KR100419006B1 - The optimum selection method of cut-off valves in fluid supply pipe network - Google Patents

Abstract

The present invention relates to a method for selecting a shutoff valve in a fluid transportation line, and more particularly, in the event of an accident in a fluid transportation line, selecting the most optimal shutoff valve in the fluid transportation line by a programmed computer. It is about a method.

The main configuration of the present invention is to store the information of a specific fluid transport pipe in the storage device of the computer, and then read the layout of the fluid transport pipe in the accident area from the stored information to store the valve node pair, and then enter the pipe number Set one of the first node pairs corresponding to the main node, read the main node and connecting node from the search data based on the set main node, and save the number of the conduit of each node pair and node pair from them again. It is determined whether there is already a searched one among the stored pipes, and whether there is a corresponding part among the nodes, and then the number of the searched and stored valve pipes is output.

Since the present invention accurately selects only the valve that needs to be shut off, it is possible to quickly cope with a pipeline accident, and there is an advantage that can be applied regardless of the size of the pipe network.

Description

OPTIMUM SELECTION METHOD OF CUT-OFF VALVES IN FLUID SUPPLY PIPE NETWORK}

The present invention relates to a method of selecting a shutoff valve in a fluid transportation line, and more particularly, a method of quickly and accurately selecting the most optimal shutoff valve in a fluid transportation line by a programmed computer when an accident occurs in the fluid transportation line. It is about.

Today, in order to transfer any fluid from one area to another, there is a method of intermittent operation such as in a tank lorry vehicle, and a method of forming a predetermined pipeline and continuously transporting it through the pipeline. The former intermittent method is only suitable for transporting a small amount of fluid, but not for transporting a large amount of fluid. On the other hand, the latter method is the most widely used today because it has the advantage of transporting a large amount of fluid continuously and inexpensively, and the typical method is gas pipelines such as water supply, LNG LPG, oil pipelines, and heat. Fluid passages; and the like. By the way, in the latter method, the fluid transport pipes are usually buried underground, and in the case of an abnormality in the fluid pipes, two methods are generally performed as follows. .

Among them, the most common method is by manual method, which is to close the accident area by finding the valve to be shut off manually by the operator (worker) depending on his experience or by drawing it in the drawing network diagram. Not only that, but there is a risk of selecting the wrong valve, the efficiency and accuracy is reduced. This method does not have fatal consequences for piping such as tap water, but if the transport fluid is fuel gas such as LNG LPG, toxic gas or explosive gas in chemical plants, it is fatal if the shutoff valve is not selected quickly and accurately. It must be a very inappropriate method, as it will result.

Another method is to find the shut-off valve using the shape analysis technique provided by GIS or CAD-related software. This method tracks a large number of lines. There is a risk that it will, and even in this case, will have fatal consequences. In addition, the use of this technique requires the purchase of expensive software and the construction of a separate system for use.

Facilities for transporting fluids such as water supply, gas pipelines, thermal fluid pipelines, oil pipelines, and the like, form a single pipe network by combining multiple pipelines. By the way, when the size of the network is simple, the maintenance is easy because the number of valves is small, otherwise, various operational problems are likely to occur. In particular, in the case of a water supply pipe network or a gas pipe network in a large city, the number of valves is difficult to count, and in many cases, operation is impossible due to investment or failure. In this situation, it is difficult to isolate the accident area quickly, and if the appropriate valve is not selected, the damage area may be unnecessarily widened and the magnitude of the damage may increase.

In order to solve this problem, the present invention proposes a method for optimally selecting a shutoff valve that minimizes an isolated line and minimizes an isolated damage area by selecting a shutoff valve quickly and accurately by a computer programmed with an accident line. .

1 is a flowchart schematically showing a process for realizing a method for selecting a shutoff valve in a fluid transportation line according to the present invention;

Figure 2 is an exemplary view showing an embodiment of a pipe network modeled to explain the technical idea of the present invention,

3 is a view showing search data according to the exemplary view of FIG.

4 is a flow chart schematically illustrating a process for realizing a method of optimizing and selecting a shutoff valve in a fluid transportation line as a more preferred embodiment of the present invention.

The present invention relates to a method for quickly and accurately selecting the most optimal shut-off valve in a fluid transportation pipeline by a programmed computer in the event of an accident.

The present invention stores the information about a specific fluid transport line in the storage device of the computer, and then reads the layout of the fluid transport line in the accident area from the stored information to store the valve node pairs, and then corresponds to the pipe number input A first step of setting one of the first node pairs as a main node; Reading a main node and a connection node from the search data based on the set main node, and storing the number of the conduit of each node pair and the node pair from them; A third step of determining whether there is already found one among the pipelines searched and stored in the second step, and proceeding according to the result; A fourth step of determining whether there is a valve line among the newly stored lines in the third step, and proceeding to the next step according to the result; A fifth step of determining whether a portion corresponding to the main node is present among the nodes that have been performed in the fourth step, and then repeatedly proceeding to the second step according to the result or proceeding to the sixth step below ; In addition, the present invention provides a method for optimally selecting a shutoff valve for a fluid transportation line including a sixth step of outputting the number of the valve line stored and searched in the above process.

In addition, the present invention more preferably includes the step of minimizing the shut-off valve searched in addition to the above steps.

Hereinafter, the present invention will be described in more detail.

