KR101237900B1 - Hub connector for geodesic dome-shaped house and geodesic dome-shaped house having the same - Google Patents

Abstract

PURPOSE: A hub connector for constructing a geodesic dome house and the geodesic dome house using the same is provided to manufacture a hub connector with a simple and efficient structure, and to improve construction efficiency by smoothly controlling the angles of square lumbers coupled to the circumference of the hub connector. CONSTITUTION: A hub connector(100) for constructing a geodesic dome house and the geodesic dome house using the same includes a connector body plate(110), multiple guide brackets(120), and multiple square lumber coupling modules(130). The connector body plate has a polygonal structure. The guide brackets are respectively coupled to the circumference surface of the connector body plate. One side of the square lumber coupling modules is coupled to a square lumber, and the other side is rotatably hinged to the guide bracket.

Description

Hub connector for geodesic dome-shaped house and geodesic dome-shaped house having the same}

The present invention relates to a geodesic dome house construction hub connector and a geodesic dome house having the same, and more particularly, can be manufactured in a simple and efficient structure, as well as smoothly adjusting the angle of the angles coupled along the circumference The present invention relates to a geodesic dome house construction hub connector capable of improving construction efficiency and to a geodesic dome house having the same.

A soccer ball looks like a sphere, but in fact it is a pentagonal and regular hexagonal leather. If it is not blown up by wind, it must be polyhedron.

Since the face is made up of two polygons, it is not a regular polyhedron but can be made from an icosahedron.

Learn how to make a soccer ball. First, divide each corner of the icosahedron into three and cut it around each vertex.

Then, five vertices are gathered at each vertex, and as many as 12 vertex faces are created, and the original 20 equilateral triangle faces are regular hexagons.

This is 60 vertices and 90 corners, i.e. a truncated icosahedron. If you make these polyhedrons and inflate them into leather, you can make a soccer ball.

As described above, a polyhedron consisting of two or more regular polygonal faces and inscribed in a sphere is called a quasi-polyhedron or Archimedes' solid figure. A truncated icosahedron is one of 13 quasi-polyhedra.

The geodesic dome also departs from the icosahedron. Divide the large equilateral triangle into equilateral triangles on each side, then inscribe it into the sphere and project each vertex onto the sphere.

Then all sides are almost the same, almost equilateral, and more like a sphere, a polyhedron, which is the structure of the geodesic dome.

The geodesic dome-shaped house is a structure that uses such a geodesic dome as a roof.

Since geodesic dome houses do not require walls or pillars in dome-type architecture, they can be designed freely in the interior, light natural light, and even see the sky from the inside.

On the other hand, when constructing a geodesic dome house, a plurality of hub connectors are used.

Hub connectors are used to connect the neighboring ones to each corner of the geodesic dome house, which is located at each vertex area of the geodesic dome house. Geodesic dome houses can be constructed as the panels are coupled to the hub connectors and the panels are coupled to the surfaces formed between the panels.

Such a hub connector has been widely used for the construction of geodesic dome houses since ancient times. In the case of the hub connector known to date, it is impossible to adjust the angle or only adjust a predetermined angle of about 90 degrees. Therefore, since the construction efficiency of the geodesic dome house may be lowered, a structural improvement is required.

Korean Patent Office Application No. 10-2000-0017361 Korea Patent Office Application No. 10-2008-0048180 Korean Patent Office Application No. 10-2009-0026999 Korean Patent Office Application No. 20-2000-0033153

It is an object of the present invention, a geodesic dome house construction hub connector and geodesic dome provided with the same that can be manufactured in a simple yet efficient structure, as well as smooth angle adjustment of the angles coupled along the circumference to improve construction efficiency To provide a house.

Geodesic dome house construction hub connector of the present invention is a connector body plate 110 having a polygonal structure; A plurality of guide brackets 120 individually coupled to each outer surface of the connector body plate 110; And a plurality of angler coupling modules 130 coupled to one side of the angler A, the other side of which is hinged rotatably to each of the guide brackets 120.

