JPH07121596A - Wall surface panel arranging device - Google Patents

Abstract

PURPOSE:To provide a wall surface panel arranging device capable of efficiently perform the allotment of a wall panel and a roof profile panel which comprise a wall body when a prefabricated house by a panel construction method is designed. CONSTITUTION:This device is constituted in such a way that a wall panel storage means 30 and a roof profile panel storage means 31 which store the vertical shape of the wall panel P and that of the roof profile panel Y. respectively, a wall panel selection means 41 and a roof profile selection means 42 which select panels from the panel storage means 31, 32, respectively, and a horizontal net line segment generating means 40 which generates a horizontal wall panel net line segment to divide a panel arranging area horizontally with pitch multiplying unit length by a roof slope are provided, and the wall panel P provided with an upper side line segment that coincides with one of line segments in a horizontal wall panel net group and with size as large as possible is selected, and also, the roof profile panel Y can be selected so as to be just assembled in a selected wall panel P.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wall panel allocating device for allocating panels constituting wall surfaces of a prefabricated house by a panel construction method, and more particularly to a shed having slope sides along a roof slope. The present invention relates to an allocating device for allocating a roofing panel arranged in a part.

[0002]

2. Description of the Related Art As one method for constructing a prefabricated house, a panel construction method is known in which floors, walls, roofs, etc. are constructed of panels. In this method, floor panels, wall panels, roof panels, etc., which are manufactured by pasting a face material on at least one surface of a frame body that forms a frame of a core material in a factory or the like, are assembled at a construction site. Build a house by going.

FIG. 26 shows how the wall and roof in such a house are housed. As shown in the figure, the wall 1 has an upper side that can contact the back surface of the roof 2, and has a rectangular wall panel P and a substantially triangular or trapezoidal roofing panel Y. , And an adjusting material G provided as needed. As for the wall panel P, a normal wall panel (general rectangular panel) 10
In addition, various panels such as the small wall panel 11 are prepared according to the purpose of use. The dimensions such as width and height of the various panels P and Y are determined based on one basic length (module) in construction.

For example, in the case of the wall panel P, 1 module length, 1/2 module length, 1/4 module length, 1.5 module length, 2 module length, etc.
A panel having a width or height that is an integral multiple of the module length, which is a fraction of the module length, is prepared. In the case of the roofing panel Y, for the roof slope of 1/1 shown in FIG. 27, for example, the unit length (a) is used.
The maximum width is four times the length of each of the roof slopes of 2/3, 1/2, 1/3 and 1/12 shown in FIGS. The maximum width is eight times the length a.

For any roof slope, in addition to the basic maximum width of the roofing panel Y described above, an integral multiple of the unit length a (or twice the length 2a). A substantially triangular or trapezoidal panel having a bottom line segment of the length is prepared. That is, when the roof slope is 1/2, as an example, the eight pieces Y1, Y2, Y3, Y in FIG.
4, a maximum roofing panel consisting of Y5, Y6, Y7, and Y8, a triangular panel consisting of Y1 to Y4, a trapezoidal panel consisting of Y5 to Y8, and a trapezoidal panel consisting of Y3 to Y6. , 4 pieces when the minimum length is 2a)
Panels are prepared by appropriately combining. The same applies to other roof slope roof panels.
It should be noted that a 1/1 roof slope is a combination of 4 pieces (or 2 pieces when the minimum length is 2a).

By the way, in recent years, in designing houses and the like as well as various designs, in order to save labor, CAD
(Computer-aided design) system may be used. In a general CAD system, shape data, graphic data, and other data of members as design elements are stored in advance as a database, and these data are called at the time of designing to arrange each member on a drawing. By doing so, drafting is made.

Therefore, in the conventional CAD system for a house, data concerning walls, floors, ceilings, etc. is read out by deciding the floor plan, and data concerning roofs is read by deciding roof shapes such as dormitories and gables. By determining the members such as windows and doors and their positions, the data of the windows and doors are read, and the corresponding members are arranged at the corresponding positions on the display. As a result, the shape of the house is shown on the display as a figure (three-view or perspective view) and is output as a design drawing.

[0008]

In the case of the prefabricated house by the above-mentioned panel construction method, the floor, the wall and the roof must be provided with panels of which shapes and dimensions are determined in advance. Therefore, when designing with a CAD system, data of floor panels of various sizes are stored for the floor, and wall panels and small wall panels of various shapes and sizes for the wall. Data for roofing panels, etc. is stored, and for roofs, data for roof panels of various sizes is stored, and a panel with an appropriate shape and size is selected from those data. Therefore, it is necessary to allocate to appropriate places.

However, in the design in the conventional CAD system in which the panels are mechanically allocated in order from the end, the following problems may occur. That is, floors, walls, and roofs are determined according to the design requirements of the supplier, and are not necessarily designed according to the shape and size of each panel, so there are gaps between the panels and large panels are placed. It is very likely that inefficient panel allocation will occur, such as a plurality of small panels being arranged where possible.

Further, in the case of constructing a house with the inefficient panel allocation as described above,
There is also a drawback that it is necessary to manufacture a custom-sized panel for filling the gap or to manufacture a large number of small panels having poor production efficiency as compared with a large panel, which leads to a reduction in panel productivity. . In addition, at the construction site, by using small panels or panels that fill the gaps, the work of joining the panels to each other increases, and the time and effort to manufacture the member (adjustment material) for filling the slight gaps between the panels increase. There was also a drawback.

Therefore, if the panel is not properly allocated, not only the productivity of the house is reduced but also the construction cost is increased. In particular, when the upper half of the wall body 1 shown in FIG. 26 is designed to support the roof 2 as a part of the roof structure, the upper half of the wall 1 is anomalous along the roof slope. Since it has such a shape, it is extremely difficult to combine the rectangular wall panel P and the substantially triangular or trapezoidal roofing panel Y and automatically and efficiently allocate them without creating a gap as much as possible. Met.

The present invention has been made to solve the above problems, and when designing a prefabricated house by the panel construction method, it is possible to efficiently perform the allocation of the wall panel and the roofing panel constituting the wall body. The object is to provide a wall panel allocating device that can be used if possible.

[0013]

In order to achieve the above-mentioned object, the invention according to claim 1 is a wall body having a slope side along the roof slope at its upper edge, and the elevation shape is rectangular. It is a wall panel allocating device that is used when designing a combination of a wall panel that has a shape, a roof panel that has a substantially triangular or trapezoidal elevation, and a width dimension that is an integral multiple of the unit length. A wall panel storage means for storing in advance the elevation shapes of the plurality of wall panels; a roofing panel storage means for storing the elevation shapes of the plurality of roofing panels in advance; Create a plurality of horizontal wall panel net line segments that can be horizontally divided at the pitch obtained by multiplying the unit length by the roof slope for the entire panel allocation area corresponding to some or all of the elevation shapes. Horizontal net line segment creation means,
A horizontal wall panel net that is lower than the inclined side line segment of the panel allocation area corresponding to a part or all of the inclined side and is as high as possible in the created horizontal wall panel net line segment group. An elevation wall panel having an upper side line segment that coincides with the line segment is selectable from the above wall panel storage means, and an upper side line of the elevation face shape of the selected wall panel. Minutes, and a roofing panel selecting means capable of selecting a vertical roofing panel that matches the shape between the inclined side line segment from the roofing panel storage means. .

