JP2017045163A - Land use support system and land use support method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a land use support system and a land use support method capable of inexpensively estimating a land use cost.SOLUTION: A land use support system 1 comprises a control device 10 provided with: an interface section 12 which can be connected to an internet network 3; a GIS data processing section 13 which estimates an undulation state of a planned installation site 50 on the basis of GIS data obtained through the internet network 3 and sets a development area requiring land development work in the planned installation site 50 on the basis of the estimated undulation state; a land development planning section 14 which calculates a cost for the land development work; and a control section 11 which controls the interface section 12, the GIS data processing section 13 and the land development planning section 14. A land use support method is executed by the control device 10.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a land use support system and a land use support method.

  Patent Document 1 states that “the present invention is intended for a plurality of abandoned cultivated land in a certain wide area (hereinafter referred to as“ target area ”) such as municipalities and prefectures, and the sun that these lands have. It evaluates the potential of photovoltaic power generation. Since a plurality of abandoned farmland are handled at a time, three-dimensional spatial information representing the topography is used. Therefore, first, three-dimensional spatial information will be described. The three-dimensional spatial information is information composed of points, lines, surfaces, or combinations thereof having plane coordinate values and height information. Further, the plane coordinate value is represented by latitude and longitude or X and Y coordinates, and the height means a vertical distance from a predetermined reference horizontal plane such as an altitude. This three-dimensional spatial information can be created by various means. For example, it can be created based on a set of two stereo aerial photographs (satellite photographs), created by aerial laser measurement or satellite radar measurement, or can be created by surveying the site directly. (See paragraphs 0030 and 0031).

Japanese Patent No. 5283100

The photovoltaic power generation potential evaluation apparatus (land use support system) described in Patent Document 1 creates three-dimensional spatial information about land by aerial photographs, satellite photographs, and surveying. According to this method, since it is necessary to procure large-scale materials such as aircraft and surveying equipment, a corresponding cost is required. For example, even if only the potential of solar power generation is estimated for a customer, a high cost is required, so that a great loss occurs if the estimate plan is not adopted by the customer.
As described above, the photovoltaic power generation potential evaluation apparatus described in Patent Document 1 has a problem that it takes a great deal of cost to estimate.

  Then, this invention makes it a subject to provide the land use support system which can estimate the expense for land use at low cost, and a land use support method.

  In order to solve the above problems, the present invention acquires geographical data including position information and altitude information of the target land via the Internet network, and the undulation state of the target land based on the position information and the altitude information. And a land use support system including a control device capable of calculating the construction cost of the creation work based on the estimated undulation state, and setting a creation area in the target land. The land use support method is executed by the control device.

  According to the present invention, it is possible to provide a land use support system and a land use support method capable of estimating the cost for land use at a low cost.

It is a figure which shows the structure of a land use support system. It is a figure which shows the process by a control apparatus. It is a figure which shows an example of the planned installation site made into the detailed drawing, (a) is a photograph of a planned installation site, (b) is a land inclination figure which shows the inclination of an installation planned site. It is a figure which shows the landform topography pattern, (a) is a figure which shows the 1st step-shaped pattern (Patt1), (b) is a figure which shows the 2nd undulated shape pattern (Patt2), (c) is flat It is a figure which shows a 3rd pattern (Patt3). It is a figure explaining the construction work with respect to the area | region to which a 2nd pattern respond | corresponds, (a) is a figure which shows the shape of a creation area, (b) is a figure which shows the amount of cuts. It is a figure explaining an example of the calculation method of cut amount, (a) is a figure which shows the convex-shaped part in the altitude of the reference | standard line after construction, (b) is an elevation higher by the predetermined height than the reference line after creation. The figure which shows the convex-shaped part in (c) is a figure which shows the convex-shaped part in top height. (A) is a figure which shows an installation topographical map, (b) is a figure which shows the altitude after creation of the concave part adjacent to two convex parts. It is a figure which shows an example which calculates the area of the installation possible area | region based on a land inclination map. (A) is an example of a solar power generation panel specification, (b) is an example of the specification of a power conditioner. It is a figure which shows an example of a panel layout figure. It is a figure which shows an example of an arrangement plan place and a boring point. (A) is a figure which shows the range which cannot arrange | position a photovoltaic power generation panel by a law, (b) is a figure which shows the panel layout figure based on a law.

  Hereinafter, a land use support system according to an embodiment of the present invention will be described in detail with reference to the drawings as appropriate. In the drawings shown below, common members are denoted by the same reference numerals, and redundant descriptions are omitted as appropriate.

FIG. 1 is a diagram showing a configuration of a land use support system.
The land use support system 1 of the present embodiment supports efficient arrangement of the photovoltaic power generation panel 2 on a predetermined target land (planned installation place 50) and estimation of the cost required for the arrangement of the photovoltaic power generation panel 2.
As shown in FIG. 1, the land use support system 1 of the present embodiment has a control device 10 that can be connected to the Internet network 3.
The control device 10 includes a control unit 11, a network interface (I / F) 12, a GIS (geographic information system) data processing unit 13, a creation planning unit 14, an arrangement planning unit 15, a detailed planning unit 16, an input unit 17a, and an output It has a portion 17b.
The control unit 11, the network interface 12, the GIS data processing unit 13, the creation planning unit 14, the arrangement planning unit 15, the detailed planning unit 16, the input unit 17 a, and the output unit 17 b are connected via, for example, a data bus 18 and exchange data with each other. Is possible.

  The control unit 11 is a computer device including a CPU (Central Processing Unit), a memory, and other peripheral circuits (not shown). The control unit 11 executes a predetermined program to control the network interface 12, the GIS data processing unit 13, the creation planning unit 14, the arrangement planning unit 15, the detailed planning unit 16, the input unit 17a, and the output unit 17b, and Support the promotion of usage plans.

