JP7447174B2 - building - Google Patents

Description

The present invention relates to buildings .

BACKGROUND ART Buildings in which the outer wall is composed of a plurality of wall panels have been known. For example, in Patent Document 1, wall panels of various shapes are arranged along the outer peripheral surface of a building body (see FIG. 4 of Patent Document 1).

Patent No. 6386856

Standard-sized architectural panels are used as wall panels and other architectural panels to construct the frame of a building, but depending on the shape of the building (roof slope, etc.), standard-sized architectural panels cannot be used to close the area. A region appears. In that case, it is necessary to separately prepare a construction panel with the same shape as the area.
Among architectural panels that are not standard sizes, for example, square-shaped architectural panels with two adjacent right angles (rectangular shape, right-angled trapezoid, etc.) can be easily manufactured; Architectural panels that are not shaped like parallelograms (such as parallelograms) cannot be manufactured easily. That is, in order to manufacture a rectangular architectural panel other than that, a skilled technique is required, which is time consuming and costly.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a building having a construction panel arrangement structure that can reduce labor and cost.

The invention according to claim 1 provides, for example, as shown in FIGS. 1 to 8, in a building 1 whose frame is composed of construction panels,
It has an arrangement structure in which a first trapezoidal panel 32a and a second trapezoidal panel 32b, which are right-angled trapezoidal architectural panels, are arranged in a parallelogram-shaped region R,
a sloped roof (second roof 2b);
a parapet wall (third parapet wall 3c) that slopes along the sloped roof 2b;
A roof panel 42, which is a construction panel disposed outside the parallelogram-shaped region R and has an upper end surface inclined along the slope roof 2b, is provided.
The first trapezoidal panel 32a and the second trapezoidal panel 32b are
An architectural panel constituting the parapet wall 3c,
The four end surfaces include a slope, an upper base surface, a lower base surface, and an orthogonal surface facing the slope and orthogonal to the upper base surface and the lower base surface, and arranged with the orthogonal surfaces facing each other. and,
The acute angle portions of the first trapezoidal panel 32a and the second trapezoidal panel 32b correspond to one acute angle portion and the other acute angle portion in the parallelogram-shaped region R, respectively, and
On the upper end surface of the roof panel 42, the obtuse angle portions of the first trapezoidal panel 32a and the second trapezoidal panel 32b correspond to one obtuse angle portion and the other obtuse angle portion in the parallelogram-shaped region R, respectively. It is characterized by being located in .

According to the invention described in claim 1, since two right-angled trapezoidal architectural panels are placed in combination in the parallelogram-shaped region R, the parallelogram-shaped architectural panels are not used. The region R can be closed off, and the effort and cost for manufacturing a construction panel to be placed in the parallelogram-shaped region R can be reduced.
Further, the roof panel 42 forms a parallelogram-shaped region R, and supports architectural panels (first trapezoidal panel 32a, second trapezoidal panel 32b) arranged in the parallelogram-shaped region R. There is. Therefore, the roof panel 42 can be used in new and novel ways, such as forming a parallelogram-shaped area or supporting other architectural panels.

The invention according to claim 2 provides, for example, as shown in FIG. 6, in the building 1 according to claim 1,
In the parallelogram-shaped region R, an intermediate panel 31a, which is a rectangular architectural panel, can be arranged between the orthogonal plane of the first trapezoidal panel 32a and the orthogonal plane of the second trapezoidal panel 32b. It is characterized by

According to the invention described in claim 2, it is possible to arrange a combination of two right-angled trapezoidal architectural panels and a rectangular architectural panel in the parallelogram-shaped region R, so that the parallelogram-shaped The parallelogram-shaped region R can be closed off without using the parallelogram-shaped region R, and the effort and cost for manufacturing the construction panels arranged in the parallelogram-shaped region R can be reduced.

The invention according to claim 3 is, for example, as shown in FIGS. 1 to 8, in the building 1 according to claim 1 or 2 ,
The construction panel is arranged outside the parallelogram-shaped region R, and the second trapezoidal panel 32b is adjacent to the roof panel 42 arranged on the upper end surface, and the second trapezoidal panel 32b is It is equipped with an adjacent panel (north rectangular panel 41c) which is a rectangular architectural panel that touches the slope,
The second trapezoidal panel 32b has a corner formed by the roof panel 42 on which the second trapezoidal panel 32b is disposed on the upper end surface and the adjacent panel 41c. It is characterized by the fact that the acute angle portions are arranged in a fitted manner.