The invention described in claim 2 is the same as claim 1
In the wall surface panel allocating device according to the item (1), it is provided with an adjusting material storage unit that stores the elevation shapes of a plurality of adjusting materials in advance.
In the case where the wall panel storage means does not store an elevation wall panel having an upper side line segment that can match any line segment of the horizontal wall panel net line segment group, the wall is stored. The panel selection means is below the inclined side line segment,
In addition, in the horizontal wall panel net line segment as high as possible in the horizontal wall panel net line segment formed, the elevation shape of the adjustment material read from the adjustment material storage means and the wall panel storage means The wall panel storage means is selected from the wall panel storage means such that the upper side line segment of the shape obtained by combining the read wall panel elevation shape is matched, and the roofing panel selection means is
The largest vertical roofing panel that can be assigned between the upper side line segment and the inclined side line segment of the combination shape of the adjusting material and the wall panel is selected from the roofing panel storage means. It is characterized by

Further, the invention according to claim 3 is the wall surface panel allocating device according to claim 1 or 2, wherein the entire panel allocating area can be vertically divided at a pitch of the unit length. Vertical net line segment creating means for creating a plurality of vertical wall panel net line segments, and a vertical wall panel net line that passes through the highest point of the entire panel allocation area of the created vertical wall panel net line segments The vertical line segment of the vertical shape of the largest roofing panel in the group of roofing panels having the corresponding roof slope stored in the roofing panel storage means, and the vertical line segment With the upper end aligned with the highest point, the wall panel essential line segment having the above unit length along the horizontal wall panel net line segment that passes through the starting point with the lower end of the vertical line segment as the starting point is on the eaves side. Create towards In addition, the next wall panel essential line segment having the above unit length along the horizontal wall panel net line segment passing through the starting point with a point one step lower than the end point of the wall panel essential line segment as a new starting point is on the eaves side. A wall for creating a stepwise group of wall panel essential line segments by repeating the further creation until the end of the newly created wall panel essential line segment reaches the side edge of the entire panel allocation area. If the panel essential line segment creating means and the lowest wall panel essential line segment of the created group of wall panel essential line segments are higher than the bottom line segment of the entire panel allocation area, the panel allocation is performed. First wall area setting means for making a lower half part of the entire area into a rectangular wall area that can be filled by allocating one or more wall panels in an elevational shape, and the entire panel allocation area A house-cutting area setting means for setting an area other than the wall area, which has been set, by a vertical surface shape of at least one house-cutting panel, and further comprising: The cutting area setting means sets the entire panel allocation area as a roof cutting area when the wall panel essential line segment located at the lowest position is lower than the bottom line segment of the entire panel allocation area. It is characterized by

Further, the invention according to claim 4 is the wall surface panel allocating device according to claim 3, wherein the roof cutting area is sequentially moved from the eaves side to the ridge side in the roof cutting area, First allocation yapping area setting means for setting an allocation yapping area capable of allocating the elevation shape of the yaft panel selected from the yaft panel storage means by the yaft panel selection means, 1 or 2 which is selected from the wall panel storage means by the wall panel selection means without allocating an area other than the set up layout roofing area of the roofing area, without allocating the elevation shape of the roofing panel And a second wall region setting means that is a wall region that can be filled by allocating two or more wall panels in an upright shape.

The invention described in claim 5 is the same as claim 3
In the wall surface panel allocating device according to the item (1), the roof cutting panel storage means stores the roof cutting panel with the width dimension in the elevation shape of the largest roof cutting panel among the roof cutting panels having the corresponding roof slope. Mixing area setting means capable of dividing the area into a plurality of mixed areas, and the upper half of each mixed area that is set, an allocation roofing area capable of allocating the elevation shape of the maximum roofing panel The second allocation roof cutting area setting means and the area excluding the allocation roof cutting area set in the same mixed area without allocating the elevation shape of the roof cutting panel to the wall panel selection means. And a third wall area setting means which is a wall area that can be filled by allocating one or more wall panels selected from the wall panel storage means according to the elevation shape of the wall panel. And it features.

Further, the invention according to claim 6 is the wall panel allocating device according to claim 4 or 5, wherein the roof cutting panel storage means is provided with an inclined side in the allocation target portion of the allocation roof cutting area. If the roof-shaped roof panel with the slope corresponding to the slope is not stored,
Or, when the sloped side portion of the elevation shape of the roofing panel selected from the roofing panel storage means by the roofing panel selection means does not fit within the allocation target portion,
It is characterized in that it is provided with a field framework area setting means for setting the allocation target area as a field framework area.

Further, the invention according to claim 7 is the wall panel allocating device according to claim 4 or 5,
If the vertical line segment of the vertical shape of the roofing panel selected from the roofing panel storage means by the roofing panel selection means protrudes from the allocation target portion of the allocation roofing area, the protrusion It is characterized in that it comprises an on-site processing area setting means for setting the open portion as an on-site processing area.

[0020]

According to the wall surface panel allocating apparatus of the present invention, the horizontal net line segment creating means creates horizontal wall panel net line groups at a pitch obtained by multiplying the unit length by the roof slope. In a roofing panel whose width in the elevation shape is an integral multiple of the unit length, even if the elevation shapes are different, the bottom line segment in the elevation shape is always in the above horizontal wall panel net line segment group. Matches any line segment of.

Therefore, when a wall panel is selected from the wall panel storage means by the wall panel selection means, the upper side line segment in the elevation shape of the wall panel coincides with any line segment of the horizontal wall panel net line segment group. If a wall panel having an upright surface shape is selected, the roof panel and the wall panel can be allocated without generating a gap therebetween. Therefore, it is not necessary to provide a custom-sized panel or an area for arranging the adjusting material.

In particular, by setting the horizontal wall panel net line segment whose upper side line segment in the elevation shape of the wall panel is the same as high as possible, it is possible to select the largest possible roofing panel and maximize the size. It allows the selection of wall panels and prevents inadvertently allocating small panels.

Further, when the wall panel storage means does not store a wall panel having an elevation shape such that the upper line segment matches the horizontal wall panel net line segment, the upper horizontal wall panel net line segment is as high as possible. In addition, it is designed to select a wall panel whose upper side line shape that is a combination of the elevation shape of the adjustment material and the elevation shape of the wall panel matches, so that the size of the roof panel as large as possible It is possible to select as large a wall panel as possible while making a selection, and it is possible to reduce the number of adjustment materials to be allocated between the wall panel and the roofing panel as much as possible, and without providing an area to allocate a custom-sized panel. I'm done.

