JP3644701B2 - Extractable area extraction method and apparatus therefor - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an extraction system for a supplyable area when a construction or an accident occurs in a part of a supply system of a water supply business, an electric power business, a gas business, etc. (hereinafter referred to as “water supply business etc.” as necessary). In particular, when a construction site or the like occurs in a supply system composed of supply lines that start from a cut-off section or a node, a supply-disabled area that cannot be supplied due to this effect is first identified, and then the supply is disabled The present invention relates to a supply line extraction method for determining a supply line path that forms a closed loop and a supply line path that branches from the supply line path that are determined to be able to be supplied to these.
[0002]
In recent years, the supply system of water supply business has become a complex and wide-ranging system, and it is possible to grasp the extent of the impact when a certain part goes down due to an accident or construction. It has become difficult.
[0003]
Therefore, by constructing a database related to the supply system of water supply business, etc., and processing this database using a computer, the impact when an accident or construction occurs, that is, which part of the supply line cannot be supplied Therefore, it is required that each terminal side can immediately know which part of the supply line can be supplied, and the present invention meets such a request.
[0004]
As described above, the present invention is intended for a wide variety of various supply system systems such as a water supply business, an electric power business, and a gas business, but in the following description, a water supply business as an example is used as necessary. Explain to the subject.
[0005]
In this case, it is possible to supply the "water supply system" instead of the supply system, the "distribution pipe" instead of the supply line, the "valve" instead of the shut-off part, and the "water outage area" instead of the non-supplyable area. Instead of areas, use “water supply areas”.
[0006]
[Prior art]
Japanese Laid-Open Patent Publication No. 6-108500 discloses a system for specifying a water shut-off area and a water feedable area when a water distribution pipe in a water supply system is in a water shut-off state due to an accident or construction.
[0007]
FIG. 18 to FIG. 27 are explanatory diagrams showing a method for specifying a water cutoff area and a water supply possible area disclosed in this publication.
Fig. 18 is an explanatory diagram showing the outline of the system for extracting outage areas and available water areas. 21 is a host computer, 22 is a water distribution facility database, 23 is a work file, 24 is an application program, and 25 is a search output. A terminal, 26 is a display unit, 27 is a tablet for inputting a water stop point on the drawing, and 28 is a drawing device such as a hard copy or an electrostatic plotter.
[0008]
FIG. 19 is an explanatory diagram showing an example of a water supply system in the designated processing target area.₁~ P₄₈Is water pipe, V₁~ V₁₈Is a shutoff valve, N₁~ N_{twenty one}Is the node set at the branch point, Q₁~ Q_ThreeIndicates a temporary water supply source, I indicates a water cutoff point, and the distribution pipe P₁~ P₄₈The end points are nodes or valves.
[0009]
FIG. 20 is an explanatory diagram showing an example of the data format of the distribution pipe record in the work file 23. After the header 31, an additional area 32, a representative value area 33, and a data area 34 are set and added. The area 32 includes a node or valve code number (individual number) that is an end point of the corresponding water pipe, and a water pipe identifier P of the water pipe._FThe initial value “0” and the number n of coordinate data in the data area 34 are respectively entered.
[0010]
As the coordinate data of the data area 34, the coordinate data of each feature point of this water pipe is inputted. For example, each distribution pipe P of the water supply system shown in FIG.₁~ P₄₈Is drawn as a straight line, but the actual water distribution 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, and the attribute As data, the line type up to the next feature point is input.
[0011]
Further, the maximum value and the minimum coordinate of each of the previous feature points are input to the representative value area 33, and these data are the distribution pipes specified by the respective distribution pipe records. By checking whether there is a possibility of entering the designated area and extracting only this potential distribution pipe record from the distribution equipment database 22 and transferring it to the work file 23, the water outage area extraction process is efficiently performed. Is to do to. Details of how to use the maximum coordinate and the minimum coordinate of the representative value area 33 are disclosed in Japanese Patent Laid-Open No. 5-108729.
[0012]
FIG. 21 is an explanatory diagram showing an example of the data format of the valve record in the work file 23. An additional area 42 and a data area 43 are set after the header 41, and the additional area 42 has a corresponding valve. The code number (individual number) of each water pipe connected to both sides of the valve and the valve identifier V of the valve_F, And the data area 43 contains the coordinate data of the valve.
[0013]
FIG. 22 is an explanatory diagram showing an example of the data format of the node record in the work file 23. An additional area 52 and a data area 53 are set after the header 51, and the additional area 52 has a corresponding node. The number of water pipes connected to the pipe, the code number (individual number) of each water pipe, and the node identifier N of the node_FAnd the data area 53 contains the coordinate data of the node.
[0014]
The data of each additional area in FIGS. 19 to 21 is obtained by extracting the respective records from the water distribution equipment database 22 and transferring them to the work file 23, that is, the coordinate data of each record, that is, the data. Added based on the first and last coordinate data of the data area 34, the coordinate data of the data area 43, and the coordinate data of the data area 53, and In the distribution pipe record, valve record and node record transferred to the work file 23, the serial number P for each record_i, V_JAnd N_KIs touched.
[0015]
FIG. 23 is an explanatory diagram showing a procedure for extracting a water stop area starting from the water stop point I in FIG.
That is,
(51) Water distribution pipe P corresponding to water cut off point (construction point or cut point) I₉And proceed to the next step.
(52) This water pipe identifier P_FIs changed from the initial value “0” to “1”, and the process proceeds to the next step. Here, water pipe identifier P_F"1" of the distribution pipe P₉Indicates that it has been set as a water outage area.
(53) The value of the variable i is set to “1”, and the process proceeds to the next step.
(54) Set the extraction state flag F of the water cutoff area to “0” and proceed to the next step.
(55) All water pipes P₁~ P₄₈It is determined whether or not the confirmation processing related to is completed. If “YES”, the process proceeds to step (62), and if “NO”, the process proceeds to the next step.
(56) Water pipe P_iIdentifier P_FIs “1”, the process proceeds to the next step if “YES” and proceeds to step (61) if “NO”.
(57) Water pipe P_iID of the valve or node that is the end point of V_F, N_FAre both “1”, if “YES”, the process proceeds to step (61), and if “NO”, the process proceeds to the next step.
(58) This water pipe identifier V_F, N_FIf it is “0”, change it to “1” and go to the next step.
(59) Identifier N_FDistribution pipe identifier P connected to the node whose value is changed from “0” to “1”_FIs set to “1” and the process proceeds to the next step.
(60) The extraction state flag F is set to “1”, and the process proceeds to the next step.
(61) Increase the value of variable i by “1” and return to step (55).
(62) It is determined whether or not the extraction state flag F is “0”. If “YES”, the water cut section extraction process is terminated, and if “NO”, the process returns to step (53).
The distribution pipe P corresponding to the water cutoff point₉Water outage areas that are affected by (the shaded area at the lower left in Fig. 19) are extracted.
[0016]
When specifying the water cutoff location I, there are a method of obtaining the coordinates by inputting an actual street address and using a predetermined correspondence table, a method of inputting the coordinates on the drawing target drawing, and the like.
