JPH06108500A - Extracting system of water supply suspension section - Google Patents

Abstract

PURPOSE:To reduce the burden of data input on a feed water system, regarding a water supply suspension section extracting type. CONSTITUTION:When a data base 1 consisting of the distributing pipe data of a vector data form, and end point data for displaying the coordinate of valves and nodes as the end points of the respective distributing pipes is used and a section to be influenced by a water supply suspension section 6 specified from a terminal 8 is extracted, and when the distributing pipe corresponding with the water supply suspension section 6 is set to be a first water supply suspension section, first and the sort of the end point of the distributing pipe is discriminated and it is a node, then the distributing pipe jointed to the node is set to be a second water supply suspension section. After that, the sort of the end point on a side opposite to the first water supply suspension section, of the distributing pipe set to be the second water supply suspension section is discriminated and when it is a node, then the distributing pipe jointed to the node is set to be a third water supply suspension section. Disposal in this manner is repeated till the sort of end point on the opposite side comes to a valve.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water cut area extraction method, and more particularly to a water supply mapping system, that is, water distribution pipe data showing the route of each water distribution pipe constituting a water supply system in vector data format, A water distribution facility database consisting of end point data indicating the position coordinates of valves or nodes as the end points of the water distribution pipe is provided, and the application program is the water supply system in the designated area, and the water cut point input from the terminal is instructed. The present invention relates to a method of extracting a water cutoff area, which uses the water distribution facility database to identify a portion where a predetermined water supply is not performed due to the influence of the above.

[0002]

2. Description of the Related Art In recent years, the water supply system has become a complicated and wide-ranging system, and if a water cut point occurs due to an accident or construction, its effect will be great, and it will be possible to understand to what extent the area will be affected. It's getting harder.

Therefore, the distribution facility data relating to the water supply system
It is demanded that each terminal side can instantly grasp the influence of the occurrence of the water cut point by constructing a database and processing this water distribution facility database using a computer. To meet such demands.

[0004] Conventionally, as a method for processing a water distribution system database of a water supply system by a computer to extract a water cutoff area, for example, there is one disclosed in JP-A-63-163099. Here, a table in which the code of the sluice valve to be operated when the water line between the sluice valves next to each other is cut off and the code of the water line is registered in advance is created, and the water line in the water cutoff area is created. The code of the sluice valve to be operated is obtained from the registration table by inputting the code.

[0005]

As described above, according to the conventional method, in addition to the construction of the water distribution facility database for the route of the water supply line and the position of the associated sluice valve, the operation is performed when the water supply line is cut off. Since a table is created by associating the code of the gate valve to be coded with the code of the water supply line, the input work becomes complicated, and mistakes are likely to occur at the stage of this association. was there.

Therefore, in the present invention, the water distribution equipment data consisting of the water distribution pipe data showing the route of each wiring path of the water supply system and the end point data showing the valve or node as the end point of each water distribution pipe. For the water pipes that will be the water cutoff area, that is, the valves to be shut off,
By making it possible to identify from the water distribution facility database by running the application program,
The purpose is to reduce the burden of data input.

[0007]

FIG. 1 is a diagram for explaining the principle of the present invention. In the figure, 1 is a file for a water distribution facility database, 2 is an application program, 3 is a drawing target drawing, 4 is a water supply system, 5 is a designated area, 6 is a water cut point,
Reference numeral 7 indicates a temporary water supply source, 8 indicates a terminal, and P ₁ ′ to P ₈ ′
The water pipe, V ₁ '~V _3' are respectively valves, N ₁ '~N _2' are nodes.

Here, in the file 1 for water distribution equipment database, water distribution pipe data showing the route of each water distribution pipe in vector data format for each drawing object drawing 3, for example, for each drawing number, The end point data indicating the valve or the node as the end point of each water pipe is stored.

Further, the terminal device 8 gives an instruction to the application program 2 of the host computer about the designated area 5 and the water cut point 6 which are the processing target areas in the drawing target drawing 3, and according to this instruction content, Application program 2 executes the extraction process of the water cutoff area.

