JP7393508B1 - Channel design support device and channel design support program - Google Patents

Abstract

An object of the present invention is to assist a designer in easily and accurately modeling a waterway in 3D by specifying the installation position of the waterway while looking at 3D data in 2D. A waterway design support device includes: a display unit 11 that displays a three-dimensional model from a planar perspective; an input unit that accepts designation of a waterway installation position on the three-dimensional model from a planar perspective displayed on the display unit 11; A calculation unit that calculates the waterway installation height at the waterway installation position received by the input unit based on height information included in the three-dimensional model; and a waterway model representing the waterway at the waterway installation height calculated by the calculation unit. and a model generation unit that generates the model. [Selection diagram] Figure 13

Description

The present disclosure relates to a waterway design support device and a waterway design support program used, for example, in designing roads, building blocks, residential land development, rivers, and the like.

For example, Patent Document 1 discloses a system for using a computer to generate a three-dimensional model of a civil engineering structure based on three-dimensional data including the topography on which the civil engineering structure, such as a river embankment, is formed. This system has the ability to acquire information on the amount of water passing through river embankments, land use and environment near river embankments, and based on the acquired information, optimal locations for structures such as waterways that penetrate river embankments. , the optimal direction, optimal volume, optimal shape, and optimal size are calculated, and a three-dimensional model of the waterway is generated by superimposing a three-dimensional model of the river embankment.

JP2022-84484A

By the way, when designing drainage works such as basins and channels using the two-dimensional design method for existing roads, building blocks, housing land development, river embankments, etc., it is necessary to use information such as vertical slope, cross slope, slope slope, width, etc. , it was necessary to find out where high and low points were, and then calculate the altitude value for that position, which was very time-consuming and prone to mistakes.

In addition, although it is necessary to design a waterway with a downward slope toward the end of the flow, the lowest point may occur in the middle of the flow, during processes such as branching and merging, or connecting basins, and as a result, the lowest point may occur in the middle of the flow, resulting in There is a risk of incorrect design, such as an uphill slope and water flowing backwards. In order to prevent such problems from occurring, the height of the mounds is checked by raising flags and making diagrams, but there is no equipment that can easily do this.

In this regard, the system of Patent Document 1 can generate a three-dimensional model of a waterway by superimposing it on a three-dimensional model of a river embankment, but it is necessary to confirm the validity of the generated three-dimensional model of a waterway. is not taken into account, and in the first place it does not support the detailed design of waterways, including bending points.

The present disclosure has been made in view of this point, and its purpose is to facilitate the creation of a three-dimensional model of a waterway by allowing the designer to designate the installation position of the waterway while looking at three-dimensional data in two dimensions. The goal is to support canal design so that it can be done quickly and accurately.

In order to achieve the above object, one aspect of the present disclosure can be based on a waterway design support device that generates a waterway model representing a waterway on a three-dimensional model representing the current topography and plan. The waterway design support device includes a 3D model acquisition unit that acquires the 3D model, a display unit that displays the 3D model acquired by the 3D model acquisition unit from a plan view, and a 3D model that is displayed on the display unit. an input unit that accepts designation of a waterway installation position on the three-dimensional model from a plan view; and calculation of a waterway installation height at the waterway installation position accepted by the input unit based on height information possessed by the three-dimensional model. and a model generation unit that generates a waterway model representing the waterway at the waterway installation height calculated by the calculation unit.

According to this configuration, when the three-dimensional model acquisition unit acquires a three-dimensional model representing the current topography and plan, the acquired three-dimensional model is displayed on the display unit from a planar perspective. When the user specifies a waterway installation position, which is a waterway installation position, while looking at the three-dimensional model displayed from a plan view, the specified waterway installation position is input into the input unit. Since the three-dimensional model has height information, the height information of the designated waterway installation position can be obtained from the data making up the three-dimensional model. This allows calculation of the waterway installation height. The calculated waterway installation height is based on a three-dimensional model representing the current topography and plan, so it is an accurate height and can be calculated without requiring any effort on the part of the user.

Further, the input unit can also accept input of dimensions of the waterway. In this case, the calculation unit calculates the waterway installation height at the waterway installation position received by the input unit based on the height information of the three-dimensional model and the dimensions of the waterway received by the input unit. Calculate. The model generation unit can generate a waterway model representing the waterway having the dimensions received by the input unit at the waterway installation height calculated by the calculation unit.

Further, the input unit can also receive designation of a basin installation position on the three-dimensional model from a planar perspective displayed on the display unit. In this case, the calculation unit calculates the installation height of the basin at the basin installation position received by the input unit based on the height information possessed by the three-dimensional model, and the model generation unit calculates the installation height of the basin at the basin installation position received by the input unit, and the model generation unit Since a basin model representing the basin can be generated at the calculated basin installation height, the waterway model and the basin model can be placed overlapping on the three-dimensional model.