[0017]
Here, water pipe P₁The identifier P in order from_FWill be examined, but each identifier P_FHas a default value of “0”.₈Until, repeat the loop of step (55) -step (56) -step (61)₉Only then becomes step (57).
[0018]
And this water pipe P₉Node N that is the end point of_FourAnd N_FiveEach identifier N_FIs set to “1” (step 58), then this node N_FourAnd N_FiveDistribution pipe P connected to₈, P_Ten, P₁₅Each identifier P_FIs set to “1” (step 59). At this time, the extraction state flag F is set to “1” (step 60).
[0019]
Then P_TenTo P₄₈The above processing is performed in order for each of the water distribution pipes up to, for example, the water distribution pipe P in the middle₁₅Node N when processing for₇Node identifier N_FIs "1" and the distribution pipe P₁₆And P₁₈Identifier P_FIs set to “1”, the process proceeds from step (62) to step (53).
[0020]
At the time when the number of times L passing through the route of step (62) -step (53) becomes “L = 1” and the process returns to step (53), the water distribution pipe P₈, P₉, P₁₅, P₁₆, P₁₈Each water pipe identifier P_FBecomes “1” and valve V_Three, V_Four, V_FiveEach valve identifier V_FIs "1", node N_Four, N_Five, N₇Each node identifier N_FIs set to “1”.
[0021]
Next, until “L = 2” and the process returns to step (53), the water distribution pipe P₈Node N at the processing stage_ThreeNode identifier N_FIs set to “1” and the distribution pipe P_Five, P₆Each water pipe identifier P_FIs set to “1”.
[0022]
Next, until “L = 3” and return to step (53), the water distribution pipe P_FiveAnd water pipe P₆Valve V at the processing stage₇, V₈Each identifier V_FIs set to “1”.
[0023]
Thus, as the number of times of passing through the route from step (62) to step (53) increases, the values of the identifiers of the water pipes, valves and nodes change, and this number L becomes “L = 3”. Then, when returning to step (62) again, the determination result is “YES”, and the watershed extraction process ends. 24 to 27 are explanatory diagrams showing how the identifiers change.
[0024]
When the water cut area extraction process is completed in this way, for example, the processing target area 15 in FIG. 19 is displayed on the display unit 26 in a form that emphasizes the water cut area (the left-slanted hatched portion), and the user who sees this is the tablet Temporary water supply source Q which becomes starting point when we operate 27 and identify water supply available area₁~ Q_ThreeSet.
[0025]
When extracting possible water supply area, this temporary water supply source Q₁~ Q_ThreeDistribution pipe identifier P of the distribution pipe connected to this with reference to_FIs set to “2”, and when the other end point (node or valve) of the distribution pipe is not the valve set to the identifier “1” by the watershed extraction process, the distribution pipe identifier of the distribution pipe connected thereto P_FFor example, “2” is repeatedly set.
[0026]
As a result, in the case of the water supply system of the processing target area 15 in FIG. 19, the distribution pipe identifier P of each distribution pipe excluding the hatched portion._FIs set to “2”, and each distribution pipe identifier P at this stage_FIs
・ "1" in the water cut-off area (the shaded area on the lower left)
・ "2" in the supply available area (distribution pipe part not shaded)
・ Remaining (downward slanted part) “0”
There are three types.
[0027]
And water pipe identifier P_FThe remaining water distribution pipe P whose initial value remains at “0”₇And P₁₁~ P₁₄Are extracted as isolated areas. The details described above are disclosed in the publication.
[0028]
[Problems to be solved by the invention]
As described above, in the conventional method of extracting the supplyable area, the temporary supply source is first set when the supplyable area and the isolated area are obtained after the supply impossible area based on the construction or the accident is specified. It was.
[0029]
In this case, the reliability of the extraction process of the supplyable area and the isolated area can be ensured only after the temporary supply source can be an actual supply source.For example, the area 16 is set as the process target area in FIG. Q as a temporary water supply source₁'~ Q_ThreeThis reliability is not guaranteed when ′ is selected.
[0030]
That is, temporary water supply source Q_Three′ Is not connected to the outside of the area to be treated, and the water pipe connected to this is extracted as a supplyable area although water supply from the outside cannot be expected.
[0031]
Therefore, when selecting a temporary supply source, it is necessary to check the connection status between it and the outside of the processing target area, which places a heavy burden on the system user in extracting the supplyable area and the isolated area. Despite the efforts of the system users, there was a problem that the reliability of the extraction results was not perfect.
[0032]
Therefore, in the present invention, after specifying an unsupplyable area based on construction or an accident in a supply system such as a water supply business, an electric power business, or a gas business, an arbitrary supply line is within the range of the outer portion of the unsupplyable area. The other supply line starting from this one end point and sequentially connected to it is connected to the other end point of the first supply line to form a closed loop, and this supply line path and It is an object of the present invention to improve the reliability of the extracted supplyable area and the isolated area and to simplify the extraction work by determining that the supply line path to be branched is a supplyable area.
[0033]
[Means for Solving the Problems]
FIG. 1 is an explanatory diagram of the principle of the present invention.
1 is a designated area, which is set around an I point corresponding to an occurrence point of construction or an accident. Here, a node N₁'~ N₉′ And blocking part V₁'~ V_FiveSupply line P consisting of each end point of ′₁′ 〜P₁₅An area with a supply system of ′ is used.
Reference numeral 2 is a supply impossible area specifying means, which selects each end point to the first cut-off portion in each of the first supply line paths starting from the point I by the same method as the above-described conventional technique. Supply line P specified by end point₁₂′ 〜P₁₄′ (Shaded area) is specified as an unsupplyable area.
3 is a supplyable area specifying means, and in a supply line network that is not specified as an unsupplyable area, a reference supply line P₁One end point V of ′_FiveStarting from 'through the other supply line and the other end N_FiveThe thick line portion between the path reaching ′ and the supply line connected thereto is selected, and the thick line portion and the reference supply line P are selected.₁′ Is specified as the supply available range.
Reference numeral 4 denotes supply line information, and each supply line is associated with an end point number and a supply line identifier of the both end points.
Reference numeral 5 denotes end point information. For each end point, the supply line number and the end point identifier of each supply line connected to the end point are associated with each other.
[0034]
The reference supply line P₁′ Is arbitrarily selected from the supply line network not specified in the unsupplyable area, the end point identifier of the end point is set so as to be distinguishable from the unselected end point identifier, and one of the reference supply lines The caller identifier is set at the end point of the caller, and the callee identifier is set at the other end point.
[0035]
Here, the supply line information 4 and the end point information 5 are made into a database as described above (see FIGS. 20 to 22), and the supply line identifier and the end point identifier therein can be supplied to the corresponding supply line and end point, respectively. The value is changed from the initial value “0” in accordance with the processing in the unsupplyable area specifying unit 2 and the supplyable area specifying unit 3. It should be noted that how to set various identifier values used in the present specification is arbitrary, and each description here is merely an example.
[0036]
And the final value of each identifier after the process of specifying the supplyable area ends is
(1) Supply line P belonging to the unsupplyable area₁₂′ 〜P₁₄', Node N₈′ And blocking part V₂'~ V_Four′ ・ ・ ・ “1”
(2) Supply line P belonging to the supply available area₁′ 〜P₁₁', Node N₁'~ N₇′ And blocking part V₁', V_Five'... "2"
(3) Supply line P belonging to isolated area₁₅'And node N₉′ ・ ・ ・ “0”
Thus, the supply available area can be specified by these identifiers.
