JP2001222521A - Document preparation system and recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To automatically and efficiently prepare a document for a road occupancy/use permission application from design data and further to exactly reflect this document with design contents. SOLUTION: This document preparation system is provided with a format pattern library storing plural format patterns corresponding to a road occupancy/use permission application or a road occupancy/use permission application format and a graphic pattern library storing plural graphic patterns. When buried object plan data 9 and 11-13 containing buried object laying route data are generated on the basis of status quo drawing data 7, buried object position data 3 and 4 and buried object design data, on the basis of format pattern data from the format pattern library and the buried object plan data, a road occupancy or use permission application is prepared and on the basis of graphic data from the graphic pattern library, the status quo drawing data and the buried object laying route data, an attached drawing is prepared.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a document preparation system for preparing documents such as a road occupation permit application and a road use permit application relating to the laying of an underground buried object, and a recording medium therefor.

[0002]

2. Description of the Related Art Generally, gas pipes, water and sewage pipes, power cable pipes, and communication cable pipes (telephone lines, optical fiber networks, C
In order to lay underground buried objects called “lifeline” such as ATV network, ITS, information box, etc., common ditch, etc., first, survey the laying site and survey the current topography or bury other types Investigate things and grasp the current situation. In the next design stage, the laying route of the underground buried object is planned with due consideration of the grasped current situation, the design data such as the plan plan view and the plan sectional view are created, and various calculation data are created.
After the design and quantity calculation, it enters into the stage of constructing the underground buried object based on the design result, but before that, create documents such as `` Road occupancy permission application '' and `` Road use permission application '', These documents must be submitted to road owners or road managers (national and local governments; hereinafter simply referred to as “road managers”) and road supervisors (prefectural police).

Conventionally, such documents have been manually written by a drawing clerk or an operator while referring to design data. In many cases, it is often necessary to submit a large number of attached documents covering several tens of pages, such as drawings and tables, for one application. The work of preparing application documents is often a repetition of the same work, but the format of the application form and the auxiliary documents attached to it are not limited to the road administrator / road supervisor in charge, but also to the area (local organization).
Since the specifications differ depending on each other, and manual preparation of documents is performed, not only the problem that the content of the work is specialized or too much data is required, but also a work error is inevitably involved. For this reason, further checks for accuracy are required, and preparation of application documents requires a great deal of time and effort.

[0004] As described above, the application document preparation work is a major bottleneck in the efficiency of the work of laying underground buried objects, and automation is desired.

[0005]

SUMMARY OF THE INVENTION In view of such circumstances, the present invention automatically provides a "road occupation license application" based on the current situation data and design data acquired at the design stage when laying underground buried objects. Or the main purpose is to provide a document creation support system that can efficiently create a "Road Use Permit Application" and the documents attached to these, and create an application document that accurately reflects the design details. And

[0006]

According to one aspect of the present invention, there is provided a means for acquiring status map data, a means for acquiring position data of an already buried object, a means for inputting buried object design data, Based on the format pattern library that stores multiple format patterns corresponding to the permit application or road use permit application format, the acquired current state map data and the existing buried object position data, and the entered buried object design data. Means for generating buried object planning data;
A means for reading format pattern data from the format pattern library in accordance with the type instruction of document creation, and a road occupation permission application or a road use permission application based on the generated buried object plan data and the read format pattern data. And a document creation system comprising means for generating document data for the system, and a step of obtaining current state map data; a step of obtaining existing object position data; a step of inputting embedded object design data; Generating the buried object plan data based on the current state map data and the existing buried object position data and the inputted buried object design data, and a plurality of roads corresponding to the road occupation permission application or the road use permission application format. From the format pattern library that stores the format patterns of the A program comprising the steps of reading data and generating document data for a road occupation permission application or a road use permission application based on the generated buried object plan data and the read format pattern data. A recording medium for document preparation characterized by recording is provided.

According to another feature of the present invention, a means for acquiring current state map data, a means for acquiring existing buried object position data, a means for inputting buried object design data, a road occupation permission application or a road use permission A format pattern library that stores a plurality of format patterns corresponding to the application format, a graphic pattern library that stores a plurality of graphic patterns, acquired status map data and buried object position data, and input Means for generating buried object planning data based on the buried object design data, and means for extracting buried object laying route data from the buried object planning data,
A means for creating a road occupation permission application or a road use permission application based on the generated buried object plan data and predetermined format pattern data read from the format pattern library, and acquired status map data A means for generating a road occupation permission application or a drawing attached to the road use permission application based on the extracted buried object laying route data and the graphic data selected from the graphic pattern library Creation system, and the step of acquiring the current state map data, the step of obtaining the existing buried object position data, the step of inputting the buried object design data, the obtained current state map data and the existing buried object position data, and, Based on the input design data of buried objects,
A step of generating buried object plan data, a step of extracting buried object laying route data from the buried object plan data, and a format pattern storing a plurality of format patterns corresponding to a road occupation permission application or a road use permission application format Reading a predetermined format pattern data from the library; generating a road occupation permission application or a road use permission application based on the generated buried object plan data and the read format pattern data; , A road occupation permit application or a road use permission based on the acquired current state map data, the extracted buried object laying route data, and the graphic data selected from the graphic pattern library storing a plurality of graphic patterns. Recording a program comprising the steps of generating a drawing attached to the application Recording medium for paperwork, characterized the door is provided.

According to one feature of the present invention, there is provided a format pattern library storing a plurality of format patterns corresponding to a road occupation permission application or a road use permission application format. When the buried object plan data is generated based on the buried object position data and the buried object design data, the format pattern data corresponding to the type instruction of the document creation is read from the format pattern library, and the buried object plan data is read. Since it is configured to generate document data for a road occupation permission application or a road use permission application in combination with the format pattern data, the "road occupation permission application" or "road use permission application" and It is possible to efficiently create the attached document and, at the same time, create an application document accurately reflecting the design contents.

