KR101310327B1 - geodesic dome having multitude structure - Google Patents

Abstract

The present invention relates to a multi-structure geodesic dome.
The geodesic dome of the multi-structure of the present invention, the geodesic dome is installed in a plurality consisting of the inner dome and the outer dome, having a tubular shape in which a thread is formed on the outer peripheral surface or a thread formed on the inner peripheral surface Protruding member is provided to protrude in any one selected from the center upper and lower parts, the center upper portion, the center lower portion of the connector, the interlayer connection member having a tubular shape with a thread formed on the inner peripheral surface or a rod shape with a thread formed on the outer peripheral surface of the connector. By screwing with the protruding member, the inner dome and the outer dome are each characterized in that the protruding members installed in the connector is connected by an interlayer connection member.
According to the present invention, the construction is very difficult geodesic dome consisting of a multi-structure consisting of the structure of the inner dome and the outer dome, the protruding member is installed in the center of the connector of each dome, using the interlayer connection member By connecting the projecting members of the external dome and the construction of the dome, after installing the internal dome, after installing the interlayer connection member, the external dome is installed to facilitate the construction of the external dome. The internal dome and the outer dome are structurally more stable, and the interlayer connecting member connecting the inner dome and the outer dome can be adjusted by using a length adjusting member to adjust the length according to the environment at the construction site. It solves the error of each connector part, and each inner dome and the outer dome rotate the bracket on the base plate because each connector and connector are connected. The angular error occurring at the construction site can be eliminated by connecting the compliant member, and the connecting member fixing hole formed in the fixing member for connecting the connecting member is formed in a rectangular shape along the longitudinal direction to solve the length error of the connecting member. do.

Description

Geodesic dome having multitude structure}

The present invention is a geodesic dome formed by connecting a plurality of connecting members to the connector, the geodesic dome is formed in and out of multiple, while the connector of the inner dome and the connector of the outer dome is connected to each other to have structural stability, The present invention relates to a multi-structure geodesic dome that facilitates assembly of an outer dome in a state where an inner dome is formed.

The geodesic structure, conceived in the late 1940s by American architect Berkminster Plugger, refers to a sphere or spherical type of structure, in which triangle cells form a delusion that fills the sphere.

At this time, the load of the structure is distributed evenly in each triangular cell, and the geodesic dome can enclose the maximum volume with the minimum amount of material so that it can cover a very large space without any support in the hemispherical shape and heat loss occurs. The small part is also excellent in energy efficiency.

These geodesic domes do not have pillars or girders inside, providing a very large indoor space, and are used as indoor sports facilities, large performance halls, or exhibition halls as various warehouses.

However, this geodesic dome has a disadvantage in that it is difficult to construct unless it is a highly skilled technician.

In particular, due to such construction difficulties, a multi-structure geodesic dome has not been disclosed.

Figure 1 is a perspective view showing a typical geodesic dome is formed by connecting a plurality of connecting members (1) to the connector (2), a plurality of connecting members (1) are connected to one connector (2) of the construction Requires precision

On the other hand, as a technology related to the connector of the general geodesic dome, as shown in Figure 2, the "space frame connector" (Korea Patent Publication No. 10-2009-0069399) is arranged and fixed at an equal angle on the side of the central column, the center A technique is disclosed in which a plurality of connecting wings extending radially about a pillar and having a plurality of space frames coupled to each other are disclosed.

This configuration is to connect the space frame, that is, the connecting member 1 to the connecting blades of each connector 2 with bolts so that it can be easily assembled.

However, such a technique discloses only a connector that cannot form a geodesic dome with multiple structures.

KR 10-2009-0069399 (2009.07.01)

Geodesic dome of the multi-structure of the present invention is to solve the problems occurring in the prior art as described above, the construction is very difficult geodesic dome consisting of a multi-structure consisting of the structure of the inner dome and the outer dome, Protruding members are installed at the center of each dome, and connecting the protruding members of the inner dome and the outer dome by using the interlayer connecting member. The construction is intended to facilitate the construction of the external dome to facilitate the construction of multiple geodesic domes.

In particular, the inner dome and the outer dome is made of a structure connected to each other to provide a structurally more stable dome structure.

In addition, the interlayer connecting member connecting the inner dome and the outer dome can adjust the length by using the length adjusting member to solve the error of each connector part according to the environment at the construction site, and according to the construction site The purpose of this is to make it possible to construct a dome of multiple structures easily in different situations.

