication module 330 to process whether or not the power source is rebooted.

Also, the automatic restoration system and method for the real-time monitoring system includes a general facility 400. [ The general equipment part 400 is used by receiving power from the power source part 100 and is connected to the monitoring part 300.

The general equipment part 400 is a remaining part of the ship except for the power supply part 100, the monitoring part 300 and the surveillance & rebooting part 200, as well as equipment and systems connected to the monitoring part 300 .

The general equipment part 400 includes a schematic equipment and a system of a ship, is operated by receiving power, and periodically transmits a signal from the monitoring part 300. The signal transmitted from the general equipment unit 400 can be confirmed by using the measurement system 310 of the monitoring unit 400. When an error occurs in the general equipment unit 400, the monitoring unit 300 detects the error, .

The controller 210 continuously monitors the communication state of the general equipment 400 and performs real-time monitoring and rebooting by using the operating program unit 320 and the communication module unit 330 of the monitoring unit 300 Data transmission between the server and the client is confirmed as to whether or not the data communication is successful. In accordance with such data, the controller 220 manages the power of the monitoring unit 300.

FIG. 2 is a block diagram illustrating a configuration of a communication module and a relay switch B of an automatic restoration method and system for a real-time monitoring system according to an embodiment of the present invention. FIG. 3 is a block diagram of a real- time monitoring system according to an embodiment of the present invention. And an operating program of the system and a configuration of a relay switch A. FIG.

2 and 3, the monitoring and rebooting system unit 200 includes a controller 210, a relay switch A 220, and a relay switch B 230.

The relay switch A and the relay switch B are respectively comprised of 0 terminal 1 terminal, 4 terminal, and 6 terminal.

The terminal of the relay switch A is composed of a relay switch A 0 terminal 221, a relay switch A 1 terminal 222, a relay switch A 4 terminal 223 and a relay switch A 6 terminal 224.

The relay switch A 0 terminal 221 and the relay switch A 1 terminal 222 are connected to the controller 210 to transmit a signal to the controller 210. The relay switch A 4 terminal 223 is connected to the power supply unit 100 and the relay switch A 6 terminal 224 is connected to the operating program 320 receiving or providing a signal.

Accordingly, the relay switch A is operated by receiving power from the power supply unit 100 to the relay switch A 4 terminal 223. At this time, a signal is received and sent from the operation program 320 through the relay switch A 6 terminal 224, and the signal is received or sent to the controller through the relay switch A 0 terminal 221 and the relay switch A 1 terminal 222 .

 The terminal of the relay switch B is composed of a relay switch B 0 terminal 231, a relay switch B 1 terminal 232, a relay switch B 4 terminal 233 and a relay switch B 6 terminal 234.

The relay switch B 0 terminal 231 and the relay switch B 1 terminal 232 are connected to the controller 210 to transmit a signal to the controller 210. The relay switch B 4 terminal 233 is connected to the power supply unit 100 and the relay switch B 6 terminal 234 is connected to the communication module 330 receiving or providing a signal.

Accordingly, the relay switch B is operated by receiving power from the power supply unit 100 to the relay switch B 4 terminal 233. At this time, a signal is received and sent from the communication module 330 through the relay switch B 6 terminal 234 and is received or sent to the controller through the relay switch B 0 terminal 231 and the relay switch B 1 terminal 232 .

An embodiment of the automatic restoration method for the real-time monitoring subsystem of the present invention will be described with reference to FIG. 4 and FIG.

FIG. 4 is a flowchart illustrating an algorithm for automatically performing real-time monitoring and rebooting through an automatic restoration method and system for the real-time monitoring system of the present invention. FIG. 5 is a flowchart illustrating an automatic restoration method and system for a real- FIG. 2 is a block diagram of an automatic restoration system for use with the present invention.

When the use is started for the first time, the monitoring & rebooting system unit 200 has communication confirmation data A, B "1 ". At this time, A, B "1" is the value which shows the simultaneous value of relay switch A and relay switch B as "1". At this time, the delay value of the relay switch AA "1", the relay switch BB "1", the relay switch A "1" and the relay switch B "1" are additionally provided.

 After the setting, the relay switch A 220 and the relay switch B 230 are connected to the relay switch A 0 terminal 221, the relay switch A 1 terminal 222, the relay switch B 0 terminal 231, the relay switch B 1 terminal 232 Is turned on. A relay switch A 4 terminal 223, a relay switch A 6 terminal 224, a relay switch B 4 terminal 233 and a relay switch B 6 terminal 234 of a relay switch A 220 and a relay switch B 230, . The communication module 330, the operating PC, and the operating program 220 are turned on.

According to the result, the communication confirmation data value is initialized and the communication is successful. When the communication is successful, the communication confirmation data value is initialized again, and communication is performed. If the initialization of communication confirmation data value fails, the delay is set

At this time, the delay setting switches relay switch B, which is communication confirmation data, to a value of "0" to turn off relay switch B 0 terminal 231, relay switch B 1 terminal 232, relay switch B 4 terminal 233, Relay switch B 6 terminal (234) and communication module turn off.