According to another feature of the present invention, a format pattern library storing a plurality of format patterns corresponding to a road occupation permission application or a road use permission application format, and a plurality of graphic patterns are stored. A figure pattern library is provided, and based on the current state map data, the existing buried object position data and the buried object design data, the buried object planning data is generated, and the buried object laying route data is extracted from the buried object planning data, Based on the format pattern data and the buried object planning data read from the format pattern library, a road occupation permission application or a road use permission application is created, and the graphic data selected from the graphic pattern library, the present situation data and the buried object are prepared. Based on the laying route data, a road occupation permit application or road use permission application Since so as to produce a drawing to be subjected, the drawings that are attached "road private use license application" or "road license application" and to create efficiently,
In addition, it is possible to create an application document that accurately reflects the design contents.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment in which the present invention is applied to buried power pipes will be described below in detail with reference to the drawings. The following embodiment is merely an example and can be applied to various underground objects such as water pipes, communication (telephone) pipes, etc., in addition to power pipes. Various configuration changes are possible without departing from the scope of the invention.

[System Configuration] FIG. 1 is a block diagram showing the overall configuration of a document creation system according to an embodiment of the present invention. In this example, the system includes a host computer 1 that mainly performs underground burial design and application document creation, a site computer 2 for acquiring current terrain data (three-dimensional coordinates), a digitizer system 3 and a scanner system 4. It consists of various drawing input devices.

In order to grasp the current situation of a site where new underground objects are to be laid (laid), generally, map graphic data and attribute data already obtained by a GIS (Geographic Information System) which can be used by a design builder. However, since the present situation changes every moment, usually, the present situation is observed using the on-site computer 2 and the latest present situation map data is obtained digitally. The on-site computer 2 is, for example, a portable personal computer using device called an “electronic flat plate”, and includes a total station (TS) 3 and a GPS (Global Positio).
A digital surveying device such as a ning System (Global Positioning System) device 4 is connected for communication, and an automatic contour generation function is provided by application software.

The total station (TS) 3 is an external business machine that is installed on a tripod at the surveying site and is used. The light emitted from the TS 3 is applied to a reflecting mirror at the measuring point and the angle and distance are calculated from the time when the light returns. Digitally measure three-dimensional position coordinates. In the latest TS model, there is a non-prism type that does not require a prism. GPS4 is GPS
Digital geodetic device based on the system. Due to the remarkable advancement of technology in recent years, miniaturization is achieved, measurement operation is easy, equipment is very simple, and very high accuracy digital three-dimensional position coordinates in a short time. Since data can be obtained, there is no obstacle (curtain) such as a high-rise building around the survey point in the GPS survey, and this is used when high-precision survey is required.

The digital survey data from the TS 3 or the GPS 4 is transferred to the on-site computer 2 by wireless or transmission line, the three-dimensional coordinates of each survey point (generally several hundred to 1,000 points) are determined by a program, and the contour line data is obtained. Automatically generated. By repeating the operation of inputting the attributes of points such as telephone poles and sidewalk edges simultaneously with the measurement, the on-site computer 2 can also generate the current state map data (three-dimensional coordinates) on the screen.

The host computer 1 includes surveying devices 5 and 6
Receives the digital survey data of each measurement position sent directly from the computer or via the on-site computer 2, determines the three-dimensional coordinates of all the measurement points in the processing block 7, automatically generates the contour data, and performs the attribute input work. Then, the current plane data is generated. In addition, the processing block 7 is a current state map data (three-dimensional coordinates) generated by the site computer 2.
Is received, this data can be directly output as the current plane data.

On the other hand, in order to grasp the underground buried object already laid at the site, the GIS which can be used by the design builder is used, or by conducting a desk survey or a test excavation survey, the underground buried object is checked. Get current status data. In the case of a desk survey, a drawing reader such as the digitizer system 3 or the scanner system 4 can be used. The digitizer system 3 is also called a “digital tracer”, and takes in a drawing of a paper by drawing it into the host computer 1 by tracing the drawing with a remouse, and is a method of reading only necessary objects. , It is suitable for reading only a part of the equipment drawing,
Input attributes at the same time as reading the object.

The scanner system 4 is also an input device for taking a paper drawing into the computer 1. Since the scanner system 4 reads everything described in the drawings, it is suitable for reading accurate equipment drawings based on actual measurements, such as equipment drawings of a power company. Scanner system 4
Is used, a procedure is adopted in which, once the entire drawing has been read, attributes are assigned to only necessary parts. Therefore, which one of the digitizer system 3 and the scanner system 4 is used depends on the function and purpose.

By using such drawing readers 3 and 4, the already laid underground objects and the like are traced from the existing drawings, and in the processing block 8 of the host computer 1, the type of the buried equipment and its Obtain data on the existing underground buried objects including information such as position and depth.
The acquired existing underground object data is additionally input to the existing plane data generated in the processing block 7, and the figure is edited with the aid of display on the display screen, and the underground object data is corrected. It can correspond to plane data accurately.

Subsequently, a design stage DS including processing blocks 9 to 13 is entered, and various design data are created in accordance with the floor plan. First, the laying route is selected / decided in consideration of the relationship with the existing underground buried object on the current plan, and plan data is created (processing block 9). Based on this, plan plan design data is created. (Processing block 11) Further, by inputting the attributes and positions of the laid underground objects, plan longitudinal design data is generated (processing block 12), and plan cross-sectional design data is created (processing block 13). For example, setting of a pipe type, insertion of a plane curve of a power pipe, insertion of a manhole, and the like are performed. Also, the cross section design data is created by reading the crossing distance from the plan view and inputting the altitude using the plan view / longitudinal section design data and the existing underground buried object data. As a result, plan data including plan view data, longitudinal view data, cross-sectional view data, and the like is created, and based on each plan data, for example, a design drawing is output from a color laser printer or a color inkjet plotter. The use of a color inkjet plotter allows the final output drawing to be output in color at the maximum size.

Since the power pipe is laid in this system, the processing block 10 determines the tension and the cable strength when the power cable is pulled after the buried pipe is laid. The processing block 10 automatically calculates the elongation and bending of the laid cable from the plan view and longitudinal section design data and automatically calculates the tension, thereby performing a pulling tension simulation and creating a cable pulling tension calculation report. The result of the tension calculation process is fed back to the laying route selection / determination process of the processing block 9, and if a desired result cannot be obtained, the laying route is selected again.