In addition, each of the inner dome and the outer dome is to be connected to each connecting member and the connector so that the bracket is rotatably connected to the base plate to solve the angle error occurring in the construction site.

In addition, the connection member fixing hole formed in the fixing member for connecting the connecting member to form a rectangular along the longitudinal direction to solve the length error of the connecting member.

In order to solve the above problems, the geodesic dome of the multi-structure of the present invention, the geodesic dome is installed in a multiple consisting of the inner dome and the outer dome, the thread is formed in the rod shape or the inner circumferential surface is formed on the outer peripheral surface The tubular protrusion having the tubular shape formed therein is protruded and installed at any one selected from the upper, lower, middle, and lower portions of the connector, and the rod is formed on the tubular shape or the outer circumferential surface of which the thread is formed on the inner circumferential surface. Since the interlayer connecting member having a shape is screwed with the protruding member, the inner dome and the outer dome are each characterized in that the protruding members provided in the connector are connected by the interlayer connecting member.

At this time, the interlayer connection member and the outer side dome connecting member is screwed with the protruding member of the outer dome; An inner dome connecting member having one side screwed into the protruding member of the inner dome; The other side of the outer dome connecting member and the other side of the inner dome connecting member is screw length adjustment member; consisting of, the inner dome and the length of the inner dome connecting member and the inner dome connecting member is screwed to the length adjusting member Characterized in that the length can be adjusted according to the distance between the outer dome.

In addition, the connector is made of a circular metal plate material with a protruding member insertion hole formed in the center, and a plurality of circular first pin insertion holes are formed at a predetermined distance from the center at equal angles. A base plate having a second pin insertion hole having a rectangular arc shape having a width greater than a width toward the center and having a predetermined distance to both sides from the imaginary line extending to the circumference by connecting the one pin insertion hole; The upper surface or the bottom surface of the base plate is in close contact with each other, both sides are connected from the periphery of the base plate to the center of the base plate, the connecting side connecting the two sides is formed in an arc shape, one side of the A third pin insertion hole having the same diameter as the first pin insertion hole is formed to vertically coincide with the first pin insertion hole, and the second side is positioned at a position corresponding to a distance from the center of the second pin insertion hole to the other side. A bracket having a circular fourth pin insertion hole having a diameter corresponding to the width of the pin insertion hole; A fixing member having an upper one side connected to the connection side of the bracket and having a connection member fixing hole having a rectangular shape in a direction connecting the center of the bracket; A rotation pin having one side installed through the first pin insertion hole and the third pin insertion hole to connect the bracket to the base plate based on the first pin insertion hole to be rotatable; The body has the same outer diameter as the fourth pin insertion hole, and the nut member passes through the fourth pin insertion hole of the bracket that rotates the third pin insertion hole and the second pin insertion hole of the base plate. The bolt member is fastened to fix the bracket and the base plate; the protruding member has a head having a size larger than the diameter of the protruding member insertion hole in the upper portion, and a thread is formed in the outer circumferential surface of the head lower portion, protruding It consists of a body of the same outer diameter as the member insertion hole diameter, characterized in that the nut is fastened to the body through the protruding member insertion hole.

According to the present invention, the construction is very difficult geodesic dome consisting of a multi-structure consisting of the structure of the inner dome and the outer dome, the protruding member is installed in the center of the connector of each dome, using the interlayer connection member By connecting the protruding member of the external dome, the construction of the dome is facilitated the construction of the external dome by installing the external dome after installing the interlayer connecting member after the completion of the internal dome construction. .

In particular, the inner dome and the outer dome is composed of a structure connected to each other to provide a structurally more stable dome structure.

In addition, the interlayer connecting member connecting the inner dome and the outer dome can adjust the length by using the length adjusting member to solve the error of each connector part according to the environment at the construction site, and according to the construction site In the situation where the outer dome is different, it is easy to construct a multi-structure dome.

In addition, each of the inner dome and the outer dome is connected to each connecting member and the connector so that the bracket is rotatably connected to the base plate can be eliminated the angular error occurring in the construction site.

In addition, it is possible to solve the length error of the connection member by forming a connection member fixing hole formed in the fixing member for the connection member in a rectangular shape along the longitudinal direction.

