KR101951760B1 - monitoring method for monitoring valves - Google Patents

Abstract

The present invention includes position information, opening / closing information, and leakage information from a plurality of monitoring valve devices disposed in the piping facility of the process line so that the operator can immediately recognize the leakage state of the fluid to be transferred into the pipe to improve safety. A first step in which valve integration information is acquired; A second step in which leakage information of the acquired valve integrated information is compared with a preset reference value to extract positional information of the valve integrated information determined as a leakage state as leakage position information and an emergency guidance mode is activated; And when the emergency guidance mode is activated, a process layout diagram in which at least one of the valve position markers on the predetermined map data corresponding to the process line is matched with the extracted leakage position information is converted into an emergency guide landmark, And a third step of outputting the monitoring signal to the monitoring valve device.

Description

Monitoring method for monitoring valve devices [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a monitoring method for a monitoring valve device, and more particularly, to a monitoring method of a monitoring valve device with improved safety by promptly recognizing a leakage state of a fluid to be transferred into a pipe.

Generally, piping is provided for transferring fluids required for processes such as oxygen, nitrogen, argon, and carbonic acid to process lines in various industrial fields. At this time, the pipe is provided with a valve at a predetermined position to selectively block the fluid or adjust the flow rate.

In this case, since the worker individually confirms the opening and closing states of the valves installed in a plurality of pipes, it takes a lot of time to work and it is difficult to efficiently manage the process line.

Therefore, conventionally, sensors and actuators are installed to construct a system for integrally managing the valves of the process line. At this time, the sensor is installed in a pipe or a valve of each process line and transmits a detection signal corresponding to the flow rate of the fluid to be transferred, and the actuator is connected to a valve installed in each pipe to control the open / close state.

Accordingly, the operator can confirm the detection signal through the separate monitor device without leaving the field, and can monitor the opening / closing state of each valve installed in each pipe, or control the valve.

However, as the opening and closing member for selectively blocking the flow of the fluid in the valve is repeatedly rotated, a space is generated due to a decrease in durability, thereby causing leakage of the fluid.

Further, if the fluid to be leaked is a fluid that is fatal to the human body or can be blended with other gases or air, it may cause a serious accident.

Also, in the past, even if the operator perceives the leakage of the fluid, it is necessary to find a figure showing the position of the valve where the leakage occurs, and it takes time to confirm the accurate position, and it is difficult to immediately respond to the leakage.

Korean Patent No. 10-0498075

In order to solve the above problems, the present invention provides a method for monitoring a monitoring valve device having an improved safety by guiding an operator to immediately recognize a leakage state of a fluid conveyed in a pipe.

According to an aspect of the present invention, there is provided a method for controlling a process line, including: a first step of obtaining valve integration information including position information, opening / closing information, and leakage information from a plurality of monitoring valve devices disposed in a piping facility of a process line; A second step in which leakage information of the acquired valve integrated information is compared with a preset reference value to extract positional information of the valve integrated information determined as a leakage state as leakage position information and an emergency guidance mode is activated; And when the emergency guiding mode is activated, a plurality of valve position markers, which are classified into an open state image and a closed state image, are displayed as preset map data corresponding to the process line, and the extracted leakage position information, And a third step of generating and outputting a matched process layout diagram in which one or more matching matrices are converted into an emergency guide mark and outputting the generated process layout map through an output unit, wherein the output unit is configured to convert the emergency map marker into a blinking image, The process layout is forcibly output by a pop-up window, and the leaked elapsed time counted cumulatively over time from the first leakage information occurrence time determined as the leakage state is displayed in real time. In the first step, The positional information of the valve integrated information determined to be in an undelivered state is not received Receiving position information and extracting the received position information and activating the non-receiving guide mode, wherein when the non-receiving guide mode is activated, at least one of the valve position markers matched with the extracted non- Further comprising the step of outputting, through the output unit, the time at which the opening / closing information is received in the valve integrated information in which the process layout diagram is generated and the opening / closing information is not received, wherein the first step includes: The step of matching the positional information of the valve integrated information and outputting the process layout diagram in which the output image of the valve position mark is set according to the obtained information of opening and closing of the valve integrated information through the output section, When the command is inputted, the valve integration information corresponding to the selected valve position marker is subjected to image conversion, Wherein the valve integrated information includes information on the transported fluid to which the type of the fluid to be transferred into the piping facility in which the monitoring valve apparatus is disposed is preliminarily displayed. And a method for monitoring the valve device.