By the first wall area setting means, the lower half part of the entire panel allocation area is set as a wall area for allocating only the wall panel, and by the roof cutting area setting means, at least one area except the wall area is set. By making the roofing panel to be the roofing area to be allocated, it is possible to make the roofing area in the entire panel allocation area, that is, the area for considering the combination of the roofing panel and the wall panel as small as possible, Therefore, even if the wall panel should be originally allocated, carelessly allocating the combination of the roof panel and the wall panel is prevented.

By the first allocation shop cutting area setting means,
From the eaves side to the ridge side of the roof cutting area, allocation roof cutting areas capable of allocating the elevation shape of the roof cutting panel are sequentially set in the roof cutting area, and second wall area setting means. By doing so, the roof cutting area excluding the allocation roof cutting area is set as a wall area that can be filled by allocating the elevation shape of the wall panel. Panels can be assigned.
In particular, it is effective for allocating the roofing panel to the roofing area when the roof is located above the girder material of the house.

The mixed area setting means divides the roofing area into a plurality of mixed areas according to the width dimension of the largest vertical roof panel shape, and the second layout roofing area setting means divides each of the mixed areas. The upper half part of the mixing area is defined as the allocation roofing area for allocating the maximum surface shape of the roofing panel, and the mixing area excluding the allocation roofing area is defined as a wall by the third wall area setting means. Since the wall area can be filled by allocating the vertical shape of the panel, the roofing panel can be efficiently allocated in the roofing area. In particular, it is effective for allocating the roofing panel to the roofing area when the roof is located below the girder material of the house.

When there is no roofing panel corresponding to the allocation target portion of the allocation roofing area, the site allocation area setting means sets the allocation target area to the field assembly area. This makes it possible to deal with the case of designing a wall body that supports a roof with an irregular slope or shape.

In the case where the vertical line segment portion of the elevation shape of the roofing panel corresponding to the allocation target portion of the allocation roofing area protrudes from the allocation target portion, the projecting portion is set by the on-site machining area setting means. By designating as the on-site processing area, it is possible to deal with the case of designing a wall body in which the roofing panels cannot be assigned exactly without excess or deficiency.

[0029]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the wall panel allocating device according to the present invention will be described below with reference to the drawings. FIG. 1 shows an example of the basic configuration of a wall panel allocating device according to the present invention. As shown in the figure, this wall surface panel allocating device stores in advance the wall panel storage means 30 in which the elevation shapes of a plurality of wall panels are stored in advance and the elevation shapes of a plurality of roofing panels. Horizontal net line segment creation for creating a plurality of horizontal wall panel net line segments for the whole roof panel storage means 31 and the panel allocation region corresponding to the elevation shape of the wall body 1 as shown in FIG. A means 40, a wall panel selecting means 41 capable of selecting a wall panel having an elevation shape suitable for allocation from the wall panel storage means 30 using the created horizontal wall panel net line segment group as an index, and an elevation surface suitable for allocation. There is provided a roofing panel selecting means 42 capable of selecting a shaped roofing panel from the roofing panel storage means 31. The wall surface panel allocating device also includes an adjusting material storage unit 32 that stores the elevation shapes of a plurality of adjusting materials in advance.

The horizontal net line segment creating means 40 uses the horizontal wall panel net line segment group to horizontally set the panel allocation area at a pitch obtained by multiplying the unit length a shown in FIGS. 27 to 31 by the roof slope. It is designed to be split. In addition, the roofing panel Y having a substantially triangular shape or a trapezoidal shape is shown in FIG.
Component pieces Y1, Y2, Y3, Y4, Y as shown in FIG.
It is composed of a combination of 5, Y6, Y7, and Y8, and has a width (length of bottom line segment) that is an integral multiple of the unit length a.
Therefore, the roofing panel Y can have various shapes depending on the combination, but regardless of the shape, when the roofing panel Y is allocated to the panel allocation area, the bottom line segment of the roofing panel Y and the horizontal wall are formed. Any one of the panel net line segment groups is made to match.

Therefore, the vertical shape of the roofing panel Y and the vertical shape of the wall panel P are arranged vertically, and the roofing panel Y is formed.
In order to fill a part or the whole of the panel allocation area without creating a gap between the wall panel P and the wall panel P, the following wall panel P may be selected. That is, the wall panel P
When the bottom line (bottom side) of the elevation shape of the wall panel P is matched with the bottom line segment of the allocation target part, the top line segment of the elevation shape of the wall panel P is among the horizontal wall panel net line segment groups. It is a panel that matches any of the line segments. Moreover, the wall panel P matches the upper horizontal wall panel net line segment as much as possible in order to reduce the number of panels allocated to the allocation target portion as much as possible, that is, to allocate the largest possible panel. A panel having an upper side line segment is preferable. The wall panel selecting means 41 is adapted to select such a wall panel P.

Further, when the wall panel P satisfying the above-mentioned conditions is not stored in the wall panel storage means 30, the wall panel selection means 41 performs the selection as follows. There is. That is, the elevation shape of an appropriate one of the adjustment material groups stored in the adjustment material storage means 32 and the elevation shape of an appropriate one of the wall panel groups stored in the wall panel storage means 30. A combination is selected such that the upper side line segment in the shape of being arranged in the vertical direction matches the uppermost line segment of the horizontal wall panel net line segment group, and the wall panel P at that time is selected. Further, the adjusting materials G combined at that time are selected from the adjusting material storing means 32 by the adjusting material selecting means omitted in FIG.

As described above, the wall panel P and the adjusting material G
When the selection candidates of the above are decided, the above-mentioned roofing panel selecting means 42
Selects a roofing panel Y having an upright shape that can be exactly accommodated in the allocation target portion excluding the allocation candidate wall panel P and the adjusting material G.

Specific examples in which the wall surface panel allocating device configured as described above is applied to a CAD system configured by a computer system will be described below, and the features thereof will be made clearer. In Figure 2, the C
An example of the basic configuration of a wall panel allocating device that operates as part of an AD system is shown. As shown in the figure,
This wall panel allocating device is provided with the wall panel storage means 3 described above.
0, the roofing panel storage means 31, the adjusting material storage means 32, the horizontal net line segment creating means 40, the wall panel selecting means 41, the roofing panel selecting means 42, and an adjusting material selecting means not shown. , A vertical net line segment creating means 43, a wall panel essential line segment creating means 44, a roofing area setting means 45, and a first wall area setting means 46.

The vertical net line segment creating means 43 creates a plurality of vertical wall panel net line segments for the entire panel allocation area, and creates a panel allocation area by the vertical wall panel net line group created. It is designed to be split vertically. The arrangement pitch of the vertical wall panel net line segment is the unit length a, and an integral multiple of the pitch corresponds to the width dimension of the roof panel Y or the wall panel P in the vertical shape.

