JP4792038B2 - Panel connector - Google Patents

Description

  The present invention relates to a technique for forming a three-dimensional structure by a plurality of panels.

A technique for forming a predetermined three-dimensional structure by preparing a plurality of panels formed in a predetermined contour shape in advance and connecting the plurality of panels via corresponding sides is developed. . According to this technique, the three-dimensional structure can be transported in a state of being divided into a plurality of panels, and the three-dimensional structure can be formed by a relatively simple operation.
Patent Document 1 describes a technique for forming a spherical shell three-dimensional structure using a plurality of hexagonal panels. In this technique, a plurality of hexagonal panels are connected in advance to simplify the work of forming a three-dimensional structure. At this time, by connecting a plurality of hexagonal panels in series, it is possible to fold a plurality of hexagonal panels alternately while facing the front and front surfaces or the back and back surfaces of the hexagonal panels. The volume required to store the hexagonal panel is reduced.
JP 2001-116187 A

According to the technique of Patent Document 1, in a panel assembly in which a plurality of panels are coupled in series, sides and sides to be connected when forming a three-dimensional structure are variously positioned. When forming a three-dimensional structure, it is necessary to connect the corresponding sides while specifying the corresponding sides one by one, which complicates complicated operations.
The present invention solves the above problems. The present invention provides a technique for simplifying the operation of forming a three-dimensional structure with a plurality of panels.

The technology of the present invention provides a new and useful panel connector. In this panel connection body, a plurality of three or more polygon panels are connected in series via sides. Adjacent panels are connected so as to be swingable about the connecting side. When this panel coupling body is connected in order from the predetermined vertex to the side extending in one direction along the extension of the panel coupling body and the side extending from the predetermined vertex to the other direction along the extension of the panel coupling body In addition, a predetermined three-dimensional structure is formed.
Here, the panels connected in series means that the panels are sequentially connected one by one from the panel positioned at one end to the panel positioned at the other end. It means that it is prohibited to connect a plurality of three or more panels to one panel, and two panels are connected to one panel except for the panels located at both ends.

According to this panel coupling body, the side connected in one direction along the outer extension of the panel coupling body from the predetermined vertex and the side continuous in the other direction along the outer extension of the panel coupling body from the predetermined vertex are connected in order. By this, a three-dimensional structure can be formed. When assembling the panel connection body into the three-dimensional structure, the sides to be connected can be easily found, so that the work of forming the three-dimensional structure is simplified.
In this panel connection body, since the plurality of polygon panels are connected in series, the plurality of polygon panels can be alternately folded while the front surface and the front surface or the back surface and the back surface of the polygon panel face each other. Thereby, the volume required to accommodate the panel connector can be suppressed.
By using this panel coupling body, it is possible to simplify the operation of forming a three-dimensional structure with a plurality of panels.

In the above-mentioned panel connection body, when the plurality of polygonal panels are triangular panels whose outline shape is a triangle, when a predetermined three-dimensional structure is formed, the triangular structure has five or more apexes in the three-dimensional structure. Preferably it is formed.
Thereby, it becomes possible to form a polyhedron shape that approximates a curved surface with a large radius of curvature. For example, a panel connection body that forms a dome-shaped three-dimensional structure, a panel connection body that forms a parabolic antenna-shaped three-dimensional structure, etc. Can be realized.

Furthermore, when the contour shape of the triangular panel is an isosceles triangle having different apex and base angles, the triangle in the three-dimensional structure has five or six vertices when the predetermined three-dimensional structure is formed. The apex formed by the five panels gathers the larger of the apex and base angles of the triangular panel, and the apex formed by the six panels has the apex formed by the five panels. It is preferable that the smaller one of the apex angle and the base angle is gathered.
Thereby, it is possible to realize a panel connection body that accurately forms a dome shape, a parabolic antenna shape, or the like.

In the above-mentioned panel coupling body, the side that continues in one direction along the outer extension of the panel coupling body from the predetermined vertex and the side that continues in the other direction along the outer extension of the panel coupling body are sequentially connected from the predetermined vertex It is preferable that a connecting means is added.
Thereby, it is possible to easily form a three-dimensional structure without mistaken sides to be connected.

In the panel connector, it is preferable that at least one connection side can be separated / connected.
Thereby, when a panel coupling body is provided with many polygon panels, for example, it can be divided into a plurality of panel coupling bodies as needed. A large number of polygonal panels can be divided and handled, and the work of transporting the panel connection body and the work of forming the three-dimensional structure can be facilitated.