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The present invention provides the following effects through the above-mentioned solution.

First, since the monitoring terminal is provided with a real-time monitoring function for forcibly outputting the process layout diagram in which a monitoring valve device determined as a leak state is switched to an emergency guide marker to a pop-up window, the operator can check the leakage state in real time and immediately And the maintenance can be performed promptly, so that safety can be remarkably improved.

Secondly, in the process layout diagram, the leaked elapsed time counted from the first leak information occurrence time determined as the leaked state and the transferred fluid information indicating the type of fluid to be transferred are displayed, so that the operator can recognize the risk The safety can be further improved since it is possible to grasp the hazard of the fluid in advance.

Thirdly, when the opening / closing information of the monitoring valve device is not received for a predetermined time or longer, the monitoring terminal displays the process layout diagram in which the valve position marking is switched to the non-receiving guide marking, So that the efficiency of management can be further improved.

1 is a block diagram showing a monitoring system of a monitoring valve device according to an embodiment of the present invention;
2 is a flowchart illustrating a monitoring method of a monitoring valve apparatus according to an embodiment of the present invention.
3 is an exemplary view showing a process layout in which a monitoring valve device is opened or closed in a monitoring method for a monitoring valve device according to an embodiment of the present invention.
4 is an exemplary view showing a valve integrated information window of a monitoring valve device in a monitoring method for a monitoring valve device according to an embodiment of the present invention.
FIG. 5 is an exemplary view showing a process layout in a state in which a non-receiving guide mode is activated in a monitoring method of a monitoring valve device according to an embodiment of the present invention; FIG.
6 is an exemplary view showing a process layout in a state in which an emergency guidance mode is activated in a monitoring method of a monitoring valve apparatus according to an embodiment of the present invention.

Hereinafter, a monitoring method for a monitoring valve device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a monitoring system of a monitoring valve device according to an embodiment of the present invention.

1, a monitoring system 300 of a monitoring valve apparatus according to an embodiment of the present invention includes a signal receiving unit 110, a storage unit 111, an image processing unit 112, and an output unit 113, .

Here, each configuration may be included in the monitoring terminal 200, and the monitoring terminal 200 may be provided as a smart phone, a pad, a notebook, a desktop, and the like.

The monitoring system 300 of the monitoring valve device is not limited to the monitoring terminal 200 but may be connected to the monitoring terminal 200 through a monitoring valve device 100).

Here, the monitoring valve apparatus 100 may be installed in a plurality of piping facilities for transferring fluids used in process lines of various industrial fields such as mechanical, electrical, and electronic fields. At this time, the monitoring valve apparatus 100 can selectively block the flow of the fluid conveyed through the pipe, and includes an opening / closing sensor, a leakage sensor, and a signal communication unit.

Here, the opening / closing sensor transmits a sensing signal to the signal communication unit according to the opening / closing state of the opening / closing member of the monitoring valve apparatus 100. The leakage sensor senses fluid leaking from the piping in which the monitoring valve apparatus 100 is disposed, and sends a detection signal to the signal communication unit. In addition, the signal communication unit transmits a state signal including opening / closing information corresponding to a sensing signal of the input opening / closing sensor, leakage information corresponding to a sensing signal of the input leakage sensor, and input position information to the transceiver 250 send.

The transceiver 250 receives status signals from the plurality of monitoring valve devices 100 and transmits the status signals received through the wired / wireless communication network to the monitoring terminal 200.

At this time, the transceiver 250 may transmit the received status signal through long distance wireless communication such as RF communication according to the installed environment. Of course, the transceiver 250 may transmit the received status signal to the monitoring terminal 200 by wire.

Further, the transceiver 250 may be configured to transmit the received status signal to the manufacturer server (not shown) in consideration of the data size of the received status signal, the installed environment, and the like, It is possible to receive a status signal stored in a manufacturer server (not shown). Also, the monitoring terminal 200 may not receive the transceiver 250 and may receive status signals from the plurality of monitoring valve devices 100.