When generating a cell model, the input unit may accept input of cell dimensions. In this case, the calculation unit calculates the installation height of the basin at the installation position of the basin received by the input unit based on the height information of the three-dimensional model and the dimensions of the basin received by the input unit. Calculate. Then, the model generating section can generate a cell model representing the cell having the dimensions received by the input section at the cell installation height calculated by the calculation section.

Moreover, the calculation unit may calculate the slope value of the waterway based on the waterway model generated by the model generation unit. In this case, the display unit can display the slope value of the waterway calculated by the calculation unit, so that the designer can accurately grasp the slope direction and degree of the slope of the waterway.

Moreover, the calculation unit may calculate the water flow direction of the waterway based on the waterway model generated by the model generation unit. In this case, the display unit can display the water flow direction of the waterway calculated by the calculation unit, so that the designer can accurately grasp the water flow direction of the waterway.

Moreover, the calculation unit may calculate the height of the position where the waterway joins the basin based on the waterway model and the basin model generated by the model generation unit. In this case, the display section can display the height of the position where the channels of the basins merge, which has been calculated by the calculation section, so that the designer can accurately grasp the installation height of the channels with respect to the basin.

Further, the three-dimensional model may include a road model representing a road. In this case, the calculation unit calculates the waterway installation height based on the height information of the lower shoulder and middle part of both shoulders of the road model, or if there is a middle part, the lower one of the shoulders and the middle part. The model generation unit can automatically generate the waterway model at the lower shoulder and middle of the road model and at the waterway installation height calculated by the calculation unit. That is, for locations where waterways are required, such as road shoulders and midway sections, waterways can be automatically installed based on road standards, structure information, slope information, and the like.

Further, the input unit specifies, as the waterway installation position, an installation position of a waterway to be installed at the waterway, on the three-dimensional model from a plan view displayed on the display unit. can also be accepted. Then, the calculation unit calculates the installation height of the Hojiri canal installation position based on the height information of the three-dimensional model, and the model generation unit calculates the installation height of the Hojiri canal installation position calculated by the calculation unit. The waterway model can be generated at the installation height of the installation position. In other words, for example, whether or not to install a waterway at the foot of a slope or a vertical drainage canal is determined by the designer's specifications, so in such places, the designer's instructions should be followed without automatically installing a waterway. This allows the designer's intentions to be accurately reflected.

Another aspect of the present disclosure may be based on a waterway design support program that generates a waterway model representing a waterway on a three-dimensional model representing the current topography and plan. The waterway design support program includes a 3D model acquisition step of acquiring the 3D model, a display step of displaying the 3D model acquired in the 3D model acquisition step from a plane perspective, and a display step of displaying the 3D model acquired in the 3D model acquisition step, and an input step for receiving designation of a waterway installation position on the three-dimensional model from a plan view; and calculating a waterway installation height at the waterway installation position accepted in the input step based on height information possessed by the three-dimensional model. and a model generation step of generating a waterway model representing the waterway based on the waterway installation height calculated in the calculation step.

Moreover, the computer may execute a display step of calculating the gradient value and flowing water direction of the water channel in the calculation step and displaying the gradient value and flowing water direction of the water channel calculated in the calculation step.

Yet another aspect of the present disclosure may be based on a waterway design support method that generates a waterway model representing a waterway on a three-dimensional model representing the current topography and plan. The waterway design support method includes a 3D model acquisition step of acquiring the 3D model, a display step of displaying the 3D model acquired in the 3D model acquisition step from a plan perspective, and an input step for receiving designation of a waterway installation position on the three-dimensional model from a plan view; and calculating a waterway installation height at the waterway installation position accepted in the input step based on height information possessed by the three-dimensional model. a model generation step of generating a waterway model representing the waterway at the waterway installation height calculated in the calculation step, and displaying the slope value and flowing direction of the waterway calculated in the calculation step. and a display process.

As explained above, according to the present waterway design support device and waterway design support program, the designer can easily create a three-dimensional model of a waterway by specifying the installation position of the waterway while looking at three-dimensional data in two dimensions. It can be carried out quickly and accurately, and can support, for example, waterway design used in the design of roads, building blocks, housing land development, rivers, etc.

1 is a configuration diagram of a waterway design support device according to an embodiment of the present invention. FIG. 2 is a block diagram of a waterway design support device. It is a flowchart which shows the procedure of waterway design. FIG. 3 is a diagram showing an example of a three-dimensional display format. FIG. 3 is a diagram showing an example of a flat display format. FIG. 3 is a diagram showing an example of a three-dimensional polygon display format. FIG. 3 is a diagram illustrating an example of an enlarged display of a three-dimensional polygon display format. It is a figure which shows the example of the input window for inputting the dimension of a waterway and the dimension of a basin. It is a figure which shows the example of a display in which a waterway model is automatically arranged. It is a figure which shows the example of a display in which the waterway model and the basin model specified by the user are arranged. It is a figure which shows the example of a display in which an additional waterway model and a basin model are arranged. It is a figure which shows the example of a display of the height of each square and the height of each waterway. It is a figure which shows the example of a display of the gradient value of each waterway, and the water flow direction of each waterway. It is a figure which shows the example 1 of a display of the height of a waterway and the height of a square when a waterway enters a square from four directions. It is a figure which shows the example 2 of a display of the height of a waterway and the height of a square when a waterway enters a square from four directions.