The procedure of the treatment application program 2 for extracting the water cutoff area is that the water pipe data and the end point data corresponding to the water supply system in the designated area 5 are used for the water distribution equipment database. Extract from file 1 and proceed to the next step. The water distribution pipe P ₅ ′ corresponding to the water cut point 6 is specified as the water cut area, and the process proceeds to the next step. It is determined whether or not the end points (N ₁ 'and V ₃ ') of the water pipe P ₅ 'are nodes, and if "YES", proceed to the next step, and if "NO", proceed to step. The water distribution pipes (P ₂ ′ and P ₃ ′) connected to this node (N ₁ ′) are specified as water cutoff areas, and the process proceeds to the next step. The other end point (V) of this water pipe (P ₂ ′ and P ₃ ′)
₁ ′ and V ₂ ′) is a node, and “YE
If "S", the process returns to the step, and if "NO", the process proceeds to the next step. Water distribution pipes P ₂ ′, P ₃ ′, P ₅ ′ that have been identified as water cutoff areas
Each distribution pipe data is transmitted to the terminal 8. Has become.

[0011]

According to the present invention, as described above, the water distribution system comprises the water distribution pipe data indicating the route of each water distribution pipe and the end point data indicating the position coordinates of the valve or node which is the end point of each water distribution pipe. The equipment database is constructed in advance, and when there is an input about the water cutoff point from the terminal, the water distribution pipe to be the water cutoff area is extracted by the processing of the application program of the host computer.

In addition to the above method, the provisional water supply source 7 may be set to actively extract the water-supplyable area, and the water distribution pipes other than the water-supplyable area may be determined as the water-off area. Good.

That is, the water distribution pipe P corresponding to the temporary water supply source 7.
₁ 'and P _8' sequentially from the water supply in the specified area 5 to the results to determine whether water pipe next is a water stoppage zone by treatment with the step-is "water stoppage is the area" The system is sequentially traced, and the water pipes P ₁ ′, P ₄ ′, P ₆ ′ _, P ₇ ′ and P ₈ ′ selected at this time are identified as normal supply channels, that is, the other water pipes are cut off. May be set.

The temporary water supply source 7 shown in the figure uses the portions of the distribution pipes P ₁ ′ and P ₈ ′ cut out in the designated area 5 in the water supply system 4, but the present invention is not limited to this. Alternatively, any one of the water distribution pipes in the designated area 5 which is not specified as the water cutoff area may be designated from the terminal 8 as the temporary water supply source.

In addition, when designating the water cut point 6, there are a method of inputting the actual town name and address and using the predetermined correspondence table to obtain the coordinates, a method of inputting the coordinates on the drawing target drawing, and the like. Be taken. Then, the designated area 5 centering on the water cutoff point 6 is set, but empirically, it is sufficient to set a local area of about 600 m × 600 m.

[0016]

Embodiments of the present invention will be described with reference to FIGS. FIG. 2 is an explanatory view showing an outline of the water cut area extraction system of the present invention, in which 21 is a host computer, 22 is a water distribution facility database, 23 is a work file, 24 is an application program, 25 is a search output terminal, 26 is a display part, 27 is a tablet for inputting water cut points on the drawing,
Reference numerals 28 respectively denote hard copy devices.

FIG. 3 is an explanatory view showing a water supply system in a designated area used for explaining the present invention. P _{1 to} P ₂₄ are water distribution pipes, V _{1 to} V ₉ are water supply valves, and N ₁ to. N ₉ is a node set as a branch point, Q ₁ and Q ₂ are temporary water sources,
C indicates water cutoff points, and the water distribution pipe P ₁
The end points of P ₂₄ are nodes or valves for water supply.

FIG. 4 is an explanatory view showing an example of the data format of the water distribution pipe record in the work file 23.
Additional area 32, representative value area 33 and data area in header 31
In the additional area 32, the code number (individual number) of the node or the water supply valve, which is the end point of the corresponding water pipe, the initial value “0” of the water pipe identifier P _F , and the data area 34 are added. The number n of coordinate data is input.