Meanwhile, the signal receiving unit 110 may receive a status signal from the transceiver 250 through a wired / wireless communication network. In addition, the received status signal may be stored in the storage unit 111 provided in the monitoring terminal 200.

At this time, the preset map data is stored in the storage unit 111 so as to correspond to the process line in which the plurality of monitoring valve apparatuses 100 are arranged. Here, the map data may be stored in the storage unit 111 by wired / wireless communication by an operator. Of course, if the manufacturer server (not shown) is provided, the map data may be received from the manufacturer server (not shown) through the signal receiving unit 110 and stored in the storage unit 111.

The image processing unit 112 generates the valve integration information from the stored state signal. Also, the leakage information of the valve integrated information is compared with a preset reference value, and position information of the valve integrated information determined as the leakage state is extracted and set as leakage position information. Here, the image calculation processing unit 112 sets a process layout in which one or more matched valve position markers of the stored map data are matched with the extracted leak position information, and outputs the set map to the output unit 113 do. At this time, the image processing unit 112 converts the emergency guide landing flag into a blinking image, and sets the displayed process layout to be forcibly outputted as a pop-up window.

In addition, the output unit 113 outputs a process layout diagram and various output images generated from the image processing unit 112.

The monitoring terminal 200 may further include an input unit 114. At this time, the input unit 114 may be provided with a touch panel or the like provided on the front of the output unit 113. An operator touches the valve position marker 141 displayed on the output unit 113 to select a command Can be input. Here, the image operation processing unit 112 may generate an output image corresponding to the input selection command and output the generated output image to the output unit 113.

FIG. 2 is a flowchart illustrating a monitoring method of a monitoring valve device according to an embodiment of the present invention. FIG. 3 is a flowchart illustrating a monitoring method of a monitoring valve device according to an embodiment of the present invention. FIG. 4 is an exemplary view showing a valve integrated information window of a monitoring valve apparatus in a monitoring method for a monitoring valve apparatus according to an embodiment of the present invention, and FIG. FIG. 6 is a flowchart illustrating a method of monitoring a monitoring valve device according to an exemplary embodiment of the present invention. Referring to FIG. 6, FIG. 7 is an exemplary view showing a process layout in an activated state.

1 to 6, a monitoring method for a monitoring valve device according to an embodiment of the present invention is performed as follows.

First, valve integration information is obtained from a plurality of monitoring valve devices 100 disposed in the piping facility of the process line (s10). In detail, the signal receiving unit 110 receives a status signal from the transceiver 250, and the received status signal is stored in the storage unit 111. At this time, the image operation processing unit 112 generates the valve integration information including the position information, the opening / closing information, and the leakage information for each monitoring valve apparatus 100 from the state signal stored in the storage unit 111. [

Here, the valve integrated information may further include transported fluid information matched for each of the monitoring valve apparatuses 100. In detail, in the storage unit 111, the type of the fluid to be delivered into the piping system in which the monitoring valve apparatuses 100 are disposed corresponds to the positional information of the monitoring valve apparatuses 100, Information is stored in the database. At this time, the image processing unit 112 may generate the inclusion of the transferred fluid information in the valve integrated information by matching the position information of the database with the position information of the received state signal.

When the battery is installed in the monitoring valve device 100, the remaining amount of the battery may be included in the valve integration information. The signal communication unit may receive the battery remaining amount detected from the battery loading unit of the monitoring valve apparatus 100 and may transmit the remaining amount of battery to the transceiver 250. The image calculation processing unit 112 may calculate the remaining battery amount as a percentage And the calculated numerical values may be included in the valve integration information corresponding to the positional information of each of the monitoring valve devices 100.

Further, if the monitoring valve device 100 transmits a status signal via Bluetooth wireless communication, the valve integration information may include a transmission power level, a received signal strength indicating power received from the transceiver 250 Received signal strength indicator (RSSI).

At this time, the image calculation processing unit 112 loads map data including a predetermined valve position mark corresponding to the process line from the storage unit 111. [ Here, the valve position marker may be set with valve position information input to match the positional information of the obtained valve integrated information.

The image calculation processing unit 112 matches the valve position information of the loaded map data with the position information of the obtained valve integration information. The image processing unit 112 sets a coordinate of the valve position marker and sets a process layout diagram 160 in which an output image of the valve position marker is set according to the obtained information of opening / 113.