Hereinafter, embodiments of the present invention will be described in detail based on the drawings. Note that the following description of preferred embodiments is essentially just an example, and is not intended to limit the present invention, its applications, or its uses.

FIG. 1 is a block diagram of a waterway design support device 1 according to an embodiment of the present invention, and FIG. 2 is a block diagram of the waterway design support device 1. The waterway design support device 1 is composed of a personal computer, and includes a main body 10 , a display 11 , an operation section 12 , and a storage device 13 . The main body section 10 has a control section 10A and a communication module 10B. The control unit 10A is composed of, for example, a CPU (central processing unit), a ROM, a RAM (memory), etc., and operates according to a program. The memory is a work memory for expanding the waterway design support program when the CPU executes the program, and a buffer memory for temporarily storing data. Further, the communication module 10B is a part that communicates with an external terminal via, for example, the Internet, and is configured to be able to transmit data, receive data, and the like.

The control unit 10A constitutes a three-dimensional model acquisition unit 10a, an input unit 10b, a calculation unit 10c, a model generation unit 10d, etc., which will be described later. The three-dimensional model acquisition unit 10a, input unit 10b, calculation unit 10c, and model generation unit 10d may be configured only with the hardware that configures the control unit 10A, or may be configured with a combination of hardware and software. may have been done. For example, when the CPU executes the waterway design support program, the control unit 10A can realize the functions of the three-dimensional model acquisition unit 10a, input unit 10b, calculation unit 10c, and model generation unit 10d.

The display unit 11 includes, for example, a liquid crystal display device, an organic EL display device, or the like. The display unit 11 is connected to the control unit 10A, and is controlled by the control unit 10A, and is capable of displaying various setting screens, input screens, design screens, analysis screens, three-dimensional display screens, planar viewpoint screens, etc. There is.

The operation unit 12 is composed of equipment for a user to operate the waterway design support device 1. The operation unit 12 includes, for example, a keyboard 12a and a mouse 12b, but may also include a touch operation panel built into the display unit 11, various pointing devices, and the like. The operation unit 12 is connected to the control unit 10A, and the control unit 10A can detect a user's operation using the operation unit 12.

The storage device 13 is comprised of a hard disk drive, solid state drive, etc. that can store various data, programs, and the like. The storage device 13 is connected to the control unit 10A, and according to instructions from the control unit 10A, stores the sent data and reads out the stored data. The storage device 13 may be built into the main body 10 or may be provided outside the main body 10. Further, the storage device 13 may be an external server or a so-called cloud-type storage system. Alternatively, only a part of the storage device 13 may be built into the main body 10, and the rest may be provided outside.

The storage device 13 stores a waterway design support program that causes a computer to execute each process described below. The form in which this waterway design support program is provided to users is not particularly limited; for example, as shown in FIG. 1, it is provided to users in a state recorded on a recording medium A such as a CD-ROM or DVD-ROM. Alternatively, the information may be provided to the user in a form that can be downloaded from an external server via the Internet or the like. By installing the provided waterway design support program into a general-purpose personal computer, it becomes possible to use the personal computer as the waterway design support device 1.

Note that when installing the waterway design support program on a general-purpose personal computer, it may be installed in the storage device 13. Furthermore, a general-purpose personal computer can be used as the canal design support device 1 by accessing an external server on which the canal design support program is installed, and the installation location of the canal design support program is particularly limited. It's not a thing.

The waterway design support device 1 facilitates the design work of a designer (user) by generating a waterway model representing a waterway on a three-dimensional model representing various topography and plans such as roads, building blocks, housing land development, river embankments, etc. This is a device that supports More specifically, when the canal design support device 1 receives a designation of a canal installation position on a three-dimensional model representing the current topography and plan, the three-dimensional model specifies the canal installation height at the received canal installation position. Calculate based on the height information you have. A waterway model representing the waterway is generated at the calculated waterway installation height. Similarly, when a designation of a basin installation position is received on the three-dimensional model, the basin installation height at the accepted basin installation position is calculated based on the height information included in the three-dimensional model. A basin model representing the basin is generated at the calculated basin installation height. The three-dimensional model includes height information at each point.

Further, the waterway design support program is a program that can generate a waterway model on a three-dimensional model representing the current topography and plan by operating a computer as follows. By using the waterway design support device 1, it is also possible to execute a method of generating a waterway model on a three-dimensional model representing the current topography and plan.