The figure which shows a mode that the panel coupling body of Example 1 was expand | deployed on the substantially plane. The figure which shows the three-dimensional structure which the panel coupling body of Example 1 forms. The figure which shows the connection part of a polygon panel. The figure which shows the state by which the polygon panel was folded. The figure which shows the state by which the panel coupling body of Example 1 was folded. The figure which shows the panel coupling body which can be isolate | separated / connected. The figure which shows a mode that the panel coupling body of Example 2 was expand | deployed on the substantially plane. The figure which shows the three-dimensional structure which the panel coupling body of Example 2 forms. The figure which shows the state by which the panel coupling body of Example 2 was folded. The figure which shows a mode that the panel coupling body of Example 3 was expand | deployed on the substantially plane. The figure which shows the three-dimensional structure which the panel coupling body of Example 3 forms. The figure which shows the state by which the panel coupling body of Example 3 was folded. The figure which shows a mode that the panel coupling body of Example 4 was expand | deployed on the substantially plane. The figure which shows the three-dimensional structure which the panel coupling body of Example 4 forms. The figure which shows the state by which the panel coupling body of Example 4 was folded. The figure which shows a mode that the panel coupling body of Example 5 was expand | deployed on the substantially plane. The figure which shows the three-dimensional structure which the panel coupling body of Example 5 forms. The figure which shows the state by which the panel coupling body of Example 5 was folded. The figure which shows a mode that the panel coupling body of Example 6 was expand | deployed on the substantially plane. The figure which shows the three-dimensional structure which the panel coupling body of Example 6 forms. The figure which shows the state by which the panel coupling body of Example 6 was folded.

Explanation of symbols

40, 50, 60, 70, 80, 90, 100 .. panel connector

First, the main features of the embodiments described below are listed.
(Mode 1) The polygon panel has a predetermined rigidity.
(Form 2) A hole is formed in the polygonal panel.
(Form 3) The polygon panel of the panel coupling body has an isosceles triangular contour shape. The vertex angle of the isosceles triangle is larger than 60 degrees, and the base angle of the isosceles triangle is smaller than 60 degrees. The panel connecting body forms one vertex when the apex angles of the five triangular panels are gathered, and forms one vertex when the base angles of the six triangular panels are gathered to form a three-dimensional structure. Form things.
(Embodiment 4) As the panel connection body, a polygon panel constituted by an outer frame frame or a polygon in which a membrane material is stretched on a skeleton frame can be used.
(Form 5) The panel coupling body is provided with the fastener. The fastener includes a pair of rails and a slider. One of the pair of rails is provided along a side continuous in one direction from the predetermined apex along the outer extension of the panel coupling body. The other of the pair of rails is provided along a side continuous in the other direction from the predetermined vertex along the outer extension of the panel coupling body. The slider connects a pair of rails when operated in a direction away from the predetermined vertex along the pair of rails, and a pair of sliders when operated in a direction toward the predetermined vertex along the pair of rails. Separate the rails.

Example 1
A panel body of Example 1 embodying the present invention will be described with reference to the drawings. FIG. 1 shows a state in which the panel connector 40 of the present embodiment is developed on a substantially flat surface. As shown in FIG. 1, the panel coupling body 40 includes 32 polygonal panels 1 to 32 having a triangular contour shape. Among the polygon panels 1 to 32, the polygon panels 1 to 21 and the polygon panels 24 to 30 have the same shape, and are isosceles triangles having a base to height ratio of approximately 4: 3. This isosceles triangle is different from the regular triangle in that the apex angle and the base angle are different. The apex angle is greater than 60 degrees and the two base angles are less than 60 degrees. The shapes of the polygon panels 22, 23, 31, 32 are half the shapes of the polygon panels 1-21, 24-30.
In the panel coupling body 40, the 32 polygonal panels 1-32 are connected in series via sides. That is, in the panel connection body 40, two or more polygon panels are not connected to one polygon panel, but two panels are included in one panel except for the polygon panels 1 and 32 located at both ends. Are connected. Adjacent panels are connected so as to be swingable about the connecting side. As shown in FIG. 1, for example, the polygon panel 16 and the polygon panel 17 are connected so as to be swingable about a connecting side 35.
Each of the polygon panels 1 to 32 has a predetermined rigidity. The material and configuration of the polygon panels 1 to 32 are not particularly limited. For example, wood, a metal material, a resin material, or the like can be used as the material for the polygon panels 1 to 32. Moreover, it is good also as a structure which coat | covers the plate-shaped material used as a core material with a film | membrane material etc. For example, when the core material is formed of a foamable resin, a lightweight panel having excellent heat insulation can be configured.