In the design stage DS, when the buried pipe propulsion method is performed, a drawing of a vertical shaft temporarily constructed by steel sheet pile, a liner plate, a main shaft horizontal sheet pile, etc. (a temporary shaft temporary construction diagram).
And collects various quantities from each design data, and creates a quantity calculation report, a gold-finished design document, and the like. The various data obtained in the design stage DS are stored in a storage device provided in the host computer 1.

When the design stage DS is completed by performing such design and quantity calculation, a document creation stage PS including processing blocks 14 and 15 is entered. That is, before the construction stage of the underground buried object based on the design result, the “road occupation permission application” (processing block 14) or the “road use permission application” (processing block 15) submitted to the management / supervisory agency in charge ) Is automatically created from design / plan data. In the processing block 14, in order to occupy the road when constructing the underground buried object, a road occupation permission application to be submitted to a road manager / institution (a country, a local government, and its branch office) of the road with the underground buried object is created. I do. In the processing block 15, a road use permission application to be submitted to a road supervising agency (prefectural police station) to use the road, and a position map, a plan view, a traffic measure map, and the like that need to be attached to the application. Create Here, processing block 9 is used to create the position map and the plan view.
Can be used.

[Main Processing Flow] FIGS. 2 and 3 are flowcharts showing the overall processing flow of an underground buried work laying work support system with a document creation function according to an embodiment of the present invention. Power pipes will be laid underground. Step M1
When the current situation is digitally surveyed by the surveying devices 5 and 6, the survey result is sent to the host computer 1 via the on-site computer 1 and the like, and digital survey data representing the current topography is obtained in step M2. In the next step M3, current state map data is generated based on the digital survey data, and in step M4, the current state map is obtained.

Next, in step M5, the embedded object reflection diagram data is generated. For this purpose, for example, as shown in Step M6, the GIS is used by using an equipment ledger diagram of a company managing the existing underground buried object at the laying site.
If there is data, use it. Existing underground buried objects include already laid power pipes, water pipes, gas pipes, sewer pipes, and other buried objects.

Here, a method for reflecting the existing telephone equipment by the digitizer system 3 will be described. in this way,
A telephone equipment drawing is set in the digitizer system 3, and first, a current drawing generated by the host computer 1,
An operation of adjusting the positional relationship with the telephone equipment drawing set in the digitizer system 3 is performed. That is, using a mouse, two points of the current state drawing and two points of the telephone equipment drawing (for example, a manhole, a corner of an intersection, etc.) are matched on the computer on the display screen, and the two drawings are overlapped. State. Since the function of automatically changing the scale is used in this superimposing operation, it is possible to superimpose even drawings having different scales.

Subsequently, the object to be reflected in the telephone equipment drawing set in the digitizer system 3, that is, the telephone line, is clicked with the mouse. Usually, since the telephone line is only displayed on the screen as a picture, an input screen is opened and attributes (for example, pipe material (“vinyl pipe” or the like) and pipe diameter (“100 mm "
), Earth covering (“0.5 m to 1.0 m” etc.)]. By repeating this operation, the telephone line is superimposed on the existing drawing, and a drawing in which the burial route of the telephone line is entered can be created.

Next, a method of reflecting the survey result of a buried object by the scanner system 4 will be introduced. First, when a drawing of a water supply facility at a site obtained from a waterworks bureau is read by a scanner, the status of the reading by the scanner is displayed on a display screen of the host computer 1. When the reading of the drawings is completed, the same two points are put together on the computer on the already created current drawing and on the read water supply equipment drawing, and the two drawings are overlapped using the automatic scale change function.

When the two drawings overlap, an input screen is opened, and the user clicks on a water pipe to be given an attribute.
Attributes of the water pipe (for example, pipe material (“steel pipe” etc.), pipe diameter (“200 mm” etc.), earth covering (“1.2 m to 1.5 m”)
Etc.)]. By this repetitive operation, the data of the water supply equipment drawing is superimposed on the current state drawing, and a drawing in which the water supply laying route is entered can be created.

Similarly, for the gas, sewage and other buried objects, the current state data of the existing underground buried object is obtained by superimposing the current state data on the underground buried object, and all the buried objects are reflected on the existing state map data, thereby obtaining the step M7. , The data generation of the embedded object reflection diagram can be completed.

In the design stage from the following step M8, first, in step M8, a route for laying a pipeline is written in the buried object reflection drawing in consideration of the relationship with the existing underground buried object on the current plan view. Create a laying route (selection /
decide. To do this, first, on the display screen of the host computer 1, a buried object reflection diagram in which the reflection of buried objects is completed is called, and on this screen, a planned route for laying a pipeline is entered using a mouse. . At this point,
Since the pipeline is simply drawn on the screen as a data line (skeleton), the attributes [for example, the pipe material (“PD and KGP6 holes”, etc.), the pipe diameter (“125 mm”, etc.), the soil cover (“1. 2m to 1.8m ")] is input. This operation is repeated to complete the pipeline laying route diagram.

Next, in step M9, plan plan view design data is generated based on the completed pipeline laying route.
In step M10, plan sectional view design data is generated. In step M11, plan sectional view data is generated. The generated plan plan view data, plan longitudinal view data, and plan sectional view data are provided in the host computer 1. Is stored in the storage device.

In preparing the plan profile design data in step M10, the pipeline in which the plane was input in the plan plan view is specified, and the ground height is input at the elevation change point.
Next, the planned height of the planned pipeline, the type of pipe used (for example,
"KGP125"), earth covering (for example, "1.2m-1.
8m ”), while confirming the input shape on the spot,
Furthermore, pick the center point of the manhole, select the manhole standard from the list, and enter the manhole data.
It is automatically drawn when drawing the plan cross section. ).

In preparing the plan cross section design data in step M11, cross section data can be generated by cutting a cross line on the plan plane drawing. To do this, first specify the line you want to cut on the plan floor plan on the display screen, then read the change point from the plan view and enter the ground height, and then automatically change the plan pipe and underground burial topography Is included in the plan cross section data. 4 to 6
Shows an example of the plan plan view, plan sectional view, and plan cross-sectional view obtained in this manner.