The configuration of each part of the waterway design support device 1 will be explained with reference to the flowcharts shown in FIGS. 1, 2, and 3. The three-dimensional model acquisition unit 10a shown in FIG. 2 is a part that acquires a three-dimensional model representing the current topography and plan. The three-dimensional model is stored as data in any format, for example, in the storage device 13, an external server, a recording medium such as a CD-ROM or DVD-ROM (hereinafter collectively referred to as the storage device 13, etc.). ing. The user of the waterway design support device 1 operates the operation unit 12 to read data of a desired three-dimensional model from the storage device 13, etc., so that the three-dimensional model acquisition unit 10a acquires the three-dimensional model. If the data of a plurality of three-dimensional models is stored in the storage device 13 or the like, the user may select the data of the desired three-dimensional model using the operation unit 12, and then perform a reading operation. The step of acquiring a three-dimensional model is a three-dimensional model acquiring step executed in step S1 of the flowchart shown in FIG.

The three-dimensional model data acquired in step S1 is temporarily stored inside the waterway design support device 1. The control unit 10A shown in FIG. 2 reads temporarily stored three-dimensional model data and displays it in a three-dimensional display format as shown in FIG. 4 so that the height can be seen in three dimensions. The display unit 11 displays the image by converting it into a two-dimensional display mode, which is displayed from a plane perspective as shown, and a three-dimensional polygon display mode, which is displayed using three-dimensional polygons, as shown in FIG. In FIG. 6, the image is displayed from a plane perspective. A plane viewpoint is a viewpoint when looking at the terrain from directly above. By operating the operation unit 12, the user can select whether to display in a three-dimensional display format, a planar display format, or a three-dimensional polygon display format from a planar viewpoint. Note that in FIGS. 3 to 6, a portion indicated by the reference numeral 101 is a road model representing a road.

When the user selects the 3D display format, the control unit 10A shown in FIG. 2 controls the display unit 4 to display the 3D model in the 3D display format shown in FIG. and can understand the plan three-dimensionally. Furthermore, when the user selects the planar display format, the control section 10A controls the display section 4 to display the three-dimensional model in the planar display format shown in FIG. It can be grasped visually. Further, when the user selects the three-dimensional polygon display format, the control unit 10A controls the display unit 4 to display the three-dimensional model in the three-dimensional polygon display format shown in FIG. and plans can be understood as a collection of three-dimensional polygons. The process of displaying the three-dimensional model on the display unit 11 is a three-dimensional model display process.

In the three-dimensional model display step, a part of the three-dimensional model displayed on the display unit 11 can also be displayed in an enlarged manner. For example, as shown in FIG. 7, by enlarging and displaying three-dimensional data displayed in a three-dimensional polygon display format, details can be confirmed in detail. By operating the operation unit 12, the user can select a portion to be enlarged and a magnification rate, and can enlarge any portion at any magnification rate. Reduction after enlargement is also possible. It is also possible to scroll and display the three-dimensional model on the display unit 11.

As shown in FIG. 7, a road center line 101a is set in the road model 101. In this example, on both sides (left and right sides) of a road model 101, there are an embankment model 102 representing an embankment and a cut model 103 representing a cut. Between the embankment models 102 below the road model 101 in FIG. 7, there is a berm model 104 representing a berm. In this way, the three-dimensional model includes, in addition to the road model 101, an embankment model 102, a cut model 103, and a berm model 104. Although the embankment model 102, cut model 103, and berm model 104 can be understood on a three-dimensional model, it is difficult to accurately understand the direction and degree of slope of each part on the three-dimensional model. Ta. In particular, there is a risk that the gradient at a point where both vertical and transverse gradients are intricately intertwined may be incorrectly grasped. Similarly, it may be difficult to grasp the slope of the road model 101 as well.

Further, the road model 101 includes, on both sides thereof, an embankment protected road shoulder model 101b representing an embankment protected road shoulder, and a cut protected road shoulder model 101c representing a cut protected road shoulder. Among the embankment protected road shoulder models 101b on both sides, one embankment protected road shoulder model 101b may be higher or lower than the other embankment protected road shoulder model 101b. Moreover, among the cut protection road shoulder models 101c on both sides, one cut protection road shoulder model 101c may be higher or lower than the other cut protection road shoulder model 101c. When determining which embankment protection road shoulder model 101b or cut earth protection road shoulder model 101c is higher, accurate judgment can be made based on the height information possessed by the three-dimensional model.

The input unit 10b shown in FIG. 2 is a part that accepts the designation of the waterway installation position and the basin installation position on the three-dimensional model (which may be in a three-dimensional polygon display form) from a plan view displayed on the display unit 11. It is. The user operates the operation unit 12 when specifying the waterway installation position and when specifying the basin installation position. What kind of operation is performed on the operation section 12 is detected by the input section 10b of the control section 10A. The input unit 10b detects the operation of the operating unit 12, thereby accepting the designation of the water channel installation position and the designation of the basin installation position. For example, when an arbitrary point on the three-dimensional model is clicked with the mouse 12b, the position on the three-dimensional model corresponding to the clicked point is input, and this position can be the waterway installation position or the basin installation position. Furthermore, by dragging the mouse 12b from any point on the three-dimensional model to another point, that range is specified on the three-dimensional model, and can be the range for installing water channels or the range for installing basins.