The wall panel essential line segment creating means 44, as shown in FIGS. 13 and 14, is a horizontal wall panel net line created by the horizontal net line segment creating means 40 and the vertical net line segment creating means 43, respectively. Based on the line segment 100 and the vertical wall panel net line segment 101.
The wall panel required line segment 110 is created on the wall. The wall panel essential line segment 110 serves as a criterion for determining whether or not the entire panel allocation area 200 can be divided into two areas, a wall area and a roofing area, when the allocation processing of the roofing panel Y or the wall panel P is started. It will be. Specific details of the creation processing of the wall panel essential line segment 110 will be described later.

Here, as shown in FIG. 15, the wall region 21
0 is a rectangular area that corresponds to the lower half of the panel allocation area 200 and can be filled by allocating only the wall panel P in an upright shape, and its setting is the first wall area setting means. 46. In addition, the house cutting area 2
20 corresponds to the upper half of the panel allocating area 200, that is, the panel allocating area 200 excluding the wall area 210, and only the roofing panel Y or the roofing panel Y and the wall panel P (including the adjusting material G). , And the area can be filled with an upright shape formed by a combination of the above, and the setting thereof is made by the roofing area setting means 45. Each area 220, 210 by the both setting means 45, 46
The specific setting process contents of will be described later.

The wall panel P is a general rectangular panel 1.
0 and a small wall panel 11, which are not particularly shown in FIGS. 1 and 2, the wall panel storage means 30 includes a general rectangular panel storage means for storing the general rectangular panel 10 and a small wall panel. A small wall panel storage means for storing the data is provided for the storage unit 11. Regarding the wall panel selection means 41, the general rectangular panel 10 and the small wall panel 11 are included.
Independent selection means may be provided for each, or the same selection means may serve as both.
The wall area 210 set by the first wall area setting means 46 is an allocation area of the small wall panel 11, and hence this area is hereinafter referred to as an internal small wall area 210.

Further, the wall panel allocating device comprises the first allocating roof cutting area setting means 47 and the second wall area setting means 4.
It also has 8. First allocation stapling area setting means 47
17, as shown in FIG.
The roof cutting area 220 set by the above is further allocated to the layout roof cutting area (allocation area of only the roof cutting panel Y) 221.
When dividing the small wall panel 11 excluding the roofing panel Y into a wall area to be allocated, the allocation roofing area 221 is set. The second wall area setting means 48 sets the allocation area of the divided small wall panel 11, that is, the internal small wall area 225. Specific contents of the setting processing of the areas 221 and 225 by the both setting means 47 and 48 will be described later.

Incidentally, the first allocation roofing area setting means 4
7 and the second wall area setting means 48 are provided for the girder material of the house (for the roof of the first floor part, the girder material of the first floor, and for the roofs of the second floor and above, the roof is provided). The setting process is effectively performed when panel allocation is performed for the so-called roofing area 220 in a so-called girder roof in which the roof is located above the girder on the floor.

The wall surface panel allocating device also includes a mixing area setting means 49, a second allocation roofing area setting means 50 and a third wall area setting means 51. In each of the setting means 49, 50, 51, the roof cutting area 220 is a so-called under-girder roof (a roof located below the girder material of the house).
It is supposed to be effective when it is against.

As shown in FIG. 23, the mixed area setting means 49 vertically divides the roof area 220 into a plurality of mixed areas 230. Width b of each mixing area 230
Is the same as the width dimension of the largest roofing panel in the roofing panel group having the corresponding roof slope stored in the roofing panel storage means 31 in the vertical shape. For example, in the case of the roofing panel Y shown in FIG. 27, the width dimension b is four times as long as the unit length a, and in the case of the roofing panel Y shown in FIGS. 28 to 31, respectively. In each case, the width dimension b is eight times as long as the unit length a.

The second allocation roofing area setting means 50
As shown in FIG. 23, the mixed area 230 is further divided into an allocation roofing area (allocation area of only the roofing panel Y) 23.
1 and a wall area 235 for allocating the wall panel P excluding the roofing panel Y, the allocation roofing area 231
Is to be set. Third wall area setting means 51
Is for setting the divided wall area 235. The wall area 235 may be an allocation rectangular area to which the general rectangular panel 10 is allocated or an internal small wall area to which the small wall panel 11 is allocated depending on the height dimension thereof. Specific setting processing contents of the areas 231 and 235 by the setting means 50 and 51 will be described later.

The wall surface panel allocating device also includes on-site framing area setting means 52 and on-site machining area setting means 53. The on-site framing area setting means 52 stores the allocation roofing areas 221 and 231 in the roofing panel storage means 31.
In the case where the roof-shaped roofing panel Y having a slope that matches the slope of the inclined side in the allocation target portion is not stored,
Panels are not assigned by designating the part to be allocated to the field framework area. The same applies to the case where the inclined side portion of the vertical shape of the roofing panel Y selected by the roofing panel selecting means 42 does not fit within the allocation target portion. It should be noted that on-site framework refers to the production of matching panels at a construction site.

In the field framing area setting means 52, the vertical line segment of the vertical shape of the roofing panel Y selected by the roofing panel selecting means 42 corresponds to the allocation roofing areas 221 and 231. When protruding from the allocation target part, as shown in FIG. 25, the protruding part of the allocated roofing panel Y is designated as the on-site processing area 240 for cutting at the site. In addition, the roof panel Y can be cut only in the vertical direction.

FIG. 3 shows an example of the basic configuration of a CAD system which is an application of the wall panel allocating device.
As shown in the figure, this CAD system is, as is well known, a central processing unit, an arithmetic processing unit (computer) 3 including a memory such as RAM and ROM as an internal storage unit, a hard disk and a magneto-optical disk. And the like, and the display device 5 such as a display.
An input device 6 including a keyboard, a pointing device (coordinate position input device) 7 including a mouse, a tablet, a digitizer, and the like, and an output device 8 including a printer, a plotter, and the like.

The wall panel storage means 30, the roof panel storage means 31, and the adjustment material storage means 32 are provided in the auxiliary storage device 4. Further, in the auxiliary storage device 4,
Internal code No. of various members for building a house , Graphic data, shape data, ordering product code N
o. The unit prices of various members are stored as a database, and the data designed on the CAD system is stored. Further, the auxiliary storage device 4 is a CAD
It also stores the panel layout data designed by the system.

In the arithmetic processing unit 3, the horizontal net line segment creating means 40, the wall panel selecting means 41, the roofing panel selecting means 42, the vertical net line segment creating means 43,
Wall panel essential line segment creating means 44, roofing area setting means 4
5, first wall area setting means 46, first allocation roofing area setting means 47, second wall area setting means 48, mixed area setting means 49, second allocation roofing area setting means 50,
Third wall area setting means 51, field framework area setting means 52
Also, the on-site processing area setting means 53 is provided.