In this system, a power pipe is laid,
Further, in step M12, the tensile force A is automatically calculated, and in step M13, a tension calculation report is created based on the calculation result.

In step M14, it is determined whether or not the calculated tension A is below the allowable limit. If it is below the allowable limit, the process proceeds to step M15. If not, the process proceeds to step M8. Decision step M8
The process returns to the step (a), and a new installation route is selected / determined again, and the processes of steps M8 to M14 are repeated. When the determination criteria of step M14 are satisfied, the integration process is performed in step M15, a man-hour calculation document is created in step M16, and the man-hour integration document (material man-hour table / specification) is created in step M17. to go into.

The document creation processing routine MR includes a step M
It comprises a road occupation permission application document creation subroutine RA consisting of 18 to M20 and a road use permission application document creation subroutine RB consisting of steps M21 to M23. In the road occupancy permission application document creation subroutine RA,
In step M18, data necessary for applying for a road occupation permission is extracted from the current state map data and the design data and edited, and in step M19, a road occupation permission application and a number table attached thereto are created. , Step M20
Submission of these documents to a road management organization (such as a national or local government branch office). Here, if each document relating to the road occupancy permission application is incomplete, a "application content change instruction" is issued from the road management organization, and the work of steps M18 to M20 of the road occupation application document creation subroutine RA is performed again.

In the road use permission application document creation subroutine RB, in step M21, data necessary for applying for a road use permission is extracted from the current state map data and design data and edited.
At, create a road use permission application, and construction time (period) attached to it, a list of effective width of roads, and documents such as traffic countermeasures drawings, and submit these documents to the road regulatory agency (the police station). Submit to Also in this case, if the documents related to the road permission application are incomplete, a "application content change instruction" is issued by the road supervisory authority, and the operations of steps M21 to M23 of the road use permission application document creation subroutine RB are performed again. In addition, when there is a "application change instruction" from the road management organization or the road supervisory authority in steps M20 and M23, if the designed underground buried object plan itself is defective, the process returns to step M8 and returns to steps M8 to M20. ,
The processing of M8 to M23 is repeated.

Upon completion of submission of each application document, the work enters the construction stage (M24 to M26), generates construction drawing data in step M24, creates a construction drawing in step M25,
At step M26, the work of constructing the underground buried object at the site starts. The work of step M26 is performed while changing the contents of the work data in steps M24 and M25 in accordance with the progress of the work and confirmation of the inconvenient location. When the construction work is completed,
In step M27, completed drawing data is generated based on the final data based on the construction content change data obtained in the construction stage, and a completed drawing (equipment drawing) is created in step M28. After the completion of the construction, the process proceeds to step M29, and the subsequent management of the laid underground buried object facility is performed based on the facility diagram.

[Road occupancy permission application document creation processing] FIG.
FIG. 3 is a functional block diagram relating to the preparation of a road occupation permission application document in the document preparation system according to one embodiment of the present invention. In preparation for preparing a road occupancy permit application,
Various types of format patterns (functional block S11) of the "road occupation permission application" and the "quantity table" attached thereto in advance
Are prepared in advance (function block S12). This is because the format of these documents differs depending on the road manager / institution. In addition,
The “number table” is formally described as a “dedicated property quantity breakdown table” or a “dedicated quantity breakdown table”. And
Format pattern data for these format patterns
Various patterns are registered as a format pattern library (functional block S13).

Now, in order to complete the design phase and create a road occupation permission application, first, the corresponding “road occupation permission” should be set according to the format of the road manager / institution that is responsible for the road on which the laying work will be performed. The format pattern data of the "application" and "quantity table" is called from the format pattern library (function block S14). Next, the design data is obtained for the called "road occupation permission application" and the "quantity table" format pattern data. (Function block S1)
5). This synthesis process extracts data necessary for a road occupation permit application from the design data including pipeline data and manhole data, calculates the required quantity data, and inputs the format data required for the application. Is performed to synthesize the pattern pattern data with the format pattern data (functional block S1).
5).

The “road occupation permit application” is usually accompanied by a drawing and a “number table”. The "Number of Persons" table lists the quantities of underground buried objects (power pipelines) and manholes that occupy the road by specification, and various quantities are automatically calculated from the pipeline data and manhole data. Is calculated. In addition, to create the attached drawings, mainly
By using the planned floor plan (pipe laying route drawing) data (function block S17), data necessary for the design but unnecessary for the application is deleted, the laying route is left, and necessary items are newly entered. The accompanying drawings are obtained. Some road managers may need a drawing that shows the width of the private property, that is, the width of the pipeline. In this case, the width of the pipeline is calculated from the plan plan (pipe laying route drawing) data. Create drawings for attachment by automatically changing to the completed drawings.

The “Road occupancy permission application”, the drawing and the “quantity table” created in this way are drawn and output by a printer or plotter provided in the host computer 1 (functional block S18), and are stored in a storage device. (Function block S19).

FIG. 8 is a flowchart relating to the preparation of a road occupation permission application document in the document preparation system according to one embodiment of the present invention. In step S21, the format pattern library is accessed, and in step S22, the "road occupation permission application form" and the "quantity table"
The desired format pattern is selected and displayed, and the combining process is performed in the next step S23. That is, in step S24,
The design data including the pipeline data and the manhole data is accessed, and in step S25, the plan plan view (the pipeline laying route drawing) data is accessed, and in step S23,
Various data on the power pipes to be applied to the system 1
Read in.

Subsequently, a combining process is performed in step S26. In other words, the data necessary for the application is derived from the various design data read out in step S25, the required quantity data is calculated, and the data is combined with the format pattern data, thereby obtaining the “road occupation permission application form” and the “ And edit the plan drawing (pipe laying route drawing) data to create the attached drawing. Then, the created “road occupation permission application”, the drawing, and the “quantity table” are drawn and output from the printer or the plotter in step S27, and are stored and stored in the storage device in step S28. FIG. 9 and FIG. 10 each show a “road occupation permission application” created by the above-described road occupancy permission application creation function.
And an example of a “number table” (private quantity breakdown table).