[0037]
[Action]
In this way, the present invention displays the supply system of the designated area indicating the vicinity of the occurrence point of construction or accident based on the supply system database, and after specifying the unusable area including this occurrence point, the supply impossible In the outer part of the area, an arbitrary supply line is first selected as a reference supply line, and then, among the supply lines other than this selection, a part connected in sequence to the reference supply line is connected to the reference supply line. A supply line route is obtained, and this supply line route and a reference supply line connected to the supply line route are specified as a supplyable area.
[0038]
When determining the supply line path, the supply impossible area specifying means 2 and the supply possible area specifying means 3 use at least one of the supply line information 4 and the end point information 5, and the basic processing in the supply impossible area specifying means 2 is conventionally performed. This is the same as the method (see FIG. 23). The supply line information 4 or the end point information 5 may be either because the relationship between the other's own number and the end point number or the connection number can be obtained based on either information. is there.
[0039]
FIG. 2 shows an outline of a processing procedure in the supplyable area specifying means 3, and the contents are as follows.
(1) Supply line P from among the supply lines belonging to the outer part of the unsupplyable area₁Select ′ as a reference supply line and go to the next step.
(2) Standard supply line P₁One end point V of ′_Five′ Is the calling party identifier “13” and the other end point N_FiveThe callee identifier “19” is set in each of ′, and the process proceeds to the next step.
(3) It is determined whether or not there is a supply line having an end point identifier connected to the end point of the calling side identifier “13” and having an initial value “0”. If “YES”, Proceed to the next step. If “NO”, proceed to step (5). Reference supply line P₁'Is excluded from the judgment object here.
(4) The supply line identifier of the supply line and the end point identifier of the other end of the supply line are changed from the initial value “0” to the calling side identifier “13”, and the process returns to step (3). It should be noted that the cutoff point V whose end point identifier has already been changed to “1” by the processing in the supplyable area specifying means 2₂'~ V_FourEach of ′ is excluded from the identifier change target here.
(5) It is determined whether there is an endpoint having the destination identifier “19” as the endpoint identifier before the change among the endpoints changed to the originating identifier “13”. If “NO”, the process proceeds to step (7). Note that “YES” here is the reference supply line P.₁One end point V of ′_FiveTo the other end point N via the other supply line_FiveThis is the case where there is a path back to ′, that is, there is a closed loop.
(6) Supply line path (thick line portion) consisting of a supply line having a calling side identifier “13” and a reference supply line P connected thereto₁′ Is determined to be a supplyable area, and each of these identifiers is changed to “2”.
(7) Standard supply line P₁It is determined that there is no supplyable area corresponding to '.
[0040]
The supplyable area specifying means 3 repeats such an identifier changing process until the supply line in step (3) does not exist in the part that is not the supply impossible area, and specifies the thick line part in FIG. In the end point of the reference supply line P₁The other end point N of ′_FiveWhether or not 'is included is confirmed by using its called side identifier “19”.
[0041]
In step (3), the reference supply line P₁As pre-processing for removing ′ from the judgment target,
・ End point N_Five′ And V_FiveFrom the connection number of each end point information of ′, the reference supply line P₁Excluding ′
・ Standard supply line P₁The supply line identifier of ′ is the other supply line P₂′ 〜P₁₅Set to a value different from that of ′
and so on.
[0042]
Reference supply line P₁′ Is excluded from the judgment target
-Supply line P without being excluded from this identifier change target₁′ Is not subject to the identifier change in step (4), the loop processing from step (3) to step (4) will not end.
-Supply line P without being excluded from this identifier change target₁′ Is the identifier change target in step (4), for example, supply line P₈Reference supply line P due to missing ′₁One end point V of ′_FiveTo the other end point N via the other supply line_FiveThis is to avoid the fact that the determination result in step (5) becomes “YES” even though the route back to ′ is not established, that is, there is no supplyable area in the present invention.
[0043]
In step (4), the blocking section V₂'~ V_FourEach of ′ is excluded from the identifier change target for these end point identifiers that may be boundary points with the supply available region, as well as other supply lines P in the supply disabled region.₁₂′ 〜P₁₄'And node N₈This is because it is held in the same “1” as each identifier of ′.
[0044]
The reference supply line may be any supply line that belongs to the outside portion of the supply impossible region. For example, a supply line that intersects with a straight line set in an arbitrary direction from the point I may be used.
[0045]
When a plurality of reference supply lines are used, as will be described later, different originating side identifiers and destination side identifiers are set for each reference supply line, and the processing of FIG. 2 is performed for each of the reference supply lines. Execute.
[0046]
In step (4) at the time of execution, the end point identifier of the other end point of the supply line has already become a second originating side identifier different from the first originating side identifier “13”, for example, “23”. Sometimes, one of these first or second calling party identifiers set so far is changed to the other, and the called party identifier corresponding to this one is changed to the called party identifier corresponding to the other. It is done together.
[0047]
Looking at the specific end points in FIG._FourIn the case of ′, it can be seen from the end point information 5 that the end point identifier of the blocking section remains “1” set by the unsupplyable area specifying means 2, so that the new process by the supplyable area specifying means 3 is Not done.
[0048]
In addition, node N in the available area₆In the case of ′, it is first determined by referring to the end point information 5 whether or not the end point identifier of the node is the same as the originating side identifier “13”.₆Supply line P connected to ′₈′ 〜P_TenFind ′.
[0049]
Next, by referring to the supply line information 4, a P having an initial value “0” as a supply line identifier is selected from the supply lines.₉′ And P_Ten′ Is selected and each supply line identifier is changed to the originating identifier “13”.₉′ And P_Ten'Find each end point number. When the result is “different”, no new processing is performed.
[0050]
Next, the end point identifier corresponding to the end point number in the end point information 5 is changed to the calling side identifier “13”. Each identifier changed to the calling side identifier “13” is the node N having the called side identifier “19”._FiveAfter confirming the establishment of the supply line route up to this point, it is finally reset to “2” indicating the supply available region.
[0051]
Node N₆That the end point identifier of ′ is the same as the originating side identifier “13” means that the supply line path P can be obtained by the repetitive processing of the supplyable area specifying means 3 so far.₂'-P_Three'-P_Four'-P₇'-P₈This means that at least a route of 'is formed, and each supply line identifier and each end point identifier of the route have been changed from the initial value “0” to the originating identifier “13”.
[0052]
In the above description, when changing the identifiers of the end point and the supply line, the supply line identifier “0” connected to the end point is based on checking the end point identifier if this is the same as the originating side identifier. Although the procedure of changing the end point identifier of the other end point to the originating side identifier is used, a procedure based on examining the identifier of the supply line may be used instead.