Next, an example of the processing contents of the wall surface panel allocating device in the CAD system will be specifically described. FIG. 4 shows an example of the flow of the wall panel allocation procedure. First, when starting the wall panel allocation process, the panel allocation area 20 is set by the CAD system.
The shape of 0 is determined, and the shape is stored in the auxiliary storage device 4. At this time, the attribute of the wall body that is the panel allocation target is whether it is the outer wall that faces the outside or the inner wall that is provided indoors, and whether the wall body wins or loses with other wall bodies. Ancillary items such as are input and stored.

Then, a horizontal wall panel net line segment 100 and a vertical wall panel net line segment 101 are created in the entire panel allocation area 200 (step S10). Subsequently, the roof-cutting area 220 and the internal small wall area 210 are set (step S20). Next, the roofing area 220 is divided into an allocation roofing area 221 and an inner small wall area 225 in the case of a girder roof, and an allocation roofing area 231 and a wall area 235 in the case of a girder roof. (Step S
30). Then, the allocation roofing areas 221 and 23
1 and the roof panel Y corresponding to the wall regions 225 and 235
The wall panel P is allocated (step S40), and the allocation process ends.

FIG. 5 shows a specific example of the procedure for creating the wall panel net line segment in step S10. As shown in the figure, first, the panel allocation area 200
Is horizontally divided by the vertical wall panel net line segment 101 (step S100), and vertically by the horizontal wall panel net line segment 100 (step S110). At this time, if the edge of the panel allocation area 200 is deviated from the core by the size d due to winning or losing (see FIG. 11 (in case of losing) and FIG. 12 (in case of winning)) (step S12)
0) After adjusting so that the end line segment of the vertical wall panel net line segment 101 coincides with the core (step S130), the process proceeds to the setting process of the roofing area in step S20.

FIG. 6 shows a specific example of the procedure for setting the roof-cut area in step S20. As shown in the figure, first, the wall panel essential line segment 110 is created (step S200). The creation process is as follows (see FIG. 13). That is, from the point A along the vertical wall panel net line segment 101a that passes through the highest point A in the panel allocation area 200 (in this example, the point corresponding to the ridge), the maximum elevation shape of the roofing panel Y (hatched). A point B which is lowered by the length of the vertical line segment 111 in the indicated portion) is obtained, and a horizontal line segment 110a of one pitch length passing through the point B is created, and both sides (one-way flow) are reached until the side edge of the panel allocation area 200 is reached. In the case of a roof, only one horizontal wall panel essential line segment 110 of 1 pitch length, which descends stepwise step by step toward the eaves on one side, is sequentially created. When the panel allocation area 200 is not symmetrical (see FIG. 14), when the wall panel essential line segment 110 reaches the side edge on one of the eaves sides, the wall panel on the other eaves side is essential. The creation of the line segment 110 is also terminated and the line segment 110 is extended to the side edge.

Subsequent to step S200, the height of the wall panel essential line segment 110b having the lowest height, that is, the wall panel essential line segment 110b reaching the side end of the panel allocation region 200 is the bottom of the panel allocation region 200. If it is higher than the line segment 120 (see FIG. 15) (step S210), the following processing is performed. That is, below the edge height h of the panel allocation area 200, a dimension corresponding to an integral multiple (two times in the example of FIG. 15) of the height dimension c of the largest small wall panel is smaller than the bottom line segment 120. A dividing line 130 is provided at the upper position, and the dividing line 130 divides the panel allocation area 200 into upper and lower parts. Then, the upper side, which is divided into two, is defined as the roofing area 220, and the lower side is defined as the internal small wall area 210 (step S220), and the processing for dividing the roofing area in step S30 is performed.

In step S210, if the wall panel essential line segment 110b having the lowest height is lower than the bottom line segment 120, the above-described step S220 is performed.
Without performing such division, the entire panel allocation area 200 is set as the roofing area 220 (step S230), and the process proceeds to the division of the roofing area in step S30.

FIG. 7 shows a specific example of the procedure for dividing the roof area in step S30 in the case of a girder roof. As shown in FIG.
The length from the dividing line 130 to the highest point A (height of the roofing area 220) is equal to or longer than the length of the vertical line segment 111 in the maximum elevation of the roofing panel Y. If it is long (step S300), the bottom line segment group for the allocation cutting area is created as follows.
The creation process is as follows (see FIG. 16). That is, an allocation-use roofing area bottom line segment 140a corresponding to a bottom line segment in the roofing panel Y is created at the eaves of the roofing area 220 (step S301). Then, the upper rear end portion C of the vertical shape of the roofing panel Y having the created allocation roofing area bottom line segment 140a as the bottom coincides with the ridge (point A) of the roofing area 220, or more than that. Until the upper position (step S303), a line segment 14 for the bottom of the allocation roofing area that has a stepwise shape toward the ridge
0s are sequentially created (step S304).

It should be noted that the bottom line segment 140
In creating (140a), the selection of the roofing panel Y is performed by the wall panel selection means 41 as described above, and the horizontal wall panel net line segment 10 as high as possible is selected.
In consideration of a wall panel P having an upper surface having an upper side line segment that matches 0, or a combination of the wall panel P and the adjusting material G, a roof panel having the largest vertical surface is selected as much as possible. It goes without saying that it is done like this.

When the grouping of the bottom line segment for the allocation yairing region is completed, the yairing region 220 is bisected into the upper side and the lower side of the bottom line segment 140 for the allocating yaring region, and the upper side of the two is divided. Is defined as the allocation roofing area 221 (see FIG. 17, hatching portion), while the lower side is the inner small wall area 2
25 (step S305). In addition, in step S300, when the height of the roofing area 220 is shorter than the length of the vertical line segment 111 in the maximum elevation of the roofing panel Y, the entire roofing area 220 is allocated to the layout roofing area. The area 221 is set (step S302).

Subsequently, a surplus area corresponding to the deviation generated from the vertical wall panel net line segment 101 due to a win or loss is created in the allocation roofing area 221 (step S30).
6). Specifically, when the winning / losing attribute of the rear end of the roofing panel Y is "win", the connecting girder arrangement area 250 (see FIG. 1).
A remaining area 251 is created in a state of being lowered by the area indicated by the two-dot chain line in FIG. 8 (see FIG. 18). Further, when the attribute of the leading end of the roofing panel Y is “win”, nothing is arranged for the area 252 (the area indicated by the chain double-dashed line in FIG. 19) that originally projects from the vertical wall panel net line segment 101. No (see FIG. 19).

Then, the inner small wall regions 210 and 225 are formed.
Is divided into internal small wall areas for allocation (step S307),
The process proceeds to the panel allocation process in step S40. The allocation inner small wall region 260 is created by horizontally dividing the inner small wall regions 210 and 225 into horizontal line segments (see FIG. 20).