The guide bracket 120 may include a first fixing part 121 fixed to one side of the connector body plate 110; A second fixing part 122 formed at a position spaced apart from the first fixing part 121 and fixed to the other side of the connector body plate 110; A linear extension part 123 extending along the thickness direction of the connector body plate 110 from the first fixing part 121; An arc connecting part 124 connecting the linear extension part 123 and the second fixing part 122 in an arc shape; And a first hinge portion 125 provided on the first fixing portion 121.

The shell material coupling module 130, the shell material clamp 131 is clamped in a state that the shell material (A) is partially fitted; A second hinge portion 132 which is formed to extend from one side of the angle clamp 131 and is hinged to the first hinge portion 125 of the guide bracket 120; And a guide bridge 133 extending in the form of an arc from the other side of the angular clamp 131 and overlapping the arc connecting portion 124 of the guide bracket 120 and being guided by the arc connecting portion 124. It is preferable to include;

The guide bridge 133 is preferably formed such that its width is gradually narrowed toward the tip portion.

The pair of pairs are spaced apart from each other in the lengthwise direction of the guide bridge 133, and the arc of the guide bracket 120 is adjusted when the angle of the angler coupling module 130 is first adjusted with respect to the guide bracket 120. A plurality of first long holes 133a are formed in the plurality of first bolt holes 124a formed at the connecting portion 124 to be fastened by the bolts B1, and the pair of first pairs of holes are formed in the guide bridge 133. When the long hole 133a is disposed along the length direction of the guide bridge 133, and the angle of the horn member coupling module 130 with respect to the guide bracket 120 is adjusted to be more than the first degree. Preferably, a single second long hole 133b for fastening with the bolt B2 is formed in the plurality of second bolt holes 124b formed in the arc connecting portion 124 of the guide bracket 120.

In the central region of the body plate 110, a through hole 111 for selectively exposing the tip portion of the guide bridge 133 is further formed, and the connector body plate 110 is preferably hexagonal or pentagonal.

Geodesic dome house of the present invention has a geodesic dome house construction hub connector (100,200) of the above structure.

According to the present invention, it is possible to produce a simple yet efficient structure, as well as to smoothly adjust the angle of the angles coupled along the circumference has the effect of improving the construction efficiency.

In addition, according to the present invention, since the angle of the angle coupled to the circumference of the hub connector can be adjusted freely from 0 degrees to 90 degrees, the construction work is convenient, there is an effect that can shorten the air.

1 is a schematic structural diagram of a geodesic dome house according to an embodiment of the present invention.
2 is a front view of a state in which the shell material is coupled to the geodesic dome house construction hub connector according to an embodiment of the present invention.
3 is a perspective view of the geodesic dome house construction hub connector shown in FIG.
4 is a partially exploded perspective view of FIG. 3.
5A is an enlarged view illustrating main parts of FIG. 4.
FIG. 5B is a rear perspective view of the guide bracket shown in FIG. 5A.
6 is a rear perspective view of FIG. 3.
FIG. 7 is a perspective view of the angle coupling module rotated in FIG. 3.
8 is a rear perspective view of FIG. 7.
9 is a front view of a state in which the shell material is coupled to the geodesic dome house construction hub connector according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a schematic structural diagram of a geodesic dome house according to an embodiment of the present invention.

1 is a geodesic dome house whose roof has a geodesic dome structure.

Since geodesic dome houses do not require walls or pillars in dome-type architecture, they can be designed freely in the interior, light natural light, and even see the sky from the inside.

When the geodesic dome house construction, geodesic dome house construction hub connector (100,200) of the present embodiment is applied. Therefore, the geodesic dome house shown in FIG. 1 should also belong to the scope of the present invention.

2 to 8 is a view of the geodesic dome house construction hub connector 100 in which the connector body plate 110 is a hexagonal structure so that each of the guide bracket 120 and each of the lumber coupling module 130 are used six by one. to be.

9 is a diagram of a geodesic dome house construction hub connector 200 in which the connector body plate 210 has a pentagonal structure so that the guide bracket 120 and the lumber coupling module 130 are each used five.