As the coordinate data of the data area 34, the coordinate data of each characteristic point of this water pipe is input. For example, each distribution pipe P in the water supply system shown in FIG.
_{Although 1 to} P ₂₄ are drawn as straight lines, the actual water pipe is like connecting many line segments, and the coordinate data of each connection point (feature point) at this time is input in the order along the route. Further, the type of line to the next feature point is input as the attribute data.

In the representative value area 33, x of each of the above feature points is
The maximum and minimum coordinates of each coordinate and y-coordinate have been entered, and these data check whether the water pipe specified in each water pipe record may enter the designated area. This is for efficiently performing the water cut area extraction processing by extracting only the water distribution pipe record having this possibility from the water distribution equipment database 22 and transferring it to the work file 23. Note that this representative value area
Details of how to use the maximum and minimum coordinates of 33 are disclosed in Japanese Patent Application No. 301059/93.

FIG. 5 is an explanatory diagram showing an example of the valve record data format in the work file 23.
Additional area 42 and de header 41 - data area 43 is followed, the corresponding code number of each water distribution pipe connected to opposite sides of the valve (individual number) and the initial value of the identifier V _F valve is the additional region 42 "0" is input to the data area 43, and the coordinate data of the valve is input.

FIG. 6 is an explanatory diagram showing an example of the data format of the node record in the work file 23.
The header 51 is followed by an additional area 52 and a data area 53. In the additional area 52, the number of water pipes connected to the corresponding node, the code number (individual number) of each water pipe and the node identifier. The initial value "0" of N _F and the coordinate data of the node is input to the data area 53.

The data of each additional area shown in FIGS. 4 to 6 is the coordinate data of each record when each record is extracted from the water distribution facility database 22 and transferred to the work file 23. That is, it is added based on the first coordinate data and the last coordinate data of the data region 34, the coordinate data of the data region 43, and the coordinate data of the data region 53. The distribution pipe record, the valve record and the node record transferred to the work file 23 have serial numbers P _i , V _J and N _K for each record.

FIG. 7 is an explanatory view showing a procedure for starting a water cutoff point and extracting a water cutoff area. That is, (1) The water distribution pipe P ₉ corresponding to the water cut point (construction point or cut point) is specified, and the process proceeds to the next step. (2) The identifier P _F of this water pipe record is set to “1” and the process proceeds to the next step. Here, the identifier P _F is “1”.
Indicates that the water distribution pipe P ₉ is set in the water cutoff area. (3) Set the value of the variable i to "1" and proceed to the next step. (4) Set the extraction status flag F of the water cutoff area to "0",
Go to the next step. (5) It is judged whether or not the confirmation processing for all the water distribution pipes P _{1 to} P ₂₄ is completed, and if “YES”, the step (1
Proceed to 2), and if "NO", proceed to the next step. (6) It is determined whether the identifier P _F of the water distribution pipe P _i is “1”. If “YES”, the process proceeds to the next step, and if “NO”, the process proceeds to step (11). (7) Valve and node identifier V connected to the water distribution pipe P _i
It is judged whether both _F and N _F are “1”, and “YE
If "S", proceed to step (11), and if "NO", proceed to the next step. (8) If the identifiers V _F and N _F are “0”, change them to “1” and proceed to the next step. (9) an identifier P _F identifier N _F is the water pipe connected to the changed node to "1" from "0" is set to "1", the flow proceeds to the next step. (10) Set the extraction state flag F to "1" and proceed to the next step. (11) Increase the value of the variable i by "1", and step (5)
Return to. (12) It is judged whether or not the extraction state flag F is "0", and if it is "YES", the water cutoff area extraction processing is terminated and "N"
If “O”, return to step (3). By the procedure described above, the water cut-off area affected by the water distribution pipe P ₉ corresponding to the water cut-off point (the hatched portion in the lower left of FIG. 3) is extracted.

Here, the identifier P is assigned in order from the distribution pipe P _1.
The value of _F will be examined, but each identifier P
Repeat the loop of step (5) -step (6) -step (11) until the water distribution pipe P ₈ where _F remains the initial value "0", and proceed to step (7) only after the water distribution pipe P ₉ is reached. It will be.