FIG. 8 and FIG. 9 show a specific example of the procedure for dividing the roofing area in step S30 in the case of a girder roof. As shown in FIG. 8, first, when the height of the roofing area 220 is equal to or longer than the length of the vertical line segment 111 in the maximum elevation of the roofing panel Y (step S350). The mixed area 230 is created (step S351). Then, the mixed region 230
If the width is equal to the width dimension of the maximum roofing panel Y in the vertical shape as described above (step S353), the area corresponding to the vertical shape of the maximum roofing panel Y is allocated to the layout roofing panel. The region 231 is defined as the wall region 23 on the lower side.
5 (step S354). In step S353,
If the width of the mixed area 230 is smaller than the above-described size, the process proceeds to step 355 in FIG.

Then, the following processing is performed depending on whether or not the mixed area 230 can be divided without excess or deficiency by the optimum combination of the roofing panel Y and the wall panel P (step S355). When it can be divided without excess or deficiency (see Fig. 21)
The upper half of the mixed area 230 is the allocation roofing area 23
1 and the lower half part thereof as the wall region 235 (step S
356). On the other hand, if it cannot be divided as described above (see FIG. 2).
2), the mixed area 230 is divided into a wall area 235 corresponding to the largest wall panel P accommodated in the area 230 and an upper area 232 other than that (step S35).
7), and the upper area 232 is further divided into the allocation roofing area 231 corresponding to the roofing panel Y that is accommodated in the area 232.
And the remaining area 233 other than that (step S358).

Steps S354, S356, S35
8, the height dimension of the wall region 235 is equal to or more than the minimum height dimension (for example, a length dimension four times the unit length a) in the general rectangular panel (general wall panel). When it is larger (step S359), the wall area 235 is set as the allocation rectangular area 236 to which the general rectangular panel 10 is allocated (step S360). On the other hand, when the height dimension of the wall region 235 is smaller, the wall region 23
5 is set as the inner small wall area 237 (step S361).

In step S350, if the height of the roofing area 220 is shorter than the length of the vertical line segment 111 in the maximum elevation of the roofing panel Y, the entire roofing area 220 is allocated. It is set as the shop cutting area 231 (step S352).

Steps S352, S360, S36
Subsequent to 1, a surplus area corresponding to the deviation generated from the vertical wall panel net line segment 101 due to a win or loss is created in the allocation roofing area 231 (step S362). Specifically, in the case of the above-mentioned girder roof (see FIGS. 18 and 19)
Similarly to the above, the remaining area 25 excluding the arrangement area 250 of the joint girders
1 is created and an area 252 in which nothing is placed is set. As a result, the panel arrangement as shown in FIG. 23 is made. Next, the internal small wall areas 210 and 237 are divided into the allocation internal small wall areas 260 (see FIG. 20) (step S36).
3) The process proceeds to the panel allocation process in step S40.

FIG. 10 shows a specific example of the panel allocation procedure in step S40. As shown in the figure, first, the general rectangular panel 10 corresponding to the allocation rectangular area 236 is arranged (step S400). Next, the small wall panel 11 corresponding to the allocation inner small wall region 260 is arranged (step S410). Internal small wall area 26 for allocation
If a region having a size smaller than the smallest small wall panel 11 in both width and height occurs in 0 (step S
411), and the generated area is set as a remainder area (step S412).

Next, a special panel corresponding to the side wall area of the overhang portion where a part of the upper floor projects above the outer wall of the lower floor, or the wall area when the facing room attribute is a bathroom is provided. It is arranged (step S420).

Next, the allocation cutting areas 221, 231
Although the roofing panel Y is allocated to the above, but when there is no corresponding roofing panel Y in the part to be allocated (step S430), the area is set as the field framework area (step S431). On the other hand, in step S430, when there is a corresponding roofing panel Y, the corresponding roofing panel Y is arranged in the allocation roofing areas 221 and 231 (step S432). At that time, in the case of girder roof,
One roof cutting panel Y is allocated to one allocation roof cutting area bottom line segment 140 (see FIG. 24).

Further, when the arranged roofing panel Y is arranged and the arranged roofing panel Y protrudes from the allocation target portion (step S433), the protruding portion (over portion) is processed in the field processing area 240. Is designated (step S434). At that time, the front end side of the roofing panel Y is aligned with the corresponding portion in the allocated area, and the rear end portion of the roofing panel Y is cut vertically (see FIG. 25).

After arranging the panels, the above step S412 is performed.
Material G corresponding to the surplus area and other surplus areas 233 and 251 generated in the allocation inner small wall area 260 in FIG.
Are arranged (step S440). At that time, if a region smaller than the smallest one of the adjusting materials G is generated in these surplus regions (step S441), the region is set as a field framing region (step S442).

As described above, the data for each of the arranged panels Y, P (10, 11) and the adjusting material G, and the designated on-site machining area 240 and on-site framing area are registered. It is stored in the auxiliary storage device 4 (step S4).
50). With the above, the wall panel allocation process is completed.

When the layout is completed, the allocated wall panel P (10, 11) and the roofing panel Y stored in the auxiliary storage device 4 in the CAD system.
Ordering product code No. It is possible to create a quote for the relevant wall body and a purchase order for the panel and adjustment material by searching for the unit price, etc. Further, it is also possible to print (output) the quotation and purchase order. Needless to say, a design drawing of the wall body can be printed.

According to the above-described embodiment, the wall panel allocating device has the line segment 1 of any one of the horizontal wall panel net line segment groups.
It is designed to select the largest possible wall panel P having an upper side line segment that coincides with 00, and to select the roofing panel Y that is just combined with the selected wall panel P. The panel Y and the wall panel P can be allocated as large as possible without creating a gap between them. Therefore, not only is it unnecessary to provide a custom-sized panel or a region for arranging the adjusting material G, but also it is possible to prevent a small panel from being carelessly allocated, so that the panel allocation is efficiently performed and the design work is saved. Needless to say, it is possible to avoid a decrease in panel productivity and save labor in panel joining work at a construction site, thereby improving productivity of houses and reducing construction costs.

Further, the wall panel allocating device combines the wall panel P and the adjusting material G when there is no wall panel P having an upper line segment that matches any of the horizontal wall panel net line segments 100. Is selected and a combination is selected such that the upper side line segment in the combination matches any one of the horizontal wall panel net line segments 100, so that the panel allocation is efficiently performed. Therefore, even if the adjustment material G is used, the number of the adjustment materials G allocated between the wall panel P and the roofing panel Y is reduced as much as possible, and even the adjustment material G cannot be filled. Can be prevented as much as possible, so that no area for allocating a custom-sized panel is required.