The network interface 12 is an interface (I / F) unit that connects the control device 10 to the Internet network 3.
The GIS data processing unit 13 is a data processing unit that processes GIS data that can be acquired from the Internet 3 via the network interface 12. Details of the GIS data processing unit 13 will be described later.
The creation planning unit 14 determines the necessity of creation work for creating the land (the planned installation site 50) so that the photovoltaic power generation panels 2 are efficiently arranged. Details of the creation planning unit 14 will be described later.
The arrangement planning unit 15 sets the arrangement of the photovoltaic power generation panels 2 in the planned installation site 50. The photovoltaic power generation panel 2 is installed on the installation site 50 by being attached to the gantry 2a. A plurality of photovoltaic power generation panels 2 are attached to one gantry 2a. The arrangement planning unit 15 sets the arrangement of the gantry 2a to which the photovoltaic power generation panel 2 is attached. Details of the arrangement planning unit 15 will be described later.
The detailed planning unit 16 calculates the cost required for the arrangement of the photovoltaic power generation panel 2 based on information on the cable length, ground information, and the like. Details of the detailed planning unit 16 will be described later.
The input unit 17a is an operation unit such as a keyboard or a mouse for inputting information necessary for an administrator or the like to the control device 10.
The output unit 17b is a data output unit configured to include a monitor, a printer, and the like.

  The GIS data is data (geographic data) including location information and elevation information of the land, and can be obtained via the Internet network 3 or the like. The land use support system 1 of the present embodiment uses GIS data relating to the planned installation site 50 where the photovoltaic power generation panel 2 is to be installed. In the GIS data, the position information is indicated by latitude and longitude.

  The control device 10 provided in the land use support system 1 of the present embodiment acquires GIS data relating to the planned installation site 50. Based on the acquired GIS data, the GIS data processing unit 13 of the control device 10 determines the necessity of the construction work for creating the planned installation site 50 so as to efficiently arrange the photovoltaic power generation panels 2. When the GIS data processing unit 13 determines that the creation work is necessary, the creation planning unit 14 of the control device 10 calculates a construction cost required for the creation work. Further, the arrangement planning unit 15 of the control device 10 sets an effective arrangement of the photovoltaic power generation panel 2. As described above, the control device 10 provided in the land use support system 1 of the present embodiment determines the necessity of the creation work for the planned installation site 50 and calculates the cost of the creation work when it is determined that the creation work is necessary. . Furthermore, the control device 10 provided in the land use support system 1 supports the promotion of the land use plan by setting the effective arrangement of the photovoltaic power generation panels 2 on the planned installation site 50.

  FIG. 2 is a diagram showing processing by the control device. FIG. 3 is a diagram showing an example of the planned installation site in a detailed drawing. (A) is a photograph of the planned installation site, and (b) is a land inclination diagram showing the inclination of the planned installation site. In addition, the photograph Pic1 shown to (a) of FIG. 3 and the land inclination map 50a shown to (b) show north (N) above and the south (S) below.

  As shown in FIG. 2, the GIS data processing unit 13 responds to a command from the control unit 11 (see FIG. 1) through the Internet network 3 (see FIG. 1) to the GIS of the planned installation site 50 (see FIG. 1). Data is acquired (13s1). Then, the GIS data processing unit 13 makes a detailed drawing of the planned installation site 50 based on the acquired GIS data. The GIS data processing unit 13 makes a detailed drawing of the planned installation site 50 based on the position information and altitude information of the planned installation site 50 included in the GIS data (13s2).

The control unit 11 gives a command to the network interface 12 when position information (latitude and longitude) of the planned installation site 50 is input by an administrator or the like, and acquires GIS data corresponding to the input position information. . For example, the administrator or the like inputs position information (latitude and longitude) of several points on the boundary line Lb of the planned installation site 50 (an example is indicated by a white line in FIG. 3A) with the input unit 17a (see FIG. 1). To the control device 10.
In this case, the control unit 11 gives a command to the network interface 12 to acquire the GIS data of the part surrounded by the input position information.

The GIS data processing unit 13 shown in FIG. 2 outputs a land inclination map 50a (see (b) of FIG. 3) (13s3).
Based on the position information included in the acquired GIS data, the GIS data processing unit 13 superimposes the altitude information on the photograph Pic1 of the planned installation site 50 as shown in FIG. Then, the GIS data processing unit 13 converts the photograph Pic1 into a detailed drawing, and displays the boundary line Lb of the planned installation site 50 with a white line, for example. Note that the photograph Pic1 shown in FIG. 3A can be a map information photograph that can be acquired via the Internet 3 (see FIG. 1), for example. Further, the GIS data processing unit 13 draws a boundary line Lb (white line) by dividing the planned installation site 50 in the photograph Pic1 based on the position information (latitude and longitude) of the installation site 50.
Note that the GIS data processing unit 13 can also superimpose the altitude information on the photograph Pic1 and display the photograph Pic1 three-dimensionally (not shown).

Next, the GIS data processing unit 13 estimates the inclination of the planned installation site 50 from the position information and altitude information of the planned installation site 50.
For example, the GIS data processing unit 13 extracts two points included in the planned installation site 50 from the position information included in the GIS data, and calculates the inclination from the distance between the two points and the elevation difference. Such a process is performed on the entire area of the planned installation site 50 to estimate the inclination of the planned installation site 50.

  Further, the GIS data processing unit 13 sets a predetermined inclination as a threshold (10 ° in the example shown in FIG. 3B), and classifies the planned installation site 50 by the threshold. As shown in FIG. 3B, the GIS data processing unit 13 has an area (indicated by dots) where the inclination of the planned installation site 50 is greater than or equal to a threshold value (10 °) and an area where the inclination is equal to or less than the threshold (outlined). And a land inclination map 50a divided into (shown) is output (13s3). The GIS data processing unit 13 may three-dimensionally display the land inclination map 50a based on the altitude information included in the GIS data.