According to the invention described in claim 3 , one acute angle in the parallelogram-shaped region R is formed by the roof panel 42 and the rectangular architectural panel (north rectangular panel 41c) adjacent to the roof panel 42. The second trapezoidal panel 32b is arranged such that the acute-angled portion of the second trapezoidal panel 32b fits into the one acute-angled portion. Therefore, since the second trapezoidal panel 32b can be provided in a state that is wedged between the architectural panels arranged outside the parallelogram-shaped area R, the positioning of the second trapezoidal panel 32b, and even the first trapezoidal panel 32a and the intermediate The panel 31a can be easily positioned.
Further, since the architectural panels (first trapezoidal panel 32a, second trapezoidal panel 32b) arranged in the parallelogram-shaped region R are provided on the upper end surface (slope) of the roof panel 42, the upper end surface However, since the adjacent panel (northern rectangular panel 41c) functions as a non-slippery for the second trapezoidal panel 32b, the position of the second trapezoidal panel 32b may shift, and in turn, the first trapezoidal panel 32a Also, it is possible to prevent displacement of the intermediate panel 31a.

The invention according to claim 4 is, for example, as shown in FIGS. 1 to 8, in the building 1 according to any one of claims 1 to 3 ,
a rectangular architectural panel 31 that is a rectangular architectural panel that is arranged outside the parallelogram-shaped region R;
A third trapezoidal panel 32c, which is an architectural panel arranged outside the parallelogram-shaped area R and is a right-angled trapezoidal architectural panel, is provided.
The third trapezoidal panel 32c has a lower bottom surface in contact with the rectangular panel 31, and an upper bottom surface of the third trapezoidal panel 32c in contact with the slope of the first trapezoidal panel 32a, It is characterized in that it is arranged between the first trapezoidal panel 32a and the rectangular panel 31.

According to the fourth aspect of the present invention, the third trapezoidal panel 32c having a right-angled trapezoid shape is used as an architectural panel that connects the parallelogram-shaped region R and the rectangular panel 31. Therefore, it is not necessary to change the first trapezoidal panel 32a and the second trapezoidal panel 32b depending on the height dimension of the rectangular panel 31, and it is only necessary to change the third trapezoidal panel 32c. The second trapezoidal panel 32b can be made versatile.

The invention according to claim 5 is, for example, as shown in FIGS. 1 to 8, in the building 1 according to any one of claims 1 to 4 ,
A finishing material 3d is provided at the upper end of the parapet wall (third parapet wall 3c),
The finishing material 3d is
It is arranged astride the first trapezoidal panel 32a and the architectural panel arranged outside the parallelogram-shaped region R, and
It is characterized in that it is arranged astride the second trapezoidal panel 32b and the architectural panel arranged outside the parallelogram-shaped region R.

According to the invention set forth in claim 5 , the first trapezoidal panel 32a and the second trapezoidal panel 32b are connected by the finishing material 32d to a construction panel disposed outside the parallelogram-shaped region R, so that the first trapezoidal panel 32a and the second trapezoidal panel 32b are parallel It is possible to enhance the sense of unity between the architectural panels arranged in the quadrilateral region R and the architectural panels arranged outside the parallelogram region.

According to the present invention, labor and costs can be reduced.

It is a perspective view showing a building. It is a figure which shows the relationship between the roof of a building, a parapet wall, and an outer wall, (a) is a sectional view, (b) is a top view. It is a figure showing an example of arrangement structure of a building panel. FIG. 3 is a diagram illustrating a parallelogram-shaped area. It is a figure which shows the modification of a 3rd trapezoidal panel. It is a figure which shows the modification of the arrangement structure of a building panel. It is a figure which shows the modification of the roof of a building. It is a figure which shows the modification of the arrangement structure of a building panel.

Embodiments of the present invention will be described below with reference to the drawings. However, although the embodiments described below have various limitations that are technically preferable for carrying out the present invention, the technical scope of the present invention is limited to the embodiments (including modified examples) and the figures below. The examples are not limited to the examples shown. Note that directions in the following embodiments and illustrated examples are set for convenience of explanation only.

FIG. 1 is a perspective view showing a building 1. FIG. FIG. 2(a) is a sectional view showing the relationship between the roof 2, parapet wall 3, and exterior wall 4 of the building 1, and FIG. 2(b) is a sectional view showing the relationship between the roof 2, parapet wall 3, and exterior wall 4 of the building 1. FIG. FIG. 3 is a diagram showing an example of the arrangement structure of architectural panels, and is a side view showing the third parapet wall 3c and its vicinity. FIG. 4 is a diagram illustrating a parallelogram-shaped region R.
As shown in FIG. 1, the building 1 in this embodiment is a square-form two-story house, and has a parapet wall 3 surrounding the roof (above the roof 2) on three sides.
Although the building 1 in this embodiment is a two-story building as described above, it is not limited to this, and may be a one-story building or three or more stories. .