The wall surface panel allocating device and the CAD system to which the wall surface panel allocating device is applied are configured such that the upper side line segment of the wall panel P or the upper side line segment of the combination of the wall panel P and the adjusting material G is either horizontal It goes without saying that if the wall panel P, the roofing panel Y and the adjusting material G are allocated so as to match the wall panel net line segment 100, the configuration in the above-mentioned embodiment is not limited at all. Also,
The specific procedure of the panel allocation process is not limited to the above embodiment.

[0075]

According to the wall surface panel allocating device of the present invention, the horizontal net line segment creating means creates horizontal wall panel net line groups at a pitch obtained by multiplying the unit length by the roof slope, and the line group groups are created. Since the combination of the roofing panel and the wall panel is considered using as an index, the roofing panel and the wall panel can be allocated without creating a gap between them, and a custom-sized panel or There is no need to provide an area to allocate adjustment materials. In addition, it is possible to allocate the largest possible wall panel while selecting the largest possible roofing panel within the range that can be allocated without excess or deficiency, and prevent inadvertent allocation of a small panel. Therefore, panel allocation can be efficiently performed, reduction of panel productivity can be avoided, labor saving of panel joining work at a construction site can be achieved, and productivity of a house can be improved and construction cost can be reduced.

If the wall panel storage means does not store an elevational wall panel whose upper side line segment matches the horizontal wall panel net line segment, the horizontal wall panel net line group is used as an index. Since the combination of roofing panels, wall panels and adjustment materials has been studied, panel allocation is made efficiently, and therefore the number of adjustment materials allocated between wall panels and roofing panels is reduced as much as possible. Or
It can prevent gaps that cannot be filled even with adjustment materials, and eliminates the need to provide an area to allocate custom-sized panels.

The lower half portion of the entire panel allocation area is the wall area, and the upper half area excluding the wall area is the roofing area. It is only necessary to allocate the wall panels without including them, and to consider the combination of the roofing panel and the wall panel only in the roofing area.The area to be considered can be made as small as possible, and even the place where the wall panel should be originally allocated should be considered. It prevents the layout from being inadvertently combined with the roof panel and the wall panel.

From the eaves side to the ridge side of the roof cutting area, the layout roof cutting areas are sequentially set in the roof cutting area, and the roof cutting area excluding the layout roof cutting area is defined as a wall area. By doing so, the roofing panel can be efficiently allocated in the roofing area. In particular,
This is effective for allocating the roofing panel to the roofing area when the roof is located above the girder of the house.

The roof cutting area is divided into a plurality of mixing areas, the upper half of each mixing area is used as a layout cutting area, and the mixing area excluding the layout cutting area is defined as a wall area. By this, the roof cutting panel can be efficiently allocated in the roof cutting area. In particular, it is effective for allocating the roofing panel to the roofing area when the roof is located below the girder material of the house.

When there is no roofing panel corresponding to the allocation target portion of the allocation yapping area, the allocation target portion is set as the site allocation area by means of the field assembly area setting means. This makes it possible to design a wall that supports a roof with an irregular slope or shape,
It can be designed according to any design requirement of the supplier.

In the case where the vertical line segment portion of the vertical shape of the roofing panel corresponding to the allocation target portion of the allocation roofing area protrudes from the allocation target portion, the projecting area is set by the on-site processing area setting means. Since it is set as the on-site processing area, it is possible to correspond to the case of designing a wall body that can not allocate the roofing panel exactly just enough, and it can respond to any design request of the ordering party. Can be designed accordingly.

[Brief description of drawings]

FIG. 1 is a block diagram showing an example of a basic configuration of a wall surface panel allocating device according to the present invention.

FIG. 2 is a block diagram showing a basic configuration of an example in which the wall surface panel allocating device according to the present invention is applied to a CAD system.

FIG. 3 is a block diagram showing an example of a basic configuration of the CAD system.

FIG. 4 is a flowchart showing an example of a wall panel allocation procedure in the CAD system.

FIG. 5 is a flowchart showing an example of a procedure for creating wall panel net line segments in the allocation procedure.

FIG. 6 is a flowchart showing an example of a procedure for setting a roof area in the allocation procedure.

FIG. 7 is a flowchart showing an example of a procedure for dividing a roof area in the allocation procedure.

FIG. 8 is a flowchart showing an example of a procedure for dividing a roofing area in the allocation procedure.

FIG. 9 is a flowchart showing an example of a procedure for dividing a roof-cut area in the allocation procedure.

FIG. 10 is a flowchart showing an example of a panel allocation procedure in the allocation procedure.

FIG. 11 is a diagram showing a vertical shape of a roofing panel for explaining a process of creating a wall panel net line segment in the CAD system.

FIG. 12 is a diagram showing an elevation shape of a roof panel for explaining a process of creating a wall panel net line segment in the CAD system.

FIG. 13 is a diagram showing an example of a panel allocation area for explaining a process of setting a roof-cut area in the CAD system.

FIG. 14 is a diagram showing another example of the panel allocation area for explaining the setting processing of the roof cutting area in the CAD system.

FIG. 15 is a diagram showing an example of a panel allocation area in a state where a roof cutting area is set by the CAD system.

FIG. 16 is a diagram showing an example of a roofing area for explaining the division processing of the roofing area in the CAD system.

FIG. 17 is a diagram showing an example of a roofing area in a state where an allocation roofing area is set by the CAD system.

FIG. 18 is a diagram showing an example of an allocation roofing area for explaining a process of winning or losing an end of the allocation roofing area in the CAD system.

FIG. 19 is a diagram showing another example of the allocation roofing area for explaining the process of winning or losing the end of the allocation roofing area in the CAD system.

FIG. 20 is a diagram showing an example of an internal small wall area for explaining a setting process of an internal small wall area for allocation in the CAD system.

FIG. 21 is a diagram showing an example of a mixed area in a state where a layout cutting area is set by the CAD system.

FIG. 22 is a diagram showing another example of a mixed area in a state where an allocation roofing area is set by the CAD system.

FIG. 23 is a diagram showing an example of a roofing area in a state where an allocation roofing area that has been won and lost by the CAD system is set.

FIG. 24 is a diagram showing an example of an allocation roofing area in a state where roofing panels are allocated by the CAD system.

FIG. 25 is a diagram showing an example of a roofing panel in a state where a field processing area is set by the CAD system.

FIG. 26 is an exploded perspective view showing how the wall and roof are housed in the prefab house by the panel construction method.

FIG. 27 is an elevation view of a roofing panel (roof slope 1/1) used in the prefab house.

FIG. 28 is an elevation view of a roofing panel (roof slope 2/3) used in the prefab house.

FIG. 29 is an elevation view of a roofing panel (roof slope 1/2) used in the prefab house.

FIG. 30 is an elevation view of a roofing panel (roof slope 1/3) used in the prefab house.

FIG. 31 is an elevation view of a roofing panel (roof slope 1/12) used in the prefab house.