  As shown in FIG. 1, in the panel connector 40, a side continuous in one direction from the reference vertex P along the extension of the panel connector 40 (along the arrow L <b> 1 in FIG. 1), and a reference vertex A side continuous from P to the other direction along the extension of the panel coupling body 40 (along arrow L2 in FIG. 1) can be connected. Arrows a to m in FIG. 1 indicate connectable sides and combinations of sides. The panel connection body 40 forms a three-dimensional structure by sequentially connecting a side continuous from the vertex P along the one direction L1 and a side continuous from the vertex P along the other direction L2.

FIG. 2 shows a three-dimensional structure formed by the panel connector 40. As shown in FIG. 2, when the connectable sides and sets of sides a to m are connected, the polygonal panels 1 to 32 are positioned without gaps along the substantially hemispherical surface, so that a substantially circular opening. 42 and a dome shape having an internal space. In the three-dimensional structure formed by the panel connection body 40, each vertex is formed by five or more polygonal panels 1 to 32. Specifically, each vertex is formed by five or six polygon panels 1-32. More specifically, the apexes formed by the five polygon panels 1 to 32 are the apex angles of the polygon panels 1 to 32 that are isosceles triangles, and the apexes formed by the six panels are Are gathered at the base angles of the polygon panels 1 to 32 which are isosceles triangles. As shown in FIG. 2, for example, apex A formed by five polygon panels 10, 11, 26, 27, 28 has each apex angle of the polygon panels 10, 11, 26, 27, 28 (see FIG. 2). Corners with white circles inside) are gathered. In addition, the vertex B formed by the six polygon panels 11, 12, 13, 28, 29, 30 has base angles (in the figure) of the polygon panels 11, 12, 13, 28, 29, 30. Corners with black circles) are gathered. Here, each vertex angle of the polygon panels 1-32 is larger than 60 degrees, and each base angle of the polygon panels 1-32 is larger than 60 degrees.
When the polygon panels 1 to 32 have a triangular contour shape, one vertex is formed by the polygon panels 1 to 32 having 5 or more, thereby approximating a curved surface having a relatively large radius of curvature. A polyhedral shape can be formed. Accordingly, it is possible to realize a panel coupling body that forms a dome shape, a panel coupling body that forms a parabolic antenna shape, and the like. Furthermore, the apex angles or base angles of the polygonal panels 1 to 32 that are isosceles triangles are gathered at each apex to realize a panel connection body that accurately forms a dome shape, a parabolic antenna shape, etc. It becomes possible to do.
In addition, the vertex in the three-dimensional structure referred to here does not include a corner (for example, corner C) located in the opening 42.
For the connection between the sides of the panel connector 40, for example, a fastening component such as a bolt can be used. Alternatively, from the reference vertex P along the extension of the panel connection body 40 in one direction (along arrow L1 in FIG. 1) and the reference vertex P along the extension of the panel connection body 40 A fastener, Velcro (registered trademark), or the like may be provided in advance on each of the continuous sides in the other direction (along arrow L2 in FIG. 1).