The present invention stores the information about a specific fluid transport line in the storage device of the computer, and then reads the layout of the fluid transport line in the accident area from the stored information to store the valve node pairs, and then corresponds to the pipe number input And a first step of setting one of the first node pairs as the main node. In the present invention, the information of a specific fluid transport channel refers to information about a pipe network designed or installed so that a specific fluid can be transported from any particular supply source to any particular demand destination. The above information may include information about various piping materials installed from the supply site to the demand site. However, the most useful information in the present invention may be obtained when the information on the incident pipe detected by the characteristics of the present invention is input to the computer system. The concept and information about pipelines, nodes and valves is important for the quick and accurate search for the optimum shut-off valve. In the present invention, the concept of pipelines, nodes and valves is defined as follows. For example, in the case of selecting the end points ⓘ and 에 for a single pipeline, the fluid transport system is represented by the pipe network, which is the interconnection of the pipeline, and the starting and ending points in the pipeline are called nodes ( i , j ), And the pipe formed between the two nodes ( i , j ) is called a pipeline, and a mechanical means for controlling the flow of fluid installed in the pipeline is defined as a valve. In the above nodes, the node that is the center of the following shutoff valves is called the main node, and the node immediately adjacent to the main node is called a connection node, and these are referred to as node pairs. In addition, the information in which the relation between the main node and the connection node is arranged in order is referred to as search data, and the order of the main node and the connection node in the search data is relative and does not mean an absolute order.

(Definition 1) Nodes, pipelines:

(Definition 2) Nodes, valves:

(Definition 3) Main node, connected node:

(Definition 4) Search material:

The present invention stores in advance the information of a fluid transportation conduit consisting of a plurality of conduits, nodes and valves designed to be installed or installed in a specific area in a storage device of a computer. The information of the fluid transport pipe may be stored and used in a memory device of a computer individually in a small amount, and may be used by separately storing a large amount of data.

According to the present invention, after the information on the accident pipeline in the fluid transportation pipeline is set, one of the first node pairs corresponding to the input pipeline number is set as the main node. In the present invention, the information on the accident pipeline refers to information on an accident occurring in any one pipeline or two or more pipelines, which are previously inputted into the storage device of the computer as the information of the fluid transportation pipeline about a specific region. . Fluid leakage will be one of the most representative examples here, but is not necessarily limited thereto. For example, in a chemical plant, when a high temperature more than a critical limit generate | occur | produces in a specific pipe line, the high pressure more than a critical limit generate | occur | produces, or the case progresses to the flow rate below a critical limit, etc. are mentioned. Such an accident can be defined as the oversight of the risk of a real or potential disadvantage around it by disrupting normal fluid flow. In the present invention, the information of the accident pipeline can be recognized by the operator and input the information into the computer, if necessary, it can be automatically input by the automatic detection system. In the former case it is most commonly done, in the latter case it can be done in the art by automated plumbing equipment. The present invention selects one of the first node pairs corresponding to the accident pipeline number as the main node. This is to determine the initial search point. In the present invention, the first step corresponds to those indicated by 1 to 5 in the flowchart of FIG. 1.

The present invention includes a second step of reading the main node and the connection node from the search data based on the set main node, and stores the number of the conduit of each node pair and node pair from them again. In the present invention, once the main node is set, the corresponding main node and the connection node are searched for from the already stored search data, and the main node and the connection node are stored as a pair. This saves the selected route number and node pair. In the present invention, the second step corresponds to those denoted by 6, 7 and 8 in the flowchart of FIG.

The present invention includes a third step of determining whether there is already found one among the pipelines searched and stored in the second step, and proceeds to the next step according to the result. In the present invention, if there is already a searched route among the pipelines that have been carried out in the second step, the number of the route is excluded once, and the rest of the route number and the node pair are stored and then proceeded to the next step. . This is because the whole process of the present invention is configured to search repeatedly until the last shut-off valve is found. Therefore, it is effective to exclude unnecessary search data in the repetition process. However, in the present invention, if there are no conduits already searched, the numbers and connection pairs for all those conduits are stored and proceed to the next step. In the present invention, the third step corresponds to those indicated by ⑨ and ⑩ in the flowchart of FIG. 1.

The present invention includes a fourth step of determining whether there is a valve line among the newly stored pipe lines in the third step, and proceeds to the next step according to the result. In the present invention, if there is a valve pipeline among the pipelines that have been performed in the third step, the number of the valve pipeline is once extracted and stored. This is because the present invention aims to search for a valve capable of efficiently blocking the fluid passing through the accident pipeline in the fluid transportation means. At this time, if necessary, the flow of the fluid may be immediately interrupted by operating the actual shutoff valve corresponding to the valve line at the same time as the extraction and storage of the extracted valve line by a conventional automatic shutoff facility. Once the number of valve lines has been extracted and stored, proceed to the next step for the remaining lines except those numbers. However, in the present invention, if no valve conduits exist, store the numbers and connection pairs for all of those conduits and proceed to the next step. In the present invention, excluding them for overlapping nodes, and storing and proceeding with the remaining nodes is also to exclude duplicate work. In the present invention, the fourth step may be performed in the flowchart of FIG. Corresponds to that indicated by

The present invention determines whether there is a portion corresponding to the main node among the nodes that have been carried out in the fourth step, and then proceeds repeatedly to the second step according to the result or proceeds to the sixth step below. A fifth step is included. In the present invention, the fifth step may determine whether there is a part corresponding to the major node among the nodes that have been performed in step 4 of step 4, and then if the part corresponding to the major node exists, the stored node is determined. Set it as the main node and return it to the second step above. Thereafter, the process starts from the second step again, proceeds to the fourth step through the general process, and then proceeds to the fifth step again. The reason for the present invention to continue the repetitive process is to search for the shut-off valves in the piping equipment one by one during the repetitive process. On the other hand, in the present invention, if the part corresponding to the main node of the nodes that proceeded in step 4 of the fourth step no longer exists, the valve for the accident pipeline is no longer present in the already stored fluid transport pipeline. This means, this time proceed to the sixth step below. In the present invention, the fifth step above is performed in the flowchart of FIG. And Corresponds to that indicated by

The present invention includes a sixth step of outputting the number of the valve duct searched and stored in the above process. The present invention of the fifth step After repeating the process several times, if the process proceeds to this step, the number of valves searched and stored during the repetition process is read, and the number of the valve line is output or the actual value corresponding to the number of the valve line is obtained. To operate the valve directly. That is, the present invention, when the shutoff valve is quickly searched by the operation of the computer, the number of the shutoff valves may be output, and the operator may block the flow of the fluid by manual labor in the field. At the same time, the shut-off valve corresponding to the number can be automatically shut off by directly operating by electromagnetic means which are commonly used. In the case of the latter automatic shut-off, it can be usefully used for a system for transporting a fluid such as a chemical plant or LNG LPG. In the present invention, the sixth step corresponds to those indicated by 19 and 20 in the flowchart of FIG. 1.