[0053]
For example, as the supply line information 4, for each supply line, information including data indicating the other supply lines connected to the supply line is used, and the supply line connected to one end point of the reference supply line And the destination line identifier is set to the supply line connected to the other side, and then the supply line connected to the supply line having the origin side identifier and having the supply line identifier of “0” is set. The supply line path (the thick line portion in FIG. 1) is specified by changing the supply line identifier to the calling side identifier, and this supply line is included if the supply line having the called side identifier is included in this. The route and the reference supply line connected to the route may be determined as the supplyable area.
[0054]
【Example】
An embodiment of the present invention will be described with reference to FIGS.
In the following embodiments, as described at the beginning, a description will be given for a water supply system which is an application example of the present invention. The outline of the watershed extraction system itself used in the present invention and the outline of the processing procedure when extracting the watershed based on the distribution pipe information and the end point information are the same as in the conventional example.
[0055]
3 and 4 show a target area (water supply system) for extracting a water supply available area.
The water supply system in FIG.₁~ N_{twenty one}And valve V₁~ V₁₈Distribution pipe P consisting of each end of₁~ P₄₈4 and the water supply system in FIG.₄₉And P₅₀Are added. In addition, I is a construction or accident occurrence point, 11 is a temporary cutting line that is set in any direction starting from this I point, a slanting line part on the lower left is a water cut-off area, and a sloping line part on the lower right is an isolated area Show.
[0056]
FIG. 5 and FIG. 6 show the processing procedure for extracting the water supply area in the outer part of the water cut-off area, and the contents thereof are as follows.
The initial values of the water pipe identifier, node identifier and valve identifier at the start of the extraction process are as follows:
・ Node N constituting water cut_Three~ N_Five, N₇, Valve V_Three~ V_Five, V₇, V₈And water pipe P_Five, P₆, P₈~ P_Ten, P₁₅, P₁₆, P₁₈Is "1"
・ Other nodes, valves and water pipes are “0”
It has become.
[0057]
(1) Among the distribution pipes crossing the temporary cutting line 11, the distribution pipe identifier is “0”, that is, the distribution pipe outside the water cut-off area,
・ In the water supply system shown in FIG.₁₂And water pipe P₃₀
・ In the water supply system shown in FIG.₁₂Water pipe P₄₉Water pipe P₅₀And water pipe P₃₀
Select as the reference water pipe and proceed to the next step.
(2) The origin identifiers “13”, “23”, etc. are assigned to the origin end points of these reference water distribution pipes, and the destination identifiers “19”, “29”,. Set and proceed to the next step (see FIGS. 8 and 9). Among these identifiers, the numerical value of the ten digit indicates the cross location number, the first digit “3” indicates the calling end point, and the first digit “9” indicates the called end point.
(3) Cut the connection of each standard water pipe and proceed to the next step. Here, as a method for cutting connection relations, here, a method is used in which the reference water pipe is deleted from the connection water pipe number for each end of the reference water pipe in the end point information. This connection relationship is not obtained from the end point numbers (see FIGS. 12, 13, 16, and 17). For example, standard water distribution pipe P₃₀Is the valve V which is its end point₁₂And node N₁₄This P from the part of each connected water pipe number₃₀Is deleted.
(4) Loop completion flag L for each standard water pipe_FIs set to “0”, and the process proceeds to the next step (see FIGS. 8 and 9).
(5) The variable i indicating the endpoint number is set to “1”, and the process proceeds to the next step.
(6) The extraction state flag F is set to “0” and the process proceeds to the next step. The extraction state flag F is updated from “0” to “1” in response to a change in the identifier of any endpoint of the processing target area.
[0058]
The reference distribution pipe is selected and the connection relationship is cut by the above steps (1) to (6), and the identifier of the end of the reference distribution pipe, the loop completion flag L_FIn addition, initial values such as the extraction state flag F are set, and the process proceeds to the next continuous route selection process starting from the reference water distribution pipe.
[0059]
(7) It is determined whether or not the round process for all end points has been completed. If “YES”, the process proceeds to step (23), and if “NO”, the process proceeds to the next step.
(8) Node identifier N of the endpoint of number i_FiOr valve identifier V_FiIt is determined whether or not one digit is “3”. If “YES”, the process proceeds to the next step, and if “NO”, the process proceeds to step (22).
(9) Distribution pipe identifier P of “0” among the distribution pipes connected to the end point_FIf “YES”, the process proceeds to the next step. If “NO”, the process proceeds to step (22). At this time, each reference cutoff water pipe that has already been subjected to the cutting process in step (3) is excluded from the judgment.
(10) Identifier P of the distribution pipe_FNode identifier N of step (8)_FiOr valve identifier V_FiUpdate with and go to the next step.
(11) Node identifier N of “0” among the other end points (one end point different from the end point obtained in step (8)) of one or a plurality of water pipes_FOr valve identifier V_FIf “YES”, the process proceeds to the next step, and if “NO”, the process proceeds to step (14).
(12) Node identifier N of the end point_FOr valve V_FIs the identifier N of step (8)_FiOr V_FiUpdate with and go to the next step.
(13) The extraction state flag F is set to “1”, and the process proceeds to the next step.
(14) Node identifier N whose one digit is “3” in the other end point_FOr valve identifier V_FIn other words, the other end point has the same end point identifier as that of another reference water pipe. If “YES”, the process proceeds to the next step. If “NO”, the process proceeds to step (17). Here, “YES” means that the distribution pipe paths extending from different reference distribution pipes are connected at the other end point, and this connection state does not occur in the water supply system of FIG. , P of the water supply system in FIG.₅₀And P₃₀It occurs in the distribution pipe route from.
(15) A plurality of calling party identifiers identified in the case of “YES” in each of steps (8) and (14) (P in the case of FIG. 4)₅₀"33" and P₃₀"43") and the corresponding callee identifier (P in the case of FIG. 4)₅₀"39" and P₃₀Each identifier identical to “49” in FIG. 4 is unified to, for example, the younger value (in the case of FIG. 4, “43” is changed to “33”, and “49” is changed to “39”).
(16) The extraction state flag F is set to “1”, and the process proceeds to the next step.
(17) Node identifier N whose one digit is “9” among the other end points_FOr valve identifier V_FIf there is something that has an end point on the arrival side of one of the reference water distribution pipes, proceed to the next step if "YES", if "NO" Goes to step (22). The end point that advances to this step and becomes “YES” is node N in the water supply system of FIG.₁₄In the water supply system of FIG.₁₄And node N₁It is.
(18) Identifier N_FOr V_FIs the identifier N of step (8) or step (15)._FiOr V_FiIf the answer is "YES", it is determined whether the destination end point is that of the reference distribution pipe as the starting part of the distribution pipe route leading to this. Proceed to step, and if “NO”, proceed to step (20). Node N in the water supply system of FIG. 3 and FIG.₁₄This is the only end point that can be “YES” here, and in the case of “YES”, a closed loop composed of the distribution pipe path to the end point and the reference distribution pipe is formed.
(19) Loop completion flag L of the reference distribution pipe corresponding to the end point on the arrival side_FIs set to “1” and the process proceeds to the next step. In each water supply system of FIG. 3 and FIG.₃₀Corresponds to this.
(20) End-point identifier N_FOr V_FIs the identifier N of step (8) or step (15)_FiOr V_FiUpdate with and go to the next step.
(21) The extraction state flag F is set to “1” and the process proceeds to the next step.