[Road Use Permission Application Document Creation Processing] FIG.
FIG. 2 is a functional block diagram relating to road use permission application document creation in the document creation system according to one embodiment of the present invention. In order to prepare a road use permission application, as a preparation stage, a format pattern of a “road use permission application” (function block S31) and a format pattern of a “list of construction time and effective road width” attached thereto are previously set. (Function block S32) is created in advance. Here, the format of these documents differs depending on the road supervisor (prefectural police) and may also differ depending on the supervising agency (each police station) in charge. As the format pattern data relating to these format patterns, various patterns are registered as a format pattern library (functional block S33).

Here, in order to prepare a road use permission application, a corresponding “road use permission” is required in accordance with a format required by a road supervision agency (each police station) in charge of supervising a road on which laying work is to be performed. The form pattern data of the "application form" and the "list of construction time and effective road width" is called from the form pattern library (function block S34). First, the form pattern data of the called "road use permission form" is designed. While comparing the data, a process of inputting and synthesizing the format data necessary for the application is performed (functional block S35), and then a synthesizing process of a "list of construction time and effective road width" is performed (functional block 36). ).

The "Road use permission application" is usually accompanied by drawings such as "List of construction time and effective width of road", location map and "Traffic measures map". Various design data and design plan view data are read from the storage device (functional blocks S37, S38). "List of construction time and effective width of roads" should be secured for construction work of underground buried objects (power pipes) and manholes to be laid on roads, construction time (hour), used road area, It describes the quantity of the effective width, etc., and derives the necessary data for the road use permission application from the pipeline data, manhole data, construction classification data, etc. in the design data and calculates the necessary quantity data. The data is automatically created by a combining process of incorporating the data into the format pattern data of the "list of construction time and effective road width" (functional block 36).
Also, of the attached drawings, a position map indicating a construction location is automatically created using commercially available map software (functional block 36).

The “traffic measure diagram” is created mainly by using the plan data (planning laying route drawing) data and editing it (functional block S3).
9). First, a section (construction section) where a traffic countermeasure map is created based on the construction section setting obtained as a design result in the design stage DS.
Cut out the "current plane + plane pipeline" diagram data on the display screen. For this purpose, for example, unnecessary data is deleted from the planned plan view (pipe laying route drawing) data to leave only the present state map data and the pipe line data [or the planned plan view (pipe laying route drawing) (Drawing) overlaps the pipeline data of the data). That is, the unnecessary existing underground object line is automatically cut, and at this time, an excavation line indicating a range to be excavated for laying a pipeline (power pipe) is automatically added.

Since it is necessary to display security equipment and construction machines using figures of a predetermined shape in the "traffic countermeasure diagram", a plurality of required security equipment graphic data are created in advance (function block S40). ), These are registered in the security equipment library (function block S41), and a plurality of types of construction machine graphic data are similarly registered in the construction machine library (function blocks S42, S43). Therefore,
Use the mouse to enter a mark indicating the construction area on the road used for construction work on the “current plane + plane pipeline” drawing of the predetermined construction section cut out on the screen and perform the image conversion button operation This mark is converted into a picture of a security fence (for example, a cone or a security bar) by the graphic data of the security equipment library. In other words, just by selecting the displayed mark indicating the construction area and holding down the point, the picture of the security fence is displayed. Subsequently, symbols such as a guardman, a construction sign, and lighting can be similarly written, and further, with regard to the construction machine, the figure of the designated construction machine can be filled in at the designated point in the same manner. .

Then, by filling in the effective width of the construction area and the road, the "traffic countermeasure map" data of the predetermined construction area is completed. By repeating such operations, it is possible to create the “traffic countermeasure diagram” data for all the construction sections. The created "traffic plan" data is plotted and output from the plotter or printer as a "traffic plan" (function block S44) and stored in a storage device (functional block S45). It should be noted that the traffic countermeasures are often A4 size and A3 size, and the main scale is 1/100 to 1/250. In addition, traffic countermeasure maps need to be created for each construction section (construction section), so the number of traffic sheets is often large, but as described above, necessary parts are cut out from the By automatically changing the map, a traffic countermeasure map can be created efficiently.

FIG. 12 is a flowchart relating to the preparation of a road use permission application document in the document preparation system according to one embodiment of the present invention. In step S51, a format pattern library is accessed, and in step S52,
"Road use permission application" and desired format pattern data of the document attached thereto are selected and displayed from this library, and the following road use permission application document creation steps S53 to S5 are performed.
In step 5, by reading in steps S56 to S59 and combining the predetermined data with the format pattern data,
Create various documents required for road use permission application.

That is, in step S53, the necessary format data is synthesized with the format pattern data of the "road use permission application" to automatically create a "road use permission application". In step S54, the data is read out in steps S56 and S57. The necessary quantity data is calculated based on the various design data and the design plan data, and the "List of construction time and effective road width"
A "list of construction time and effective width of road" is automatically created by incorporating it into the format pattern data. In the accompanying drawings, a position map indicating a construction location is created by using commercially available map software or by reading a commercially available map by the scanner system 4 and automatically creating it.

In step S55, first,
Cut out the "current plane + plane pipe" map data of each construction section using the planned floor plan (pipe laying route drawing) data, and fill in the figure showing the construction area etc. using the security equipment library acquired in step S58. By using the construction machine library acquired in step S59 to enter construction machine graphics and entering the effective width of construction areas and roads, "transportation plan" data for each construction section is created.

The “Road use permission application” data thus created, “List of construction time and effective road width”
The data, the “traffic measure diagram” data, and the like are output as drawings by an output device such as a printer or a plotter in step S60, and are stored and stored in a storage device in step S61. FIGS. 13 to 15 respectively show a “road use permission application”, a “construction time and effective road width list”, and a “traffic measure diagram” (partly) which are created by this road ownership permission application creation function. ) Is shown.

In order to create a “traffic measure diagram”,
The method of selecting desired graphic data from the graphic library and creating a drawing using the selected graphic data can be used to create a drawing attached to the “road occupation permission application”.