Building 1 will be constructed using the panel construction method, in which building components such as walls, floors, and roof are made into panels in advance at a factory, and these panels (wall panels, floor panels, roof panels, etc.) are assembled at the construction site. be done. However, the structure is not limited to this, and may be constructed using conventional frame construction methods, wall construction methods, two-by-four construction methods, or the like.
In addition, a panel is a construction panel, in which vertical and horizontal frame materials A are assembled into a rectangular shape (or right-angled trapezoidal shape) to form a rectangular frame (or right-angled trapezoidal frame), and auxiliary beams are placed inside this frame. B is assembled vertically and horizontally to form a frame body, and face materials are attached to both or one side of this frame body, and the structure is hollow inside. The internal hollow part (the back side of the face material) is usually filled with a heat insulating material such as glass wool or rock wool. Furthermore, architectural panels are connected to each other using adhesives, screws, bolts and nuts, and the like.

As shown in FIGS. 1 and 2(a), the roof 2 of the building 1 includes a first roof 2a and a second roof 2b provided on the north side of the first roof 2a.
The first roof 2a and the second roof 2b are set at different angles from each other. In other words, the roof 2 is a different slope roof.
As shown in FIG. 2(b), the first roof 2a is composed of a plurality of roof panels 20, and slopes downward toward the north. The first roof 2a is a gently sloped roof (for example, a flat roof) with a gentler angle than the second roof 2b.

Further, the second roof 2b is composed of a plurality of roof panels 20, and slopes downward toward the north. The second roof 2b is a steeply sloped roof (sloped roof) with a steeper angle than the first roof 2a.
The slope (angle) of the second roof 2b corresponds to, for example, the north diagonal line restriction, the road diagonal line restriction, and the adjacent land diagonal line restriction. In addition, in areas with many narrow spaces such as Tokyo and Yokohama City, Kanagawa Prefecture, there are regulations regarding the height of buildings called "height districts", and the building 1 in this embodiment was constructed to meet the regulations. has been done. More specifically, the building 1 in this embodiment satisfies the regulations of "Tokyo Class 2 Altitude" and "Yokohama Class 3 Altitude."

The second roof 2b in this embodiment is a sloped roof with a 1/1 slope.
The first roof 2a in this embodiment has a gentle slope as described above, and a metal roof (sheet metal roof) is used to improve rain protection. On the other hand, since the second roof 2b has a steep slope, it is not necessary to necessarily adopt a sheet metal roof, but in this embodiment, considering the workability of the entire roof 2, the first roof 2a and the second roof are 2b both have sheet metal roofs.
Although the roof 2 in this embodiment is a heterogeneous slope roof including a first roof 2a and a second roof 2b having different angles from each other, the roof 2 is not limited to this. For example, it may be a sloped roof with a plurality of roof surfaces such as a gable roof, a hipped roof, or an inviting roof, or it may be a single-slope roof.

As shown in FIGS. 1 and 2(a), the parapet wall 3 includes a first parapet wall 3a erected at the south edge of the first roof 2a, and an east edge and a west edge of the first roof 2a. It consists of a second parapet wall 3b erected at each of the second roof 2b, and a third parapet wall 3c erected at each of the east and west edges of the second roof 2b. Further, on the parapet wall 3, a finishing material 3d such as Kasagi is provided.
The first parapet wall 3a and the second parapet wall 3b are provided horizontally. On the other hand, the third parapet wall 3c is provided to be inclined along the slope of the second roof 2b. That is, the third parapet walls 3c, which are erected at the east and west edges of the second roof 2b, are inclined according to the slope of the second roof 2b, whereas the third parapet walls 3c are erected at the east and west edges of the second roof 2b. The second parapet wall 3b erected on each of the east and west edges of the roof 2a is not inclined in accordance with the slope of the first roof 2a.

The outer wall 4 of the building 1 (the wall that separates indoors and outdoors) is composed of a plurality of wall panels, and the surface (outdoor side surface) of the outer wall 4 is provided with an exterior finishing material 4a such as an external wall material. It is being Moreover, the parapet wall 3 is also constituted by a plurality of wall panels. In this embodiment, the wall panel that constitutes the outer wall 4 is referred to as an exterior wall panel 40, and the wall panel that constitutes the parapet wall 3 is referred to as a parapet panel 30.