(22) Add “1” to the number variable i and return to step (7).
(23) It is determined whether or not the extraction state flag F is “0”. If “YES”, the process proceeds to the next step, and if “NO”, the process returns to step (5). As described above, the extraction state flag F remains at the initial value “0” set in step (6) and proceeds to step (23) because there is no change in the endpoint identifier in the latest round process for each endpoint. That is, in step (9), “YES” is set and the distribution pipe identifier is updated. The other end of each distribution pipe is the boundary point (valve V_Three, V_FourAnd V₈In this case, it is determined that all distribution pipes that can be continuous routes from each reference distribution pipe have been selected.
[0060]
When the end point of number i belongs to the part which is the final end point at that time of the continuous water pipe route from each reference water pipe and is not a water cut area by the processing of steps (8) to (21) above. A new water pipe connected to this end point is added to the water pipe path.
[0061]
In one step of step (8),
Check the identifier of the valve with number i and the node with number i
First check the identifier of the valve of number i or the node of number i, ie one of the valves, for example.
Either method may be taken. In the latter case, the final number of valve V is obtained by repeating steps (7) to (22).₁₈When the processes up to are completed, the number i is set to “0” and then the process returns to step (22), and then the process proceeds to the repetition process of steps (7) to (22) for the node.
[0062]
Steps (11) to (13), steps (14) to (16), and steps (17) to (20) are each a group of processing targets, and the processing order between these is arbitrary.
[0063]
Subsequently, the process proceeds to the following specific processing of the water supply available area.
(24) Loop completion flag L of “1”_FIf “YES”, the process proceeds to the next step, and if “NO”, it is determined that there is no water supply available area, and the series of processing ends. In the water supply system of FIG. 3 and FIG.₃₀(Refer to FIG. 8 and FIG. 9).
(25) Standard distribution pipe P₃₀Each identifier identical to the originating identifier or the terminating identifier is changed to “2”, and the process proceeds to the next step. This identifier changing process is performed in the standard water distribution pipe P.₃₀Standard distribution pipe P in each distribution pipe connected continuously from₄₉And P₅₀These are the distribution pipes excluding, and their end points (however, the boundary points between the distribution pipes and the cut-off areas in the cut-off area are excluded).
(26) Change the distribution pipe identifier of each reference distribution pipe having the end point changed to “2” to “2”, and proceed to the next step. Here, whether or not the end point identifier of the end point of each reference water distribution pipe has been changed to “2” is obtained by first obtaining the end point number of the end point of the reference water distribution pipe from the distribution pipe information and then the end point identifier of this end point number from the end point information What is necessary is just to investigate, in the water supply system of FIG.₃₀In the water supply system shown in FIG.₃₀In addition to the loop completion flag L_FDistribution pipe P with "0" remaining₄₉And P₅₀Also applies.
(27) Change the identifiers of the remaining end points of the reference water distribution pipe and the water pipes connected continuously from the reference water supply pipe to “0” in the isolated area display, and proceed to the next step. In this case, the standard water distribution pipe is the standard water distribution pipe P in both the water supply systems of FIGS.₁₂Is applicable.
(28) The route of the distribution pipe having the distribution pipe identifier of “2” is extracted as the water supply available area, and the series of processing is finished.
[0064]
As described above, the concept such as the cross with the temporary cutting line 11 starting from the point I is used when selecting the reference water distribution pipe in order to simplify the closed loop confirmation process.
That is, the water pipes on both sides of the point I (for example, the water pipe P)₃₀And water pipe P₄₄) Is selected as the reference distribution pipe, the continuous distribution pipe path from one reference distribution pipe stops at the other reference distribution pipe, and the loop completion flag L that should be changed to “1”_FHowever, since the initial value “0” remains, it is necessary to add a process for solving this problem. However, by using the temporary cutting line 11, the water distribution pipes having such a positional relationship are used as the reference water distribution pipes. It is made not to be selected.
[0065]
FIG. 7 is an explanatory diagram showing a skeleton of the processing procedure of FIG. 5 and FIG.
・ In step (1) to step (6), initial values are set.
-In step (8) to step (21), the identifier changing process is performed for the end point of number i,
・ In step (24) to step (28), the water supply available area is specified,
-Loop processing such as Step (7)-Step (23)-Step (5)-Step (7) is performed every time the round processing for all end points that do not belong to the watershed area is completed.
・ When this loop process is repeated and the extraction status flag remains at the initial value set in step (6) and the process proceeds to step (23), the process proceeds to step (24) to step (28) blocks only. Is shown. Note that L indicates how many times this loop processing is performed.
[0066]
In addition to the processing of step (24) to step (28), the restoration of the connection relation of each reference distribution pipe cut in step (3), and then the water supply available area by the method using the conventional temporary water supply source is restored. Confirmation may be performed together.
[0067]
8 and FIG. 9 show origin side end point information, destination side end point information and loop completion flag L for each reference water distribution pipe._FFIG. 8 shows the water distribution system of FIG. 3 and FIG. 9 shows the water distribution system of FIG. 4, respectively.
[0068]
FIG. 10 to FIG. 17 show how the identifiers of the water pipe table, the valve table, and the node table are changed with the repetition of the processing of the above steps (5) to (23), that is, as L increases. FIG. 10 to FIG. 13 correspond to the water supply system of FIG. 3, and FIGS. 14 to 17 correspond to the water supply system of FIG. The format of each table is the same as that shown in FIGS.
[0069]
In any water supply system, the initial value of each identifier at the time when the processing of step (2) is completed is the state after the watershed extraction (the end points constituting the watershed and each identifier of the distribution pipe are “1”. The other end points and the identifiers of the distribution pipes are in a state in which the identifiers of the origin end points and the destination end points of the reference water distribution pipes are changed from “0”.
[0070]
Here, the end point identifier is changed from the state after extraction of the watershed area.
・ Valve V₆, Valve V₁₂, Node N₆And N₁₄(In case of water supply system in Fig. 3)
・ Valve V₆, Valve V₁₂, Node N₁, Node N₆, Node N₁₃, Node N₁₄Node N_{twenty two}And node N_{twenty three}(In case of water supply system in Fig. 4)
8 and 9 are set to the respective end point identifiers.
[0071]
In the case of the water supply system of FIG. 3, for example, the node with the same end point number is given priority over the valve, and the node N₁-Valve V₁-Node N₂-Valve V₂When the round process of steps (8) to (21) is executed in the order of._FiveUntil this time, each identifier is not changed, and the processing target is node N₆For the first time, the judgments of steps (8) and (9) both become “YES”, and the distribution pipe P₁₁And water pipe P₁₄Is changed from the initial value “0” to “13”.
[0072]
After that, the processing target is the valve V₁₂Water pipe P when moving to₂₉And node N₁₃And the processing target is this node N₁₃Water pipe P when moving to₂₈And node N₁₁Are changed from the initial value “0” to “23” by the determination in step (8) to step (12) and the identifier update process.
[0073]
After that, the processing target is the last node N_{twenty one}However, no new identifier update occurs, and the second round of identifier update processing starts through the route of step (7) -step (23) -step (5).