In addition, the present invention more preferably includes minimizing the shut-off valves searched. In the present invention, the step of minimizing the shut-off valve is A step of searching for nodes inside and outside the blocking area when the nodes stored in the table no longer exist; It includes a later step to find the minimum optimal shutoff valve.

The present invention of the fifth step If the stored node no longer exists, the process does not directly proceed to the sixth step, but may proceed to the previous step for searching for the nodes inside and outside the blocking area. In the present invention, the previous step is to first read the search data of the fluid transport pipe. This is done as a preparatory work for carrying out the next work, and if it is the same as that already done in step 2 of the first step, it can be omitted. Subsequently, the previously searched pipeline is read. This is to find the conduit involved in the blocking area of the fluid conduit. In addition, the main node finally counted and stored in step 4 of step 4 is used as the found main node. These are the nodes for the valve located inside the shutoff zone. The present invention then uses these nodes to obtain nodes located outside the blocking area. This can be obtained by removing the nodes inside the blocking area from the whole nodes shown in the search data. In the present invention, the reason for finding the nodes outside the shut-off zone is that the optimum shut-off valve must be located on the boundary line of the shut-off zone, and the optimum shut-off valve must be on the inside of the shut-off zone. Since the other side of the valve is located outside the shut-off zone, it is used to find the optimum shut-off valve by finding the node located outside the shut-off zone. In the present invention, the previous step corresponds to the ones indicated by ① 'to ⑥' in the flowchart of FIG. 4.

The invention also includes a post step of searching for the minimum optimal shutoff valve after the previous step. In the present invention, the above step is the above Read the pipeline number and node pair of the valve that was finally aggregated and stored in the section. This is necessary because these are the valves located inside the shut-off area in the event of an accident in the fluid transport line, among which there is an optimum shut-off valve to be shut off quickly. Subsequently, the present invention determines whether there is a node located outside the blocking area among the pairs of nodes of the plurality of shutoff valves read above, and stores only the valve having the node located outside thereof as an optimum shutoff valve. In the present invention, in order to perform this process, it is made by determining whether any of the nodes of the searched valve overlap with the nodes outside the blocking area. At this time, if there are nodes overlapped with each other in comparison with the nodes located outside the blocking range, the valve including the node is stored as a shutoff valve, and then the shutoff valve is output or the shutoff valve is directly It works. However, if there are no longer overlapping nodes compared to nodes located outside of the blocking range for all read nodes (searched), the optimum shutoff valve is already stored at the previous stage, so the shutoff valve is output. Or shut off the valve directly. In the present invention, the reason for searching for the overlapping nodes as described above is that the valves located on the boundary line of the blocking zone have one node outside the blocking zone and the other node inside the blocking zone. By finding the nodes that are located, it is to find the optimum valve.

As described above, the present invention may output the number of the optimum shutoff valve or directly operate the actual valve corresponding to the number of the optimal shutoff valve, which is also manually performed or commonly used. It is possible to operate the shutoff valve automatically by electromagnetic means. In the present invention, the above step corresponds to those indicated by ⑦ 'to ⑩' in the flowchart of FIG. 4.

Hereinafter, the present invention will be described in more detail with reference to the following examples. However, the following examples are only presented on the basis of the most preferred embodiments so that the technical idea of the present invention can be easily carried out by those skilled in the art, the scope of the present invention is limited to the following examples It is self-evident.

2 is a diagram illustrating one of the pipe networks given to explain an embodiment of the present invention. In Fig. 2, ①, ②, ③, .... ⑬, ⑭ represent each node, and 101, 102, 103, .... 114, 115 represent a pipeline, among which 101 and 105 And 112 indicate an accident pipeline, while 107, 110, 111, and 113 represent a shutoff valve installed in the pipeline.

FIG. 3 shows the main nodes and the connection nodes based on the pipe network of FIG. 2 and shows search data for the pipe network of FIG.

Meanwhile, in the present invention, each step can be described in detail with the flowchart of FIG. 1, and therefore, the embodiment will be described with reference to the flowchart of FIG. 1 for convenience. In addition, in Example 1, the case where an accident occurred in only one pipeline 105 in the pipe network of FIG. 2, and in Examples 2 and 3, the case where an accident occurred in two or more pipelines will be described.

<< Example 1 >>

Here, the case where an accident occurs in only one pipeline 105 in the pipe network of FIG. 2 will be described. Line 105 is 3 and 6 node pairs, but 3 is the main node for convenience.

(Iii). Process of searching for node 3 as main node:

① It means the start of search.

② Read the search data configured as shown in FIG. At this time, the search data is already input to the storage device of the computer.

③ Save valve number to distinguish valve from general pipe. The valve number and node pair to be stored are 113 (11, 12), 110 (9, 8), 111 (7, 10), 107 (2, 7), and the order of storage may be interchanged.

④ Designate number of accident pipe. In the first embodiment, the accident pipeline is pipeline 105, and the pair of nodes is (6, 3).

⑤ Designate search point. The search begins by entering the pipeline where the accident occurred.

(6) One of the two nodes of the pipeline designated as the search point is selected as the search start point. The designated node is recognized as the main node and moves to the main node position of the saved search data as shown below. Since the node pair of the accident pipeline is (6, 3), the node 3 is determined as the search point.