FIG. 3 is a cross-sectional view taken along line III in FIG. 2 and shows a configuration in the vicinity of the connection side in the panel connection body 40. As illustrated in FIG. 3, in the panel connector 40, the polygon panels are connected to each other by a hinge-type connector 37 so as to be swingable. As shown in FIG. 3, the polygon panels 1 to 32 have a predetermined thickness, and each side of the polygon panels 1 to 32 becomes a surface having a spread in the thickness direction. Therefore, if the side surfaces of the polygon panels 1 to 32 are tapered, the polygon panels come into contact with each other through the surface when the three-dimensional structure is formed, and the rigidity of the three-dimensional structure can be increased. . The angle of the taper provided on the side surface of the polygon panel can be determined based on the angle formed between the polygon panels when the three-dimensional structure is formed.
The connectors 37 are alternately arranged on the front and back of the panel connector 40. For example, the connection tool 37 that connects the polygon panel 1 and the polygon panel 2 is provided on the surface 1s, 2s side of the polygon panels 1, 2. Thereby, the polygon panel 1 and the polygon panel 2 can be folded so that the surface 1s of the polygon panel 1 and the surface 2s of the polygon panel 2 face each other. Further, the coupler 37 that connects the polygon panel 2 and the polygon panel 3 is provided on the back surfaces 2t and 2t of the polygon panels 2 and 3. Thereby, the polygon panel 2 and the polygon panel 3 can be folded so that the back surface 2t of the polygon panel 2 and the back surface 3t of the polygon panel 3 face each other.
FIG. 4 shows a state in which the polygon panels 1, 2, 3,. As shown in FIG. 4, in a state where the polygon panels 1, 2, 3,... Are folded, the surface 1s of the polygon panel 1 and the surface 2s of the polygon panel 2 face each other. Further, the back surface 2t of the polygon panel 2 and the back surface 3t of the polygon panel 3 face each other. The other polygon panels 4 to 32 can be folded in the same manner. In the panel coupling body 40, since the polygon panels 1-32 are connected in series, the polygon panels 1-32 are alternately folded while facing the front surface and the front surface or the back surface of the adjacent polygon panel. Is possible.
FIG. 5 shows an overall image of the panel coupling body 40 in a folded state. As shown in FIG. 5, the panel coupling body 40 can have a triangular prism shape in the same manner as when the polygon panels 1 to 32 are overlapped while the polygon panels 1 to 32 are connected in series. .

Since the panel coupling body 40 can be folded so that the polygon panels 1 to 32 overlap in order, the volume required for storage can be kept relatively small. Thereby, conveyance etc. can be performed easily. On the other hand, when the three-dimensional structure is formed by the panel connector 40, a side continuous from the reference vertex P in one direction along the extension of the panel connector 40 (along the arrow L1 in FIG. 1), A three-dimensional structure can be formed by sequentially connecting the reference vertex P to the other side (along arrow L2 in FIG. 1) along the outer extension of the panel connection body 40 in the other direction. Thereby, the operation | work which forms a three-dimensional structure can be performed easily.
The panel coupling body 40 can be applied to a three-dimensional structure used in the outdoors, underwater, outer space, or the like, for example, by appropriately selecting the size and the material to be used.

In the panel coupling body 40, at least one of the coupling sides that couple the polygon panels 1 to 32 may be configured to be separable / coupled. As shown in FIG. 6, for example, by providing a separable / connectable connection tool 39 between the polygon panel 16 and the polygon panel 17, the connection side 35 that connects the polygon panel 16 and the polygon panel 17 is separated. / Can be connectable. Thereby, it becomes possible to divide and handle the panel coupling body 40 into a plurality of panel coupling bodies, and it becomes easier to carry the panel coupling body 40 and to form a three-dimensional structure.
As shown in FIG. 6, the polygon panel used for the panel coupling body 40 is a polygon panel 27a composed only of the outer frame frame 27b or a polygon panel 28a obtained by stretching a membrane material 28c on the skeleton frame 28b. You can also.

(Example 2)
The panel coupling body 50 of Example 2 which implemented this invention is demonstrated referring drawings. FIG. 7 shows a state in which the panel connector 50 of this embodiment is developed on a substantially flat surface. As shown in FIG. 7, the panel connector 50 includes six polygon panels 51 to 56 having a rectangular outline shape. In the panel coupling body 50, the six polygon panels 51-56 are connected in series via sides.
Each of the polygon panels 51 to 56 has a predetermined rigidity. Polygon panels 51-56 are made of a material having heat insulation properties. Specifically, a plate-like member formed of a foamable resin is covered with a synthetic fiber cloth.