Then, the identifiers N _F of the nodes N ₄ and N _5, which are the end points of the water distribution pipe P ₉ , are set to "1" (step 8), and subsequently connected to the nodes N ₄ and N _5. Identifier of each distribution pipe P ₈ , P ₁₀ , P ₁₅ P _F
Will be set to "1" (step 9), and at this time the extraction state flag F will be set to "1" (step 9).
Ten).

After that, the above-mentioned processing is sequentially performed for each of the water distribution pipes from P ₁₀ to P _24, but at the time of the processing for the water distribution pipe P ₁₅ on the way, the identifier N of the node N _7
F is "1" and the identifiers P _{F of the} distribution pipes P ₁₆ and P ₁₈
Step (12) -Step (3) after is set to "1"
Will proceed.

At the time when the number L of times of passing through the route of step (12) -step (3) becomes "L = 1" and the process returns to step (3), the distribution pipes P ₈ , P ₉ , P ₁₅ , P ₁₆ , The identifier P _{F of} each P ₁₈ is “1”, the identifier V _{F of} each of the valves V ₃ , V ₄ , V ₅ is “1”, and the node N ₄ ,
This means that the identifiers N _{F of} N ₅ and N ₇ are set to “1”.

Next, by the time "L = 2" is reached and the process returns to step (3), the identifier N _F of the node N ₃ is set to "1" at the processing stage of the water distribution pipe P ₈ , and the water distribution pipe is also returned. The identifiers P _{F of} P ₅ and P ₆ are set to “1”.

Next, until "L = 3" is reached and the process returns to step (3), the identifiers V _F of the valves V ₇ and V ₈ are "at the processing stage of the water distribution pipes P ₅ and P _6. Will be set to "1".

In this way, step (12) -step (3)
The value of each identifier of water pipe, valve, and node changes as the number of times of passing through the route of increases, and when the number of times L becomes “L = 3”, the process returns to step (12) again. The result of the determination is "YES", and the water cut area extraction processing ends. 8 to 10 are explanatory diagrams showing how the identifiers change.

FIG. 11 is an explanatory view showing a procedure for starting a temporary water supply source Q ₁ and extracting a water cutoff area (water supplyable area). That is, (21) the water distribution pipe P ₂₃ corresponding to the temporary water supply source Q ₁ is specified, and the process proceeds to the next step. (22) The identifier P _F of this water pipe record is set to “2” and the process proceeds to the next step. Here, the identifier P _F is "2"
The fact that it is set to indicates that the water distribution pipe P ₂₃ is a water-supplyable area. (23) Set the value of the variable i to "1" and proceed to the next step. (24) Set the extraction state flag F of the water-supplyable area (water-off area) to "0", and proceed to the next step. (25) It is judged whether or not the confirmation processing for all the distribution pipes P _{1 to} P ₂₄ is completed, and if “YES”, the step (3
Proceed to 2), and if "NO", proceed to the next step. (26) It is determined whether the identifier P _F of the water distribution pipe P _i is “2”. If “YES”, the process proceeds to the next step, “NO”.
In case of, proceed to step (31). (27) Identifier V of the valve or node connected to the water distribution pipe P _i
F, to determine whether the N _F there is "0", "YE
If "S", proceed to the next step. If "NO", go to (31).
Proceed to. (28) If the identifiers V _F and N _F are “0”, change them to “2” and proceed to the next step. (29) The identifiers P of the water pipes connected to the valves or nodes whose identifiers V _F and N _F are changed from “0” to “2”
Set _F to "2" and go to the next step. (30) Set the extraction state flag F to "1" and proceed to the next step. (31) Increase the value of the variable i by "1", and step (25)
Return to. (32) It is determined whether or not the extraction state flag F is "0". If "YES", the extraction process is terminated, and if "NO", the process returns to step (23). By the procedure described above, the water supplyable area is extracted from the water distribution pipe P ₂₃ corresponding to the temporary water supply source Q ₁ .