And the GIS data processing part 13 shown in FIG. 2 sets the installation possible area | region 51 in which the photovoltaic power generation panel 2 (refer FIG. 1) can be installed in the installation planned site 50 (13s4). The GIS data processing unit 13 of the present embodiment sets an area where the inclination is equal to or less than the threshold in the land inclination map 50 a as the installable area 51. In the present embodiment, an area having an inclination of 10 ° or less (area shown in white) is set as the installable area 51.
Note that the GIS data processing unit 13 may be configured to set only the region (southern slope) that is inclined so as to descend toward the south (S) as the installable region 51. That is, the area where the altitude is lower toward the south (S) may be set as the installable area 51.

4A and 4B are diagrams showing land-form topographic patterns, where FIG. 4A shows a staircase-shaped first pattern (Patt1), FIG. 4B shows a undulating-shaped second pattern (Patt2), and FIG. ) Is a diagram showing a flat third pattern (Patt3).
The GIS data processing unit 13 associates the land shape (topography) of the installable area 51 set in the planned installation site 50 with one of the three topographic patterns shown in FIGS. The GIS data processing unit 13 calculates the terrain of the installable area 51 based on the altitude information included in the GIS data, and selects one of the terrain patterns based on the calculated terrain.

  For example, the GIS data processing unit 13 has the same altitude or a small altitude difference over a predetermined distance on a straight line toward the south (S). When the state of continuing for a predetermined distance is repeated, the staircase-shaped first pattern shown in FIG. 4A is selected.

  In addition, when the elevation is repeated on the straight line toward the south (S), the GIS data processing unit 13 selects the second pattern of the undulating shape shown in FIG.

  Further, the GIS data processing unit 13 selects the third pattern having a flat slope shape shown in FIG. 4C when the altitude is uniformly lowered on the straight line toward the south (S).

In this way, the GIS data processing unit 13 estimates the undulation state of the planned installation site 50 (installable area 51) by associating one of the first pattern, the second pattern, and the third pattern. In particular, the GIS data processing unit 13 determines that there is an undulation in the area where the second pattern is selected.
Note that the GIS data processing unit 13 may be configured to divide the installable area 51 into a plurality of areas in the east-west direction, and to associate the terrain pattern with each of the divided areas.
Further, the topographic pattern corresponding to the installable area 51 is not limited to the three patterns shown in FIGS.

  The GIS data processing unit 13 shown in FIG. 2 determines that the construction work is unnecessary for the region corresponding to the topographic pattern of the first pattern (step shape) and the region corresponding to the third pattern (flat), and these regions. It is determined that the photovoltaic power generation panel 2 can be effectively arranged.

Further, the GIS data processing unit 13 shown in FIG. 2 determines that the area corresponding to the second pattern (undulation shape) in the installable area 51 (see FIG. 3B) needs to be reconstructed. Then, the GIS data processing unit 13 sets the area corresponding to the second pattern as the creation area 52 (13s5).
As described above, the GIS data processing unit 13 according to the present embodiment determines the necessity of the creation work for the installable area 51 based on the terrain (undulation state) of the installable area 51 and determines that the creation work is necessary. In this case, the area to be constructed (creation area 52) is set in the installable area 51 (in the planned installation site 50). As an example, the formation area 52 is indicated by a broken line in FIG.

  The creation planning unit 14 illustrated in FIG. 2 calculates the cost (construction cost) required for the creation work for the creation region 52 set by the GIS data processing unit 13.

  FIG. 5 is a diagram for explaining the creation work for the region corresponding to the second pattern. FIG. 5A is a diagram showing the shape of the creation region, and FIG.

  In the case where the formation area 52 has an undulating shape (second pattern) as shown in FIG. 5A, the formation planning unit 14 (see FIG. 2) is at an altitude at the point where the elevation is high (convex portion Hp). A construction work (cutting) is set so that the construction area 52 is flattened by filling the low point (concave portion Lp).

  At this time, the creation planning unit 14 sets the creation work with the amount of soil (cutting amount) moving from the convex portion Hp to the concave portion Lp as a parameter.

  For example, when the height (elevation) of the creation region 52 after the creation work is set to an intermediate height between the height difference between the convex portion Hp and the concave portion Lp, as shown in FIG. The part of the soil higher than the line indicating the elevation after the formation of the region 52 (the reference line L1 after the formation) is moved to a part lower than the reference line L1 after the formation. At this time, the cost (construction cost) required for the construction work is determined by the amount of movement (cutting amount) of the soil that moves. Therefore, the creation planning unit 14 (see FIG. 2) calculates the cut amount.

  In FIG. 5B, the height (top height) of the top of the convex portion Hp is “ht”, and the height (bottom height) of the bottom of the adjacent concave portion Lp is “hb”. Is shown. For example, the formation planning unit 14 (see FIG. 2) has an intermediate height between the portion having the lowest bottom height of the concave portion Lp adjacent to the convex portion Hp and the top height ht of the convex portion Hp. Is the elevation of the reference line L1 after creation. In (b) of FIG. 5, the intermediate height ((ht + hb) / 2) between the top height (ht) of the convex portion Hp and the bottom height (hb) of the adjacent concave portion Lp is the reference line after formation. An example of setting the altitude (h1) of L1 is shown.

  6A and 6B are diagrams for explaining an example of the calculation method of the cut amount, in which FIG. 6A is a diagram showing a convex portion at an elevation of the reference line after creation, and FIG. 6B is a predetermined height from the reference line after creation. The figure which shows the convex part in height only high, (c) is a figure which shows the convex part in top height. In the following, the volume (cutting amount) of the convex portion Hp at the elevation (h1) of the post-construction reference line L1 is approximated by a collection of cubes each having a side of 5 m.

  For example, the creation planning unit 14 (see FIG. 2) changes the shape of the convex portion Hp at the height (elevation (h1)) of the post-creation reference line L1 to a mesh of a predetermined size (for example, a 5 m square mesh). To divide. When the elevation of the reference line L1 after creation is “h1”, the creation planning unit 14 divides the convex portion Hp at the elevation (h1) into a 5 m square mesh (indicated by dots in FIG. 6A).