[Explanation of symbols]

 G adjustment material P wall panel Y roofing panel 1 wall body 10 general rectangular panel (wall panel) 11 small wall panel (wall panel) 30 wall panel storage means 31 roofing panel storage means 32 adjustment material storage means 40 horizontal net line segment Creating means 41 Wall panel selecting means 42 Roofing panel selecting means 43 Vertical net line segment creating means 44 Wall panel indispensable line segment creating means 45 Roofing area setting means 46 First wall area setting means 47 First allocation roofing Area setting means 48 Second wall area setting means 49 Mixing area setting means 50 Second allocation roofing area setting means 51 Third wall area setting means 52 Field assembly area setting means 53 Field processing area setting means 100 Horizontal Wall panel net line segment 101, 101a Vertical wall panel net line segment 110, 110b Wall panel essential line segment 111 Vertical line segment 120 Bottom Side line segment 200 Panel allocation area 210, 225, 237 Internal small wall area (wall area) 220 Roofing area 221,231 Layout roofing area 230 Mixing area 235 Wall area 236 Rectangular area for allocation 240 On-site processing area

Claims (7)

[Claims] 1. A wall body having a slope side along a roof slope at an upper edge, a wall panel having a rectangular elevation shape, or an elevation shape having a substantially triangular shape or a trapezoidal shape. A wall panel allocating device used when designing a combination of a roofing panel having a width dimension that is an integral multiple of the length, the wall panel storage means storing in advance the elevation shapes of a plurality of the wall panels. A roofing panel storage means for storing in advance the elevational shapes of a plurality of the roofing panels, and the whole panel allocation area corresponding to the elevational shape of a part or all of the wall, Horizontal net line segment creating means for creating a plurality of horizontal wall panel net line segments that can be horizontally divided at a pitch obtained by multiplying a unit length by a roof slope, and the panel corresponding to a part or all of the slope side Below the inclined side line segment of the allocation area, and From the wall panel storage means, an upright wall panel having an upper side line segment that matches the uppermost horizontal wall panel net line segment in the horizontal wall panel net line segment as much as possible is created. The selectable wall panel selection means, and the roofing panel having an elevation shape that matches the shape between the upper side line segment of the elevation shape of the selected wall panel and the inclined side line segment is the roofing panel. A wall panel allocating device comprising: a roofing panel selecting unit that can be selected from a storage unit. 2. An adjusting material storage means for storing elevational shapes of a plurality of adjusting materials in advance, wherein the wall panel storing means stores any one of the horizontal wall panel net line segment groups. In the case where the wall panel of the elevation shape having the upper side line segment that can be matched is not stored, the wall panel selection means is below the inclined side line segment and is created. In the horizontal wall panel net line segment as high as possible in the horizontal wall panel net line segment group, the elevation shape of the adjustment material read from the adjustment material storage means and the standing of the wall panel read from the wall panel storage means. The wall panel storing means selects a wall panel such that the upper side line segment of the shape formed by combining the surface shapes is the same, and the roofing panel selecting means selects the adjusting material and the wall panel. On combination shape 2. The largest roof-shaped roofing panel that can be assigned between the side line segment and the inclined side line segment is selected from the roofing panel storage means. Wall panel allocation device. 3. A vertical net line segment creating means for creating a plurality of vertical wall panel net line segments that can be vertically divided at the pitch of the unit length with respect to the entire panel allocation area, and the created net net line segment. Among the vertical wall panel net line segments, the vertical wall panel net line segment that passes through the highest point of the entire panel allocation area has a roof roof panel group with a corresponding roof slope stored in the roof panel storage means. Along the vertical line of the vertical shape of the largest roofing panel, and,
With the upper end of the vertical line segment aligned with the highest point above,
A wall panel essential line segment having the above unit length is created toward the eaves side along the horizontal wall panel net line segment that passes through the starting end with the lower end of the vertical line segment as the starting end, and the wall panel essential line segment Creating a next wall panel mandatory line segment having the above unit length along the horizontal wall panel net line segment that passes through the starting point with the point that is one step lower than the end point as a new starting point toward the eaves side, Wall panel essential line segment creating means for creating a stepwise group of wall panel essential line segments by repeating until the end of the newly created wall panel essential line segment reaches the side edge of the entire panel allocation area, When the wall panel essential line segment located at the lowest position of the created wall panel essential line group is higher than the bottom line segment of the entire panel allocation region, the lower half part of the entire panel allocation region is set to 1 Alternatively, a first wall area setting unit that is a rectangular wall area that can be filled by allocating two or more wall panels only in an upright shape, and the wall area that is set in the entire panel allocation area. And a roofing area setting means for setting the removed area as a roofing area capable of being filled with at least one vertical shape of the roofing panel, and the roofing area setting means is the lowest. If the wall panel essential line segment located is lower than the bottom line segment of the entire panel allocation region, the entire panel allocation region is set as a roofing region. The wall panel allocating device described in 2. 4. A roofing panel selected from the roofing panel storage means by the roofing panel selecting means in order in the roofing area from the eaves side to the ridge side. First allocation roofing area setting means for setting an allocation roofing area capable of allocating an elevation shape, and an area other than the allocation roofing area which is set in the same roofing area A wall region that can be filled by allocating one or more wall panel elevation shapes selected from the wall panel storage means by the wall panel selection means without allocating the panel elevation shapes The wall surface panel allocating device according to claim 3, further comprising: two wall area setting means. 5. The plurality of roofing areas are defined by the width dimension in the vertical shape of the largest roofing panel of the roofing panel group having the corresponding roof slope stored in the roofing panel storage means. A second mixing area setting means that can be divided into mixing areas and an upper half of each mixing area that is set as the allocation roofing area capable of allocating the vertical shape of the largest roofing panel. The allocation roofing area setting means and the area excluding the allocation distribution area set in the same mixed area are allocated by the wall panel selection means without allocating the elevation shape of the distribution panel. A third wall area setting means which is a wall area that can be filled by allocating one or more wall panels selected from the storage means in an upright shape. Note 3 Mounted wall panel allocation device. 6. The roof-cutting panel storage means does not store a vertical roof-cutting panel having a slope corresponding to a slope of an inclined side in an allocation target portion of the allocation roofing region. Or, when the sloped side portion of the elevation shape of the roofing panel selected from the roofing panel storage means by the roofing panel selection means does not fit within the allocation target portion, the allocation target portion is set on site. The wall surface panel allocating device according to claim 4 or 5, further comprising on-site framing area setting means for setting a framing area. 7. A vertical line segment of a vertical shape of a roofing panel selected from the roofing panel storage means by the roofing panel selection means protrudes from a portion to be allocated in the layout roofing area. 6. The wall surface panel allocating device according to claim 4 or 5, further comprising: an on-site processing area setting means for setting the protruding portion as an on-site processing area.