[Details of creating a road occupation permission application] In the laying work of buried objects, an application for occupation permission to a road manager or an institution such as a civil engineering office occurs. A license application form) is submitted to the road manager, and at that time, a number table that summarizes the number of specifications for private property (pipelines and manholes) required to calculate private charges is attached. In addition, some road managers need a drawing showing the width of the private property (the width of the pipeline). The conventional work of reading the number of occupied properties such as pipelines and manholes from the design drawings by specification took a long time, but in one embodiment of the present invention, the application form cover is automatically converted from the basic design data. A pipeline width entry drawing is automatically created from the created and designed pipeline laying route diagram, and a workforce table is automatically created using the pipeline data in the pipeline laying route diagram. Therefore, an accurate document can be created in a very short time. FIG. 16 is a detailed processing flow chart for creating a road occupation permission application document in the document creation system according to one embodiment of the present invention.

Prior to the application for a road occupation permit, data necessary for preparing a road occupancy permission application and the like are registered in a library or a database in steps R1 to R8 prior to application preparation. As described above, the format of the “road occupation permit application” (cover) and the “number of staff” attached thereto vary depending on the road manager / institution and also depending on the region. Therefore, in step R1,
A variety of cover format patterns for the road occupation permission application cover are created in advance and registered in the road occupation permission application cover format pattern library shown in step R2. Similarly, for the “quantity table”, various quantity table format patterns are created in advance in step R3 and registered in the quantity table format pattern library shown in step R4. In addition,
Regarding the registration of these format patterns, in accordance with the subsequent format change, it will be updated and registered as needed with the changed format pattern, and in order to accommodate the buried object laying work in the new area, the format in the new area The pattern is configured to be able to be additionally registered, and the latest format data is always prepared.

Also, at the beginning of the design of the buried plan, the name of the buried work, the buried object owner data including the person in charge of design, the place and period of the buried work, the basic design data of the road management / supervisor / institution, etc. Is determined and input to the system. These basic design data are registered in the basic design database shown in Step R6 in Step R5, and can be used as data necessary for preparing a road occupation permission application cover. Furthermore, at the stage when the laying route is examined and determined, as a design result, the pipe type, pipe diameter, span length, etc. of the pipe line used as the buried object, the standard (type, shape, etc.) and the number of the human hole, etc. , Since various specific design data can be obtained for each process, these design data
In step R7, the data is automatically registered in the design database shown in step R8, and can be used as data necessary for creating the number table.

Therefore, in order to complete the design stage and create a road occupation permission application, first, in step R11, the road on which the laying work is to be performed is controlled from the road occupation permission application cover format pattern library (R2). According to the format of the road manager / institution, a corresponding desired cover format pattern data is selected and called, and step R12 is performed.
Proceed to. In step R12, a process of retrieving required design basic data from the design basic database (R6) and synthesizing the selected cover format pattern data is performed.

For example, when creating a “road occupation permission application” in the format shown in FIG. 9, when the operator selects this desired format pattern, an unfilled road occupation permission application cover is read out and read from the host. It is displayed on the display screen of the computer 1. Furthermore, when the laying work of the buried object is specified, the name of the "road manager / institution" read out as the basic design data is automatically entered in the destination column of the cover format pattern, and the address / name is obtained from the buried object owner data.・
Bibliographic items are automatically entered in each column of the format pattern based on the design basic data input and set at the start of the design, such as the person in charge and the telephone being automatically entered.

Further, the date of the application date is automatically entered by the timer of the host computer 1, and general items, such as the purpose of occupation and the occupation period, which are not directly related to the laying design items, include the format pattern and the laying work. Is displayed by default in association with the selection of the format pattern. In addition, in any of the item fields, the operator can select other candidate data or input new data using the input operation device while looking at the display screen, thereby changing the automatically filled data to the optimum data. Can be. Then, when the operator performs a confirmation input of the display content, the content of the cover data is determined.

In step R12, the cover data is determined by the above-described synthesizing process, and the road occupation permission application cover data is created. In step R13, the road occupation permission application as shown in FIG. The book cover is printed out, and the cover data of the road occupation permission application form is stored and stored in the storage device of the host computer 1 in step R14.

In the next step R15, step R11
Similarly to the above, when desired quantity table format pattern data is selected from the quantity table format pattern library (R4), the process proceeds to step R16, where required design data is read from the design database (R8), and the selected quantity table format pattern is read. Performs processing to combine with data.

For example, in the case of creating a “quantity table (dedicated quantity breakdown table)” in the format shown in FIG. 10, when the operator selects this format pattern, a blank number table is displayed on the display screen. The design data corresponding to the designated buried object laying work is read, and the read design data such as the pipe type, the pipe diameter, and the span length are stored in the corresponding columns of the workforce table format pattern for each of the section numbers (no.). A value automatically entered or automatically calculated from design data is automatically entered (for example, a total extension breakdown).

When the member count table data is created by the synthesizing process, in step R17, for example, in response to a print instruction,
The cover page of the road occupation permission application as shown in FIG. 9 is printed out, and the number table data is stored and stored in the storage device in step R18, and the road occupation permission application creation processing ends.

[Details of Preparation of Road Use Permission Application] The road use permission application is submitted to the competent police station, which is a road supervisory body, with a "Traffic Plan" and "List of Construction Time and Effective Width". You. In particular, one traffic countermeasure map is usually created in a construction area of about 30 m. However, if there are many intersections and side roads in the construction site, it must be created each time the form of traffic guidance changes. Rather, dozens of traffic countermeasure maps are often created in one underground line laying operation, and it took a long time to create them. In one embodiment of the present invention, an application document cover, a list, a traffic measure map, and the like are automatically created using design results, so that accurate documents are created in a very short time. be able to. FIG. 17 is a detailed processing flow chart for creating a road use permission application document in the document creation system according to one embodiment of the present invention.