[0074]
When the number of times L of passing through this route is “L = 1” and the process returns to step (5), that is, when the identifier update process for the first round is completed, the identifier “13” or “23” has
・ Standard water distribution pipe P₁₂Node N based on₆Water pipe P₁₁And water pipe P₁₄
・ Standard water distribution pipe P₃₀Valve V based on₁₂Water pipe P₂₉, Node N₁₃Water pipe P₂₈And node N₁₁
Each group.
[0075]
Next, the identifier is changed from “0” to “23” in the identifier update process in the second round until “L = 2” and the process returns to step (5).₃₀Distribution pipe P based on_{twenty five}, Valve V_TenWater pipe P₂₆, Valve V₁₁Water pipe P₂₇And node N₁₂6 elements.
[0076]
In addition, standard distribution pipe P₁₂Node N that is the originating endpoint of₆There is no end point or water distribution pipe whose identifier is changed to “13” by the identifier update processing in the second and subsequent rounds on the route that started from.
[0077]
Next, the identifier is changed from “0” to “23” in the third round of identifier update processing until “L = 3” and the process returns to step (5).₃₀Distribution pipe P based on_{twenty four}And node N_TenAre two elements.
[0078]
In this way, as the number of times L passing through the route of step (7) -step (23) -step (5) increases, the number of water pipes, valves and nodes having the identifier "23" also increases.
[0079]
And the identifier is changed in each identifier update process after the 4th round.
・ In the 4th round (L = 4), water pipe P₄₈, Node N₁₉Water pipe P₄₅, Valve V₁₇Water pipe P₄₆, Valve V₁₈Water pipe P_{twenty three}And node N₉8 elements
・ On the 5th round (L = 5), water pipe P₄₄, Node N₁₈Water pipe P₄₁, Node N₁₇Water pipe P₄₂, Valve V₁₆Water pipe P₄₇, Node N₂₀Water pipe P_{twenty two}And valve V₁10 elements of
・ In the 6th round (L = 6), the distribution pipe P₃₈, Node N₁₆Water pipe P₄₀Water pipe P_{twenty one}, Node N₈Water pipe P₂₀, Valve V₂And water pipe P₁₉8 elements
・ In the 7th round (L = 7), water pipe P₃₆, Valve V₁₄Water pipe P₃₇, Valve V₁₅And water pipe P₁₇5 elements
・ In the 8th round (L = 8), water pipe P₃₅, Node N₁₄Water pipe P₃₉And node N_{twenty one}4 elements
・ In the 9th round (L = 9), the distribution pipe P₃₁, Node N₁₅Water pipe P₃₃, Node N₁Water pipe P₃₂And valve V₁₃6 elements
・ In the 10th round (L = 10), water pipe P₁, Valve V₉Water pipe P₂, Node N₂And water pipe P₃₄5 elements
・ In the 11th round, water pipe P_ThreeAnd water pipe P_Four2 elements
It is. In addition, standard distribution pipe P₃₀Node N at the destination end of₁₄The node identifier of is changed from “29” to “23” in the 8th round, and the reference distribution pipe P is processed by the process of step (19) at this time.₃₀Loop completion flag L_FIs changed from the initial value “0” to “1”.
[0080]
In this way, the standard water distribution pipe P₃₀Valve V at the starting end of₁₂From the 11th round, the identifier update target is only the distribution pipe, so in steps (13), (16) and (21) The extraction state flag F is not changed from the initial value “0” to “1”. Therefore, the process proceeds to step (23) with this initial value, and the determination there is “YES”.
[0081]
The identifier of each element (distribution pipe, node and valve) at the time when the judgment of step (23) becomes “YES”
▲ 1 ▼ 'Watershed area element (lower left slanted line part) ... "1"
(2) ′ Isolated area element (lower right slanted line part) “0”, “13”, “19”
(3) 'Water supply possible area element ... "0", "23"
It has become. Here, it is the reference water pipe P that has the identifier “0” of (2) ′.₁₂Water pipe P₁₃And water pipe P₇It is the standard distribution pipe P that has the identifier “0” of (3) ′.₃₀Only.
[0082]
Each of these identifiers is processed by the processing from step (24) to step (28).
・ Each identifier of isolated area element is set to “0”
・ Each identifier of the water supply area element is “2”
To be unified. In addition, each identifier of the watershed element remains “1”.
[0083]
Next, how each identifier changes in the case of the water supply system of FIG. 4 will be described.
In this water supply system, four standard water pipes P₁₂, P₄₉, P₅₀And P₃₀Is selected, and the initial values shown in FIG. 9 are set to the end point identifiers of the calling side end point and the destination side end point, respectively.
[0084]
The order of the round process for each end point here is the valve V₁-Valve V₂-Valve V_Three... Valve V₁₆-Valve V₁₇-Valve V₁₈-Node N₁-Node N₂-Node N_Three... Node N_{twenty one}-Node N_{twenty two}-Node N_{twenty three}In this way, the entire valve is given priority over the node.
[0085]
In this one-round process, first the valve V₁₁Until this time, there is no change of each identifier, and the processing target is the valve V₁₂For the first time, the judgments of steps (8) and (9) both become “YES”, and the distribution pipe P₂₉Is changed from the initial value “0” to “43”.
[0086]
At this time, unlike the case of the water supply system of FIG.₂₉The other end point N₁₃Is the standard water distribution pipe P₅₀Its node identifier N at the originating endpoint (node) of_FIs "33", the determination result in the next step (11) is "NO", and this endpoint identifier is not changed.
[0087]
Further, the difference from the case of the water supply system in FIG. 3 is that the determination result in step (14) is “YES”. As a result, in the next step (15), the valve V₁₂Each identifier identical to the originating side identifier “43” of node N₁₃And the same identifier as the called side identifier “49” corresponding to the calling side identifier “43” is the node N_{twenty three}To the called side identifier “39”.
[0088]
This valve V₁₂In the process of valve V₁₂Valve identifier “43” and water pipe P₂₉The distribution pipe identifier “43” of node N₁₃To the calling party identifier “33”, and the node N₁₄Node identifier (destination identifier) “49” of node N_{twenty three}To the called side identifier “39”. Which one to change is arbitrary.
[0089]
By this change, standard water pipe P₅₀Distribution pipe route and standard distribution pipe P from₃₀It can be reflected in each identifier that it is connected at a certain endpoint with that from.
[0090]
After that, the processing target is node N₆When moving to, water pipe P₁₁And water pipe P₁₄Each of the distribution pipe identifiers is changed from the initial value “0” to “13” by the determination in step (8) to step (10) and the identifier update process.
[0091]
After that, the processing target is node N₁₃When moving to, water pipe P₂₈And nodes₁₁Are respectively changed from the initial value “0” to “33” by the determination in step (8) to step (12) and the identifier update process.
[0092]
After that, the processing target is the last node N_{twenty two}However, no new identifier update occurs, and the second round of identifier update processing starts through the route of step (7) -step (23) -step (5).
[0093]
The element whose identifier is changed before the first round of processing, that is, “L = 1” and returning from step (23) to step (5) is
・ Standard water distribution pipe P₁₂Distribution pipe P based on₁₁And P₁₄(Identifier after change “13”)
・ Standard water distribution pipe P₅₀And P₃₀Valve V based on₁₂Water pipe P₂₉Water pipe P₂₈And node N₁₁(Identifier after change "33")
・ Standard water distribution pipe P₅₀And P₃₀Node N based on₁₄(Identifier after change "39")
Each.