The exterior wall panel 40 includes, for example, a rectangular panel 41 and a roof panel 42 that has a right trapezoid shape (or may have a right triangular shape). The outer wall 4 of the building 1 is mainly composed of rectangular panels 41.
The roof panel 42 has an upper end surface inclined according to the slope (1/1 slope) of the second roof 2b, and is provided on the upper end surface of the rectangular panel 41 as necessary. Specifically, as shown in FIG. 3, the roof panel 42 includes a third parapet wall 3c and a rectangular panel 41 (south rectangular panel 41a, central rectangular panel 41b) provided below the third parapet wall 3c. A right-angled trapezoid-shaped (or right-angled triangular) gap formed between them, and a right-angled trapezoid formed between the finishing material 3d and the rectangular panel 41 (north rectangular panel 41c) provided below the finishing material 3d. It is provided to close a gap in the shape of a right triangle (or a right triangle). Therefore, in this embodiment, the roof panel 42 is installed with the upper end surface (slope) of the roof panel 42 facing north.

Among the rectangular panels 41 constituting the outer wall 4 on the second floor of the building 1, the rectangular panels 41 having the roof panel 42 on the upper end face, except for the rectangular panel 41 located on the northernmost side (northern rectangular panel 41c), The height dimension is set shorter than that of the rectangular panel 41 adjacent to the south.
Specifically, in the example shown in FIG. 3, among the rectangular panels 41 constituting the outer wall 4 on the second floor of the building 1, the south rectangular panel 41a is the rectangular panel 41 in which the roof panel 42 is provided on the upper end surface. A central rectangular panel 41b and a north rectangular panel 41c are provided.

The height of the south rectangular panel 41a is set shorter than that of the rectangular panel 41 (rectangular panel 41d) adjacent to the south rectangular panel 41a on the south side.
Further, the height of the central rectangular panel 41b is set shorter than that of the rectangular panel 41 (south rectangular panel 41a) adjacent to the central rectangular panel 41b on the south side. The difference between the height dimension of the south rectangular panel 41a and the height dimension of the central rectangular panel 41b is determined by the difference between the height dimension of the south rectangular panel 41a and the height dimension of the central rectangular panel 41b. The difference is set so that the upper end surface of the roof panel 42 and the upper end surface of the roof panel 42 are flush with each other.
On the other hand, the north rectangular panel 41c is set longer in height than the rectangular panel 41 (central rectangular panel 41b) adjacent to the north rectangular panel 41c on the south side. Here, the upper part of the north rectangular panel 41c and the roof panel 42 provided on the upper end surface of the north rectangular panel 41c constitute a part (northern end) of the third parapet wall 3c.

The parapet panel 30 includes, for example, a rectangular panel 31 having a rectangular shape and a trapezoidal panel 32 having a right-angled trapezoid shape.
The first parapet wall 3a is composed of a plurality of rectangular panels 31.
The second parapet wall 3b includes a plurality of rectangular panels 31 and one trapezoidal panel 32 (third trapezoidal panel 32c). Specifically, as shown in FIG. 3, among the parapet panels 30 constituting the second parapet wall 3b, the parapet panel 30 located furthest north is the trapezoidal panel 32 (third trapezoidal panel 32c); The parapet panel 30 is a rectangular panel 31. The height dimension of the rectangular panel 31 constituting the second parapet wall 3b is set to be approximately equal to the height dimension of the rectangular panel 31 constituting the first parapet wall 3a.

The upper end surface (slope) of the third trapezoidal panel 32c is inclined according to the slope (1/1 slope) of the second roof 2b. That is, the inclination angle of the upper end surface (slope) of the third trapezoidal panel 32c is set to be approximately equal to the inclination angle of the upper end surface (slope) of the roof panel 42. Further, the height of the south end surface (lower bottom surface) of the third trapezoidal panel 32c is set to be approximately equal to the height of the rectangular panel 31 constituting the second parapet wall 3b. Further, in this embodiment, an adjusting member 33 made of a square timber or the like is provided between the third trapezoidal panel 32c and the rectangular panel 31 adjacent to the third trapezoidal panel 32c on the south side for dimension adjustment. It is being

The third parapet wall 3c is composed of two trapezoidal panels 32 (a first trapezoidal panel 32a and a second trapezoidal panel 32b). Further, as described above, a part (northern end) of the third parapet wall 3c is constituted by the upper part of the north rectangular panel 41c and the roof panel 42 provided on the upper end surface of the north rectangular panel 41c. ing.
As shown in FIG. 4, the area where the parapet panel 30 is provided in the area where the third parapet wall 3c is provided has a parallelogram shape. Specifically, the finishing material 3d, the north end surface of the parapet panel 30 that forms the second parapet wall 3b (specifically, the north end surface (upper bottom surface) of the third trapezoidal panel 32c), and the outer wall 4 are formed. The upper end surface of the roof panel 42 (specifically, the upper end surface (slope) of the roof panel 42 provided on the upper end surface of the south rectangular panel 41a, and the upper end surface (slope) of the roof panel 42 provided on the upper end surface of the central rectangular panel 41b. upper end surface (slope)) and the south end surface of the outer wall panel 40 that constitutes a part (northern end) of the third parapet wall 3c (specifically, above the central rectangular panel 41b of the north rectangular panel 41c). The area surrounded by the south end face of the protruding portion and the south end face of the roof panel 42 provided on the upper end face of the north rectangular panel 41c has a parallelogram shape, and the area R of this parallelogram shape has a parallelogram shape. Trapezoidal panels 32a, 32b are provided.