⑦ Search for the node connected to the main node. As shown in the figure above, the nodes connected to the main nodes are 6, 4, 2.

⑧ Store main node and connecting node as one pair each. Stored conduit numbers and node pairs are 105 (3, 6), 103 (3, 4), 102 (3, 2), and their order is relative.

⑨ Of the node pairs searched in ⑧ above, check whether the previously searched pipeline exists in the stored order. By the way, since this is the first time, there can be no previously searched pipeline. Thus, the process proceeds to the next step.

관 Because the route searched in ⑧ above is the first search, store the route number and node pair again. At this time, the pipe number and node pair to be stored are 105 (3, 6), 103 (3, 4), 102 (3, 2).

⑪ it is determined whether or not and reads all stored as the pipeline from the stored sequence of ⑩ wherein, the conduit comprising a valve to the pipeline. By the way, in the present embodiment 1 because the pipelines searched to date is not a valve pipeline, it proceeds to the next process.

절 Arrange the nodes in the pair of nodes stored in the above paragraph in the order stored in the paragraph. Thus the stored nodes are 3, 6, 3, 4, 3, 2.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 6, 4, 2.

⑭ Save main node. The main node saved so far is 3.

저장 Re-save all the nodes stored in ⑬ above, except for the main nodes. Thus the stored nodes are 6, 4, 2.

Since the main node is stored at ⑮ above, proceed to the next step.

The first node among the nodes stored in the above paragraph is 6, so 6 is the main node and return to ⑥ above.Repeat the process.

(Ii). Process of searching for node 6 as main node:

⑥ Since the main node is designated as No. 6 node, the search data using No. 6 node as main node is as shown below.

⑦ When searching for the node connected to the main node, it is 8, 5, 3 as above.

⑧ When the main node and the connecting node are stored as one pair, the stored pipe number and node pair are 108 (6, 8), 106 (6, 5), 105 (6, 3).

⑨ Check whether the previously searched conduit exists among the node pairs searched in the section ⑧ in the stored order. At this time, pipeline 105 is already the pipeline that has been searched out, and after this pipeline, the controller moves to the following paragraph.

관 The remaining pipeline numbers and node pairs are 108 (6, 8) and 106 (6,5) except for pipeline 105. Therefore, the pipe numbers and node pairs stored so far are 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), and 106 (6, 5).

⑪ However, the searched pipelines are not valve pipelines, so proceed to the next paragraph.

절 Arrange and store the node pairs stored in the above paragraph. The nodes stored so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 4, 3, 2, 8, 6, 5.

⑭ Save main node. The major nodes saved so far are 3 and 6.

저장 Save again except the main node among the nodes stored in ⑬ above. Thus the stored nodes are 4, 2, 8, 5.

Since the main node is stored at ⑮ above, proceed to the next step.

In the above paragraph, the first node among the stored nodes is 4, so node 4 is the main node. Then, back to item ⑥, ⑦ ～Repeat the process.

(Iii). Process of searching node 4 as main node:

⑥ Since the main node is the 4 node, the search data using the 4 node as the main node is as shown below.

⑦ When searching for the node connected to main node, it is 5 and 3.

⑧ When the main node and the connecting node are stored in one pair, the stored pipe number and node pair are 104 (4, 5) and 103 (4, 3).

⑨ Check whether the previously searched conduit exists among the node pairs searched in the section ⑧ in the stored order. In this case, pipeline 3 is already a pipeline that has been searched out.

⑩ At this time, the channel number and node pair to be newly stored are 104 (4, 5). Therefore, the pipe numbers and node pairs stored so far are 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), 106 (6, 5), 104 (4 , 5).

⑪ However, the searched pipelines do not include the valve pipeline, so proceed to the next paragraph.

절 Arrange and store the node pairs stored in the above paragraph. The nodes stored so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 2, 8, 6, 4, 5.

⑭ Save main node. The major nodes stored so far are 3, 6 and 4.

저장 Save again except the main node among the nodes stored in ⑬ above. Thus the stored nodes are 2, 8 and 5.

Since the main node is stored at ⑮ above, proceed to the next step.

In the above paragraph, the first node of the stored nodes is 2, so node 2 is the main node. Then, back to item ⑥, ⑦ ～Repeat the process.

(Iii). Process of searching for node 2 as main node:

⑥ Since the main node is node 2, the search data using node 2 as the main node is as shown below.

⑦ When searching for the node connected to the main node, it is 1, 3, 7 as above.

⑧ When the main node and the connection node are stored as one pair, the stored pipeline number and node pair are 101 (2, 1), 102 (2, 3), and 107 (2, 7).

⑨ Check whether there is a previously searched pipeline among the node pairs searched in the section ⑧ and confirm it in the stored order. In this case, pipeline 102 is excluded because it has already been explored.

⑩ Therefore, the route number and node pair to be stored are 101 (2, 1), 107 (2, 7), and the route number and node pair stored up to now are 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), 106 (6, 5), 104 (4, 5), 101 (2, 1), 107 (2, 7) .

⑪ At this time, the searched pipelines include the valve pipelines of 107 (2, 7), and then extract and store the pipeline number and node pair of the pipeline 107 ( Proceed to the next step for the rest of the pipeline.

⑫ the ⑪ arranges the node pair related to the channel, and the remaining term storage. At this time, the nodes stored so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5, 2, 1.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 8, 6, 4, 5, 2 and 1.

⑭ Save main node. The major nodes saved so far are 3, 6, 4 and 2.

저장 Save again except the main node among the nodes stored in ⑬ above. Thus the stored nodes are 8, 5, 1.

Since there are major nodes stored in the above, the process proceeds to the next step.

In the above paragraph, the first node among the stored nodes is 8, so node 8 is the main node. Then, returning to the item ⑥ above, ⑦ toRepeat the process.

(Iii). Process of searching node 8 as main node:

⑥ Since the main node is the 8 node, the search data using the 8 node as the main node is as shown below.