The input unit 10b also accepts input of the dimensions of the waterway and the dimensions of the basin. When inputting the dimensions of the waterway and the dimensions of the basin, the control unit 10A generates an input window 200 as shown in FIG. 8 as a user interface for input, and displays it on the display unit 11. The input window 200 is provided with a first input area 201 for inputting dimensions related to the basin, and a second input area 202 for inputting dimensions related to the waterway. The first input area 201 includes a selection section 201a that allows you to select whether or not to install a basin, and a numerical value ( For example, a numerical value input section 201b that can input data in m units) is provided. Further, the second input area 202 is configured with a numerical input section that allows the width and depth of the waterway to be input in numerical values (for example, in meters). The configuration of input window 200 is not limited to that shown in FIG. 8.

The user can input arbitrary numerical values into the numerical value input section 201b of the first input area 201 and the second input area 202 by operating the operation section 12. The input numerical values are temporarily stored inside the waterway design support device 1 as dimensional information used when generating the waterway model and the basin model and when calculating the installation height. When inputting each dimension, it is possible to input the dimensions at intervals of, for example, 0.1 m, but the invention is not limited to this. This process is a dimension input process executed in step S2 of the flowchart shown in FIG.

Here, in the three-dimensional model, there are places such as road shoulders, middle sections, and berms where it can be automatically determined whether or not to install a waterway based on road standards, road structure information, slope information, etc. Information on road standards, road structure, slope information, etc. are input in advance and stored in, for example, the storage device 13 in a state associated with data constituting the three-dimensional model. For such locations, the control unit 10A acquires road standards, road structure information, slope information, etc., and creates road shoulder models 101b and 101c included in the three-dimensional model, and an intermediate segment model (not shown) indicating the intermediate segment. ), a waterway is automatically installed on the small step model 104. Automatically means that the waterway design support device 1 installs the waterway without the user performing any operation for installing the waterway (specifying the installation position, etc.). In addition, the model is automatically installed on the road shoulder and middle section using the lower slope as a reference. The small step model can be automatically installed based on the attribute information of the three-dimensional model. This attribute information includes, for example, whether there is a waterway, type of work, dimensions, etc., and by acquiring the attribute information, the waterway design support device 1 can automatically install a waterway model.

Step S3 of the flowchart shown in FIG. 3 is an automatic installation process of road shoulders, middle sections, and berm waterways. Specifically, the calculation unit 10c shown in FIG. 2 automatically calculates the waterway installation height based on the height information of the lower shoulder of the road model 101 shown in FIG. 7. For example, if the embankment protected shoulder model 101b located on the lower side of FIG. 7 is lower among the embankment protected shoulder models 101b on both sides, the lower embankment protected shoulder model 101b is The installation height (shoulder waterway installation height) of the first road shoulder waterway model 300 installed on the side embankment protection road shoulder model 101b is automatically calculated.

Thereafter, the model generation unit 10d shown in FIG. 2 generates a first A road shoulder waterway model 300 (shown in FIG. 9) is automatically generated.

Further, as shown in FIG. 9, regarding the cut protection road shoulder, a second road shoulder waterway model 301 and a third road shoulder waterway model 302 are installed on the cut protection road shoulder models 101c on both sides of the road, respectively. Therefore, the calculation unit 10c calculates the second road shoulder channel model 301 installed on the cut protection road shoulder model 101c located in the upper part of FIG. 9 based on the height information of the cut protection road shoulder model 101c located in the upper part of FIG. The installation height (road shoulder waterway installation height) is automatically calculated, and the cut protection road shoulder model 101c located at the bottom of FIG. The installation height (roadside waterway installation height) of the third roadside waterway model 302 installed on 101c is automatically calculated. In this case, the model generation unit 10d automatically generates the second shoulder waterway model 301 at the cut protection road shoulder located on the upper side of FIG. 9 and at the shoulder waterway installation height calculated by the calculation unit 10c, and A third road shoulder waterway model 302 is automatically generated at the cut protection road shoulder located below the cut protection road shoulder 9 and at the road shoulder waterway installation height calculated by the calculation unit 10c.

In addition, when there is a berm, the calculation unit 10c automatically calculates the installation height of the berm waterway model 304 to be installed on the berm model 104 (the berm waterway installation height) based on the height information of the berm model 104. do. In this case, the model generating unit 10d automatically generates a berm model 304 (shown in FIG. 9) at the berm and the berm installation height calculated by the calculation unit 10c. Although not shown, the same applies to the intermediate division, and the calculation unit 10c calculates the installation height of the intermediate diversion channel model (intermediate diversion channel installation) to be installed on the intermediate division model based on the height information of the intermediate division model. height), and the model generation unit 10d automatically generates an intermediate diversion channel model at the intermediate division and the installation height of the intermediate diversion channel calculated by the calculation unit 10c. If there is no water channel to be automatically generated, step S3 is omitted.