3 to 4, a process layout 160 in which an output image of the valve position marker output to the output unit 113 is set is divided into a plurality of open state images 161 and a closed state image 162 Valve position markings are displayed corresponding to the process line. Thus, the operator can visually confirm the open / close state of each monitoring valve device 100 disposed in the process line at a glance.

Here, the image processing unit 112 may receive a selection command corresponding to the coordinates of the set valve position marker from the input unit 114. At this time, the image calculation processing unit 112 may image-convert the valve integration information corresponding to the coordinates of the set valve position markers to generate the valve integration information window 170 and display the expanded information on the process layout diagram 160. [

In detail, the valve integrated information window 170 includes sector information 171a indicating a zone of the process line in which the monitoring valve device 100 corresponding to the selection command is disposed, Line information 171b indicating the piping in which the pipeline 100 is disposed and position information 171 including the identification information 171c previously input to the monitoring valve apparatus 100 corresponding to the selection command may be displayed have.

In the valve integrated information window 170, status information 172 indicating the open / close state of the monitoring valve apparatus 100 corresponding to the selection command may be displayed. At this time, the status information 172 may highlight any of the notification messages displayed to indicate opening and closing corresponding to the open / closed status.

In the valve integrated information window 170, the transfer fluid information 173 indicating the fluid to be transferred on the piping on which the monitoring valve apparatus 100 corresponding to the selection command is disposed may be displayed.

In addition, in the valve integrated information window 170, the transmission power level 174 of the monitoring valve apparatus 100 corresponding to the selection command and the remaining battery amount 175 generated by the numerical value calculated as the percentage can be displayed have. The received signal strength 176 of the transceiver 250 may be displayed.

The operator checks the transmission power level 174 and the received signal strength 176 to check the mutual communication state between the monitoring valve apparatus 100 and the transceiver 250 corresponding to the selection command . In addition, the battery remaining amount 175 of the monitoring valve apparatus 100 corresponding to the selection command can be confirmed and confirmed beforehand to be replaced if necessary, and the efficiency of management can be improved.

The return button 177 may be displayed on the valve integrated information window 170. The image operation processing unit 112 receives a return instruction corresponding to the coordinates of the return button 177 from the input unit 114 The control unit 110 cancels the valve integrated information window 170 output to the output unit 113 and outputs the process layout diagram 160 to the output unit 113. [

The image processing unit 112 generates one or more sector classification tabs 190a and 190b corresponding to the sector information included in the positional information of the valve integration information, It can also be displayed.

In detail, when the division instruction corresponding to the coordinates of the sector classification tabs 190a and 190b is inputted from the input unit 114, the image calculation processing unit 112 outputs sector information corresponding to the division instruction, Can be extracted. Here, the image processing unit 112 loads the map data corresponding to the positional information of the extracted valve integrated information, and then sets the output image of the valve position marker according to the opening / closing information of the extracted valve integrated information And output the layout to the output unit 113.

For example, in the state in which the process layout 160 corresponding to the one sector classification tab 190a is output to the output unit 113, a division command for selecting the other sector classification tab 190b may be input. At this time, a process layout diagram in which the output image of the valve position mark is set corresponding to the opening / closing information of the valve integrated information including the sector information corresponding to the other sector classification tab 190b may be output to the output unit 113. [

The image operation processing unit 112 may generate the disappearance button 191 and display the disappearance button 191 on the output unit 113. At this time, if the extinction command corresponding to the coordinates of the extinction button 191 is inputted from the input unit 114, the image operation processing unit 112 outputs the image including the process layout map from the output unit 113 .

Accordingly, the operator can select the sector classification tabs 190a and 190b and identify the opening and closing states of the monitoring valve apparatus 100 for each sector to check them.

If the valve integration information is obtained (s10), it is determined whether the valve opening / closing information of the acquired valve integration information is not received (s20). Here, the transceiver 250 may transmit a status signal corresponding to a predetermined transmission time interval. Accordingly, the signal receiving unit 110 receives a status signal corresponding to the predetermined transmission time, and the image processing unit 112 can generate the valve unification information from the received status signal.