As shown in FIG. 7, in the panel connection body 50, a side continuous in one direction along the extension of the panel connection body 50 from the reference vertex P (along the arrow L <b> 1 in FIG. 7), and the reference vertex Sides that continue from P to the other direction along the extension of the panel coupling body 50 (along arrow L2 in FIG. 7) can be connected in order. Arrows a to g in FIG. 7 indicate combinations of sides that can be connected. The panel connection body 50 forms a three-dimensional structure by sequentially connecting a side continuous from the vertex P in the one direction L1 and a side continuous from the vertex P in the other direction L2.
In the panel coupling body 50, a fastener including a first rail 61, a second rail 62, and a slider 63 is provided. The first rail 61 is provided along a side extending from the apex P in one direction along the outer extension of the panel coupling body 50 (arrow L1 in FIG. 7). The second rail 62 is provided along the side extending from the apex P along the outer extension of the panel connector 50 in the other direction (arrow L2 in FIG. 7). When the slider 63 is operated in a direction away from the apex P along the first rail 61 and the second rail 62 in a state where the first rail 61 and the second rail 62 are substantially parallel to each other, The second rail 62 is connected. Further, when the slider 63 is operated along the first rail 61 and the second rail 62 in a direction approaching the vertex P, the slider 63 separates the first rail 61 and the second rail 62. In the panel coupling body 50, by connecting the slider 63, the connectable sides and side pairs a to f can be connected in order. Further, by operating the slider 63 in the reverse direction, the connectable sides and sets of sides ag can be separated in the reverse order. In the panel coupling body 50, the polygon panels 50 to 56 are connected by the series of fasteners 61, 62, and 63, so that the polygon panels 50 to 56 are connected without a gap.

FIG. 8 shows a three-dimensional structure formed by the panel connector 50. As shown in FIG. 8, the polygon panels 51-56 of the panel coupling body 50 can form a rectangular parallelepiped shape that seals the internal space. The polygon panel 56 located on the upper surface functions as a lid that can be opened and closed by operating the slider 63. Since the polygon panels 51 to 56 have heat insulation properties, the three-dimensional structure formed by the panel connector 50 can reduce the temperature change of the article accommodated in the internal space. The three-dimensional structure formed by the panel coupling body 50 can be used as a heat insulation (cold insulation).
FIG. 9 shows a state in which the panel connector 50 is folded. In the panel coupling body 50, since the polygon panels 51-56 are connected in series, the polygon panels 51-56 are alternately folded while the front surface and the front surface or the back surface and the back surface of the polygon panels 51-56 are opposed to each other. It is possible. As shown in FIG. 9, the panel connector 50 can be folded into a form in which the polygon panels 51 to 56 are superimposed, and the volume required for storage is suppressed to be relatively small.

(Example 3)
The panel coupling body 70 of Example 3 which implemented this invention is demonstrated referring drawings. FIG. 10 shows a state in which the panel connector 70 of the present embodiment is developed on a substantially flat surface. As shown in FIG. 10, the panel connector 70 includes nine polygon panels 71 to 79. In the panel coupling body 70, nine polygon panels 71 to 79 are coupled in series via sides. Each of the polygon panels 71 to 79 has a predetermined rigidity. Moreover, the polygon panels 71-79 have water resistance.

  As shown in FIG. 10, in the panel connector 70, a side continuous in one direction along the extension of the panel connector 70 from the reference vertex P (along the arrow L <b> 1 in FIG. 10), and the reference vertex Sides that are continuous from P to the other direction along the extension of the panel coupling body 70 (along arrow L2 in FIG. 10) can be connected in order. Arrows a to f in FIG. 10 indicate combinations of sides that can be connected. The panel connection body 70 forms a three-dimensional structure by sequentially connecting a side continuous from the vertex P in the one direction L1 and a side continuous from the vertex P in the other direction L2.

FIG. 11 shows a three-dimensional structure formed by the panel connector 70. As shown in FIG. 11, the polygonal panels 71-79 of the panel coupling body 70 can form a ship shape. Since the polygon panels 71-79 have water resistance, the three-dimensional structure which the panel coupling body 70 forms can be utilized as a ship by connecting the polygon panels 71-79 liquid-tightly.
FIG. 12 shows a state in which the panel coupling body 70 is folded. Since the polygon panels 71 to 79 are connected in series in the panel connector 70, the polygon panels 71 to 79 are alternately folded while the front surfaces and the front surfaces or the back surfaces and the back surfaces of the polygon panels 71 to 79 are opposed to each other. It is possible. As shown in FIG. 12, the panel coupling body 70 can be folded into a form in which the polygonal panels 71 to 79 are superimposed, and the volume required for housing is suppressed to be relatively small.

Example 4
The panel coupling body 80 of Example 4 which implemented this invention is demonstrated referring drawings. FIG. 13 shows a state in which the panel connector 80 of the present embodiment is developed on a substantially flat surface. As shown in FIG. 13, the panel connector 80 includes six polygonal panels 81 to 86. In the panel coupling body 80, the six polygon panels 81-86 are connected in series via sides. Each of the polygon panels 81-86 has predetermined rigidity. The polygonal panel 81 has a hole 81x.