Step S4 in the flowchart shown in FIG. 3 is an input step in which designation of the installation position of the water channel and the basin is accepted. In this step, as described above, the user specifies the waterway installation position and the basin installation position on the three-dimensional model while looking at the three-dimensional model from a plan view displayed on the display unit 11. The specified waterway installation position and basin installation position are temporarily stored in the storage device 13 or the like. The waterway whose installation position is specified is, for example, a waterway installed at the foot of a slope, a vertical drainage channel extending vertically along a slope, or the like. Examples of the squares whose installation positions are specified include squares installed on the roadside, squares installed in the middle, squares installed on small steps, squares installed at the foot of the slope, and the like.

Step S5 of the flowchart shown in FIG. 3 is a height calculation step of calculating the heights of the water channel installation position and the basin installation position. In this step, the calculation unit 10c calculates the waterway installation height at the waterway installation position and the basin installation height at the basin installation position received by the input unit 10b, based on the height information included in the three-dimensional model. The height calculation step utilizes the fact that when the position accepted by the input unit 10b is specified, the height of the position can be obtained from the height information included in the three-dimensional model.

Specifically, the calculation unit 10c calculates the waterway installation height at the waterway installation position received by the input unit 10b based on the height information possessed by the three-dimensional model and the dimensions of the waterway received by the input unit 10b. do. Thereby, the waterway installation height becomes a height that takes into account the dimensions of the waterway, so the height of the waterway model described later can be set to an appropriate height. Further, the calculation unit 10c calculates the installation height of the basin at the basin installation position received by the input unit 10b, based on the height information included in the three-dimensional model and the dimensions of the basin received by the input unit 10b. As a result, the installation height of the basin takes into account the dimensions of the basin, so that the height of the basin model, which will be described later, can be set to an appropriate height.

Step S6 of the flowchart shown in FIG. 3 is a model generation step of generating a waterway model representing the waterway at the waterway installation height calculated by the calculation unit 10c. In this model generation step, it is also possible to generate a box model representing a box at the box installation height calculated by the calculation unit 10c. Specifically, the model generation unit 10d shown in FIG. 2 generates a waterway model representing a waterway having the dimensions received by the input unit 10b at the waterway installation height calculated by the calculation unit 10c. A square model representing a square having the dimensions received by the input unit 10b is generated at the square installation height calculated by . This enables a design that reflects the designer's intentions.

In the example shown in FIG. 10, on the lower side of the road model 101 (lower side in FIG. 10), a road shoulder model 401 representing a road shoulder, a small step model 402 representing a small step, and a sandbox model 403 representing a small step. , a vertical drainage channel model 410 that connects the ditches and a waterway model 411 are generated and displayed overlaid on the three-dimensional model.

When generating the roadside ditch model 401, the input unit 10b selects the roadside ditch, which is the installation position of the ditch installed on the road shoulder, as the installation position of the roadside ditch on the three-dimensional model from a plan view displayed on the display unit 11. Accepts specification of installation location. The calculation unit 10c calculates the installation height of the shoulder ditch installation position based on the height information of the three-dimensional model. The model generation unit 10d generates a roadside barrier model 401 at the installation height of the roadside barrier installation position calculated by the calculation unit 10c.

In addition, when generating the small berm model 402, the input unit 10b inputs the installation position of the small berm installed on the small berm on the three-dimensional model from a plane perspective displayed on the display unit 11. We accept requests for the location of small terraces. The calculation unit 10c calculates the installation height of the small step installation position based on the height information of the three-dimensional model. The model generation unit 10d generates a small berm model 402 at the installation height of the small berm installation position calculated by the calculation unit 10c.

In addition, when generating the sandbox model 403, the input unit 10b determines the installation position of the sandbox on the three-dimensional model from a plane perspective displayed on the display unit 11. We accept requests for the location of the hojirimasu installation. The calculation unit 10c calculates the installation height of the sandbox installation position based on the height information of the three-dimensional model. The model generation unit 10d generates a sandbox model 403 at the installation height of the sandbox installation position calculated by the calculation unit 10c.

Furthermore, when generating the vertical drainage channel 410, the input unit 10b accepts designation of the vertical drainage channel installation position on the three-dimensional model from a plan view displayed on the display unit 11 as the installation position of the vertical drainage channel. For example, when a user specifies a shoulder ditch installation position and a berm installation position, this is accepted by the input unit 10b, and a vertical drainage channel is automatically installed between the shoulder ditch installation position and the berm installation position. Thereafter, when the location for installing the sandbox is specified, it is accepted by the input unit 10b, and a vertical drainage channel is automatically installed between the location for installing the small terrace and the location for installing the sandbox. The calculation unit 10c calculates the installation height of the vertical drainage channel installation position based on the height information of the three-dimensional model. The model generation unit 10d generates a vertical drainage channel model 410 at the installation height of the vertical drainage channel installation position calculated by the calculation unit 10c.