[0094]
The elements whose identifiers are changed in each process after the second round are as follows, and the identifiers after the change at this time are all “33”.
That is,
・ In the second round, water pipe P_{twenty five}, Valve V_TenWater pipe P₂₆And valve V₁₁4 elements
・ In the third round, water pipe P₂₇, Node N₁₂Water pipe P_{twenty four}, Node N_TenWater pipe P_{twenty three}, Node N₉Water pipe P₄₈, Node N₁₉Water pipe P₄₅, Valve V₁₇Water pipe P₄₆And valve V₁₇12 elements
・ In the 4th round, water pipe P₄₇, Node N₂₀Water pipe P₄₄, Node N₁₈Water pipe P₄₂, Valve V₁₆Water pipe P₄₁, Node N₁₇Water pipe P_{twenty two}And valve V₁10 elements of
・ In the 5th round, water pipe P₄₃Water pipe P₄₀Water pipe P₃₈, Node N₁₆Water pipe P_{twenty one}, Node N₈Water pipe P₂₀And valve V₂8 elements
・ In the 6th round, water pipe P₃₆, Valve V₁₄Water pipe P₃₇, Valve V₁₅Water pipe P₁₇And water pipe P₁₉6 elements
・ In the 7th round, water pipe P₃₉, Node N_{twenty one}Water pipe P₃₅, Node N₁₄Water pipe P₃₁, Node N₁₅Water pipe P₃₃, Node N₁Water pipe P₃₂And valve V₁₃10 elements of
・ In the 8th round, water pipe P₁, Valve V₉And water pipe P₃₄3 elements
・ In the ninth round, water pipe P₂And node N₂2 elements
・ In the 10th round, water pipe P_ThreeAnd water pipe P_Four2 elements
It has become. In addition, standard distribution pipe P₃₀Node N that is the destination endpoint of₁₄The node identifier after the change is changed from “39” to “33” in the seventh round, and the reference water pipe P is changed by the processing of step (19) at this time.₃₀Loop completion flag L_FIs changed from the initial value “0” to “1”.
[0095]
In this way, the identifiers are updated sequentially, but the identifiers are updated in the tenth round of the distribution pipe P._ThreeAnd P_FourTherefore, the extraction state flag F does not change from “0” to “1”, and proceeds to step (23), where the determination is “YES”.
[0096]
The identifier of each element (distribution pipe, node and valve) at the time when the judgment of step (23) becomes “YES”
▲ 1 ▼ 'Watershed area element (lower left slanted line part) ... "1"
(2) ′ Isolated area element (lower right slanted line part) “0”, “13”, “19”
(3) 'Water supply possible area element "0", "23", "33"
It has become. It is to be noted that the reference water pipe P has the identifier “0” of (2) ′.₁₂Water pipe P₁₃And water pipe P₇It is the standard distribution pipe P that has the identifier “0” of (3) ′.₂₀, Standard water distribution pipe P₅₀And standard water distribution pipe P₃₀It is.
[0097]
Each of these identifiers is processed by the processing from step (24) to step (28).
・ Each identifier of isolated area element is set to “0”
・ Each identifier of the water supply area element is “2”
To be unified. In addition, each identifier of the watershed element remains “1”.
[0098]
【The invention's effect】
Thus, the present invention seeks a closed loop consisting of a supply line path starting from and returning to a reference supply line arbitrarily set in the outer portion of the water cut-off area, and this closed loop and the supply line connected thereto Is determined to be a supplyable area.
[0099]
As a result, the troublesome work of selecting a temporary supply source that can be an actual supply source after specifying a water cutoff area as in the past becomes unnecessary, while the connection between the outside of the processing target area and the entire supplyable area is closed loop. Therefore, it is possible to provide an extraction method and an apparatus therefor that are highly reliable and highly convenient in extracting a supplyable area and an isolated area.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating the principle of the present invention.
FIG. 2 is an explanatory diagram showing an outline of a processing procedure in a supplyable area specifying unit according to the present invention.
FIG. 3 is an explanatory view (No. 1) showing a target area for extracting a water supply possible area according to the present invention.
FIG. 4 is an explanatory diagram (No. 2) showing a target area for extraction of a water supply possible area according to the present invention.
FIG. 5 is an explanatory diagram (No. 1) showing a processing procedure for extracting a water supplyable area in an outer portion of a water cutoff area of the present invention.
FIG. 6 is an explanatory diagram (No. 2) showing a processing procedure for extracting a water supplyable area in an outer portion of a water cutoff area of the present invention.
7 is an explanatory diagram showing a skeleton of the processing procedure of FIGS. 5 and 6. FIG.
FIG. 8 is an explanatory diagram showing a reference water pipe table in the case of the target area of FIG. 3;
9 is an explanatory diagram showing a reference water pipe table in the case of the target area of FIG. 4. FIG.
10 is a water pipe identifier P in the water supply area extraction procedure of FIG._FIt is explanatory drawing (the 1) which shows the change of.
11 is a distribution pipe identifier P in the water supply area extraction procedure of FIG._FIt is explanatory drawing (the 2) which shows the change of these.
12 is a valve identifier V in the water supply available area extraction procedure of FIG. 3;_FIt is explanatory drawing which shows the change of.
FIG. 13 is a node identifier N in the water supply available area extraction procedure of FIG. 3;_FIt is explanatory drawing which shows the change of.
14 is a distribution pipe identifier P in the water supply available area extraction procedure of FIG._FIt is explanatory drawing (the 1) which shows the change of.
15 is a distribution pipe identifier P in the water supply available area extraction procedure of FIG. 4;_FIt is explanatory drawing (the 2) which shows the change of these.
16 is a valve identifier V in the water supply available area extraction procedure of FIG. 4;_FIt is explanatory drawing which shows the change of.
FIG. 17 is a node identifier N in the water supply available area extraction procedure of FIG. 4;_FIt is explanatory drawing which shows the change of.
FIG. 18 is an explanatory diagram showing an outline of a general extraction system for a water cutoff area and a water supplyable area.
FIG. 19 is an explanatory diagram showing an example of a water supply system in a processing target area.
FIG. 20 is an explanatory diagram showing an example of a data format of a general distribution pipe record in a work file.
FIG. 21 is an explanatory diagram showing an example of a data format of a general valve record in a work file.
FIG. 22 is an explanatory diagram showing an example of a data format of a general node record in a work file.
FIG. 23 is an explanatory view showing a general procedure for extracting a water cut area starting from a water cut place.
FIG. 24 shows P in the watershed extraction procedure of FIG._FIt is explanatory drawing (the 1) which shows the change of.
25 is a diagram showing P in the watershed extraction procedure of FIG._FIt is explanatory drawing (the 2) which shows the change of these.
FIG. 26 shows V in the watershed extraction procedure of FIG._FIt is explanatory drawing which shows the change of.
FIG. 27: N in the watershed procedure of FIG._FIt is explanatory drawing which shows the change of.