In order to construct a geodesic dome house as shown in Figure 1, such a hexagonal and pentagonal geodesic dome house construction hub connector (100,200) should be used properly.

In the case of the geodesic dome house construction hub connectors 100 and 200, as described above, the connector body plates 110 and 210 are different from each other in the hexagonal structure or the pentagonal structure, and all of the roles are the same.

In the case of FIG. 1, since the geodesic dome house is completed, the exterior surface of the roof is plastered with concrete or paint, so the hub connector 100 for construction of the geodesic dome house and the lumber (A) are not exposed to the outside.

However, it can be estimated that the geodesic dome house construction hub connector 100 is used in the area indicated by the arrow in FIG. 1, that is, the vertex area.

FIG. 2 is a front view of a state in which a shell is coupled to a geodesic dome house construction hub connector according to an embodiment of the present invention, and FIG. 3 is a perspective view of the geodesic dome house construction hub connector shown in FIG. 3 is a partially exploded perspective view of Figure 3, Figure 5a is an enlarged view of the main portion of Figure 4, Figure 5b is a rear perspective view of the guide bracket shown in Figure 5a, Figure 6 is a rear perspective view of Figure 3, Figure 7 This is a perspective view of the rotated state, Figure 8 is a rear perspective view of Figure 7, and Figure 9 is a front view of the shell material coupled to the geodesic dome house construction hub connector according to another embodiment of the present invention.

Referring to these drawings, the geodesic dome house construction hub connector 100 of the present embodiment includes a connector body plate 110, a plurality of guide brackets 120, and a plurality of shell coupling modules 130.

For reference, in the present embodiment, the coupling method of the guide brackets 120 to the connector body plate 110, and the method of coupling the angle A on the angle coupling module 130 all have a screw coupling method.

This is because screwing is the easiest and most robust way to work outdoors and can be dismantled.

In order to apply such a screw method, a plurality of bolt holes are formed at positions where the connector body plate 110, the plurality of guide brackets 120, and the plurality of lumber coupling modules 130 are assembled or coupled to each other. The description of the bolt holes will be omitted for convenience.

The connector body plate 110 forms a polygonal structure, that is, a hexagonal structure. Therefore, a total of six sides (surfaces) are formed around the guide bracket 120 and the lumber coupling module 130 on each outer surface. Because of the angle A may also be used a total of six for the connector body plate 110.

The connector body plate 110 may be manufactured by pressing a metal material, for example, aluminum.

For reference, as shown in FIG. 2, the keratin A forms a skeleton of a geodesic dome house, and after the keratin A is installed, a panel or the like may be attached to a space formed between the keratin A. FIG. Make sure

The length of the shell A may be appropriately selected depending on the volume of the geodesic dome house shown in FIG. 1. The lumber (A) may be applied as wood, but not necessarily wood, and plastics, metals or pipes may be used.

Guide brackets 120 are individually coupled to each outer surface of the connector body plate 110.

In the present embodiment, as described above, a total of six guide brackets 120 may be used for one connector body plate 110.

The guide bracket 120 is formed at a position spaced apart from the first fixing part 121 and the first fixing part 121 fixed to one side of the connector body plate 110 and the connector body plate 110. A second fixing part 122 fixed to the other side, a straight extension part 123 extending along the thickness direction of the connector body plate 110 from the first fixing part 121, a straight extension part 123, and An arc connecting portion 124 connecting the second fixing portion 122 in the form of an arc, and a first hinge portion 125 provided in the first fixing portion 121.

The first fixing part 121 and the second fixing part 122 are each screwed to one side and the opposite side of the connector body plate 110. Accordingly, one side of the connector body plate 110 coupled to the first fixing part 121 and the second fixing part 122, and the first fixing part 121 and the second fixing part 122, and its A plurality of bolt holes are formed on the opposite side. As described above, reference numerals for the bolt holes are omitted for convenience.