  Next, the creation planning unit 14 (see FIG. 2) sets the shape of the convex portion Hp at an elevation higher than the height of the reference line L1 after creation by a predetermined height (5 m in this embodiment) to a mesh having a predetermined size ( In this embodiment, it is divided into 5 m square mesh). The creation planning unit 14 divides the convex portion Hp at an altitude (h1 + 5 m) 5 m higher than the altitude h1 into a 5 m square mesh (indicated by dots in FIG. 6B).

  The creation planning unit 14 divides the convex portion Hp with a mesh at a predetermined height interval (5 m interval in the present embodiment) up to the height of the top portion of the convex portion Hp (top height ht). The creation planning unit 14 divides the convex part Hp in the height direction at an interval of 5 m from the altitude h1, and projects the convex part Hp to the final altitude (final height he) that becomes an altitude not exceeding the top height (ht). Is divided by a mesh (indicated by dots in FIG. 6C).

For example, as shown in (a) of FIG. 6, when the convex portion Hp is divided into 44 meshes (5 m square) at the elevation (h1) of the reference line L1 after creation, the creation planning unit 14 The cut amount at the altitude (h1) is calculated by the following equation (1).
5 [m] × 5 [m] × 5 [m] × 44 [pieces] = 5500 [m ³ ] (1)

Further, as shown in FIG. 6B, the convex portion Hp is divided into 20 meshes (5 m square) at an altitude (h1 + 5 m) 5 m higher than the altitude (h1) of the reference line L1 after creation. In this case, the creation planning unit 14 calculates the cut amount at the altitude (h1 + 5m) by the following equation (2).
5 [m] × 5 [m] × 5 [m] × 20 [pieces] = 2500 [m ³ ] (2)

  And the creation plan part 14 integrates the cut amount calculated every 5 m in the height direction, and the integrated value is obtained from the convex part Hp that is above the elevation (h1) of the reference line L1 after the creation. The cut amount.

The creation planning unit 14 shown in FIG. 2 calculates a total cut amount in the creation work (14s1).
The creation planning unit 14 sets the post-construction reference line L1 for all the convex portions Hp, and calculates the cut-out amount from the portion above the set post-construction reference line L1. Then, the creation planning unit 14 accumulates the fill amounts of all the convex portions Hp, and sets the accumulated value as a fill amount (total fill amount) in the creation work. In this way, the creation planning unit 14 calculates the total cut amount in the creation work.
In addition, the method of calculating the total fill amount in the creation work is not limited to this method.

  In addition, the creation planning unit 14 fills all the recessed portions Lp with the soil of the total cut amount, and the elevations of all the recessed portions Lp have reached the elevation of the reference line L1 after the creation of the adjacent protruding portions Hp. Estimated. That is, the creation planning unit 14 estimates that the soil of the convex portion Hp is filled with the concave portion Lp, and the convex portion Hp and the concave portion Lp are flattened.

Then, the creation planning unit 14 shown in FIG. 2 creates post-creation terrain data (14s2).
The creation planning unit 14 replaces the elevation information higher than the elevation of the reference line L1 after the creation with the elevation of the reference line L1 after the creation, among the elevation information of the GIS data indicating each convex portion Hp, and replaces each concave portion Lp. Of the elevation information of the GIS data to be shown, post-creation terrain data is created by replacing the elevation information lower than the elevation of the post-construction reference line L1 with the elevation of the post-construction reference line L1.

(A) of FIG. 7 is a figure which shows an installation topographic map, (b) is a figure which shows the altitude after the formation of the concave part adjacent to two convex parts.
The GIS data processing unit 13 shown in FIG. 2 creates an installation topographic map Pic2 (see FIG. 7A) (13s6).
The GIS data processing unit 13 superimposes the altitude information included in the post-creation terrain data created by the creation planning unit 14 on the photograph Pic1 of the planned installation site 50 shown in FIG. In addition, the GIS data processing unit 13 is an image data in which the altitude information included in the GIS data is different from the altitude information included in the post-creation terrain data (installed terrain map Pic2 shown in FIG. 7A) Is output to the output unit 17b. In the example of the installation topographic map Pic2 shown in FIG. 7 (a), the portion where the topography has changed due to the creation is indicated by white diagonal lines. In this manner, the GIS data processing unit 13 creates the installation topographic map Pic2 based on the post-creation topographic data. Further, the GIS data processing unit 13 may display the installation topographic map Pic2 shown in FIG. 7A three-dimensionally based on the altitude information included in the post-creation topographic data.

  In addition, as shown in FIG. 7B, when one concave portion Lp is adjacent to two convex portions Hp, the creation planning unit 14 adjoins the elevation of the concave portion Lp after creation. It is estimated that the average value of the two elevations of the post-construction reference line L1 set in each of the two convex portions Hp. For example, as shown in (b) of FIG. 7, when one concave portion Lp is adjacent to two convex portions Hp (a) and Hp (b), the creation planning unit 14 is configured as shown in (b) of FIG. 7. As shown by the broken line, the elevation after the formation of the concave portion Lp is set to the elevation (h1 (a)) of the reference line L1 after the formation set to one convex portion Hp (a) and the other convex shape. It is assumed that the average value ((h1 (a) + h1 (b)) / 2) of the elevation (h1 (b)) of the post-construction reference line L1 set in the part Hp (b).

  In addition, the GIS data processing unit 13 (see FIG. 2) is a region corresponding to the topographic pattern of the first pattern (step shape) shown in FIG. For the region corresponding to the third pattern (flat) shown in FIG. 3, image data obtained by superimposing GIS data on the photograph of the planned installation site 50 shown in FIG. 3A (installation topographic map shown in FIG. 7A). Pic2) is output to the output unit 17b. In this case, the change in the topography due to the creation is not displayed on the installation topographic map Pic2 (for example, a portion other than the white hatched portion in FIG. 7A).

