JP6571428B2 - Shield tunnel plotter - Google Patents

Description

  The present invention relates to a shield tunnel drawing device, and more particularly to a shield tunnel drawing device capable of improving the drawing efficiency of a tunnel drawing drawn when designing a shield tunnel.

It is known that the shield tunnel is configured by a segment ring as shown in Patent Document 1. In the design of such a shield tunnel, a plan view, a longitudinal view, a cross-sectional view, etc. of the shield tunnel constituted by the segment ring are drawn. In these drawings, after drawing each of the various segment rings having different shapes and dimensions in 3D using drawing software such as CAD, each segment ring is arranged at a predetermined position in the design. Is used to draw a general view of the three-dimensional shield tunnel, and is drawn based on this general view.
However, if changes are made to the specifications of the shield tunnel, the segment rings must be redrawn in 3D one by one to correct the plan view, longitudinal view, and cross-sectional view. It was necessary.

JP 2012-149394 A

  In view of the above problems, an object of the present invention is to provide a drawing apparatus capable of improving the drawing efficiency of a drawing of a shield tunnel even when the specification of the shield tunnel is changed.

As a configuration of a shield tunnel drawing device for solving the above-mentioned problem, a shield tunnel drawing device for drawing a shield tunnel drawing, the contents of the drawing data of the created three-dimensional drawing of the shield tunnel, a drawing data changing means for changing, based on the contents of the change data created on the basis of specifications, based on the drawing data of the changed and a three-dimensional diagram generating means for generating a three-dimensional view of the new shield tunnel, change The previous drawing data includes segmenting data that represents the shape of the segment ring that is continuously arranged along the path of the shield tunnel, and the drawing data changing means changes the drawing data to change the shape of the segment ring. It was to that configuration.
According to this configuration, when a shield tunnel is newly designed, it is not necessary to draw the shield tunnel from scratch, so that the drawing efficiency can be improved . Also, before the change drawing data includes a segment ring data representing the shape of the segment ring arranged in succession along the path of the shield tunnel, drawing data changing means to change the shape of the segment ring Since the drawing data is changed, it is only necessary to configure the change data so as to change the shape of the segment ring when drawing a new three-dimensional view of the shield tunnel. Therefore, the change data can be easily configured .
Also, the drawing data before the change includes constraint information defining the connection state of the segment ring successive drawing data changing means, so changes the drawing data before the change based on the constraining information, reliably You can draw a 3D view of a new shield tunnel .
Also, drawing data and modification data because it is generated in spreadsheet format, the contents of the contents and change data in the drawing data can be easily confirmed.
Another configuration of the shield tunnel drawing device is a shield tunnel drawing device that draws a drawing of a shield tunnel, and the contents of the drawing data of the created three-dimensional drawing of the shield tunnel are based on the specifications of the new shield tunnel. The drawing data changing means for changing based on the contents of the changed data created in the step, and the three-dimensional drawing generating means for generating a three-dimensional view of the new shield tunnel based on the changed drawing data, the drawing data and the change The data was generated in a spreadsheet format.
In addition, it is equipped with drawing data generation means that generates either a plan view data, a longitudinal view data, or a sectional view data of a new shield tunnel based on the changed drawing data, so it corresponds to a new three-dimensional view of the shield tunnel It is possible to easily draw a plan view, a longitudinal sectional view, a sectional view, and the like.

  The summary of the invention does not list all necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.

It is a block diagram which shows one Embodiment of a shield tunnel drawing apparatus. It is a block diagram which shows one Embodiment of a processing apparatus. It is a figure which shows an example of the model tunnel figure displayed on the display apparatus. It is a figure which shows the structure of model data. It is a figure which shows the dimension of each part of a segment ring. It is a flowchart which shows operation | movement of a shield tunnel drawing apparatus. It is a figure which shows the segment ring which changed the division | segmentation number of segment pieces.

  Hereinafter, the present invention will be described in detail through embodiments. However, the following embodiments do not limit the invention according to the claims, and all combinations of features described in the embodiments are included. It is not necessarily essential for the solution of the invention.

  FIG. 1 is a block diagram showing an embodiment of a shield tunnel drawing apparatus 1. The shield tunnel drawing apparatus 1 is constituted by a so-called computer, and includes an arithmetic processing means 11 having a CPU as an arithmetic means provided as hardware resources, a storage means 12 such as a ROM and a RAM, a keyboard and a mouse, or a magnetic , An input means 13 such as an optical drive, a display means 14 such as a monitor, an external connection interface 15 for connecting a network interface, an external device, and the like. Then, the CPU of the arithmetic processing unit 11 executes the processing described later in accordance with the program stored in the storage unit 12, thereby operating the shield tunnel drawing apparatus 1 as each unit described later.