⑦ When searching for the node connected to the main node, it is 6, 9 and 7.

⑧ When the main node and the connecting node are stored as a pair, the stored pipe number and node pair are 108 (8, 6), 110 (8, 9), and 109 (8, 7).

⑨ Check the existence of the previously searched pipeline among the node pairs searched in section ⑧ in the order of storage. In this case, pipeline 108 is excluded because it has already been explored.

⑩ Therefore, the conduit numbers and node pairs to be stored are 110 (8, 9) and 109 (8, 7), and the conduit numbers and node pairs stored up to this point are 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), 106 (6, 5), 104 (4, 5), 101 (2, 1), 107 (2, 7), 110 (8, 9) , 109 (8, 7).

⑪ A, so we have discovered duct includes a valve of the pipe line 107 (2, 7), 110 (8, 9), extracts the channel number and the node pair of the 107, 110, and then stores the channel ( Proceed to the next step for the remaining pipelines.

⑫ the ⑪ arranges the node pair related to the channel, and the remaining term storage. The nodes stored so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5, 2, 1, 8, 7.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 6, 4, 5, 2, 1, 8, 7.

⑭ Save main node. The major nodes stored so far are 3, 6, 4, 2 and 8.

저장 Save again except the main node among the nodes stored in ⑬ above. Thus the stored nodes are 5, 1, 7.

Since there are major nodes stored in the above, the process proceeds to the next step.

The first node among the nodes stored in the above paragraph is 5. Therefore, make node 5 the main node and return to item ⑥ again.Repeat the process.

(Iii). Process of searching for node 5 as main node:

⑥ The main node is node 5, so the search data for node 5 is shown below.

⑦ When searching for the node connected to the main node, it is 4 and 6.

⑧ When the main node and the connecting node are stored in one pair, the stored pipe number and node pair are 104 (5, 4) and 106 (5, 6).

⑨ Check whether the previously searched conduit exists among the node pairs searched in the section ⑧ in the stored order. At this time, the 104th and 105th pipelines have already been searched for and thus this pipeline is excluded. Therefore, there are no pipelines and node pairs to be newly stored in paragraph.

⑩ Thus, the pipe and node pairs stored so far are 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), 106 (6, 5), 104 as above. (4, 5), 101 (2, 1), 107 (2, 7), 110 (8, 9) , and 109 (8, 7).

⑪ among the channel stored in the the anti ⑩, 107 (2, 7), 110 (8, 9) is a valve because the pipelines, storage to extract the channel number and the node pair of the 107, 110 and then conduit ( Proceed to the next paragraph for the remaining pipelines.

배열 Arrange and store node pairs for the remaining pipelines in paragraph 1 above. The nodes stored so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5, 2, 1, 8, 7.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 6, 4, 5, 2, 1, 8, 7.

⑭ Save main node. The major nodes stored so far are 3, 6, 4, 2, 8 and 5.

저장 Save again except the main node among the nodes stored in ⑬ above. Therefore, the stored nodes are 1 and 7.

Since there are major nodes stored in the above, the process proceeds to the next step.

The first node among the nodes stored in the above paragraph is 1. Therefore, make node 1 the main node and return to item ⑥.Repeat the process.

(Iii). Process of searching node 1 as main node:

⑥ Since the main node is node 1, the search data using node 1 as the main node is as shown below.

⑦ When searching for the node connected to main node, it is 2.

⑧ If the main node and connecting node are saved as one pair each, the saved pipeline number and node pair are 101 (1, 2).

⑨ Of the node pairs searched in ⑧ above, the route 101 is already searched and there is no pipeline and node pair to be newly added and stored.

⑩ Therefore, the pipe and node pairs stored so far are 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), 106 (6, 5) , 104 (4, 5), 101 (2, 1), 107 (2, 7), 110 (8, 9) , 109 (8, 7).

⑪ Since the pipelines stored above include the valve pipelines of 107 (2, 7) and 110 (8, 9) , the pipeline numbers and node pairs of pipelines 107 and 110 are extracted and stored ( And 107 and 110 are excluded. Then, proceed to the next paragraph for the remaining remaining pipelines.

배열 Arrange and store node pairs for the remaining pipelines in paragraph 1 above. The nodes saved so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5, 2, 1, 8, 7.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 6, 4, 5, 2, 1, 8, 7.

⑭ Save main node. The major nodes stored so far are 3, 6, 4, 2, 8, 5, 1.

저장 Save again except the main node among the nodes stored in ⑬ above. Thus the saved node is 7.

Since there are major nodes stored in the above, the process proceeds to the next step.

The first node among the nodes stored in the above paragraph is 7. Therefore, using node 7 as the main node, return to item ⑥ above.Repeat the process.

(Iii). Process of searching for node 7 as main node:

⑥ Since the main node is the 7 node, the search data using the 7 node as the main node is as shown below.

⑦ When searching for the node connected to the main node, it is 8, 2, 10 as above.

⑧ If the main node and the connection node are stored as one pair, the stored pipeline number and node pair are 109 (7, 8), 107 (7, 2), 111 (7, 10).

⑨ Of the nodal pairs searched in ⑧ above, pipelines 109 and 107 have already been discovered, so this pipeline is excluded. At this time, the stored conduit and node pair is 111 (7, 10).

관 Therefore, the pipe numbers and node pairs stored so far are 105 (3, 6), 103 (3, 4), 102 (3,2), 108 (6, 8), 106 (6, 5), 104 (4 , 5), 101 (2, 1), 107 (2, 7), 110 (8, 9) , 109 (8, 7), 111 (7, 10) .

Since 107 (2, 7), 110 (8, 9), and 111 (7, 10) are valve pipelines among the pipelines stored in the above paragraph, the pipeline numbers and node pairs of pipelines 107, 110, and 111 are After extracting and saving ( Proceed to the next paragraph.