Further, the creation planning unit 14 shown in FIG. 2 calculates a construction cost (approximate value) of the creation work by adding a predetermined coefficient to the total fill amount (14s3). For example, if the construction cost per 1 m ^{3 of} the cut amount is set in advance, the creation planning unit 14 adds the construction cost per 1 m ^{3 of the} cut amount to the total cut amount (estimated value). ) Can be calculated. It is assumed that the construction cost per 1 m ^{3 of} the cut amount is input to the control device 10 by an administrator or the like.

FIG. 8 is a diagram showing an example of calculating the area of the installable area based on the land inclination map.
The arrangement planning unit 15 shown in FIG. 2 calculates the area of the installable area 51 (area shown in white) in the land inclination map 50a shown in (b) of FIG. 3 (15s1).
As an example, the arrangement planning unit 15 divides the installable area 51 in the land inclination map 50a into meshes of a predetermined size (for example, a 5 m square mesh) as shown in FIG. Then, the arrangement planning unit 15 calculates the area of the planned installation site 50 according to the number of meshes. When the planned installation site 50 is divided into 400 meshes, the arrangement planning unit 15 calculates the area of the planned installation site 50 by the following equation (3).
5 [m] × 5 [m] × 400 [pieces] = 10000 [m ² ] (3)

FIG. 8 shows a state in which a part of the installable area 51 is divided by a 5 m square mesh. However, the arrangement planning unit 15 can be obtained by dividing the entire installable area 51 by a 5 m square mesh. Can calculate the area of the installable region 51.
Note that the method by which the arrangement planning unit 15 (see FIG. 2) calculates the area of the installable region 51 is not limited to this method.

Furthermore, the arrangement planning unit 15 (see FIG. 2) acquires the specifications of the solar power generation panel 2 (see FIG. 1) to be installed in the planned installation site 50.
(A) of FIG. 9 is an example of a solar power generation panel specification, (b) is an example of the specification of a power conditioner. FIG. 10 is a diagram showing an example of a panel layout diagram.

For example, the photovoltaic panel specification 20a shown in FIG. 9 (a) is registered in the storage unit (not shown) of the control device 10 (see FIG. 1) and used for the model name of the photovoltaic panel 2 to be used. If the administrator inputs (model), the control device 10 can acquire the specifications of the photovoltaic power generation panel 2 installed in the planned installation site 50.
Further, a power conditioner specification (PCS specification) 20b shown as an example in FIG. 9B is registered in the storage unit of the control device 10, and the type (PCS type) of the power conditioner 5 (see FIG. 10) to be used. Is input by the administrator, the control device 10 can acquire the specifications of the power conditioner 5 installed at the planned installation site 50.

  The arrangement planning unit 15 illustrated in FIG. 2 acquires the installation area (area required for installation) of the photovoltaic power generation panel 2 from the photovoltaic power generation panel specification 20a illustrated in FIG. Furthermore, the arrangement planning unit 15 calculates an area necessary for installation of one pedestal 2a from the number of photovoltaic power generation panels 2 attached to one pedestal 2a. Then, the arrangement planning unit 15 calculates the number of mounts 2 a that can be installed at the planned installation site 50.

For example, when the type of the solar power generation panel 2 to be used is “Type A1” shown in FIG. 9A, and four solar power generation panels 2 are attached to one frame 2a, the arrangement planning unit 15 calculates the area per sheet of the photovoltaic power generation panel 2 as 1 m ² (1 m × 1 m), and further calculates the area required for installation of one stand 2 a as 4 m ² (1 m ² × 4). Note that the number of the photovoltaic power generation panels 2 attached to one stand 2a is input to the control device 10 by an administrator or the like.
For example, the area of the installation region 51 at the installation proposed site 50 when a 10000 m ^2, allocation planning unit 15 calculates the number of installable frame 2a installation planned site 50 2500 and (10000m ² / 4m ²⁾ .

2 creates a panel layout diagram 60 (see FIG. 10) (15s2).
The arrangement planning unit 15 creates a panel layout diagram 60 as shown in FIG. 10 by superimposing the gantry 2a (solar power generation panel 2) on the map data indicating the planned installation site 50 (see FIG. 1). Further, the arrangement planning unit 15 outputs the created panel layout diagram 60 to the output unit 17b (see FIG. 1). The map data indicating the planned installation location 50 can be created, for example, by cutting out the planned installation location 50 from the photograph Pic1 of the planned installation location 50 shown in FIG. That is, the arrangement planning unit 15 cuts out the inside of the boundary line Lb from the photograph Pic1 shown in FIG.

Moreover, the arrangement | positioning plan part 15 arrange | positions the power conditioner (PCS) 5 in addition to the photovoltaic power generation panel 2 (base 2a) in preparation of the panel layout drawing 60. FIG. The arrangement planning unit 15 arranges the power conditioner 5 in an area where the photovoltaic power generation panel 2 (mount 2a) is not arranged.
In addition, the type | mold (PCS type | mold) of the power conditioner 5 to be used shall be input into the control apparatus 10 (refer FIG. 1) by the administrator.

  Furthermore, the arrangement planning unit 15 illustrated in FIG. 2 calculates the power generated by the solar power generation panel 2 (15s3). When the type of the photovoltaic power generation panel 2 used is “Type A1” (see FIG. 9A), the rated output of one sheet is 250 W (0.25 kW), so 10,000 sheets (2500 units × 4) of sun In the photovoltaic panel 2, the output is 2500 kW (0.25 kW × 10000 sheets). In this way, the arrangement planning unit 15 calculates the generated power at the solar power generation panel 2 arranged at the planned installation site 50.