Note that in this application, a parallelogram refers to a parallelogram in which four corners are not right angles, and does not include a quadrilateral (rectangle) in which all four corners are equal. Further, in the present application, all trapezoidal panels 32 have a right-angled trapezoid shape. In this embodiment, among the four end faces of the trapezoidal panel 32, the end face corresponding to the oblique side is referred to as a slope, the end face corresponding to the upper base is referred to as an upper base face, and the end face corresponding to the lower base (>upper base) is referred to as a slope. The end surface is referred to as the lower base surface, and the end surface perpendicular to the upper base surface and the lower base surface, that is, the end surface facing the slope, is referred to as the orthogonal surface.

Architectural panels having a rectangular shape (such as a rectangular shape or a right-angled trapezoid shape) having two adjacent right angles can be easily manufactured, but other quadrangular architectural panels cannot be easily manufactured. Therefore, parallelogram-shaped architectural panels are difficult to manufacture. Therefore, in this embodiment, two trapezoidal panels 32 (first trapezoidal panel 32a, second trapezoidal panel 32b) are used as the parapet panel 30 provided in the parallelogram-shaped region R.

As shown in FIG. 3, the first trapezoidal panel 32a and the second trapezoidal panel 32b satisfy the following conditions [1] to [5].
[1] The angle between the slope and the bottom surface of the first trapezoidal panel 32a and the second trapezoidal panel 32b (the angle of the acute angle part) is approximately equal to the angle between the slope and the south end surface of the roof panel 42.
[2] The length of the slope in the first trapezoidal panel 32a and the second trapezoidal panel 32b is approximately equal to the length of the upper bottom surface (northern end surface) of the third trapezoidal panel 32c.
[3] The length of the orthogonal plane in the first trapezoidal panel 32a and the length of the orthogonal plane in the second trapezoidal panel 32b are approximately equal.
[4] The length of the upper bottom surface of the first trapezoidal panel 32a is approximately equal to the length of the upper end surface (slope) of the roof panel 42 provided on the upper end surface of the south rectangular panel 41a.
[5] The length of the lower bottom surface of the second trapezoidal panel 32b is approximately equal to the length of the upper end surface (slope) of the roof panel 42 provided on the upper end surface of the central rectangular panel 41b.

By combining the first trapezoidal panel 32a and the second trapezoidal panel 32b as described above, the parallelogram-shaped region R can be closed off.
Specifically, in the first trapezoidal panel 32a, the slope of the first trapezoidal panel 32a is in contact with the north end surface of the third trapezoidal panel 32c, and the upper bottom surface of the first trapezoidal panel 32a is the upper end surface of the south rectangular panel 41a. It is arranged so as to be in contact with the upper end surface of the roof panel 42 provided on the roof. In addition, the second trapezoidal panel 32b has a slope in contact with the south end surface of the roof panel 42 provided on the upper end surface of the north rectangular panel 41c, and a lower bottom surface of the second trapezoidal panel 32b in the center. It is disposed in contact with the upper end surface of the roof panel 42 provided on the upper end surface of the rectangular panel 41b.

Therefore, the first trapezoidal panel 32a and the second trapezoidal panel 32b are such that the upper base surface of the first trapezoidal panel 32a and the lower base surface of the second trapezoidal panel 32b are substantially flush with each other, and The bottom surface of the trapezoidal panel 32a and the top surface of the second trapezoidal panel 32b are substantially flush with each other.
The finishing material 3d provided at the upper end of the first trapezoidal panel 32a is arranged across the first trapezoidal panel 32a and the third trapezoidal panel 32c adjacent to the first trapezoidal panel 32a. Furthermore, the finishing material 3d provided on the upper end of the second trapezoidal panel 32b is applied to the second trapezoidal panel 32b and the roof panel 42 adjacent to the second trapezoidal panel 32b (the roof provided on the upper end surface of the north rectangular panel 41c). panel 42).