The first fixing part 121, the second fixing part 122, the straight extension part 123, the arc connecting part 124, and the first hinge part 125 are made of a single material, for example, a metal material that is light and resistant to corrosion, such as aluminum. It can be manufactured integrally with.

The corner member coupling module 130 is formed with a place where the corner member (A) is coupled to one side, the other side is rotatably coupled to the guide bracket 120. The horn member coupling module 130 is individually disposed one by one on each outer surface of the connector body plate 110 while a portion thereof is guided by the guide bracket 120.

In particular, the shell member coupling module 130 of the present embodiment is adjusted at any angle on the guide bracket 120 with the bolt (B) as the center.

In other words, the horn member coupling module 130 may maintain a parallel state with the connector body plate 110 as shown in FIG. 3, or may be rotated to one side with respect to the connector body plate 110 as shown in FIGS. 7 and 8. .

Although not illustrated, the angular coupling module 130 may be freely rotated at any angle with respect to the connector body plate 110.

Therefore, there is an advantage that can improve the work efficiency compared to the conventional fixed type or the type of angle adjustment is extremely limited.

The angular coupling module 130, the angular clamp (131) is clamped in a state in which the angular material (A) and, is formed to extend from one side of the angular clamp (131), the first hinge of the guide bracket 120 A second hinge portion 132 forming a hinge shaft, for example, the place where the bolt (B) is coupled with the branch portion 125, and extends in the form of an arc from the other side of the lumber clamp 131, the guide bracket 120 And a guide bridge 133 guided by the arc connection 124 of FIG.

The corner clamp 131 is a portion that is fixed while being clamped in a state where the shell A is partially inserted.

The corner clamp 131 is manufactured to have an approximately Korean letter "c". For this reason, the lumber A may be clamped to the horn rim 131 by a bolt and a nut (see FIG. 2) in a state sandwiched between the rim rim clamp 131.

The guide bridge 133 is a banana-like shape and extends to one side from the angle member clamp 131.

The guide bridge 133 is formed to gradually narrow the width toward the tip portion, and is superimposed on the arc connecting portion 124 of the guide bracket 120, the movement is guided by the arc connecting portion 124 of the guide bracket 120 do.

The guide bridge 133 has a through-hole 111 formed at the center of the body plate 110, the front end of the body coupling module 130, while maintaining the state parallel to the connector body plate 110 as shown in FIG. Protrudes through.

However, when the lumber coupling module 130 is rotated to one side with respect to the connector body plate 110 as shown in FIG. 7, the tip end portion thereof does not protrude through the through hole 111 formed in the central region of the body plate 110. Only or less than FIG. 3 protrudes.

The corner clamp 131, the second hinge portion 132, and the guide bridge 133 may be integrally made of a single material, for example, aluminum, which is light and resistant to corrosion.

On the other hand, with reference to Figures 5a and 5b looks at the relative angle control structure between the guide bridge 133 of the lumber coupling module 130 and the arc connecting portion 124 of the guide bracket 120.

The pair of first long holes 133a are spaced apart from each other in the guide bridge 133 in the longitudinal direction thereof. The pair of first long holes 133a are formed in the arc connecting portion 124 of the guide bracket 120 when the first angle of the lumber coupling module 130 is slightly adjusted with respect to the guide bracket 120. The first bolt hole 124a forms a place for fastening with a fastening means such as a bolt B1.

The second guide hole 133b is formed in the guide bridge 133 in a single direction along the longitudinal direction of the guide bridge 133 between the pair of first holes 133a. When the angle of the lumber coupling module 130 with respect to the bracket 120 is adjusted to the secondary bent more than the first, a plurality of second bolt holes (124b) formed in the arc connecting portion 124 of the guide bracket 120 To form a place for fastening with fastening means such as bolts (B2). That is, since the second bend is to be firmly tightened, a plurality of bolts B2 are fastened along the longitudinal direction of the second long hole 133b.

Hereinafter, the usage method of this invention is demonstrated.

First, a connector body plate 110, a plurality of guide brackets 120, and a plurality of lumber coupling module 130 is prepared.