The detailed planning unit 16 illustrated in FIG. 2 acquires position information (mounting position) of the photovoltaic power generation panel 2 (mounting frame 2a) in the panel layout diagram 60 (see FIG. 10) created by the arrangement planning unit 15 (16s5). The detailed planning unit 16 acquires the position information of the position where the gantry 2a is arranged on the panel layout diagram 60 as the gantry position.
Further, the detailed plan unit 16 shown in FIG. 2 calculates the cable length based on the position information of the gantry 2a (16s4). The detailed planning unit 16 calculates the cable length from the distance between the photovoltaic power generation panel 2 (mount 2a) and the power conditioner 5 described in the panel layout diagram 60. The detailed planning unit 16 uses the position information of the position where the photovoltaic power generation panel 2 (mount 2a) is arranged and the position information of the position where the power conditioner 5 is arranged, from the position of the photovoltaic power generation panel 2 (mounting station The distance between 2a) and the power conditioner 5 is calculated, and the calculated distance is defined as the cable length. In this way, the detailed plan unit 16 calculates the cable length.

Further, the detailed planning unit 16 shown in FIG. 2 acquires GIS data (ground data) including ground information in the vicinity of the planned placement place 50 via the Internet network 3. For example, the detailed planning unit 16 acquires ground data including ground information such as position information (latitude and longitude), soil quality, and N value of a place (boring point) where the boring survey was performed. Then, the detailed planning unit 16 sets the ground information (N value, soil quality, etc.) of the boring point closest to the planned placement site 50 as the ground information of the planned placement site 50 (installable region 51).
Furthermore, the detailed planning unit 16 shown in FIG. 2 determines that foundation work using concrete or the like is necessary when the ground of the planned placement site 50 is soft, and calculates the cost (construction cost) (16s1). As described above, the detailed planning unit 16 determines the necessity of the foundation work for the planned placement site 50 (installable area 51) based on the ground information. calculate.

FIG. 11 is a diagram showing an example of an arrangement planned place and a boring point.
As shown in an example in FIG. 11, when there are two boring points (B 1, B 2) in the vicinity of the planned placement location 50, the detailed planning unit 16 determines that the boring location B 2 is close to the planned placement location 50. For example, the detailed planning unit 16 calculates the planned location from the location information (latitude and longitude) of a predetermined point within the range of the planned location 50 and the location information (latitude and longitude) of the boring points (B1, B2). Determine a boring point close to 50.

  Then, the detailed planning unit 16 uses the ground information (soil quality, N value) of the boring point close to the planned placement site 50 (in the example shown in FIG. 11, the boring point B2) as the ground information of the planned placement site 50. In the example illustrated in FIG. 11, the detailed planning unit 16 determines that the soil of the planned placement site 50 is viscous soil and the N value is 3.

When the N value in the planned placement site 50 is lower than a predetermined value (for example, when the soil is viscous soil and the N value is 3 or less, or when the soil is sandy soil and the N value is 5 or less ), It is determined that the planned placement site 50 is soft ground and that foundation work is necessary.
Then, when it is determined that the foundation work of the planned placement site 50 is necessary, the detailed planning unit 16 illustrated in FIG. 2 calculates the construction cost required for the foundation work for the installable area 51 (16s1).
If necessary foundation work per 1 m ² construction costs that are configured in advance, detailed planning unit 16, calculated by integrating the construction cost per 1 m ² in the area of the installation region 51 a construction cost of the foundation work (approximate) Is possible. It is assumed that the cost of foundation work per 1 m ² is input in advance to the control device 10 (see FIG. 1) by an administrator or the like.

Further, when the ground of the installable area 51 is soft, the detailed planning unit 16 determines that the length of a pile (not shown) that fixes the gantry 2a (see FIG. 10) needs to be longer than usual. The structure which calculates the expense which generate | occur | produces by using a long pile may be sufficient.
Moreover, when the ground of the installation possible area | region 51 is soft, the structure which determines with the detailed plan part 16 that both foundation work and a long pile are required may be sufficient. In this case, the detailed planning unit 16 is configured to calculate both the construction cost of the foundation work and the cost caused by the use of the long pile. In addition, the price etc. of the pile per unit length shall be input into the control apparatus 10 (refer FIG. 1) by the administrator.

Moreover, the detailed plan part 16 sets the number of the photovoltaic power generation panels 2 which comprise one string. Thereby, the structure (string structure) of how many photovoltaic power generation panels 2 comprise one string is set. That is, the detailed planning unit 16 illustrated in FIG. 2 sets the string configuration of the photovoltaic power generation panel 2 (16s2).
The string is formed by connecting a plurality of photovoltaic power generation panels 2 in series, and the output voltage is determined according to the number of photovoltaic power generation panels 2. For example, the arrangement planning unit 15 sets the number of photovoltaic power generation panels 2 constituting one string based on the rated voltage of the power conditioner 5 to be used. The rated voltage of the inverter 5 can be acquired by the detailed planning unit 16 by referring to the PCS specification 20b shown in FIG. 9B based on the PCS type inputted in advance.

  The detailed planning unit 16 shown in FIG. 2 displays the panel layout diagram 60 three-dimensionally based on the altitude information included in the post-creation terrain data created by the creation planning unit 14, and displays a 3D layout diagram (not shown). The structure to create may be sufficient (16s6).

Moreover, the structure which calculates the material cost required for installation of the solar power generation panel 2 may be sufficient as the detailed plan part 16 shown in FIG. 2 (16s3).
As described above, the arrangement planning unit 15 can calculate the number of mounts 2 a that can be installed in the planned installation site 50. In addition, the number of the photovoltaic power generation panels 2 attached to one stand 2a is input by an administrator or the like. Therefore, the detailed plan unit 16 determines the photovoltaic power generation panel based on the material cost per unit of the gantry 2a, the price per unit of the solar power generation panel 2, and the price per unit of the power conditioner 5. 2 can be calculated as an approximate value.