At this time, the image calculation processing unit 112 extracts positional information of the valve integrated information on which the opening / closing information of the generated valve integrated information is not received. In addition, the image processing unit 112 retrieves the valve integration information corresponding to the extracted position information, and finally extracts the time when the opening / closing information is received. If the opening / closing information of the valve integrated information corresponding to the extracted position information is not received for a predetermined time or more based on the extracted time, the image processing unit 112 may determine that the valve integrated information is not received.

Here, the predetermined time may be set so that the image processing unit 112 does not determine the opening / closing information of the valve integrated information temporarily not received from the transceiver 250 due to a transmission error or the like, as an unreceived state.

For example, when the opening / closing information of the valve integrated information including the position information of 'M1' is not received, the image operation processing unit 112 extracts the 'M1' position information from the valve integrated information. In addition, the image processing unit 112 retrieves the valve integration information including the 'M1' position information and extracts the last time the opening / closing information of the retrieved valve integration information was received. If the opening / closing information of the valve integrated information including the 'M1' position information is not received for a predetermined time or more from the extracted time, the image calculation processing unit 112 may determine that the valve integrated information is not received.

If it is determined that the valve opening / closing information of the acquired valve unification information is not received (s20), the position information of the valve unified information determined to be in an unreceived state is extracted as non-receiving position information and the non-receiving guide mode is activated (s30).

Here, the image calculation processing unit 112 extracts positional information of the valve integrated information determined to be in an unreceived state, sets it as the non-received position information, and activates the non-receiving guide mode. In addition, the image calculation processing unit 112 may extract non-reception guide information including positional information, status information, transferred fluid information, and final reception time from the valve integration information in which the opening / closing information is not received for a predetermined time or longer.

When the non-receiving guide mode is activated (s30), the process layout diagram 140 in which the valve position marker 141 is converted to the non-receiving guide marker 142 is matched with the non-receiving position information.

In detail, the image operation processing unit 112 loads the map data from the storage unit 111. In this case, when a plurality of map data of different process lines are stored in the storage unit 111, the image operation processing unit 112 may load the map data matching the extracted location information with the valve position information .

In addition, the image calculation processing unit 112 matches the valve position information with the extracted non-receiving position information, and the valve position information corresponding to the extracted non-receiving position information is set to the non- 142). The image calculation processing unit 112 generates a process layout diagram 140 in which one or more valve position markers 141 are switched to the non-reception guide markers 142 and outputs the process layout map 140 to the output unit 113. At this time, in a state in which the non-receiving guidance mode is activated, the image calculation processing unit 112 cancels the image output to the output unit 113 and switches one or more valve position markers 141 to the non- And outputs the resulting process layout diagram 140.

5, a plurality of valve position markers 141 are displayed corresponding to the process line on the process layout diagram 140 output to the output unit 113 in a state where the unreceived guide mode is activated, The valve position marker 141 matched with the unreceived position information can be switched to the non-receiving guide marker 142 and displayed.

In this case, the image calculation processing unit 112 may convert the extracted non-reception guide information into the non-receiving guide window 150, and may also convert the non-receiving guide window 150 corresponding to the emergency guide marking 142 into the non- A pop-up display can be made on the layout 140. [

The location information 151 including the sector information 151a, the line information 151b and the identification information 151c may be displayed on the non-receiving window 150. [ In addition, status information 152 indicating a status in which the opening / closing information is not received may be highlighted in the non-receiving window 150. In the non-reception guide window 150, the transfer fluid information 153 indicating the fluid to be transferred to the process line in which the monitoring valve device 100 corresponding to the position switched to the non- .

In addition, the final reception time 154 may be displayed in the non-receiving window 150. Here, at the last reception time 154, the time at which the last opening / closing information is received from the monitoring valve device corresponding to the valve integrated information for which the opening / closing information is not received may be output.

A switching button 155 may be displayed on the non-receiving guide window 150. The switching button 155 may be displayed on the input unit 114, The non-receiving guide window 150 is extinguished.

Accordingly, the operator can easily grasp the monitoring valve device 100 requiring repair or replacement work due to a component failure, a battery shortage, a communication failure, etc., and thus the efficiency of management can be further improved.

On the other hand, if there is no opening / closing information of the obtained valve unified information judged to be in an unreceived state (s20), the process layout 140 in which the valve position marker 141 is converted into the non- (S40), the leakage information of the acquired valve integrated information is compared with a predetermined reference value to determine the leakage state (s50).