[Explanation of symbols]
In FIG.
1 ... Designated area
2 ... Supply unspecified area specifying means
3 ... Supplyable area identification means
4 ... Supply line information
5 ... Endpoint information
I: Break point based on accidents or construction
P '... Supply line
V '...
N '... node

Claims (14)

A first supply line path obtained by starting from a specific location based on construction or an accident and sequentially finding the next end point in a supply system composed of each supply line having an end point as a shut-off unit or node Select each of the end points up to the first cut-off portion, and the supply line network specified by each of these end points is set as a non-supplyable area,
In the portion excluding the supply line network, a reference supply line is first selected from the supply lines, and then a second portion consisting of a portion connected in sequence to the reference supply line in the supply lines not selected. Select the supply line route for
When the second supply line path is connected via the reference supply line, it is determined that the second supply line path and the reference supply line connected to the second supply line path are within a supplyable area. Extraction method of supplyable area. 2. The supplyable area extracting method according to claim 1, wherein the supply line that intersects a line set in an arbitrary direction from the specific location is used as the reference supply line. In specifying the unsupplyable area and the supplyable area,
For each of the end points, end point information having an end point identifier relating to the supply line number of each of the supply lines connected to the end point and the supply possibility to the end point;
For each supply line, supply line information having an end point number of both end points and a supply line identifier relating to the supply possibility to the supply line;
The method of extracting a supplyable area according to claim 1 or 2, wherein at least one of the above is used. In specifying the supply available area,
Excluding the supply line number of the reference supply line from the end point information of each end point of the reference supply line,
For each reference supply line, a caller identifier is set at one end point and a callee identifier is set at the other end point, and then connected to a first end point having the same end point identifier as the caller identifier. The supply line consisting of the end points having the same end point identifier as the originating side identifier is obtained by repeating the process of changing the end point identifier of the other second end point of the supply line to the originating side identifier. A continuous portion as the second supply line path;
As a criterion for determining whether or not the second supply line path is connected via the reference supply line, the consistency between the end point identifier before the change and the destination identifier corresponding to the calling side identifier is used. The method of extracting a supplyable area according to claim 3. In specifying the supply available area,
When the end point identifier of the second end point is the same as the second calling side identifier different from the first calling side identifier which is a premise when the first end point is selected, it is set so far. In addition, the same identifier as either one of the first or second originating identifier is changed to the other, and the called identifier corresponding to the one is changed to the called identifier corresponding to the other. 5. The method of extracting a supplyable area according to claim 4, wherein both are performed. In specifying the supply available area,
The supply line identifier of the reference supply line is changed to a content that can be distinguished from each of the supply line not selected and the originating identifier and the terminating identifier described later,
For each reference supply line, an origination identifier is set for the supply line connected to one of the end points, and a destination identifier is set for the supply line connected to the other end point. The same supply as the origination identifier obtained by repeating the process of changing the supply line identifier of the second supply line connected to the first supply line having the same supply line identifier to the origination identifier A continuous portion of the supply lines having line identifiers as the second supply line path;
As a criterion for determining whether or not the second supply line path is connected via the reference supply line, the consistency between the end point identifier before the change and the destination identifier corresponding to the calling side identifier is used. The method of extracting a supplyable area according to claim 5. In specifying the supply available area,
When the supply line identifier of the second supply line is the same as the second calling party identifier different from the first calling party identifier, which is a premise when the first supply line is selected, it is set up to that point The same identifier as either one of these first or second calling party identifiers is changed to the other, and the called party identifier corresponding to this one is changed to the called party identifier corresponding to the other. 7. The supplyable area extracting method according to claim 6, wherein the processing is performed together. A first supply line path obtained by starting from a specific location based on construction or an accident and sequentially finding the next end point in a supply system composed of each supply line having an end point as a shut-off unit or node A supply disabled area specifying means for selecting each of the end points up to the first cut-off section and setting the supply line network specified at each of the end points as a supply disabled area;
In the portion excluding the supply line network, a reference supply line is first selected from the supply lines, and then a second portion consisting of a portion connected in sequence to the reference supply line in the supply lines not selected. When the second supply line path is connected via the reference supply line, the second supply line path and the reference supply line connected to the second supply line path can be supplied. A supply range specifying means for determining that
An apparatus for extracting an available area, comprising: 9. The supplyable area extracting device according to claim 8, wherein the supplyable area specifying means uses, as the reference supply line, the supply line that intersects a line set in an arbitrary direction from the specific location. When the unsupplyable area specifying unit and the unsupplyable area specifying unit specify the unsupplyable area and the supplyable area,
For each of the end points, end point information having an end point identifier relating to the supply line number of each of the supply lines connected to the end point and the supply possibility to the end point;
For each supply line, supply line information having an end point number of both end points and a supply line identifier relating to the supply possibility to the supply line;
10. The supplyable area extracting apparatus according to claim 8 or 9, wherein at least one of the above is used. When the supplyable area specifying means specifies the supplyable area,
Excluding the supply line number of the reference supply line from the end point information of each end point of the reference supply line,
For each reference supply line, a caller identifier is set at one end point and a callee identifier is set at the other end point, and then connected to a first end point having the same end point identifier as the caller identifier. The supply line consisting of the end points having the same end point identifier as the originating side identifier is obtained by repeating the process of changing the end point identifier of the other second end point of the supply line to the originating side identifier. A continuous portion as the second supply line path;
As a criterion for determining whether or not the second supply line path is connected via the reference supply line, the consistency between the end point identifier before the change and the destination identifier corresponding to the calling side identifier is used. The extractable area extracting device according to claim 10. When the supplyable area specifying means specifies the supplyable area,
When the end point identifier of the second end point is the same as the second calling side identifier different from the first calling side identifier which is a premise when the first end point is selected, it is set so far. In addition, the same identifier as either one of the first or second originating identifier is changed to the other, and the called identifier corresponding to the one is changed to the called identifier corresponding to the other. 12. The supplyable area extracting device according to claim 11, wherein the extraction is performed together. When the supplyable area specifying means specifies the supplyable area,
The supply line identifier of the reference supply line is changed to a content that can be distinguished from each of the supply line not selected and the originating identifier and the terminating identifier described later,
For each reference supply line, an origination identifier is set for the supply line connected to one of the end points, and a destination identifier is set for the supply line connected to the other end point. The same supply as the origination identifier obtained by repeating the process of changing the supply line identifier of the second supply line connected to the first supply line having the same supply line identifier to the origination identifier A continuous portion of the supply lines having line identifiers as the second supply line path;
As a criterion for determining whether or not the second supply line path is connected via the reference supply line, the consistency between the end point identifier before the change and the destination identifier corresponding to the calling side identifier is used. 13. The supplyable area extracting device according to claim 12. When the supplyable area specifying means specifies the supplyable area,
When the supply line identifier of the second supply line is the same as the second calling party identifier different from the first calling party identifier, which is a premise when the first supply line is selected, it is set up to that point The same identifier as either one of these first or second calling party identifiers is changed to the other, and the called party identifier corresponding to this one is changed to the called party identifier corresponding to the other. 14. The supplyable area extracting device according to 13, wherein the processing is performed together.

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