  As shown in FIG. 13, in the panel connection body 80, a side that is continuous in one direction along the extension of the panel connection body 80 from the reference vertex P (along the arrow L <b> 1 in FIG. 13), and the reference vertex Sides that continue from P to the other direction along the extension of the panel coupling body 80 (along arrow L2 in FIG. 13) can be connected in order. Arrows a to f in FIG. 13 indicate combinations of sides that can be connected. The panel connection body 80 can form a three-dimensional structure by sequentially connecting a side continuous from the apex P in the one direction L1 and a side continuous from the apex P in the other direction L2.

FIG. 14 shows a three-dimensional structure formed by the panel connector 80. As shown in FIG. 14, the polygon panels 81-89 of the panel coupling body 80 can form the three-dimensional structure of the shape imitating a house. The three-dimensional structure formed by the panel connector 80 can be used as a hut used by small animals such as dogs.
FIG. 15 shows a state in which the panel coupling body 80 is folded. In the panel coupling body 80, since the polygon panels 81-86 are connected in series, the polygon panels 81-86 are alternately folded, making the front surface and front surface or back surface, and back surface of the polygon panels 81-86 face each other. It is possible. As shown in FIG. 15, the panel connector 80 can be folded into a form in which the polygon panels 81 to 86 are overlapped, and the volume required for storage is suppressed to be relatively small.

(Example 5)
The panel coupling body 90 of Example 5 which implemented this invention is demonstrated referring drawings. FIG. 16 shows a state in which the panel connector 90 of the present embodiment is developed on a substantially flat surface. As shown in FIG. 16, the panel connector 90 includes seven polygonal panels 91 to 97. In the panel connection body 90, the seven polygon panels 91-97 are connected in series via the sides. Each of the polygon panels 91 to 97 has a predetermined rigidity. Each of the polygon panels 91 to 97 is coated with a light reflective paint.

  As shown in FIG. 16, in the panel connection body 90, a side that is continuous in one direction along the extension of the panel connection body 90 from the reference vertex P (along the arrow L <b> 1 in FIG. 16) and the reference vertex Sides that extend from P to the other direction along the extension of the panel coupling body 90 (along arrow L2 in FIG. 16) can be connected in order. Arrows a to f in FIG. 16 indicate combinations of sides that can be connected. The panel connection body 90 forms a three-dimensional structure by sequentially connecting a side continuous from the vertex P in the one direction L1 and a side continuous from the vertex P in the other direction L2.

FIG. 17 shows a three-dimensional structure formed by the panel connector 90. As shown in FIG. 17, the polygon panels 91-97 of the panel coupling body 90 can form a triangular pyramid-shaped three-dimensional structure. Since the light reflecting paint is applied to the polygonal panels 91 to 97, the three-dimensional structure formed by the panel coupling body 90 can be used as a triangular cone at a construction site, for example.
FIG. 18 shows a state in which the panel coupling body 90 is folded. Since the polygon panels 91 to 97 are connected in series in the panel connection body 90, the polygon panels 91 to 97 are alternately folded while the front surface and the front surface or the back surface and the back surface of the polygon panels 91 to 97 are opposed to each other. It is possible. As shown in FIG. 18, the panel coupling body 90 can be folded into a form in which the polygonal panels 91 to 97 are overlapped, and the volume required for storage is suppressed to be relatively small.

(Example 6)
The panel coupling body 100 of Example 6 which implemented this invention is demonstrated referring drawings. FIG. 19 shows a state where the panel connector 100 of the present embodiment is developed on a substantially flat surface. As shown in FIG. 19, the panel connector 100 includes 32 polygonal panels 101 to 132. Among the polygonal panels 101 to 132, the 12 polygonal panels 101, 107, 109, 111, 113, 115, 118, 120, 122, 124, 126, and 132 have a regular pentagonal outline shape. Yes. In addition, the 20 polygon panels 102, 103, 104, 105, 106, 108, 110, 112, 114, 116, 117, 119, 121, 123, 125, 127, 128, 129, 130, 131 are regular six. It has a square outline shape.
In the panel coupling body 100, the 32 polygonal panels 101-132 are connected in series via sides. Each of the polygon panels 101 to 132 has a predetermined rigidity.