In addition, when generating the Hojiri waterway 411, the input unit 10b accepts designation of the Hojiri waterway installation position on the three-dimensional model from a plan view displayed on the display unit 11 as the installation position of the Hojiri waterway. For example, the user specifies the installation position of a roadside ditch, the setting position of a waterway, and the designation of a small berm installation position, and the input unit 10b receives the designation. Further, in the case of the slope waterway, the user also specifies the bending point and the distance (step) amount from the slope, and these are accepted by the input unit 10b. The calculation unit 10c specifies the Hojiri waterway that extends from the roadside ditch to the small berm, and sets the identified Hojiri waterway installation position as the Hojiri waterway installation position. The calculation unit 10c calculates the installation height of the Hojiri waterway installation position based on the height information of the three-dimensional model. At this time, the calculation unit 10c calculates the installation height of the slope waterway installation position, taking into consideration the bending point and the amount of distance from the slope slope. The model generation unit 10d generates the Hojiri waterway model 411 at the installation height of the Hojiri waterway installation position calculated by the calculation unit 10c.

FIG. 11 shows an example in which additional basin models 404, 405, 406 and additional channel models 412, 413, 414, 415, 416 are arranged. Waterway model 416 is a transverse pipe. Further, FIG. 12 shows an example in which the height of each basin and the height of each waterway are displayed superimposed on the three-dimensional model on the display unit 11. As shown in FIG. 12, by acquiring the height of each basin and the height of each waterway, the height of each part can be presented to the user in numerical values. Note that the heights can be displayed, for example, if waterways enter the basin from four directions, the heights of the four channels and the height of the basin can be displayed respectively.

FIG. 14A shows a display example 1 of the height of the water channel and the height of the basin when water channels enter the basin from four directions. In display example 1, lead lines extending from the basin and four water channels are displayed, and the heights of the corresponding lead lines are indicated numerically.

FIG. 14B shows a second display example of the height of the water channel and the height of the basin when water channels enter the basin from four directions. In display example 2, as a legend, the first waterway, the second waterway, the third waterway, and the fourth waterway are each shown by numbers, and the basins are also shown by numbers. Along with the legend, a leader line extending from the basin is displayed, and the number of the first to fourth water channels and the number of the basin are displayed on the leader line, and the corresponding height is numerically indicated.

Step S7 in the flowchart shown in FIG. 3 is a calculation step of calculating the slope value and flowing direction of the waterway. The calculation unit 10c calculates the slope value (%) of each waterway based on the waterway models 300 to 304 and 410 to 416 generated by the model generation unit 10d. Furthermore, the calculation unit 10c calculates the water flow direction of the waterway based on the waterway model generated by the model generation unit 10d.

Specifically, the calculation unit 10c can automatically calculate the heights of the bottom and top of the basin and the bottom of the waterway from the height information of the three-dimensional model, the dimensions of the basin, and the dimensions of the waterway. can. The calculation unit 10c calculates the gradient value and the flowing water direction from the height information of the waterway bottom. By performing this calculation for each waterway, the slope value and flowing direction of each waterway can be obtained.

Step S8 of the flowchart shown in FIG. 3 is a step of displaying on the display unit 11 the slope value of the waterway and the water flow direction of the waterway calculated by the calculation unit 10c. When the control unit 10A acquires the gradient value and the water flow direction of the waterway calculated by the calculation unit 10c, the control unit 10A displays the gradient value and the flow direction of each waterway on the three-dimensional model of the display unit 11, as shown in FIG. can be displayed on top of the image and presented to the user. The direction of water flow can be indicated by, for example, an arrow, but is not limited to this. This makes it easy to determine the exact direction of water flow without having to determine the direction of the slope at each point. Note that only the slope value of the waterway may be displayed, or only the water flow direction of the waterway may be displayed.

(Operations and effects of embodiments)
As explained above, according to the present embodiment, when the 3D model acquisition unit 10a acquires a 3D model representing the current topography and plan, the acquired 3D model is displayed on the display unit 11 from a planar perspective. I can do it. When the user specifies a waterway installation position, which is a waterway installation position, while looking at the three-dimensional model displayed from a plan view on the display unit 11, the specified waterway installation position is input into the input unit 10b. Since the three-dimensional model has height information, the height information of the designated waterway installation position can be obtained from the data making up the three-dimensional model. This allows calculation of the waterway installation height. The calculated waterway installation height is based on a three-dimensional model representing the current topography and plan, so it is an accurate height and can be calculated without requiring any effort on the part of the user. Therefore, three-dimensional modeling of the waterway can be easily and accurately performed.