The above-mentioned processing is also carried out for other temporary water supply sources Q ₂ , and the water-supplyable area shown in the actual battle portion of FIG. 3 is extracted as a whole, and each water supply area other than this water-supplyable area is extracted. The distribution pipe will be treated as a water cutoff area. Then, according to this extraction method, some parts in the procedure shown in the previous figures 7 that is the enclave conditions such as water pipes P ₇ and P ₁₁ to P ₁₄ can not be extracted as a suspension of water supply zones identified Will be done. The setting point of the temporary water supply point is not limited to the intersection of the designated area and the water supply system, but can be arbitrarily selected and instructed from the terminal.

Also in the procedure of FIG. 11, as in the case of FIG. 7, as the number L of times of passing through the route of step (32) -step (23) increases, the identifiers of the water pipe, valve and node are identified. The value is changing, and the judgment of the water supplyable area extraction processing from the water distribution pipe P ₂₃ corresponding to the temporary water supply source Q ₁ is made when the number of times L returns to step (32) with “L = 4”. The result is "YES" and the process ends. 12 to 14 are explanatory diagrams showing how the identifiers change.

For example, a water distribution pipe P corresponding to the temporary water supply source Q _{1.
In the} process of extracting the water-supplyable area from ₂₃ , when “L = 1” is reached and the process returns to step (23), the distribution pipes P ₂₂ , P ₂₃
Each identifier P _F is set to “2”, and the identifier N _F of the node N ₉ is set to “2”.

Next, until "L = 2" is reached and the process returns to step (23), the identifier V _F of the valve V ₁ is set to "2" in the processing stage of the water distribution pipe P ₂₂ , and the water distribution pipe is also returned. The identifier P _{F of} P ₂₁ will be set to “2”.

Next, until "L = 3" is reached and the process returns to step (23), the identifier N _F of the node N ₈ is set to "2" at the processing stage of the water distribution pipe P ₂₁ , and the water distribution pipe is also returned. The identifiers P _{F of} P ₁₉ and P ₂₀ will be set to “2”.

Next, by the return is "L = 4" in step (23), the water supply valve V in the processing stage of the water pipe P _20
2 identifier V _F is set to "2", also the identifier P _F water distribution P ₁₇ will be set to "2".

[0039]

INDUSTRIAL APPLICABILITY The present invention provides a water distribution facility data consisting of water distribution pipe data showing routes of water distribution pipes of a water supply system and end point data showing valves or nodes as end points of each water distribution pipe. If you create only a database and enter the water cut point with a tablet etc. on the terminal side, the distribution pipe affected by this water cut point is specified from this database by running the application program, There is no need for the operator to check the valves to be operated when water is cut off for each water distribution pipe and store the corresponding relationship in advance in a table as in the conventional water cut area extraction method, reducing the burden on the operator. it can.

[Brief description of drawings]

FIG. 1 is a diagram illustrating the principle of the present invention.

FIG. 2 is an explanatory diagram showing an outline of a water cut area extraction system of the present invention.

FIG. 3 is an explanatory diagram showing a water supply system in a designated area used for explaining the present invention.

FIG. 4 is an explanatory diagram showing an example of a data format of a water distribution pipe record in a work file according to the present invention.

FIG. 5 is an explanatory diagram showing an example of a valve record data format in a work file according to the present invention.

FIG. 6 is an explanatory diagram showing an example of a data format of a node record in a work file according to the present invention.

FIG. 7 is an explanatory diagram showing a procedure of extracting a water cutoff area starting from a water cutoff point according to the present invention.

FIG. 8 is an explanatory diagram showing a change in P _F (water distribution pipe identifier) in the procedure of extracting a water cutoff area in FIG. 7.

FIG. 9 is an explanatory diagram showing a change in V _F (valve identifier) in the water cut area extraction procedure of FIG. 7.

FIG. 10 is an explanatory diagram showing changes in N _F (node identifier) in the water cut area extraction procedure of FIG. 7.

FIG. 11 is an explanatory diagram showing a procedure of extracting a water-supplyable area starting from a temporary water supply source according to the present invention.

FIG. 12 is an explanatory diagram showing a change in P _F (identifier of water distribution pipe) in the procedure for extracting a water cutoff area in FIG. 11.