배열 Arrange and store node pairs for the remaining pipelines in paragraph 1 above. The nodes stored so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5, 2, 1, 8, 7.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 6, 4, 5, 2, 1, 8, 7.

⑭ Save main node. The major nodes stored so far are 3, 6, 4, 2, 8, 5, 1, 7.

저장 Save again except the main node among the nodes stored in ⑬ above. However, this time there are no nodes stored.

On the other hand, since the main node is no longer stored in the above-mentioned, unlike this time, proceeds to the next (19).

(19) Through the above process The valves that are stored in sequence are read out. These valves are shut-off valves, and valve number (pipe number) and node pair are 107 (2, 7), 110 (8, 9), 111 (7, 10). to be.

(20) With respect to the above valves read above, the job is completed once by outputting the number to the printer. Subsequently, the shutoff valve in the region corresponding to the output number is automatically operated to directly shut off the fluid to the fluid conveying line by operating the electromagnetic means normally used by the operator.

<< Example 2 >>

In this case, in FIG. 2, a case where an accident occurs simultaneously in two pipelines will be described as an example. In the second embodiment, considering the convenience of the description of the technical thoughts of the present invention and the convenience of understanding by the ordinary experts in the art, it will be considered to consider the case where an accident occurred at the pipeline 105 and 101 at the same time In addition, the shut-off valve for line 105 should be searched first.

(Iii). Search for shut off valve for line 105:

In Figure 2, the process of searching for the shut-off valve for the passage 105 is the same as the process of the first embodiment. Therefore, the next step is to search for the shutoff valve for the 101 route.

(Ii). Process of searching for node 2 as main node:

④ Accident pipeline number shall be designated according to the assigned sequence number. Route 105 has already been explored, so the next sequence is Route 101. Therefore, the accident pipeline is pipeline 101 and the pair of nodes is (1, 2).

⑤ Designate search point. Searching starts from the pipeline where the accident occurred.

(6) One of the two nodes of the pipeline designated as the search point is selected as the search start point. Since the pair of nodes in the accident pipeline is (1, 2), we decide node 2 as the search point.

⑦ The nodes connected to the main node are 1, 3, 7.

⑧ Store main node and connecting node as one pair each. Stored channel numbers and node pairs are 101 (2, 1), 102 (2, 3), and 107 (2, 7).

⑨ Of the node pairs searched in the above section ⑧, the 101, 102, and 107 pipelines are all already explored, so there are no new pipelines and node pairs to be stored.

관 Therefore, the pipe numbers and node pairs stored so far are 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), 106 (6, 5), 104 (4 , 5), 101 (2, 1), 107 (2, 7), 110 (8, 9) , 9 (8, 7), 111 (7, 10) .

Since 107 (2, 7), 110 (8, 9), and 111 (7, 10) are valve pipelines among the pipelines stored in the above paragraph, the pipeline numbers and node pairs of pipelines 107, 110, and 111 are Extract and save ( term). At this time, there is no newly added pipeline, and proceeds to the next paragraph.

절 Arrange and store the node pairs stored in the above paragraph. The nodes stored so far are all 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5, 2, 1, 8, 7.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 6, 4, 5, 2, 1, 8, 7.

⑭ Save main node. The major nodes stored so far are 3, 6, 4, 2, 8, 5, 1, 7.

저장 Save again except the main node among the nodes stored in ⑬ above. Therefore, no nodes are stored.

Since there is no major node stored in the above-mentioned, it proceeds to the following paragraph (19) unlike the usual case.

(19) Through the above process Read the valve stored in the section. However, these valves are shut-off valves, and valve numbers and node pairs are 107 (2, 7), 110 (8, 9), and 111 (7, 10) in the same manner as in the case of the single pipe accident of the first embodiment.

(20) With respect to the above valves read above, the fluid transportation line is automatically and directly cut off by operating the valve corresponding to the number by an electromagnetic means which is commonly used.

<< Example 3 >>

In this case, in FIG. 2, the case where an accident occurs at the same time in the pipeline 105 and the 112 is described as an example. Even in this case, considering the convenience of the description of the technical idea of the present invention and the convenience of understanding by those of ordinary skill in the art, the first search for the shutoff valve for pipeline 105, and then to the pipeline 112 Shall be.

(Iii). Search for shut off valve for line 105:

In Figure 2, the process of searching for the shut-off valve for the passage 105 is the same as the process of the first embodiment. Therefore, the search process of the shutoff valve for the 112th line will be described next.

(Ii). Process of searching node 9 as main node:

④ Accident pipeline number shall be designated according to the assigned sequence number. If the order number is 105, 112, the channel 105 is the same as the process described in Example 1. The next sequence is line 112. Therefore, the accident pipeline is route 112 and the pair of nodes is (9, 11).

⑤ Designate search point. Searching starts from the pipeline where the accident occurred.

(6) One of the two nodes of the pipeline designated as the search point is selected as the search start point. Since the node pair of the accident pipeline is (9, 11), the node 9 is decided as the search point.

⑦ Search for the node connected to the main node. At this time, the nodes connected to the main nodes are 11 and 8.

⑧ Store main node and connecting node as one pair each. Stored pipeline numbers and node pairs are 112 (9, 11) and 110 (9, 8).

⑨ Of the node pairs searched in ⑧ above, pipeline 110 has already been searched, so exclude it. However, since pipeline 112 is not a searched pipeline, the newly added pipeline and node pair are 112 (11, 9).

⑩ Therefore, the pipe numbers and node pairs stored so far are all 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), 106 (6, 5), 104 ( 4, 5), 101 (2, 1), 107 (2, 7), 110 (8, 9) , 109 (8, 7), 111 (7, 10), 112 (9, 11).