Similarly, when the user specifies the gauze installation position, which is the installation position of the gauze, while looking at the three-dimensional model displayed from a planar perspective on the display unit 11, the specified gauze installation position is input into the input unit 10b. Ru. As a result, the installation height of the basin can be obtained, and since the obtained installation height of the basin is based on a three-dimensional model representing the current topography and plan, it is an accurate height and requires no user effort. It can be calculated without requiring

The embodiments described above are merely illustrative in all respects and should not be interpreted in a limiting manner. Furthermore, all modifications and changes that come within the scope of equivalents of the claims are intended to be within the scope of the present invention.

As described above, the waterway design support device and the waterway design support program according to the present disclosure can be used, for example, in various designs such as roads, building blocks, residential land development, and river embankments.

1 Channel design support device 10a Three-dimensional model acquisition section 10b Input section 10c Calculation section 10d Model generation section 11 Display section

Claims (9)

A waterway design support device that generates a waterway model representing a waterway on a three-dimensional model representing the current topography and plan,
a three-dimensional model acquisition unit that acquires the three-dimensional model;
a display unit that displays the three-dimensional model acquired by the three-dimensional model acquisition unit from a planar perspective;
an input unit that accepts designation of a waterway installation position on the three-dimensional model from a plan view displayed on the display unit;
a calculation unit that calculates a waterway installation height at the waterway installation position received by the input unit based on height information included in the three-dimensional model;
a model generation unit that generates a waterway model representing the waterway at the waterway installation height calculated by the calculation unit;
The three-dimensional model includes a road model representing a road,
The calculation unit automatically calculates the waterway installation height based on the height information of the lower shoulder and middle of both shoulders or the shoulder and middle of the road model,
The waterway design support device is characterized in that the model generation unit automatically generates the waterway model at the lower shoulder and middle of the road model and at the waterway installation height calculated by the calculation unit. The waterway design support device according to claim 1,
The input unit receives input of dimensions of the waterway,
The calculation unit calculates the waterway installation height at the waterway installation position received by the input unit based on height information included in the three-dimensional model and dimensions of the waterway received by the input unit. ,
The waterway design support device is characterized in that the model generation unit generates a waterway model representing the waterway having the dimensions received by the input unit at the waterway installation height calculated by the calculation unit. The waterway design support device according to claim 1,
The input unit accepts a designation of a box installation position on the three-dimensional model from a plan view displayed on the display unit,
The calculation unit calculates the installation height of the basin at the basin installation position received by the input unit, based on height information possessed by the three-dimensional model,
The waterway design support device is characterized in that the model generation unit generates a basin model representing the basin at the basin installation height calculated by the calculation unit. The waterway design support device according to claim 3,
The input unit accepts input of dimensions of the square,
The calculation unit calculates the installation height of the basin at the basin installation position received by the input unit, based on height information of the three-dimensional model and dimensions of the basin received by the input unit. ,
The waterway design support device is characterized in that the model generation unit generates a basin model representing the basin having the dimensions received by the input unit at the basin installation height calculated by the calculation unit. The waterway design support device according to claim 1,
The calculation unit calculates a slope value of the waterway based on the waterway model generated by the model generation unit,
The waterway design support device is characterized in that the display unit displays the slope value of the waterway calculated by the calculation unit. The waterway design support device according to claim 1,
The calculation unit calculates the water flow direction of the waterway based on the waterway model generated by the model generation unit,
The waterway design support device is characterized in that the display unit displays the flow direction of the waterway calculated by the calculation unit. The waterway design support device according to claim 1,
The input unit receives, on the three-dimensional model from a plan view displayed on the display unit, a designation of a waterway installation position, which is an installation position of a waterway installed at the waterway, as the waterway installation position,
The calculation unit calculates the installation height of the Hojiri waterway installation position based on the height information of the three-dimensional model,
The waterway design support device is characterized in that the model generation unit generates the waterway model at the installation height of the waterway installation position calculated by the calculation unit. A waterway design support program that generates a waterway model representing a waterway on a three-dimensional model representing the current topography and plan,
a 3D model acquisition step of acquiring the 3D model including a road model representing a road;
a display step of displaying the three-dimensional model obtained in the three-dimensional model obtaining step from a planar perspective;
an input step of accepting a designation of a waterway installation position on the three-dimensional model from a plan view displayed in the display step;
a calculation step of calculating the waterway installation height at the waterway installation position received in the input step based on height information possessed by the three-dimensional model;
causing a computer to execute a model generation step of generating a waterway model representing the waterway at the waterway installation height calculated in the calculation step;
In the calculation step, the waterway installation height is automatically calculated based on the height information of the lower shoulder and middle of both shoulders or the shoulder and middle of the road model,
The waterway design support program is characterized in that, in the model generation step, the waterway model is automatically generated at the lower shoulder and midsection of the road model and at the waterway installation height calculated in the calculation step . In the waterway design support program according to claim 8,
In the calculation step, calculate the slope value and flowing direction of the waterway,
A waterway design support program characterized by causing a computer to execute a display step of displaying the gradient value and flowing water direction of the waterway calculated in the calculation step.