  FIG. 2 is a block diagram showing each process executed by the arithmetic processing unit 11 as a unit. The shield tunnel drawing apparatus 1 includes a model data reading means 21, a change data reading means 22, a parameter identifying means 23, a parameter extracting means 24, a data updating means 25, a shape information updating means 26, and a coordinate position calculating means. 27, a three-dimensional map generating means 28, and a drawing data generating means 29.

  The model data reading unit 21 reads model data stored in the storage unit 12. The model data is three-dimensional drawing data for generating a tunnel three-dimensional diagram drawn in three dimensions by CAD software or the like. For the model data, for example, a three-dimensional tunnel diagram drawn at the time of designing an existing tunnel constructed by the shield method, a tunnel three-dimensional diagram drawn at the beginning of planning a newly constructed shield tunnel, or the like is used. The shield tunnel drawing apparatus 1 draws a new tunnel diagram using the model data as a base (model).

  FIG. 3 is a diagram showing an example of a model tunnel diagram M read by the model data reading means 21 and displayed on the display means 14. The model tunnel diagram M is drawn as a three-dimensional tunnel diagram including a plurality of segment rings provided in order from the start point to the arrival point of excavation by the shield machine. In the displayed model tunnel diagram M of the shield tunnel, the designated segment ring information can be displayed and referred to by designating a desired position with the cursor K.

  4A and 4B are diagrams showing the structure of model data. As shown in FIG. 4A, the model data is configured as an aggregate of ring data of a plurality of segment rings forming a shield tunnel. For example, each ring data has a ring data no. 1, ring data no. 2, ... Ring data No. A predetermined identification number is assigned to each ring, such as 1000. As shown in FIG. 4B, each ring data includes dimension information, shape information, position information, constraint information, and the like. The dimension information, shape information, position information, and constraint information are information recorded in advance in a predetermined format when a three-dimensional diagram of the segment ring is drawn on the computer by drawing software such as CAD software. The dimension information, shape information, position information, constraint information, etc. that make up each ring data are on the worksheet where data is input into cells arranged in multiple rows and columns so that it can be read by spreadsheet software, for example. Are recorded in predetermined rows and columns. Then, model data is configured by storing a plurality of worksheets in which information of each ring data is recorded in one file, for example, a spreadsheet format.

  FIG. 5 is a diagram illustrating an example of the dimension information of the segment ring. The dimension information includes the width W of the segment ring R, the inner diameter D1, the outer diameter D2, the taper amount (not shown), the vertical direction angle, the horizontal direction angle, the division number N of the segment pieces S1 to S5 forming the segment ring, and each segment piece S1. -S5 center angles θ1 to θ5, etc., including numerical information such as the number of bolt holes h and the bolt pitch angle θp when connecting adjacent segment pieces. Each information included in the dimension information is set with a symbol as a parameter, and forms one parameter group for specifying the shape of the segment ring R. Hereinafter, these parameter groups are referred to as model parameter groups. And the shape information mentioned later is changed by changing the numerical value of the model parameter group which is dimensional information. Such dimensional information is stored as numerical data in the cells on each worksheet described above.

  The shape information includes data for defining the inner and outer peripheral surfaces of the segment ring, the direction and shape of the pair of end surfaces, and the shapes of the inner and outer peripheral edges that define the respective surfaces. Note that the dimension information and the shape information are associated with each other. For example, the inner diameter of the numerical information is associated with the inner diameter of the numerical information, and the outer diameter of the numerical information is associated with the outer diameter of the numerical information.

  The position information includes an arrangement position from the starting point when the segment rings individually drawn are arranged at predetermined positions so as to form an overall view of the model tunnel, a three-dimensional coordinate position set on the computer, and A three-dimensional coordinate position of the joint J between the segment pieces constituting one segment ring is included. As the coordinate position of each segment ring, for example, the coordinate position of the center on the starting point side in the segment ring is set. As the origin of the coordinate position, for example, the starting point of the excavation by the shield machine, that is, the ring data No. The position of the center on the first departure point side of 1 is set. The coordinate position of the segment piece is set based on the center of each segment ring. Note that the above-described coordinate positions on the computer are scaled so as to correspond to the positions of the three-dimensional global coordinates obtained by GPS, IGS, surveying, or the like in the field where the shield tunnel is actually provided. Such shape information is stored as numerical data in the cells on each worksheet described above.