In the road use permission application, as in the case of the road occupation permission application, the format of the document form to be submitted differs depending on the road manager / institution and the region. Therefore,
In steps R21 to R28, data necessary for creating a road use permission application or the like is registered in a library or database. In step R21, various cover format patterns of "road use permission application" (cover) are created in advance and registered in the road use permission application cover format pattern library in step R22. Similarly, "Effective construction time and effective width list", in advance,
In step R23, various list format patterns are created,
It is registered in the list format pattern library of step R24. In addition, regarding the registration of these format patterns, in accordance with the subsequent format change, it will be updated and registered at any time with the changed format pattern, and in order to respond to the burial work in new areas, Is configured so that additional registration of the format pattern can be performed, and the latest format data is always prepared.

Also, basic design data (name of buried object laying work,
The buried object owner data including the person in charge of the design, the location and period of the burial work, the road manager / institution, etc.) are registered in the design basic database shown in step R26 (= R6) in step R25, and the road use permission application is made. It can be used as data necessary for creating a book cover, which is the same process as steps R5 and R6 in FIG. Further, in the design stage, as design results to be considered in traffic measures, design data such as the effective width, the use width, and the use extension of the road on which the laying work of the buried object is to be performed are obtained. Therefore, in step R28 (= R8), These design data are automatically registered in the design database shown in step R27 so that they can be used as data necessary for creating a list.

Now, in order to complete the design stage and create a road use permission application, first, in step R31,
Road use application form cover format pattern library (R2
From 2), a corresponding desired cover format pattern data is selected and called according to the format of the road supervisory agency that supervises the road on which the laying work is performed, and the process proceeds to step R32.
In step R32, the design basic database (R26 =
From R6), the necessary design basic data is read out, and a process of synthesizing with the selected cover format pattern data is performed.

For example, when creating a “road use permission application” in the format shown in FIG. 13, when the operator selects this desired format pattern, an unfilled road use permission application is called and the host computer 1 is displayed on the display screen. In addition, when you specify a buried object laying work, the name of the "road supervisory authority" read as basic design data is automatically entered in the destination column of the cover format pattern, and the address and name are automatically entered from the buried object owner data As described above, bibliographic items are automatically entered in each column of the format pattern as design basic data based on the design basic data input and set at the start of the design.

Further, similarly to the road occupancy permission application, the date of the application date is automatically entered by the timer of the host computer 1, and the general items such as the period and the attached documents correspond to the format pattern and the laying work of the buried object. Then, the initial data registered in advance is displayed by default in conjunction with the selection of the format pattern. In addition, any item column can be selected or changed from the automatically filled data to the optimum data by the operator using the input operation device while looking at the display screen. Then, when the operator performs a confirmation input of the display content, the content of the cover data is determined.

When the cover data is determined by the synthesizing process in step R32 and the road use permission application cover data is created, in step R33, the road use permission application cover as shown in FIG. The cover data of the road use permit application form is stored in the storage device of the host computer 1 in step R34.
Is stored.

In the next step R35, when the desired list format pattern data is selected from the list format pattern library (R24), the process proceeds to step R36, where the required design data is read from the design database (R28 = R8). A process for combining with the selected list format pattern data is performed.

For example, when creating a “list of construction time and effective width” in the format shown in FIG. 14, when the operator selects this format pattern, an unfilled list is displayed on the display screen. Therefore, in the construction location, content, and time columns of the displayed list, enter the construction location, content, and time data for each drawing number (not necessarily the construction section number due to the addition of drawings for all construction sections). I do. In addition, the design data corresponding to the designated laying work is read out in the column of length of use, width of use, and effective width, so the traffic such as the read use width, use extension (use length), and effective width is read. The design data for the measure is automatically entered in the corresponding column.

When the list data is created by the synthesizing process, in step R37, for example, in response to a print instruction,
The road use permission application cover as shown in FIG. 14 is printed out, and the list cover data is stored in step R38.
Then, the road use permission application creating process is completed.

[Details of Creating a Traffic Countermeasure Map] FIG. 18 is a detailed processing flowchart of creating a traffic countermeasure map in the document creation system according to one embodiment of the present invention. The figures, drawing data, and design data necessary to create the traffic countermeasure drawings attached to the road use permission application are stored in steps R51 to R5.
5 is registered in a library or database in advance. In this system, in step R51, security equipment drawing data necessary for drawing security equipment such as construction signs, cones, security bars, and guards (guards) is registered in a security equipment library shown in step R52. In step R53, construction machine drawing data necessary for drawing the construction machine is registered in the construction machine library indicated in step R54. For registration of these drawing data, update registration or additional registration can be performed at any time according to the change or addition of the type or design of the security equipment or construction machine, and the latest graphic data is always prepared. In addition, the plan plan drawing (the pipeline laying route drawing) obtained in the underground design drawing design stage
The data is stored in the storage device of the computer 1 so that it can be cut out for each set design section as shown in step R55.

When the traffic countermeasure diagram creation process is started, first, in step R61, plan view data is automatically cut out from the plan plan view data (R55) corresponding to the laying work of the buried object specified by the operator for each design engineer. It is displayed on the display screen as a traffic control original map. This traffic countermeasure diagram is, as described above, an “existing plane + plane pipeline” diagram in which unnecessary existing underground buried lines are automatically cut, and indicates the excavation area for laying the pipeline. Lines have been added automatically.

Next, in step R62, a required security equipment mark is selected based on the traffic control original map displayed on the display screen, and the security equipment library (R52) is selected.
The security equipment is plotted using the security equipment work graphic data. In a succeeding step R63, a required construction machine mark is further selected, and construction machines are constructed using construction machine construction data of the construction machine library (R54). Then, fill in the effective width of the construction area and road, determine the "Traffic Measures" data for the prescribed work section, and repeat the work of distinguishing such works to complete the "Traffic Measures" data for all work sections. Can be.

For example, in the case of creating a “traffic measure diagram” of a certain work section shown in FIG. 15, a mark indicating the construction work area of the work section cut out is selected with respect to the original traffic measure figure on the screen. Just by holding down the points, the picture of the security fence is displayed on the screen based on the security equipment drawing data. Similarly, when an instruction such as a guardman or a construction sign is given, a corresponding graphic symbol is displayed. Further, for the construction machine, a graphic symbol corresponding to the designated construction machine is displayed at the designated point in the same manner.