The above data is stored as BB = B and BB = 0, and then generated as communication confirmation data B "1". At this time, the relay switch B 0 terminal 231 and the relay switch B 1 terminal 232 are turned on and the relay switch B 4 terminal 233 and the relay switch B 6 terminal 234 are turned on and the communication module unit 330 is rebooted .

When the communication is successful in the above operation, the communication confirmation data value is initialized, and B = 1 is continued and BB = 1 is set to be the communication again.

If communication is not established, the delay is set again.

When the delay is set and data is received, relay switch A "0", which is communication confirmation data, is provided.

At this time, the relay switch A "0" turns off the communication connection relay switch A 0 terminal 221 and the relay switch A 1 terminal 222 of the monitoring & rebooting system unit 200 and at the same time the relay switch A 4 terminal 223, The switch A 6 terminal 224 is turned off and the communication module unit 330 is turned off.

Next, the communication confirmation data is stored with the communication confirmation data value as AA = A and AA = 0 value.

And changes to the relay switch A "1" which is communication confirmation data, and reboots the operating program 320. [

At this time, the relay switch A "1" turns on the communication connection relay switch A 0 terminal 221 and the relay switch A 1 terminal 222 of the monitoring & rebooting system unit 200 and at the same time turns on the relay switch A 4 terminal 223, The switch A 6 terminal 224 is turned on and the operating PC is turned on.

Next, the communication confirmation data is set. If the communication is successful, the data is set again and the state of the relay switch A, which is the initial operation, is returned to the state of A = 1 continuous AA = 1.

At this time, the state of relay switch B is switched to B = 1 and BB = 1. So the initialization is the same as the first.

However, if communication is not established even though the loop is executed by using relay switch B and relay switch A, keep communication confirmation data AA = 0 and check dictionary BB = 0 value. AA & BB = So as to take measures.

100: Power supply unit 200: Monitoring & rebooting system part
300: monitoring unit 400: general equipment
210: controller 220: relay switch A
230: Relay switch B 310: Measurement system
320: operating program 330: communication module
221: Relay switch A 0 Terminal 222: Relay switch A 1 Terminal
223: Relay switch A 4 Terminal 224: Relay switch A 6 terminal
231: Relay switch B 0 terminal 232: Relay switch B 1 terminal
233: Relay switch B 4 Terminal 234: Relay switch B 6 terminal

Claims (9)

A power supply unit for supplying power;
A surveillance & reboot system unit for receiving power from the power source to monitor in real time, determining if a failure or an error occurs, and rebooting;
A monitoring unit that receives power from the power source and displays real-time data for efficient operation management of the ship and utilization of collected data through monitoring;
And a general equipment unit for transmitting information to the monitoring unit in real time,
The monitoring unit includes a measurement system unit receiving power from the power source unit and measuring a signal and an error of the general equipment unit, an operation program unit for supplying and receiving signals to and receiving a signal from the relay switch A and re- And a communications module included for communicating signals between the general facility and the monitoring and rebooting system.
The method according to claim 1,
Wherein the monitoring &
And a relay switch (A) and a relay switch (B) that receive and transmit signals from the monitoring unit;
And a controller for receiving a signal of the two relay switch units and transmitting a reboot signal of the program.
3. The method of claim 2,
The relay switch (A)
A relay switch A 0 terminal and a relay switch A 1 terminal connected to the controller to transmit and receive signals;
A relay switch A 4 terminal connected to the power supply unit to supply power;
And a relay switch A 6 terminal connected to the operating program unit to receive and transmit a signal.
3. The method of claim 2,
The relay switch B,
A relay switch B 0 terminal and a relay switch B 1 terminal connected to the controller to transmit and receive signals;
A relay switch B 4 terminal connected to the power supply unit to supply power;
And a relay switch B 6 terminal connected to the communication module for receiving and transmitting signals.
delete The method according to claim 1,
Wherein the failure and error condition includes one of a case where an abnormal communication signal is received, a case in which communication is unsuccessful, and a case in which communication is not received for a predetermined period of time in the transmission of the communication from the monitoring to the controller System for real - time monitoring system.
An automatic restoration method for a real-time monitoring system and a method for rebooting through a controller of a monitoring & rebooting system part,
A first step of controlling the power of the operating program and the communication module of the monitoring unit by using the relay switch A and the relay switch B as communication signals received from the operating program;
A second step of causing the monitoring unit to reboot the communication module through control of the controller when an error occurs;
A third step of rebooting the operating program when an error occurs even after the communication module of the monitoring unit is rebooted; And
And a fourth step of transmitting alarm information to the IDC when an error occurs after the step of rebooting the operating program.
The method of claim 7,
In the step of rebooting the communication module, when an error occurs, the communication module is turned off by switching the relay switch B to '0', the value of B = 0 is stored in BB = B, Wherein the automatic restoration method for a real-time monitoring system is performed.
The method of claim 7,
When an error occurs even after rebooting the communication module, the operation program is turned off by switching the relay switch A to a value of '0', the AA = 0 value is stored in AA = A, And re-booting the operating program. ≪ RTI ID = 0.0 > 11. < / RTI >

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