Moreover, by using the first trapezoidal panel 32a and the second trapezoidal panel 32b as described above, the height dimension of the rectangular panel 31 constituting the first parapet wall 3a and the second parapet wall 3b is changed. However, if the height dimensions before and after the change satisfy a predetermined first condition, the first trapezoidal panel 32a and the second trapezoidal panel 32b can be used in common. Here, the predetermined first condition is the condition that "the height of the rectangular panel 31 is greater than or equal to the length of the slope in the first trapezoidal panel 32a (=the length of the slope in the second trapezoidal panel 32b)" It is.

Specifically, for example, the height h1 of the rectangular panel 31 shown in FIG. 5(a) is different from the height h2 of the rectangular panel 31 shown in FIG. 5(b). In this case, both can be accommodated by simply changing the third trapezoidal panel 32c without changing the first trapezoidal panel 32a and the second trapezoidal panel 32b.
That is, in the third trapezoidal panel 32c (third trapezoidal panel X) shown in FIG. 5(a) and the third trapezoidal panel 32c (third trapezoidal panel Y) shown in FIG. They are the same, and the length of the upper base is also the same, but the length of the lower base is different. Specifically, the length of the bottom surface of the third trapezoidal panel X is h1, and the length of the bottom surface of the third trapezoidal panel Y is h2. Additionally, the width dimensions of the third trapezoidal panel X and the third trapezoidal panel Y are also different accordingly.
In this way, between the rectangular panel 31 and the trapezoidal panels 32a, 32b, the length of the upper base (northern end face) is the same as the length of the slope of the trapezoidal panels 32a, 32b, and the lower base (south end face) is the same as the length of the slope of the trapezoidal panels 32a, 32b. By interposing the third trapezoidal panel 32c whose length dimension (end surface) is the same as the height dimension of the rectangular panel 31, the common trapezoidal panels 32a and 32b can be used regardless of the height dimension of the rectangular panel 31. Therefore, the trapezoidal panels 32a and 32b can be manufactured as standard products (standard products exclusively for 1/1 slope).

Furthermore, by using the first trapezoidal panel 32a and the second trapezoidal panel 32b as described above, the length dimension (dimension in the inclination direction) of the second roof 2b is changed, and the length of the parallelogram-shaped region R is changed. Even if the dimensions (dimensions in the north-south direction) are changed, if the length dimensions before and after the change satisfy the predetermined second condition, the common first trapezoidal panel 32a and second trapezoidal panel 32b are used. be able to. Here, the predetermined second condition is ``the length dimension of the parallelogram-shaped region R is L1 (= the length dimension when only the trapezoidal panels 32a and 32b are arranged in the parallelogram-shaped region R. 5(a)) or higher.”

Specifically, for example, the length L2 of the parallelogram-shaped region R shown in FIG. 6 is longer than the length L1 of the parallelogram-shaped region R shown in FIG. 5(a). In this case, even if the first trapezoidal panel 32a and the second trapezoidal panel 32b are not changed, just by arranging the intermediate panel 31a, which is the rectangular panel 31, between the first trapezoidal panel 32a and the second trapezoidal panel 32b, It can correspond to the region R whose length dimension is L2 (>L1). In addition, various length dimensions L2 (>L1) can be accommodated by changing the length dimension of the intermediate panel 31a or by changing the number of intermediate panels 31a arranged in the parallelogram-shaped region R. Can be done.
In this way, it is possible to select whether or not to arrange the intermediate panel 31a between the first trapezoidal panel 32a and the second trapezoidal panel 32b, and to select the length dimension and number of intermediate panels 31a to be arranged. Therefore, the common trapezoidal panels 32a and 32b can be used regardless of the length dimension of the parallelogram-shaped region R, so the trapezoidal panels 32a and 32b can be manufactured as standard products (standard products exclusively for 1/1 slope). It is.

Further, when the slope of the second roof 2b is changed, the trapezoidal panels 32a, 32b, 32c and the roof panel 42 are changed.
Specifically, for example, when the second roof 2b is a sloped roof with a 2/3 slope as shown in FIG. 7, the second roof 2b is A roof panel 42 whose upper end face slopes according to the slope (2/3 slope), and a third trapezoidal panel 32c whose upper end face (slope) slopes according to the slope (2/3 slope) of the second roof 2b. , and the first trapezoidal panel 32a and second trapezoidal panel 32b that satisfy the above conditions [1] to [5] are used.