The pipelines stored in paragraph 1 above contain 107 (2, 7), 110 (8, 9) and 111 (7, 10) valve pipelines. Therefore, the pipeline numbers and node pairs of pipelines 107, 110, and 111 are extracted and stored ( term). After that, proceed to the next paragraph for the remaining pipelines.

절 Arrange and store the node pairs stored in the above paragraph. The nodes stored so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5, 2, 1, 8, 7, 9, 11.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 6, 4, 5, 2, 1, 8, 7, 9 and 11.

⑭ Save main node. Thus, the major nodes stored so far are 3, 6, 4, 2, 8, 5, 1, 7, 9.

저장 Save again except the main node among the nodes stored in ⑬ above. Therefore, the stored node is 11.

Since the main node is stored at ⑮ above, proceed to the next step.

In the above paragraph, the first node of the stored nodes is 11, so node 11 is the main node. Then, return to the above item ⑥ to ⑦ ~Repeat the process.

(Iii). Process of searching for node 11 as main node:

⑥ The main node is node 11, so the search data using node 11 as the main node is as shown below.

⑦ When searching for the node connected to the main node, it is 9 and 12 as above.

⑧ When the main node and the connection node are stored in one pair, the stored pipeline number and node pair are 112 (11, 9) and 113 (11, 12).

⑨ Of the nodal pairs searched in ⑧ above, pipeline 112 has already been searched, so exclude it. At this time, the 113 channel is not a searched pipeline, and thus is added as a new pipeline.

⑩ Therefore, the route number and node pair stored so far is 113 (11, 12). The pipe and node pairs stored so far are all 105 (3, 6), 103 (3, 4), 102 (3, 2), 108 (6, 8), 106 (6, 5), 104 (4, 5) , 101 (2, 1), 107 (2, 7), 110 (8, 9) , 109 (8, 7), 111 (7, 10), 112 (9, 11), 113 (11, 12) .

The pipelines stored in paragraph 1 above contain 107 (2, 7), 110 (8, 9), 111 (7, 10), and 113 (11, 12) valve lines. Therefore, the pipeline numbers and node pairs of pipelines 107, 110, 111, and 113 are extracted and stored ( term). Thereafter, the rest of the pipelines proceed to the next step.

절 Arrange and store the node pairs stored in the above paragraph. The nodes stored so far are 3, 6, 3, 4, 3, 2, 6, 8, 6, 5, 4, 5, 2, 1, 8, 7, 9, 11, 11, 12.

저장 Save the duplicate nodes in the above paragraph by removing the duplicate nodes from the first term. The nodes stored are 3, 6, 4, 5, 2, 1, 8, 7, 9 and 11.

⑭ Save main node. The major nodes stored so far are 3, 6, 4, 2, 8, 5, 1, 7, 9, and 11.

저장 Save again except the main node among the nodes stored in ⑬ above. Therefore, there are no saved nodes.

Since there are no major nodes stored in the above-mentioned 한다, the process proceeds to the following paragraph (19) unlike the usual case.

(19) Through the above process Read the valve stored in the section. However, these valves are shut-off valves, and valve numbers and node pairs are 107 (2, 7), 110 (8, 9), 111 (7, 10), and 113 (11, 12) .

(20) With respect to the above valves read above, the fluid corresponding to the number is automatically and directly shut off by operating the electromagnetic means which are commonly used.

As mentioned above, the case that can cause a pipeline accident was simulated. If the network is independent of each other, it can be applied to each network.

On the other hand, in Example 1 and 2 mentioned above, since the valve corresponding to 107 (2, 7) is located in the shutoff area | region of a fluid, even if this valve is blocked, there will be little blocking effect to an actual accident line. In addition, in the third embodiment, the valves corresponding to 107 (2, 7) and 110 (8, 9) are also located in the blocking zone, so even if these valves are blocked, there is little effect of blocking the accident pipeline. This means that in the case of the valves in the shut-off area, they do not need to shut off these valves, since they do not have much to do with the blocking effect on the accident pipeline regardless of whether they are blocked or not blocked. This also means that the greater the number of such valves in any network, the more likely it will be to respond quickly to unexpected accidents. Therefore, it is necessary to exclude unnecessary valves existing in the blocking zone from the blocking target, and this requires a blocking valve minimization process as shown in FIG. 4. Example 4 below describes such a process of minimizing the shutoff valve.

<< Example 4 >>

This time, in the second embodiment, an embodiment regarding the minimization step of the shutoff valve will be described. Even in this case, in consideration of the convenience of the description of the technical idea of the present invention and the convenience of understanding by a person skilled in the art, the identification symbols of each step of Fig. 4 are expressed as ① ', ②', ③ '. ⑨ 'and the like, the same identifier will be used for the searching process of FIG.

① ' Read the search data configured as shown in FIG.

② ' is a conduit stored in paragraph 1 of FIG. In this case, the pipe numbers are 105, 103, 102, 108, 106, 104, 101, 107, 110, 109, 111.

③ ' All the pipelines searched at ②' are those within the blocked area. These pipelines can be seen that the fluid in the pipeline is blocked by blocking the valve as shown in FIG.

④ ' On the other hand, it is repeated in the flowchart of FIG.

⑤ 'Above The main nodes searched at ④ 'are the nodes that block the flow of fluid to the valve block. At this time, the isolated isolated nodes are 3, 6, 4, 5, 2, 1, 8, 7. It can be seen that these nodes are also present in the blocking zone when the valve is closed, as shown in FIG. 2.

⑥ ' Read all the nodes from the search data and arrange them, then exclude the main nodes in the above ⑤'. At this time, the remaining nodes become nodes outside the blocking range. Therefore, the nodes outside the blocking range are 9, 10, 11, 12, 13, 14.

⑦ 'on the other hand, is repeated in the flowchart of FIG. Read the line number and node pair of the valve that is finally aggregated and stored in the section. At this time, in the case of Example 2, the pipe number and node pair of the searched valve are 107 (2, 7), 110 (8, 9), and 111 (7, 10).