In detail, the image calculation processing unit 112 compares the leakage information of the generated valve integrated information with a preset reference value to determine the leakage state.

Here, the preset reference value may be set so that it can be compared with the leakage information. For example, when a leakage is detected from the monitoring valve apparatus 100, a signal of '1' is transmitted. When no leakage is detected, a signal of '0' is transmitted and the leakage information may be stored. At this time, the image operation processing unit 112 may compare the leakage information with the preset reference value by setting the preset reference value to '1'. If the predetermined reference value and the leakage information correspond to each other, the image calculation processing unit 112 may determine that the leakage state exists.

As described above, the predetermined reference value is not limited to the above-described example, and may be set to various types that can be compared with a signal transmitted from the leakage sensor so as to determine whether or not the leakage occurs.

If the leakage information of the acquired valve integrated information is compared with a preset reference value to determine the leakage state (s50), the positional information of the valve integrated information determined as the leaked state is extracted as the leakage position information and the emergency guidance mode is activated (S60).

Here, the image operation processing unit 112 may extract positional information of the valve integrated information determined as a leak state, set it as leakage position information, and activate the emergency guidance mode. In addition, the image calculation processing unit 112 extracts emergency information including positional information, leakage information, transferred fluid information, and leakage elapsed time from the valve integrated information determined as a leaked state.

When the emergency guiding mode is activated (s60), the process layout 120, which is matched with the leakage position information and the valve position mark 121 is switched to the emergency guidance mark 122, is output (s70).

In detail, the image operation processing unit 112 loads the map data from the storage unit 111. In this case, when a plurality of map data of different process lines are stored in the storage unit 111, the image operation processing unit 112 may load map data matching the extracted leakage position information and the valve position information .

In addition, the image operation processing unit 112 matches valve position information of the loaded map data with the extracted leakage position information, and valve position information corresponding to the extracted leakage position information is stored in the set valve position mark 121 To the emergency guide sign 122. [ The image calculation processing unit 112 generates a process layout 120 in which one or more valve position markers 121 are switched to the emergency guide markers 122 and outputs the generated process map 120 to the output unit 113.

At this time, in the state that the emergency guiding mode is activated, the image operation processing unit 112 converts the emergency guiding sign 122, which is switched on the process layout 120, into a blinking image and displays the emergency guiding sign 122 122 forcibly outputs the process layout 120 converted to the blinking image to the output unit 113 with a pop-up window.

Forcibly outputting the process layout 120 using a pop-up window may be performed such that the image processing unit 112 generates and outputs an output image other than the process layout 120 to the output unit 113 It is preferable to understand that the process layout diagram 120 is output to the output unit 113 as a new window of a pop-up format as a priority.

For example, even if an operator performs an operation other than monitoring by using the monitoring terminal 200, the process layout 120, in which the emergency guide mark 122 is converted into a blinking image immediately when the emergency guide mode is activated, And output to the output unit 113 as a pop-up window. Accordingly, the monitoring terminal 200 is provided with a real-time monitoring function that allows the operator to recognize the leakage state in real time and immediately during other operations.

6, a plurality of valve position markers 121 are displayed corresponding to the process line on the process layout 120 output to the output unit 113 as a pop-up window in the state that the emergency guidance mode is activated , The valve position marker 121 matched with the leakage position information can be switched to the emergency marker marker 122 and displayed.

At this time, the image operation processing unit 112 converts the emergency guidance landmark 122 into a flickering image which is flickered at a predetermined cycle. In this way, the operator can immediately recognize the leakage state of the monitoring valve apparatus 100 corresponding to the diverted emergency guide mark 122. As a matter of course, the image calculation processing unit 112 may generate and output an alarm sound for facilitating the operator's perception.

The image calculation processing unit 112 may convert the extracted emergency guide information into an emergency guide window 130 and may map the emergency guide window 130 corresponding to the emergency guide marker 122 The pop-up display on the layout 120 can be performed.

The emergency information window 130 displays location information 131 including sector information 131a, line information 131b and identification information 131c. The emergency guide window 130 may also display status information 132 indicating the leakage state of the monitoring valve apparatus 100 corresponding to the emergency guide marker 122.