FIG. 13 is an explanatory diagram showing a change in V _F (valve identifier) in the procedure for extracting a water cutoff area in FIG. 11.

FIG. 14 is an explanatory diagram showing changes in N _F (node identifier) in the water cut area extraction procedure of FIG. 11.

[Explanation of symbols]

 In FIG. 1, 1 ... File for water distribution equipment database 2 ... Application program 3 ... Drawing target drawing 4 ... Water supply system 5 ... Designated area 6 ... Suspended location 7 ... Temporary Water supply source 8 ... Terminal

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Norio Osawa 2-14-12 Gotenyama, Musashino City, Tokyo (72) Inventor Kazuto Oguri 4991 Shiba, Kawaguchi City, Saitama Prefecture Inventor Noboru Harima Kashiwa, Shiki City, Saitama Prefecture Town 2-22-24 (72) Inventor Kiyoshi Yoneyama 3-312 Minamiota-cho, Minami-ku, Yokohama-shi Kanagawa Prefecture (3) (72) Inventor Kiyoshi Suzuki 5-4-14 Tsubakimori (Chiba City, Chiba Prefecture) Masayuki Taguchi Tokyo 3-5-14 Higashi-Komatsugawa, Edogawa-ku, Tokyo

Claims (5)

[Claims] 1. Water distribution pipe data showing a route in vector data format for each water distribution pipe constituting a water supply system, and end point data showing position coordinates of a valve or a node as an end point of each water distribution pipe. The application program is provided with a water distribution equipment database consisting of a water supply system and a portion of the water supply system in the designated area where predetermined water supply is not performed due to the influence of the water cut point input from the terminal. A water cutoff area extraction method that is specified by using a database, wherein the application program first sets a water pipe corresponding to the water cutoff point as a first water cutoff area, and determines an end point of the water pipe. If the type is judged and it is a node, the water pipe connected to this node is set as the second water cut-off area, and then the water pipe set as the second water cut-off area is set. , Determining the type of the end point on the side opposite to the first water cutoff area and, if it is a node, setting the water pipe connected to this node as the third water cutoff area. Repeatedly until the end point type is a valve, and at least at each of these water cutoff areas, a display indicating that the predetermined water supply is not performed is displayed. 2. Water distribution pipe data showing a route in vector data format for each water distribution pipe constituting a water supply system, and end point data showing position coordinates of valves or nodes as end points of each water distribution pipe. The application program is provided with a water distribution equipment database consisting of a water supply system and a portion of the water supply system in the designated area where predetermined water supply is not performed due to the influence of the water cut point input from the terminal. A method of extracting a water supply area that is identified by using a database, wherein a temporary water supply source is set in a predetermined portion within the designated area, and the application program sets a water pipe corresponding to the water supply stop point. In addition to making it the first water cut area, if the type of the end point of this water pipe is judged and it is a node, the water pipe connected to this node is made the second water cut area. , Next, the type of the end point of the water distribution pipe that is the second water cutoff area on the side opposite to the first water cutoff area is determined, and if it is a node, the distribution pipe connected to this node is determined. The process of setting the water pipe as the third water cutoff region is repeated until the type of the end point on the opposite side becomes a valve, and subsequently, from the water pipe corresponding to the temporary water supply source, the adjacent water pipes are sequentially cut off by the water cutoff pipe. Follow the previous water supply system until it is judged whether it is an area or not, and the result is "a water cutoff area", and specify the part of the distribution pipe selected at this time as a normal water supply area, In the water supply system in the designated area, the water supply area not identified as the normal water supply area is indicated by the indication that the predetermined water supply will not be performed. 3. When determining whether the adjacent water distribution pipe is the water cutoff area, it is judged whether the type of the front end point of the water distribution pipe is a valve indicating the end point of the water cutoff area. The water-free area extraction method according to claim 2, wherein 4. The water cutoff area extraction method according to claim 2, wherein a water pipe cut out in the designated area in the water supply system is used as the temporary water supply source. 5. The method for extracting a water cutoff area according to claim 2 or 3, wherein a water supply pipe specified by a terminal in the specified area is used as the temporary water supply source.