Also in this case, as shown in FIGS. 8(a) and 8(b), between the rectangular panel 31 and the trapezoidal panels 32a, 32b, the length dimension of the upper bottom surface (northern end surface) is the slope of the trapezoidal panels 32a, 32b. By interposing the third trapezoidal panel 32c whose length dimension is the same as that of the rectangular panel 31 and whose lower bottom surface (south end surface) is the same as the height dimension of the rectangular panel 31, the height dimension of the rectangular panel 31 can be increased. Since a common trapezoidal panel 32a, 32b can be used regardless of the case, the trapezoidal panels 32a, 32b can be manufactured as a standard product (a standard product exclusively for 2/3 slope).
Also in this case, you can select whether or not to arrange the intermediate panel 31a between the first trapezoidal panel 32a and the second trapezoidal panel 32b, and select the length dimension and number of intermediate panels 31a to be arranged. By doing so, the common trapezoidal panels 32a and 32b can be used regardless of the length dimension of the parallelogram-shaped region R, so the trapezoidal panels 32a and 32b can be used as standard products (standard products exclusively for 2/3 slope). Manufacturable.
Of course, the slope of the second roof 2b is not limited to a 1/1 slope or a 2/3 slope.

According to the above embodiments and modifications, the following excellent effects can be achieved.
Since the first trapezoidal panel 32a and the second trapezoidal panel 32b, which are right-angled trapezoidal architectural panels, are arranged in a parallelogram-shaped region R where each corner is not a right angle, the parallelograms can be parallelized without using parallelogram-shaped architectural panels. The quadrilateral-shaped region R can be closed off, and the cost and labor for manufacturing the architectural panels arranged in the parallelogram-shaped region R can be reduced.

In addition to the first trapezoidal panel 32a and the second trapezoidal panel 32b, which are right-angled trapezoidal architectural panels, in the parallelogram-shaped region R where each corner is not a right angle, an intermediate panel 31a, which is a rectangular architectural panel, is provided. Since the parallelogram-shaped area R can be closed off without using parallelogram-shaped architectural panels, the cost for manufacturing the architectural panels to be placed in the parallelogram-shaped area R can be reduced. It can reduce the time and effort.
Note that the architectural panels arranged in the parallelogram-shaped region R are not limited to the parapet panels 30 (the first trapezoidal panel 32a, the second trapezoidal panel 32b, and the intermediate panel 31a), but are, for example, the roof panel 20. It may be the outer wall panel 40, the inner wall panel forming the inner wall of the building 1, or the floor panel forming the floor of the building 1.

Further, the roof panel 42 (specifically, the roof panel 42 provided on the upper end surface of the south rectangular panel 41a and the roof panel 42 provided on the upper end surface of the central rectangular panel 41b) has a parallelogram-shaped area. R, and supports the architectural panels (first trapezoidal panel 32a, second trapezoidal panel 32b, intermediate panel 31a) arranged in the parallelogram-shaped region R. Therefore, the roof panel 42 can be used in novel and unprecedented ways, such as forming a parallelogram-shaped region R and supporting other architectural panels.

In addition, the roof panel 42 (specifically, the roof panel 42 provided on the upper end surface of the central rectangular panel 41b), the rectangular architectural panel adjacent to the roof panel 42 (the north rectangular panel (the adjacent panel ) 41c) and form one acute-angled portion in the parallelogram-shaped region R, and the second trapezoidal panel 32b has the acute-angled portion of the second trapezoidal panel 32b fitted into the one acute-angled portion. It is located. Therefore, since the second trapezoidal panel 32b can be provided in a state that is wedged between the architectural panels arranged outside the parallelogram-shaped area R, the positioning of the second trapezoidal panel 32b, and even the first trapezoidal panel 32a and the intermediate The panel 31a can be easily positioned.
Furthermore, since the architectural panels (first trapezoidal panel 32a, second trapezoidal panel 32b, intermediate panel 31a) arranged in the parallelogram-shaped region R are provided on the upper end surface (slope) of the roof panel 42, However, since the north rectangular panel (adjacent panel) 41c functions as a non-slip for the second trapezoidal panel 32b, the position of the second trapezoidal panel 32b and the second trapezoidal panel 32b are prevented from slipping. Misalignment of the trapezoidal panel 32a and the intermediate panel 31a can be prevented.

Further, the third trapezoidal panel 32c is arranged such that the lower bottom surface of the third trapezoidal panel 32c is in contact with the rectangular panel 31, and the upper bottom surface of the third trapezoidal panel 32c is in contact with the slope of the first trapezoidal panel 32a. It is arranged between the trapezoidal panel 32a and the rectangular panel 31. That is, the third trapezoidal panel 32c in the shape of a right-angled trapezoid is used as an architectural panel that connects the parallelogram-shaped region R and the rectangular panel 31. Therefore, it is not necessary to change the first trapezoidal panel 32a and the second trapezoidal panel 32b depending on the height dimension of the rectangular panel 31, and it is only necessary to change the third trapezoidal panel 32c. The second trapezoidal panel 32b can be made versatile.
In addition, in this embodiment, the bottom surface of the third trapezoidal panel 32c is in contact with the rectangular panel 31 via the adjustment material 33, but it is not limited to this, and the bottom surface of the third trapezoidal panel 32c is It may be in direct contact with the rectangular panel 31.