1 is a perspective view showing an example of a conventional geodesic dome.
Figure 2 is a perspective view of a conventional geodesic dome connector.
Figure 3 is a schematic cross-sectional view showing a geodesic dome in accordance with the present invention.
Figure 4 is a schematic cross-sectional view showing the installation state of the interlayer connection member and the protrusion member in the present invention.
Figure 5 is an exploded perspective view showing a configuration example of the connector, the interlayer connection member, the projecting member in the present invention.

Hereinafter, the geodesic dome of the multi-structure according to the present invention will be described in detail with reference to the accompanying drawings.

The geodesic dome of the multi-structure of the present invention is composed of a multi-structure consisting of the inner dome 10 and the outer dome 20, as shown in FIG.

In addition, each dome is formed by connecting the connection member 1 to the connector (2).

At this time, the protruding member 30 having a rod shape with a thread formed on the outer circumferential surface or a tubular shape with a thread formed on the inner circumferential surface protrudes from any one selected from the center upper and lower portions, the center upper portion, and the center lower portion of the connector 2. The interlayer connecting member 40 having a tubular shape having a thread formed on an inner circumferential surface thereof or a rod shape having a thread formed on an outer circumferential surface thereof is screwed with the protruding member 30 so that the inner dome 10 and the outside are screwed together. The dome 20 is characterized in that the protruding members 30 provided in the connector 2 are connected by the interlayer connecting member 40, respectively.

In the figure, the protruding member 30 is formed in a tubular shape, and the interlayer connecting member 40 is formed in a rod shape.

In addition, the connector 2 of the inner dome 10 and the connector 2 of the outer dome 20 are not all the connector 2 is connected to each other, optionally, some connector (2) between the interlayer connection member 40 Can be connected by.

This means that the length of each connecting member 1 of the inner dome 10 and the length of each connecting member 1 of the outer dome 20 are identical to the inner dome 10 in the case of the outer dome 20. Since more connectors 2 are installed in comparison, some of the connectors 2 of the outer dome 20 are not connected to the connectors 2 of the inner dome 10.

The structure as described above by connecting the protruding member 30 of the inner dome 10 and the outer dome 20 using the interlayer connection member 40, the interlayer connection after the completion of the construction of the inner dome 10 in the construction of the dome After installing the member 40, the external dome 20 is constructed to facilitate the construction of the external dome 20, thereby facilitating the geodesic dome construction of the multi-structure.

In particular, the inner dome 10 and the outer dome 20 is made of a structure connected to each other it is possible to provide a structurally more stable dome structure.

By adjusting the length of the interlayer connecting member 40 in the configuration as described above to eliminate the error of each connector (2) according to the construction site environment, and according to the construction site the internal dome 10 and the external dome (20) It is possible to easily construct a multi-structure dome in different situations.

To this end, as shown in FIG. 4, the interlayer connecting member 40 includes an outer dome connecting member 41 having one side screwed with the protruding member 30 of the outer dome 20; An inner dome connecting member 42 having one side screwed to the protruding member 30 of the inner dome 10; The other side of the outer dome connecting member 41 and the other side of the inner dome connecting member 42 is screwed length adjustment member 43; consisting of, the outer dome connecting member 41 and the length adjusting member 43 The inner dome connecting member 42 may be configured to adjust the length according to the distance between the inner dome 10 and the outer dome 20 according to the length of the screw coupling.

On the other hand, forming a geodesic dome with a multi-structure of the inner dome 10 and the outer dome 20 as described above, and requires a more precise construction by connecting the inner dome 10 and the outer dome 20 to each other This requires a highly skilled worker to do the work.

In view of this point, it is possible to accommodate the errors generated in the construction site to facilitate the construction.

To this end, as shown in FIG. 5, the connector 2 may include a base plate 50, a bracket 60, a fixing member 70, a rotation pin 80, and a bolt member 90.

Specifically, the base plate 50 is made of a circular metal plate material having a protruding member insertion hole 53 formed at the center thereof, and is divided into equal parts at a certain angle from the center and positioned at a predetermined distance, that is, a plurality of circular agents on the side close to the center. One pin insertion hole 51 is formed.

In addition, a second pin insertion hole 52 is formed while connecting the first pin insertion hole 51 at the center, and spaced at both sides from an imaginary line connected to the periphery, that is, the end.

As shown in the drawing, the second pin insertion hole 52 has a longer arc-like width a in a direction parallel to the circumference than the width b toward the center of the base plate 50.

This is to solve the angular error in construction by fastening the bolt member 90 at any point along the length formed when the bolt member 90 is fastened to the second pin insertion hole 52.