  The constraint information includes information for setting an arrangement position between adjacent segment rings, information indicating a positional relationship between segment pieces constituting each segment ring, and the like. The constraint information includes, for example, that the positions of the bolt holes provided in the flange surfaces of adjacent segment rings are coincident, the axis lines of adjacent segment rings are continuous, and the joint J of the segment piece forming the segment ring. It is specified that the position is not continuous between adjacent segment rings. For example, the ring data No. 1-Ring Data No. 2, ring data No. 2-ring data No. As shown in FIG. 3, etc., they are associated in order from the starting point side. Such constraint information is stored as numerical data in the cells on each worksheet described above.

Returning to FIG. 2, the change data reading means 22 reads the change data stored in the storage means 12. The change data is data for changing the model tunnel diagram in order to draw a new tunnel diagram having a desired specification. The change data is generated in a spreadsheet format so as to correspond to the model data. The change data is configured by selecting a parameter related to shape deformation from among a group of model parameters recorded on each worksheet of the model data so that the segment ring of the model tunnel diagram is deformed to a desired shape. .
The selected parameter is recorded as a change parameter, for example, at a position serving as a header in each worksheet. In the change parameter, the contents to be changed (numerical information) are recorded in association with each other. That is, numerical data for deforming the shape is input to the cell corresponding to the header (change parameter) in the worksheet. For example, when the number of segment ring divisions is changed, the position of the segment ring to be changed and the “number of divisions” as the change parameter are input to the worksheet in a predetermined format as change data. Also, for example, when changing the diameter in the model tunnel diagram, the change data includes the position and range of the segment ring to be changed, the numerical values of the inner and outer diameters of the segment ring as change parameters in a predetermined format. Configured in the sheet.
As described above, by generating the model data and the change data as spreadsheet-type table data, the contents of the model data and the contents of the change data can be easily confirmed.

  The parameter identification unit 23 identifies the code of the parameter set in the change data read by the change data reading unit 22. The code of the parameter identified by the parameter identifying unit 23 is output to the parameter extracting unit 24. The parameter extracting unit 24 extracts a parameter having a code corresponding to the code of the changed parameter input from the parameter identifying unit 23 from the model parameter group.

  The data update unit 25 updates the content of the parameter extracted by the parameter extraction unit 24 to the content of the numerical information associated with the changed parameter.

  The shape information update unit 26 uses the update of the parameter by the data update unit 25 as a trigger, and updates the shape information of the model data based on the updated numerical information.

The coordinate position calculation unit 27 uses the update of the shape information by the shape information update unit 26 as a trigger, and determines each segment ring based on the constraint information included in the model data before the update and the updated numerical information and shape information. The three-dimensional coordinate position to be displayed on the display means 14 is calculated, and the position information of each ring data is updated. As described above, the numerical information, shape information, and position information of each ring data are configured so that the information is linked to each other.
The data updating unit 25, the shape information updating unit 26, and the coordinate position calculating unit 27 function as a drawing data changing unit that changes the model data of the model tunnel diagram. The model data updated through the data update unit 25, the shape information update unit 26, and the coordinate position calculation unit 27 is stored in the storage unit 12 as updated model data and is output to the three-dimensional diagram generation unit 28.

  Based on the model data before the change and the updated model data, the three-dimensional map generation unit 28 generates a three-dimensional map on the display unit 14 such as a model tunnel diagram or a new tunnel diagram after the change on the display unit 14.

  The drawing data generation unit 29 includes a plan view data generation unit, a longitudinal view data generation unit, and a sectional view data generation unit. The plan view data generation unit generates plan view data for displaying a plan view, for example, by deleting data including components relating to the Z axis from the updated model data. For example, the vertical section data generation unit generates vertical section data for displaying a vertical section by deleting data including components related to the Y axis from the updated model data. For example, the cross-sectional view data generation unit generates cross-sectional view data for displaying a cross-sectional view by deleting data including components relating to the X axis from the updated model data. The plan view data, longitudinal view data, and cross-sectional view data created by the drawing data generation means 29 are output to the display means 14, and the figure is displayed.