Furthermore, the finishing material 3d is placed across the first trapezoidal panel 32a and an architectural panel (specifically, the third trapezoidal panel 32c) placed outside the parallelogram-shaped region R, and It is arranged astride the second trapezoidal panel 32b and an architectural panel arranged outside the parallelogram-shaped region R (specifically, the roof panel 42 provided on the upper end surface of the north rectangular panel 41c). . That is, the first trapezoidal panel 32a and the second trapezoidal panel 32b are connected by the finishing material 3d to a construction panel placed outside the parallelogram-shaped area R, so they are placed in the parallelogram-shaped area R. It is possible to enhance the sense of unity between the architectural panel and the architectural panel arranged outside the parallelogram-shaped region R.
Note that the connecting member that connects the first trapezoidal panel 32a and the third trapezoidal panel 32c head to head is not limited to the finishing material 3d such as Kasagi, but for example, a connecting member provided between these panels and the finishing material 3d. It may also be a base material etc.
Further, the connecting member that connects the second trapezoidal panel 32b and the roof panel 42 provided on the upper end surface of the north rectangular panel 41c by head-to-head connection is not limited to the finishing material 3d such as Kasagi. It may be a base material or the like provided between the panel and the finishing material 3d.

1 Building 2b Second roof (slope roof)
3c Third parapet wall (parapet wall)
3d Finishing material 31 Rectangular panel 31a Intermediate panel 32a First trapezoidal panel 32b Second trapezoidal panel 32c Third trapezoidal panel 41c North rectangular panel (adjacent panel)
42 Yakiri panel R Parallelogram-shaped area

Claims (5)

In buildings whose framework is composed of architectural panels,
It has an arrangement structure in which a first trapezoidal panel and a second trapezoidal panel, which are right-angled trapezoidal architectural panels, are arranged in a parallelogram-shaped area,
pitched roof and
a parapet wall that slopes along the pitched roof;
A roof panel, which is a construction panel disposed outside the parallelogram-shaped area and has an upper end surface sloping along the sloped roof,
The first trapezoidal panel and the second trapezoidal panel are
An architectural panel constituting the parapet wall,
The four end surfaces include an inclined surface, an upper bottom surface, a lower bottom surface, and an orthogonal surface that faces the inclined surface and is orthogonal to the upper and lower bottom surfaces, and is arranged with the orthogonal surfaces facing each other. and,
The acute angle portions of the first trapezoidal panel and the second trapezoidal panel correspond to one acute angle portion and the other acute angle portion in the parallelogram-shaped area, respectively, and
The obtuse angle portions of the first trapezoidal panel and the second trapezoidal panel are arranged on the upper end surface of the roof panel such that the obtuse angle portions of the first trapezoidal panel and the second trapezoidal panel correspond to one obtuse angle portion and the other obtuse angle portion of the parallelogram-shaped region, respectively. A building characterized by its presence. In the building according to claim 1,
In the parallelogram-shaped area, an intermediate panel that is a rectangular architectural panel can be placed between an orthogonal surface of the first trapezoidal panel and an orthogonal surface of the second trapezoidal panel. building . In the building according to claim 1 or 2 ,
An architectural panel arranged outside the parallelogram-shaped area, wherein the second trapezoidal panel is adjacent to the roof panel arranged on the upper end surface and is a rectangle in contact with the slope of the second trapezoidal panel. It features an adjacent panel that is an architectural panel in the shape of
The second trapezoidal panel has an acute angle portion fitted into a corner formed by the roof panel on which the second trapezoidal panel is disposed on the upper end surface and the adjacent panel. A building characterized by being located in a state. The building according to any one of claims 1 to 3 ,
a rectangular architectural panel that is a rectangular architectural panel that is arranged outside the parallelogram-shaped area;
a third trapezoidal panel that is a right-angled trapezoidal architectural panel that is arranged outside the parallelogram-shaped area;
The third trapezoidal panel is attached to the first trapezoidal panel with the lower bottom surface of the third trapezoidal panel in contact with the rectangular panel and the upper bottom surface of the third trapezoidal panel in contact with the slope of the first trapezoidal panel. and the rectangular panel. The building according to any one of claims 1 to 4 ,
A finishing material is provided at the upper end of the parapet wall,
The finishing material is
disposed astride the first trapezoidal panel and an architectural panel disposed outside the parallelogram-shaped area;
A building characterized in that the building is disposed astride the second trapezoidal panel and an architectural panel disposed outside the parallelogram-shaped area.

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