In the emergency guide window 130, the transfer fluid information 133 indicating the fluid to be transferred to the process line on which the monitoring valve apparatus 100 corresponding to the position switched to the emergency guiding sign 122 is disposed is displayed do.

In addition, a leakage time 134 is displayed in the emergency guide window 130. FIG. Here, the leakage elapsed time 134 may indicate the time at which the image processing unit 112 cumulatively counts the leakage information from the first leakage information occurrence time determined as the leakage state. At this time, the image operation processing unit 112 may set the accumulated counting time to be displayed in real time in the leakage elapsed time 134 as time elapses.

Accordingly, even in a situation where the leakage state is not immediately recognized, the operator can recognize the leakage time point and recognize the time point of the first leakage information occurrence. Further, since the operator can proceed with the maintenance work after determining the risk of the site according to the leakage elapsed time, the accident can be prevented beforehand, and safety can be further improved.

 The switching button 155 may be displayed on the process layout 120. The image processing unit 112 may receive a switching command corresponding to the coordinates of the switching button 155 from the input unit 114 The control unit 120 controls the process layout 120 to disappear from the output unit 113.

Accordingly, the operator confirms the position information 131 and the process layout 120 displayed on the emergency guide window 130 and quickly grasps the position of the monitoring valve device 100 where the fluid leaks, It is possible to prevent large accidents due to the leakage of the fluid, so that the safety can be remarkably improved.

In addition, since the transported fluid information 133 is displayed on the emergency guide window 130, the operator can determine whether the fluid is a fluid that can be fatal or explosive to the human body, and can include protective equipment corresponding thereto, The safety can be further improved.

When the process layout 120 in which the valve position mark 121 is switched to the emergency guide mark 122 is outputted (S70), the process of obtaining the valve unification information (S10) is repeated do. Accordingly, in the monitoring terminal 200, the process layout corresponding to each state can be output in real time so that the operator can check the open / close state and leakage state of the plurality of monitoring valve apparatuses 100 disposed in the piping facility .

As described above, the present invention is not limited to the above-described embodiments, and variations and modifications may be made by those skilled in the art without departing from the scope of the present invention. And these modifications fall within the scope of the present invention.

100: Monitoring valve device 200: Monitoring terminal
110: signal receiving unit 111:
112: Image processing unit 113:
114: Input unit 250: Transceiver
300: Monitoring system for monitoring valve device

Claims (5)

A first step of obtaining valve integration information including position information, opening / closing information, and leakage information from a plurality of monitoring valve devices disposed in a piping facility of a process line;
A second step in which leakage information of the acquired valve integrated information is compared with a preset reference value to extract positional information of the valve integrated information determined as a leakage state as leakage position information and an emergency guidance mode is activated; And
Wherein when the emergency guidance mode is activated, a plurality of valve position markers, which are classified into an open state image and a closed state image, are displayed as predetermined map data corresponding to the process line, and matching the extracted leakage position information among the valve position markers And a third step of generating and outputting a process layout in which one or more of the process layouts converted into the emergency guide mark is output through the output unit,
Wherein the third step is such that the emergency guide marker is converted into a blinking image and the process layout diagram displayed forcibly is output as a pop-up window,
The leakage time counted in accordance with the lapse of time from the first leakage information occurrence time determined as the leakage state is displayed in real time,
The first step may further include the step of extracting the position information of the valve integrated information, which is determined that the obtained opening / closing information of the valve integrated information is not received for a predetermined time or longer, as the non-receiving position information and activating the non-receiving guide mode In addition,
When the non-receiving guidance mode is activated, the process layout diagram in which at least one matched with the extracted non-receiving position information of the valve position markers is converted to a non-receiving guide mark is generated, and finally, And outputting the time when the opening and closing information is received through the output unit,
Wherein the first step includes the step of matching the positional information of the acquired valve integrated information with the map data and setting the output image of the valve position mark according to the obtained information of the valve integrated information, Outputting,
Further comprising the step of image-transforming the valve integration information corresponding to the selected valve position marker and displaying the valve integration information corresponding to the selected valve position marker on the process layout diagram when the selection command for selecting the valve position marker is inputted,
Wherein the valve integration information includes information on the transported fluid to which the type of fluid transferred into the piping system in which the monitoring valve devices are disposed is pre-input. delete delete delete delete

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