As illustrated in FIG. 5, the bracket 60 is installed by contacting the bottom surface of the base plate 50 with the bottom surface abutting the top surface of the base plate 50.

Both sides of the bracket 60 are connected from the circumference of the base plate 50 to the center of the base plate 50, and the connection side 61 connecting the two sides is formed in an arc shape.

In addition, a third pin insertion hole 62 having the same diameter as the first pin insertion hole 51 of the base plate 50 is formed inside the point where the two sides meet, and coincides with the first pin insertion hole 51 in a vertical line. do.

In addition, the connection side 61 has a diameter corresponding to the width of the second pin insertion hole 52 at a position corresponding to the distance from the center of the second pin insertion hole 52 at the center of the base plate 50. A circular fourth pin insertion hole 63 is formed.

As shown in FIG. 5, the fixing member 70 is connected to the connection side 61 of the bracket 60 and has a rectangular shape in a direction connecting the center of the base plate 50. The member fixing hole 71 is formed.

The connecting member fixing hole 71 is formed in a rectangular shape to change the fixing position according to the length of the connecting member 1 when the connecting member 1 and the fixing member 70 are fastened through the connecting member fixing hole 71. By doing so, the length error of the connecting member 1 can be eliminated.

In this way, solving the length error of the connection member 1 is easily formed by changing the assembly position in consideration of this error when the length of the connection member 1 is formed longer than the design or deviated from the connection point slightly shifted during the assembly process. Assembly of the dome can be achieved.

The fixing member 70 can form a wing on both sides to form a connection member insertion groove 72 in the center as shown in the assembly can be assembled by fitting a member such as a square tube, H-shaped steel, channel, etc., the wing is fixed to the side of the connection member The hole 73 may be formed to secure the connection member 1 from the side.

That is, the connection member 1 is fixed by passing through the connection member fixing hole 71 by using a pair of bolts and nuts, and the connection member side fixing hole 73 is perpendicularly formed using another bolt and nut. The connection member 1 is fixed by penetrating and fixing.

As shown in FIG. 5, the rotary pin 80 has one side penetrated through the first pin insertion hole 51 and the third pin insertion hole 62 to allow the bracket 60 to insert the first pin. It is comprised so that it may be connected to the base board 50 by the hole 51 so that rotation is possible.

Rotating pin 80 for this purpose is formed in the upper rotary pin head 81 having a larger diameter than the first pin insertion hole 51 and the third pin insertion hole 62, the rotation is formed therein The pin body 82 is formed to prevent separation, and the rotary pin screw thread 83 is formed on the lower outer circumferential surface of the rotary pin body 82, and the pin pin nut 84 is formed from the bottom of the bracket 60. ) Is configured to be fastened.

At this time, the rotary pin screw thread 83 is formed only at the lower portion of the rotary pin body 82, so that the rotary pin fixing nut 84 is fastened only to a predetermined position so that the bracket 60 can freely rotate the rotary pin 80 about its axis. It is configured to be.

The bolt member 90 has a body having the same outer diameter as the fourth pin insertion hole 63 as shown, and the fourth pin insertion hole 63 of the bracket 60 rotating the rotation pin 80 about the shaft. ) And the nut member 91 is fastened to the other side while penetrating the second pin insertion hole 52 of the base plate 50 to fix the bracket 60 and the base plate 50.

As shown in the bolt member 90, a screw thread is formed in the entire body, and the nut member 91 is fastened to the bottom to fix the bracket 60 and the base plate 50 to each other.

At this time, the width (a) of the second pin insertion hole 52 is formed longer than the width (b) can be fixed by slightly turning the rotary pin 80 to the left and right on the axis.

In this configuration, the protruding member 30 has a head 31 having a size larger than the diameter of the protruding member inserting hole 53 formed thereon, a screw thread formed on an outer circumferential surface under the head 31, and the protruding member inserted. It consists of a body 32 of the outer diameter equal to the diameter of the hole 53, it is configured so that the nut 33 is fastened to the body 32 through the protrusion member insertion hole 53.

This structure is the inner dome (10) and the outer dome (20) is constructed by connecting the bracket (60) to the base plate (50) rotatably connected to each connecting member 1 and the connector (2) The angle error occurring in the field can be eliminated.

In addition, it is possible to eliminate the length error of the connection member 1 by forming a connection member fixing hole 71 formed in the fixing member 70 in a rectangular shape along the longitudinal direction for connecting the connection member (1).