For example, the material cost per unit of the gantry 2a may be input to the control device 10 by an administrator or the like. Moreover, the price per one photovoltaic power generation panel 2 should just be contained in the photovoltaic power generation panel specification 20a which shows an example in (a) of FIG.
Furthermore, if the price per unit of the power conditioner 5 is included in the power conditioner specification 20b shown in FIG. 9B as an example, the detailed planning unit 16 will install the photovoltaic power generation panel 2. Necessary material cost (approximate value) can be calculated.
The detailed planning unit 16 also calculates the cable length. Therefore, if the price of a cable having a predetermined unit length is input to the control device 10 in advance, the detailed planning unit 16 can calculate the material cost (approximate value) including the price of the cable.

Then, the control device 10 shown in FIG. 2 outputs the construction work cost calculated by the creation planning unit 14 and the generated power calculated by the arrangement planning unit 15 to the output unit 17b. When the output unit 17b includes a monitor, the control device 10 displays the construction work cost and the generated power on the monitor.
Moreover, the control apparatus 10 outputs the construction cost, the cable length, the string configuration, the gantry position, the 3D layout diagram, and the material cost calculated by the detailed planning unit 16 to the output unit 17b. When the output unit 17b includes a monitor, the control apparatus 10 displays the monitor for the construction cost of the foundation work, the cable length, the string configuration, the gantry position, the 3D layout diagram, and the material cost.

  Administrators, etc., output the construction and foundation work costs, generated power, cable length, string configuration, gantry position, 3D layout diagram, and material costs that are output to the output unit 17b as information. You can get it. For example, the administrator or the like may estimate the cost or generated power required for installing the photovoltaic power generation panel 2 (see FIG. 1) on the planned installation site 50 (see FIG. 1) based on the acquired information. it can. Further, the administrator or the like can estimate the generated power (theoretical value) when the photovoltaic power generation panel 2 is installed at the planned installation site 50.

(A) of FIG. 12 is a figure which shows the range which cannot arrange | position a photovoltaic power generation panel by a law, (b) is a figure which shows the panel layout figure based on a law.
For example, when the terrain of the installable area 51 (see FIG. 3B) is the first pattern (Patt1) having the staircase shape shown in FIG. 4A, it is 5 m or more as shown in FIG. In the vicinity of the step portion 51a, the arrangement of the structure is prohibited within 1.5 m. Further, such a stepped portion 51a is required to be formed at an angle of 60 ° or more.
Therefore, the placement of the gantry 2a (see FIG. 10) is prohibited in the range 51b shown in FIG.

Therefore, as shown in FIG. 12B, the arrangement planning unit 15 (see FIG. 2) avoids the range 51b in which the arrangement is prohibited by law or the like and arranges the gantry 2a (see FIG. 10). It is good also as a structure which creates FIG. If the arrangement plan unit 15 is configured in this way, the manager or the like can install the photovoltaic power generation panel 2 (see FIG. 1) to the planned installation site 50 (see FIG. 1) based on the more realistic panel layout diagram 60. ) Can be estimated for the cost and generated power required to install. For example, the arrangement planning unit 15 can obtain a position where the arrangement of the gantry 2a is prohibited by using the stepped portion 51a as a position where the altitude decreases in a stepped manner.
Moreover, the structure which the administrator etc. input into the control apparatus 10 (refer FIG. 1) may be sufficient as the range 51b where arrangement | positioning of the mount frame 2 is prohibited.

As described above, in the land use support system 1 (see FIG. 1) according to the present embodiment, the GIS data processing unit 13 (see FIG. 2) of the control device 10 can be installed in the installation planned area 50 (see FIG. 1). 51 (see (b) of FIG. 3) is set, and further, a creation area 52 (see (b) of FIG. 3) in the installable area 51 is set.
When the creation area 52 is present, the creation planning unit 14 (see FIG. 2) of the control device 10 calculates the total cut amount necessary for the creation work, and further, the creation work is performed based on the calculated total fill amount. Calculate the construction cost.

Moreover, the arrangement | planning plan part 15 (refer FIG. 2) of the control apparatus 10 produces the panel layout figure 60 (refer FIG. 10) which shows arrangement | positioning of the mount frame 2a (photovoltaic power generation panel 2), and has arrange | positioned the photovoltaic power generation panel 2 arranged. Calculate the power generated by
Further, the detailed planning unit 16 (see FIG. 2) of the control device 10 calculates the construction cost of the foundation work, the cable length, the string configuration, the gantry position, the 3D layout diagram, and the material cost.

  The managers of the land use support system 1 (see FIG. 1) are output from the output unit 17b (see FIG. 2), the construction cost of the construction work and foundation work, generated power, cable length, string configuration, gantry position, 3D Referring to the layout diagram and material costs, expenditures (installation costs, material costs, etc. for construction work and foundation work) and income when installing the photovoltaic power generation panel 2 in the planned installation site 50 (see FIG. 1) Power generation, etc.) can be estimated. In addition, since the work necessary for the estimation is virtually performed by the control device 10 (see FIG. 2), the actual action of the manager or the like such as on-site inspection is unnecessary. Therefore, an administrator or the like can make a quick estimate at a low cost.

In addition, the arrangement planning unit 15 (see FIG. 2) of the present embodiment calculates the generated power in consideration of the sunshine state (direct solar radiation amount and time variation of the shadow) at the arrangement planned site 50 (see FIG. 1). It may be a configuration. For example, the arrangement planning unit 15 calculates (estimates) the time change of the shadow of the planned placement site 50 from the altitude around the planned placement site 50 and date and time information (such as the sun's south and middle altitudes), and the time of the shadow The configuration may be such that the generated power is calculated according to the change.
As an example, when 20% of the installable area 51 (see FIG. 3B) is shaded on average, the arrangement planning unit 15 calculates the number of photovoltaic power generation panels 2 (see FIG. 1) and the like. The configuration may be such that 80% of the generated power is output to the output unit 17b (see FIG. 2) as generated power.
If the arrangement planning unit 15 has such a configuration, an administrator or the like can estimate the generated power that is closer to reality. And the manager etc. can estimate profitability (difference between income and expenditure) more accurately.