FIG. 6 is a flowchart showing the processing of the shield tunnel drawing apparatus 1. Hereinafter, the process of the shield tunnel drawing apparatus 1 will be described by taking as an example the case of changing the segment ring division number.
[S101]
Model data and change data are input via the input means 13. The input model data and change data are stored in the storage means 12.
[S102, S103]
The model data and change data stored in the storage means 12 are read by the model data reading means 21 and the change data reading means 22, respectively.
[S104]
The change data read by the change data reading means 22 is identified by the parameter identifying means 23 by the code of the change parameter type. The code identified by the parameter identifying means 23 is output to the parameter extracting means 24. In the following description, it is assumed that the identified code is the division number N.
[S105]
The parameter extracting unit 24 extracts a parameter corresponding to the code N (number of divisions) input from the parameter identifying unit 23 from the model parameters.
[S106]
The content of the parameter corresponding to the code N extracted by the parameter extraction means 24 is updated to the content associated with the changed parameter. For example, when the segment ring R with the number of divisions N = 5 shown in FIG. 5 is changed to the segment ring R with the number of divisions N = 7 shown in FIG. Numerical values such as “7” and the angles of the central angles θ1 to θ7 of the seven segment pieces S1 to S7 forming the segment ring R are linked and described.
[S107]
Based on the numerical value of the division number N and the dimension information in which the angles of the central angles θ1 to θ7 of the segment pieces are updated, the shape information of the model data is updated so that the division number N of the segment ring R becomes 7.
[S108]
Based on the constraint information included in the model data before update and the dimension information and shape information updated in S106 and S107, the position information on the computer included in the model data is updated. That is, since the number of segment ring divisions has been changed from “5” to “7”, the position of the segment piece joint J in the segment ring changes, so the drawing position is calculated and the content of the position information is updated. To do. By updating the position information, the model data is stored as updated data and is output to the three-dimensional map generation unit 28.
[S109]
The three-dimensional map generation unit 28 generates a new tunnel diagram on the display unit 14 by executing predetermined processing on the updated data. That is, a three-dimensional map of the new tunnel diagram is displayed on the display means 14.
[S110]
After the new tunnel diagram is displayed, after checking by the operator whether there is an error in the drawing, the drawing data generation means 29 is operated to perform predetermined editing on the updated data, and the plan view data, longitudinal view data, and sectional view data. Create and exit.

  As described above, it is possible to improve the drawing efficiency of a new tunnel diagram by using a three-dimensional view of a shield tunnel that has been drawn by a computer as a template for drawing a new shield tunnel design drawing. it can.

  In the above-described embodiment, the case where the number of divisions of the segment ring is changed has been described as an example. However, the inner diameter D1 and the outer diameter D2 included in the dimension information are obtained so that a new tunnel diagram having a desired specification can be obtained. By changing the model parameters such as, etc. according to the change data, a new tunnel diagram that is larger than the model tunnel diagram or a new tunnel diagram in which the model tunnel diagram is transformed so that the shape of the entire tunnel changes is drawn. Is also possible.

1 Shield tunnel drawing device, 21 Model data reading means,
22 change data reading means, 23 parameter identifying means, 24 parameter extracting means,
25 data update means, 26 shape information update means, 27 coordinate position calculation means,
28 three-dimensional drawing generation means, 29 drawing data generation means.

Claims (5)

A shield tunnel drawing device for drawing a drawing of a shield tunnel,
Drawing data changing means for changing the content of the drawing data of the created shield tunnel three-dimensional drawing based on the content of the changed data created based on the specifications of the new shield tunnel;
A three-dimensional map generating means for generating a three-dimensional map of a new shield tunnel based on the changed drawing data ;
The drawing data before the change includes segment ring data representing the shape of the segment ring continuously arranged along the path of the shield tunnel,
The drawing data changing means, the shield tunnel drawing apparatus characterized that you change the drawing data so as to change the shape of the segment ring. The drawing data before the change includes constraint information defining a connection state of continuous segment rings,
2. The shield tunnel drawing apparatus according to claim 1 , wherein the drawing data changing unit changes the drawing data before the change based on the constraint information. 3. The shield tunnel drawing apparatus according to claim 1, wherein the drawing data and the change data are generated in a spreadsheet format. A shield tunnel drawing device for drawing a drawing of a shield tunnel,
Drawing data changing means for changing the content of the drawing data of the created shield tunnel three-dimensional drawing based on the content of the changed data created based on the specifications of the new shield tunnel;
A three-dimensional map generating means for generating a three-dimensional map of a new shield tunnel based on the changed drawing data;
The drawing data and the change data, the shield tunnel drawing device according to claim Rukoto generated in a spreadsheet format. Based on the drawing data of the changed plan view data of the new shield tunnel, longitudinal view data, claims 1, characterized in that it comprises a drawing data generating means for generating one of a cross-sectional view Data 4. The shield tunnel drawing device according to any one of 4 above.