⑧ 'Check whether the nodes included in the node pairs of the searched valves overlap with the nodes outside the blocking area of the above ⑥'. It is determined whether there are overlapping nodes, and if there are no more overlapping nodes, it proceeds to the item ⑩ 'below.

⑨ ' At this time, the valves overlapping with the nodes outside the shutoff area are 110 (8, 9) and 111 (7, 10), so these valves are selected as the best shutoff valves. However, 107 (2, 7) is excluded because there are no overlapping nodes. According to Figure 2 it can be seen that the valve is located inside the shut-off zone.

After ⑩ ' , the above-mentioned 110 (8, 9), 111 (7, 10) valves, which are read above, are automatically shut off directly by commonly used electromagnetic means.

Comparing Example 2 and Example 4 above, it can be seen that in Example 4, two shutoff valves are operated, whereas in Example 2, three shutoff valves are operated. Therefore, it can be seen that the method of Example 4 exhibits the same blocking effect even with a smaller number of shutoff valves, which is a much more efficient method.

<< Example 5 >>

At this time, in the third embodiment, an embodiment relating to the minimizing step of the shutoff valve will be described, and the remaining conditions are the same as in the fourth embodiment.

① ' Read the search data configured as shown in FIG.

② ' is a conduit stored in paragraph 1 of FIG. In this case, in the third embodiment, the pipe numbers are 105, 103, 102, 108, 106, 104, 101, 107, 110, 109, 111, 112, and 113.

③ ' All the pipelines searched at ②' are those within the blocked area.

④ ' On the other hand, it is repeated in the flowchart of FIG.

⑤ 'Above The main nodes searched at ④ 'are the nodes that block the flow of fluid to the valve block. In this case, the isolated nodes blocked in the case of Example 3 are 3, 6, 4, 2, 8, 5, 1, 7, 9, and 11. It can be seen that these nodes are also present in the blocking zone when the valve is closed, as shown in FIG. 2.

⑥ ' Read all the nodes from the search data and arrange them, then exclude the main nodes in the above ⑤'. At this time, the remaining nodes become nodes outside the blocking range. In the case of Example 3, the nodes outside the blocking range are represented by 10, 12, 13, and 14.

⑦ 'on the other hand, is repeated in the flowchart of FIG. Read the line number and node pair of the valve that is finally aggregated and stored in the section. In the case of Example 3, the pipe numbers and node pairs of the valves searched are 107 (2, 7), 110 (8, 9), 111 (7, 10), and 113 (11, 12).

⑧ 'Check whether the nodes included in the node pairs of the searched valves overlap with the nodes outside the blocking area of the above ⑥'. It is determined whether there are overlapping nodes, and if there are no more overlapping nodes, it proceeds to the item ⑩ 'below.

⑨ ' At this time, the valves overlapping with the nodes outside the shut-off area are 111 (7, 10) and 113 (11, 12), so these valves are selected as the best shut-off valves. However, 107 (2, 7) and 110 (8, 9) are excluded because there are no overlapping nodes.

After ′ ' , the 111 (7, 10), 113 (11, 12) valves read above are automatically shut off directly by commonly used electromagnetic means.

According to the fifth embodiment, compared to the third embodiment, it can be seen that the desired performance can be achieved by operating only two shutoff valves.

As described above, since the present invention accurately selects only the valve that needs to be shut off, it is possible to quickly cope with a pipeline accident. For example, in the event of an accident in the pipe network of the water supply pipe, the shutoff valve can be quickly detected and the optimum shutoff valve can be selected to immediately shut off the supply of water supply, thereby minimizing the area of damage and enabling rapid recovery. In addition, in the case of LPG LNG gas or chemical plants handling dangerous goods, by selecting the optimal shut-off valve and automatically shutting off the shut-off valve, the accident area can be completely isolated while minimizing the damage area (isolated area). .

In addition, the present invention is easy to review the data, it is easy to find errors and easy deletion of the data.

In addition, the present invention has an advantage that can be applied regardless of the size of the network. For example, the present invention can be applied at low cost anywhere in a facility having a pipe network such as an industrial machine, a gas pipe network, a water supply pipe network, an oil pipeline network, and a thermal fluid network.

In the above description, a method of selecting a shutoff valve optimally when an accident occurs in a fluid transportation line according to the present invention has been described in detail with reference to the accompanying drawings and examples, but this is only for describing the most preferred embodiments of the present invention, and the present invention is not limited thereto. Of course. In addition, anyone of ordinary skill in the art will be able to make various modifications and imitations according to the description of the present specification, but it will be apparent that this is also outside the scope of the present invention.

Claims (2)

In the method of selecting a shutoff valve to isolate the accident area while minimizing the damage area when an accident occurs in the fluid transportation line, a) stores information about a particular fluidic conduit in a computer storage device, and then reads the layout of the fluidic conduit in the accident area from the stored information and stores a pair of valve nodes, and then corresponds to the conduit number entered A first step of setting one of the first node pairs as the main node; b) a second step of reading the main node and the connection node from the search data based on the set main node, and storing the number of the conduit of each node pair and the node pair from them again; c) a third step of determining whether there is already found one of the pipelines searched and stored in the second step, and proceeding according to the result; d) a fourth step of determining whether there is a valve pipeline among the newly stored pipelines in the third stage, and proceeding to the next stage according to the result; e) determining whether a portion corresponding to the main node is present among the nodes that have been performed in the fourth step, and then repeatedly proceeding to the second step according to the result or proceeding to the sixth step below. Step 5; And, and f) a sixth step of outputting the number of the valve line searched and stored in the above process. 2. The method of claim 1, further comprising the step of searching for nodes inside and outside the shutoff zone when the nodes stored in the fifth step no longer exist, and the step of searching for the minimum optimal shutoff valve. Optimal selection method of the shutoff valve in the fluid transportation line, characterized in that