In addition, this invention is not limited to an above-described Example. For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described.
Also, a part of the configuration of a certain embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of a certain embodiment.

For example, the creation planning unit 14 shown in FIG. 2 sets the intermediate height of the height difference between the convex portion Hp (see FIG. 5B) and the concave portion Lp (see FIG. 5B) as a reference after creation. The altitude of the line L1 is configured. For example, the flatness requested by the administrator or the like is input to the control device 10, and the creation planning unit 14 sets the altitude of the post-creation reference line L1 according to the inputted flatness. There may be.
For example, when the manager or the like does not require much flatness (when some unevenness is allowed), the creation planning unit 14 raises the reference line L1 after creation (from the middle of the height difference between the convex portion Hp and the concave portion Lp). Set to a higher position). As a result, the total cut amount is reduced, so that the construction work cost can be kept low.
As described above, the creation planning unit 14 may be configured to set the creation work so as to reflect the demands of the manager or the like.

  In addition, an arrangement planning unit 15 (see FIG. 2) that obtains information on various weather conditions such as the ratio of clear and cloudy in the planned arrangement site 50 (see FIG. 1), precipitation, and snowfall, and calculates generated power. It may be. Information regarding such weather conditions may be obtained by the control device 10 via the Internet network 3 (see FIG. 1).

In addition, the present invention is not limited to the above-described embodiments, and appropriate design changes can be made without departing from the spirit of the invention.
For example, in this embodiment, the control device 10 (see FIG. 1) of the land use support system 1 effectively arranges the photovoltaic power generation panel 2 (see FIG. 1) on the planned installation site 50 (see FIG. 1). It is configured to estimate the construction cost and placement.
Without being limited to this configuration, for example, the land use support system 1 of the present embodiment can be used for estimating construction costs and arrangement for effectively cultivating agricultural crops.
In this case, it is preferable that the control device 10 of the land use support system 1 is configured to estimate the construction cost and arrangement using weather information such as sunshine hours, temperature, and humidity as main parameters.

  Furthermore, the land use support system 1 of the present embodiment can be widely used for land used for other purposes such as arrangement of wind power generation facilities and residential land creation.

DESCRIPTION OF SYMBOLS 1 Land use support system 2 Solar power generation panel 3 Internet network 10 Control apparatus 11 Control part 12 Interface part 13 GIS data processing part (data processing part)
14 Creation Planning Department 15 Placement Planning Department 16 Detailed Planning Department 50 Planned Installation Site (Target Land)
51 Installation area 52 Creation area

In order to solve the above problems, the present invention is a land use support system that supports the promotion of land use planning by setting an effective arrangement of photovoltaic power generation panels on the planned installation site , Geographic data including position information and elevation information is obtained via the Internet network, and based on the undulation state estimated and estimated undulation state of the planned installation site based on the position information and the elevation information, The construction area where construction work is necessary is set as the planned installation site, and the intermediate height between the highest part of the adjacent convex part and the lowest part of the concave part of the planned installation site is set as a reference line after construction. , A land provided with a control device capable of approximating the cut amount, which is the volume of the convex portion at the elevation of the reference line after creation, with a collection of cubes each having a predetermined size and calculating the construction cost of the creation work Usage System, and, and land use support method control device executes.

Claims (9)

Obtain geographical data including the location information and elevation information of the target land via the Internet network,
Estimating the undulation state of the target land based on the position information and the elevation information, and based on the estimated undulation state, set the creation area that needs to be constructed in the target land,
Furthermore, the land utilization support system characterized by including the control apparatus which can calculate the construction cost of the said construction work. The controller is
An interface unit connectable to the Internet network;
A data processing unit that estimates the undulation state based on the geographic data acquired through the interface unit, and sets the creation area in the target land based on the estimated undulation state;
A creation planning department for calculating the construction cost of the creation work;
The land use support system according to claim 1, further comprising a control unit that controls the interface unit, the data processing unit, and the creation planning unit. The data processing unit estimates the inclination of the target land based on the position information and the elevation information, and sets an area where the inclination is smaller than a predetermined threshold in the target land as an area where a photovoltaic power generation panel can be installed. Set,
The land use support according to claim 2, wherein the undulation state of the settable area is estimated, and the creation area is set in the installable area based on the estimated undulation state. system. The control device has a detailed planning unit,
The detailed planning section
Based on the ground data that can be acquired from the Internet network, the necessity of foundation work for the installable area is determined, and when it is determined that the foundation work is necessary, the construction cost of the foundation work is calculated. The land use support system according to claim 3. The control device has an arrangement planning unit,
The arrangement planning unit
The panel layout diagram showing the arrangement of the photovoltaic power generation panel in the installable region is created, and the generated power by the photovoltaic power generation panel is further calculated. Land use support system. The control device of the land use support system
Obtain geographical data including location information and altitude information of the target land from the Internet,
Estimating the undulation state of the target land based on the location information and the elevation information,
Based on the estimated undulation state, determine the necessity of construction work for the target land,
When it is determined that the creation work is necessary, a creation area for the creation work is set in the target land,
A land use support method characterized by calculating a construction cost of the creation work. The control device is
Estimating the slope of the target land based on the position information and the elevation information,
A region where the slope is smaller than a predetermined threshold in the target land is set as a solar power panel installable region,
Estimating the undulation state of the settable installation area,
The land use support method according to claim 6, wherein the creation area is set in the installable area based on the estimated undulation state. The control device is
Obtain ground data from the Internet network,
Based on the ground data, determine the necessity of foundation work for the installable area,
The land use support method according to claim 7, wherein when it is determined that the foundation work is necessary, a construction cost of the foundation work is calculated. The control device is
Set the arrangement of the photovoltaic power generation panel in the installable area,
The land use support method according to claim 7 or 8, wherein power generated by the solar power generation panel is calculated.