  As shown in FIG. 19, in the panel connector 100, a side continuous in one direction along the extension of the panel connector 100 from the reference vertex P (along the arrow L <b> 1 in FIG. 19) and the reference vertex Sides that continue from P to the other direction along the extension of the panel coupling body 100 (along arrow L2 in FIG. 19) can be connected in order. The panel coupling body 100 forms a three-dimensional structure by sequentially connecting a side continuous from the vertex P in the one direction L1 and a side continuous from the vertex P in the other direction L2.

FIG. 20 shows a three-dimensional structure formed by the panel connector 100. As shown in FIG. 20, the sides that are continuous from the vertex P in the one direction L1 and the sides that are continuous from the vertex P in the other direction L2 are connected in order, so that the polygon panels 101 to 132 have a substantially spherical surface with no gap. Therefore, it is possible to form a substantially spherical shape having an internal space. That is, a spherical shape having no opening can be formed.
In the three-dimensional structure formed by the panel connector 100, each vertex is formed by three polygonal panels 101-132. More specifically, each vertex is formed by two regular hexagonal polygon panels and one pentagonal polygon panel. As a result, it is possible to form a polyhedron shape that approximates a curved surface having a large curvature radius. It is possible to realize a panel connection body that forms a dome shape, a parabolic antenna shape, or the like.
FIG. 21 shows a state in which the panel connector 100 is folded. In the panel coupling body 100, since the polygon panels 101-132 are connected in series, the polygon panels 101-132 are alternately folded while facing the front surface and the front surface or the back surface and the back surface of the polygon panels 101-132. It is possible. As shown in FIG. 21, the panel coupling body 100 can be folded into a form in which the polygon panels 101 to 132 are superimposed, and the volume required for storage can be kept relatively small.

As mentioned above, although embodiment of this invention was described in detail, these are only illustrations and do not limit a claim. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.
The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. The technology illustrated in this specification or the drawings achieves a plurality of objects at the same time, and achieving one of the objects itself has technical utility.

Claims (5)

A panel connection body in which a plurality of triangular panels are connected in series via sides,
Adjacent triangular panels are connected so as to be swingable around the connecting side as an axis,
At least nine triangular panels connected from one end have a shape of an isosceles triangle having a base to height ratio of about 4: 3 and a base angle smaller than the top angle.
A plurality of sides extending in one direction from the predetermined apex along the outer extension of the panel connection body, and a plurality of sides extending in the other direction along the outer extension of the panel connection body from the predetermined apex are sequentially from the predetermined apex side. A predetermined three-dimensional structure is formed by being connected,
Its predetermined each vertex formed in three-dimensional structure, Ri Atsuma the base angle of five triangular panels apex angle or six triangular panels,
Wherein the predetermined apex, the panel connecting member, characterized in Rukoto base angle of six triangular panels continuous from said one end Atsuma. The 21 triangular panels connected from the one end have the shape of the isosceles triangle, the two triangular panels connected from the 21 triangular panels have a half shape of the isosceles triangle, and the two 7. The seven triangular panels connected from the triangular panel have the shape of the isosceles triangle, and the two triangular panels connected from the seven triangular panels have a half shape of the isosceles triangle. Item 10. The panel connector according to Item 1 . A plurality of sides extending in one direction from the predetermined vertex along the outer extension of the panel connection body, and a plurality of sides extending from the predetermined vertex in the other direction along the outer extension of the panel connection body from the predetermined vertex side. 3. The panel coupling body according to claim 1, further comprising connecting means for connecting in order. Connecting sides of at least one place, the panel connecting member according to claim 1 or 2, characterized in that has a splitting / connectable. A panel connection body in which a plurality of triangular panels are connected in series via sides,
Adjacent triangular panels are connected so as to be swingable around the connecting side as an axis,
At least nine triangular panels connected from one end have a shape of an isosceles triangle having a base to height ratio of about 4: 3 and a base angle smaller than the top angle.
A plurality of sides extending in one direction from the predetermined apex along the outer extension of the panel connection body, and a plurality of sides extending in the other direction along the outer extension of the panel connection body from the predetermined apex are sequentially from the predetermined apex side. A predetermined three-dimensional structure is formed by being connected,
At each vertex formed in the predetermined three-dimensional structure, the apex angle of five triangular panels or the base angle of six triangular panels gathers,
At least one connecting edge is separable / connectable.

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