Then, the six guide brackets 120 are assembled to one connector body plate 110, and the respective corner joining modules 130 are coupled to the guide brackets 120 one by one. Then, the bolts (A) by inserting the bolts one by one to the angle coupling module 130 as shown in FIG.

When one set is completed, as shown in FIG. 2, another geodesic dome house construction hub connector 100 may be prepared to connect the neighboring angles A to complete the geodesic dome structure.

In this case, the construction work is convenient because the angle of the angle coupled to the circumference of the hub connector 100 can be freely adjusted from 0 degrees to 90 degrees.

Subsequently, although not shown, a geodesic dome house can be completed as shown in FIG. 1 by sandwiching panels between the lumbers (A) and plastering and painting.

According to this embodiment having such a structure, it is possible to produce a simple yet efficient structure, as well as smoothly adjust the angle of the angle A coupled to the circumference can improve the construction efficiency.

In addition, according to the present embodiment, since the angle of the angle coupled to the circumference of the hub connector 100 can be freely adjusted from 0 degrees to 90 degrees, the construction work is convenient to shorten the air.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

A: Angle 100,200: Hub connector
110: connector body plate 111: through hole
120: guide bracket 121: first fixing part
122: second fixing portion 123: straight extension portion
124: arc connecting portion 125: first hinge portion
130: lumber coupling module 131: lumber clamp
132: second hinge portion 133: guide bridge

Claims (6)

A connector body plate 110 having a polygonal structure;
A plurality of guide brackets 120 individually coupled to each outer surface of the connector body plate 110; And
And a plurality of horn material coupling modules 130 coupled to one side thereof, the other side of which is rotatably hinged to each of the guide brackets 120.
The guide bracket 120,
A first fixing part 121 fixed to one side of the connector body plate 110;
A second fixing part 122 formed at a position spaced apart from the first fixing part 121 and fixed to the other side of the connector body plate 110;
A linear extension part 123 extending along the thickness direction of the connector body plate 110 from the first fixing part 121;
An arc connecting part 124 connecting the linear extension part 123 and the second fixing part 122 in an arc shape; And
Geodesic dome house construction hub connector (100,200) comprising a; first hinge portion (125) provided on the first fixing portion (121).
delete The method of claim 1,
The lumber coupling module 130,
A angular clamp (131) clamped in a state where the horn (A) is partially fitted;
A second hinge portion 132 which is formed to extend from one side of the angle clamp 131 and is hinged to the first hinge portion 125 of the guide bracket 120; And
A guide bridge 133 extending in the form of an arc from the other side of the angular clamp 131 but overlapping the arc connecting portion 124 of the guide bracket 120 and guided by the arc connecting portion 124. Geodesic dome house construction hub connector characterized in that it comprises a (100,200).
The method of claim 3,
The guide bridge 133 is formed to gradually narrow the width toward the tip portion,
The pair of pairs are spaced apart from each other in the lengthwise direction of the guide bridge 133, and the arc of the guide bracket 120 is adjusted when the angle of the angler coupling module 130 is first adjusted with respect to the guide bracket 120. A plurality of first long holes 133a are formed in the plurality of first bolt holes 124a formed in the connection part 124 to be fastened by the bolts B1.
The guide bridge 133 is disposed along the longitudinal direction of the guide bridge 133 between the pair of first long holes 133a, and the angle of the lumber coupling module 130 with respect to the guide bracket 120. When the second to be adjusted to be more than the first secondary, a single second for fastening the bolt (B2) to a plurality of second bolt holes (124b) formed in the arc connecting portion 124 of the guide bracket 120 Geodesic dome house construction hub connector (100,200), characterized in that the long hole (133b) is formed.
The method of claim 3,
In the central region of the body plate 110 is further formed a through-hole 111 to selectively expose the tip of the guide bridge 133,
The connector body plate 110 is a hub connector for geodesic dome house construction, characterized in that the hexagonal or pentagonal (100,200).
A geodesic dome house having a geodesic dome house construction hub connector (100,200) according to any one of claims 1, 3, 4 and 5.

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