1: connection member 2: connector
10: inner dome 20: outer dome
30: protruding member 31: head
32: Torso 33: Nut
40: interlayer connecting member 41: external dome connecting member
42: inner dome connecting member 43: length adjusting member
50: base plate 51: first pin insertion hole
52: second pin insertion hole 53: protrusion member insertion hole
60: bracket 61: connection side
62: third pin insertion hole 63: fourth pin insertion hole
70: fixing member 71: connecting member fixing hole
72: connection member insertion groove 73: connection member side fixing hole
80: rotation pin 81: rotation pin head
82: rotating pin body 83: rotating pin screw thread
84: fixing pin fixing nut 90: bolt member
91: nut member a: width
b: width

Claims (3)

In the geodesic dome formed by connecting a plurality of connecting members (1) to the connector (2),
The geodesic dome is installed in multiple consisting of the inner dome 10 and the outer dome 20,
A protruding member 30 having a rod-shaped thread formed on the outer circumferential surface or a tubular thread formed on the inner circumferential surface has a central upper and lower portions, a central upper portion, of the inner dome 10 and the outer dome 20 connector 2. It protrudes and is installed in any one of the lower centers.
When the interlayer connection member 40 having a tubular shape in which a thread is formed on the inner circumferential surface or a rod shape on which the thread is formed on the outer circumferential surface is screwed with the protruding member 30,
The inner dome 10 and the outer dome 20 are each characterized in that the protruding member 30 installed in the connector 2 is connected by the interlayer connection member 40,
Multiple structure geodesic dome.
The method of claim 1,
The interlayer connecting member 40 has an outer dome connecting member 41, one side of which is screwed with the protruding member 30 of the outer dome 20;
An inner dome connecting member 42 having one side screwed to the protruding member 30 of the inner dome 10;
The other side of the outer dome connecting member 41 and the other side of the inner dome connecting member 42 is screwed length adjustment member 43; consists of,
According to the length of the outer dome connecting member 41 and the inner dome connecting member 42 to the length adjusting member 43, the length can be adjusted according to the distance between the inner dome 10 and the outer dome 20. Characterized in that,
Multiple structure geodesic dome.
The method of claim 2,
The connector 2,
It is made of a circular metal plate material with a protruding member insertion hole 53 formed at the center, and a plurality of circular first pin insertion holes 51 are formed at a predetermined distance from the center at equal angles. A second pin insertion hole having a rectangular arc shape having a width a longer than the width b toward the center while being spaced at both sides from the imaginary line extending to the circumference by connecting the one pin insertion hole 51 ( A base plate 50 on which 52 is formed;
The upper surface or the bottom surface of the base plate 50 is brought into close contact with each other, both sides are connected from the periphery of the base plate 50 to the center of the base plate 50, the connecting side connecting the two sides 61 ) Is formed in an arc shape, and at one side, a third pin insertion hole 62 having the same diameter as the first pin insertion hole 51 is formed to vertically coincide with the first pin insertion hole 51. At the side, a circular fourth pin insertion hole 63 having a diameter corresponding to the width of the second pin insertion hole 52 is formed at a position corresponding to a distance from the center of the second pin insertion hole 52. A bracket 60;
A fixing member 70 having an upper side connected to the connecting side 61 of the bracket 60 and having a connecting member fixing hole 71 having a rectangular shape in a direction connecting to the center of the bracket 60. )Wow;
One side is installed through the first pin insertion hole 51 and the third pin insertion hole 62 to rotate the bracket 60 to the base plate 50 based on the first pin insertion hole 51. Rotation pin 80 to be connected to enable;
The body has the same outer diameter as the fourth pin insertion hole 63 and the fourth pin insertion hole 63 and the base plate 50 of the bracket 60 rotating the third pin insertion hole 62 in the axial direction. The nut member 91 is fastened to the other side while passing through the second pin insertion hole 52 of the bolt member 90 for fixing the bracket 60 and the base plate 50;
The protruding member 30 has a head 31 having a size larger than the diameter of the protruding member inserting hole 53 in the upper portion, a screw thread is formed in the outer circumferential surface under the head 31, the protruding member inserting hole 53 It consists of a body 32 of the same outer diameter and diameter, characterized in that the nut 33 is fastened to the body 32 penetrating the protruding member insertion hole 53,
Multiple structure geodesic dome.

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