When the traffic countermeasure diagram data is created by the diagram editing process in steps R62 and R63, the process proceeds to step R64.
Then, in response to the print instruction, for example, a traffic countermeasure diagram as shown in FIG. 15 is printed out, and the traffic countermeasure diagram data is stored and stored in the storage device in step R65, and the traffic countermeasure diagram creation process ends.

[Effect of the Invention] As described above, according to the present invention, a format pattern library storing a plurality of format patterns corresponding to a road occupation permission application or a road use permission application format is provided. When the buried object plan data is generated based on the buried object position data and the buried object design data, the format pattern data according to the type instruction of the document creation is read from the format pattern library, and the buried object plan data is read. Is combined with the format pattern data to generate the document data for the road occupation permission application or the road use permission application, so the "road occupation permission application" or "road use permission application" And its attachments are created efficiently, and
Application documents that accurately reflect the design details can be created.

According to the present invention, a format pattern library storing a plurality of format patterns corresponding to a road occupation permission application or a road use permission application format is provided.
And, a graphic pattern library storing a plurality of graphic patterns is provided, and based on the current state map data, the existing buried object position data and the buried object design data, the buried object plan data is generated, and from the buried object plan data. Extract the buried object laying route data, create a road occupation permission application or a road use permission application based on the format pattern data read from the format pattern library and the buried object planning data, and select from the figure pattern library. Based on the provided figure data, current state map data and buried object laying route data, we will create a drawing attached to the road occupation permission application or road use permission application, Or, efficiently create a “Road Use Permit Application Form” and drawings attached to it, and correct the design contents. It is possible to create the application documents that reflect on.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an overall configuration of a document creation system according to an embodiment of the present invention.

FIG. 2 is a part of a flowchart showing an overall processing flow of an underground buried object laying work support system having a document creating function according to an embodiment of the present invention;

FIG. 3 is another part of a flowchart showing the overall processing flow of the underground buried object laying work support system having a document creating function according to one embodiment of the present invention;

FIG. 4 is an example of a plan view created by the document creation system according to the embodiment of the present invention;

FIG. 5 is an example of a plan longitudinal section created by the document creating system according to the embodiment of the present invention;

FIG. 6 is an example of a plan cross section created in the document creating system according to one embodiment of the present invention;

FIG. 7 is a functional block diagram relating to a road occupation permission application document creation process in the document creation system according to one embodiment of the present invention;

FIG. 8 is a flowchart illustrating a flow of a road occupation permission application document creation process in the document creation system according to one embodiment of the present invention.

FIG. 9 is an example of a “road occupation permission application” created by the document creation system according to one embodiment of the present invention.

FIG. 10 is an example of a “number table” created in the document creation system according to an embodiment of the present invention.

FIG. 11 is a functional block diagram relating to a road use permission application document creation process of the document creation system according to one embodiment of the present invention;

FIG. 12 is a flowchart showing a flow of a road use permission application document creation process of the document creation system according to one embodiment of the present invention.

FIG. 13 is a “road use permission application” created by the document creation system according to one embodiment of the present invention;
This is an example.

FIG. 14 is an example of a “construction time and effective road width list” created by the document creation system according to the embodiment of the present invention;

FIG. 15 is a “traffic countermeasure diagram” (part) created by the document creation system according to the embodiment of the present invention;
This is an example.

FIG. 16 is a detailed processing flowchart of creating a road occupation permission application document in the document creation system according to one embodiment of the present invention.

FIG. 17 is a detailed processing flowchart of creating a road use permission application document in the document creation system according to one embodiment of the present invention.

FIG. 18 is a detailed processing flowchart of creating a traffic countermeasure map in the document creation system according to one embodiment of the present invention.

[Explanation of symbols]

 MR document creation routine, RA road occupation permission application creation document subroutine, RB road use authorization application creation document subroutine.

Claims (4)

[Claims] 1. A means for acquiring status map data, a means for acquiring existing buried object position data, a means for inputting buried object design data, A format pattern library storing format patterns, a means for generating buried object plan data based on the acquired current state map data and existing buried object position data, and input buried object design data; Means for reading the format pattern data in accordance with the type instruction of document creation from the pattern library; and Means for generating document data for use in a document. 2. A means for acquiring status map data, a means for acquiring existing object position data, a means for inputting object design data, and a plurality of files corresponding to a road occupation permission application or a road use permission application format. A format pattern library that stores format patterns, a graphic pattern library that stores a plurality of graphic patterns, and the acquired current state map data and the existing embedded object position data and the input embedded object design data are used. Means for generating buried object plan data; means for extracting buried object laying route data from the buried object plan data; generated buried object plan data; and format pattern data read from the format pattern library. To create a road occupation permit application or a road use permit application based on the Means for generating a drawing attached to a road occupation permission application or a road use permission application based on the buried object laying route data and the graphic data selected from the graphic pattern library. Document creation system. 3. A step of obtaining status map data, a step of obtaining existing buried object position data, a step of inputting buried object design data, the obtained current state map data and existing buried object position data, and Generating a buried object plan data based on the inputted buried object design data; and a predetermined pattern pattern library storing a plurality of format patterns corresponding to a road occupation permission application or a road use permission application format. Reading the format pattern data; and generating document data for a road occupation permission application or a road use permission application based on the generated embedded object plan data and the read format pattern data. A recording medium for creating documents characterized by recording a program. 4. A step of obtaining status map data, a step of obtaining existing buried object position data, a step of inputting buried object design data, the obtained current state map data and existing buried object position data, and Generates buried object planning data based on the entered buried object design data, extracts buried object laying route data from the buried object planning data, and responds to the road occupation permission application or road use permission application format Reading out predetermined format pattern data from a format pattern library storing a plurality of format patterns to be executed; and applying for a road occupation permission based on the generated buried object plan data and the read format pattern data. Steps to prepare a certificate or road use permit application, obtained status map data, extracted buried floor Generating a drawing attached to the road occupation permission application or the road use permission application based on the installation route data and the graphic data selected from the graphic pattern library storing the plurality of graphic patterns. Recording medium for recording a document, characterized by recording a program comprising: