KR102189606B1 - Suspension for membrane structure - Google Patents

Abstract

According to an embodiment of the present invention, provided is a membrane structure suspension. The membrane structure suspension for fixing a wire for applying a tensile force to a membrane structure comprises: a main frame fixed to the ground; a first rotary plate having a first shaft formed at one end to be rotatably coupled to the main frame, and a second shaft rotatably coupled to the other end in the direction vertical to the first shaft; a second rotary plate having one end rotatably coupled around the second shaft and formed with a third shaft rotatably coupled to the other end in the direction vertical to the second shaft; a third rotary plate having one end rotatably coupled around the third shaft; and a fixing pipe coupled to the other end of the third rotary plate and having a wire inserted thereinto. According to the present invention, manufacturing costs can be reduced by having a simple structure.

Description

Membrane structure suspension {SUSPENSION FOR MEMBRANE STRUCTURE}

The present invention relates to a membrane structure suspension, and more particularly, to a membrane structure suspension for fixing a wire for introducing an appropriate tensile force to the membrane material of various membrane structures such as sports grounds and sports facilities.

Membrane structures are applied to sports fields, gymnasiums, and cultural facilities because of their advantages such as relatively low construction cost, fast construction period, and excellent waterproofing.

In general, the membrane structure is configured to install a wire at the edge, and apply a tensile force to the wire so that the membrane structure is well unfolded and wrinkles do not occur.

However, when a large-scale membrane structure is constructed, the angle of installation of the wire may be changed due to deformation or tolerance of the member, and accordingly, the configuration of fixing the wire by being bonded to the end of the wire and the wire may not interlock. .

In particular, when deformation occurs while the construction of the membrane structure is completed, the entire structure supporting the membrane structure may be damaged, and repair thereof is very difficult.

When such a problem occurs, conventionally, a member fixing the wire or a method of cutting the wire to a predetermined length and then welding again according to an angle was used. In this case, the difficulty of construction increases as well as the strength of the welding portion decreases. Was always there.

Accordingly, when the angle at which the wire of the membrane structure is inserted is deformed, a membrane structure suspension capable of compensating for such deformation has been developed. However, in the conventional suspension, angular compensation was limited while moving based on one or two axes, and as several axes were concentrated in one configuration, there was a problem that the shaft was damaged by an excessive load. In addition, the conventional suspension has a problem in that the structure is complicated, so that the manufacturing cost is increased or the installation is inconvenient.

Accordingly, there is a demand for a new membrane structure suspension having a simple structure, simple manufacturing, smooth angular compensation of the wire, and excellent durability.

The matters described as the background art are only for enhancing an understanding of the background of the present invention, and should not be taken as acknowledging that they correspond to the prior art already known to those of ordinary skill in the art.

10-1901823 B1 (2018.09.27)

The present invention is to solve the above-described problem, and an object of the present invention is to freely change the installation angle of the wire using a multi-axial structure, to prevent concentration of load by distributing the installation position of the shaft, and have a simple structure This is to provide a membrane structure suspension that can reduce manufacturing costs.

A membrane structure suspension according to an embodiment of the present invention is a membrane structure suspension for fixing a wire that imparts a tensile force to the membrane structure, comprising: a main frame fixed to the ground; A first pivoting plate having a first shaft rotatably coupled to the main frame at one end and a second shaft rotatably coupled to the first shaft at the other end; A second pivoting plate having one end rotatably coupled to the second axis and having a third shaft rotatably coupled to the second axis at the other end; A third pivoting plate whose one end is rotatably coupled around the third axis; And a fixing pipe coupled to the other end of the third rotating plate and into which the wire is inserted.

At the other end of the second pivoting plate, a first central hole into which the third shaft is inserted, and a pivoting hole formed in an arc shape around the first central hole are formed, and in the third pivoting plate, the third shaft The inserted second central hole and a fixing hole spaced apart from the second central hole are formed, and are installed to penetrate the rotating hole and the fixing hole, so that the rotation angle of the third rotating plate is adjusted to the arc angle of the rotating hole. It may further include a rotation pin limited to.

The third rotating plate includes a first plate and a second plate respectively provided to contact both sides of the second rotating plate, and the second central hole and the fixing hole are formed in the first plate and the second plate, respectively. Can be.

A connection plate interposed between the first pivoting plate and the second pivoting plate and integrally rotatably coupled to the second pivoting plate; further comprising a pipe-shaped second end portion of the first pivoting plate. A first guide is formed, and a second guide in the shape of a pipe is formed on the connection plate, so that the second shaft is inserted into the first guide and the second guide so that the first rotating plate and the connection plate can be rotated. Can be combined.

The connection plate is divided into a fixing part integrally formed with the second guide, and a reinforcing part extending along the surface of the second rotation plate from the fixing part, and the connection plate and the second rotation plate It is coupled through 1 fixing member and a plurality of second fixing members, wherein the first fixing member is installed through the fixing part of the connection plate and the second rotating plate, and the second fixing member reinforces the connection plate. It may be installed through the part and the second rotating plate.

The first shaft is installed at one end of the first pivoting plate perpendicular to the surface of the first pivoting plate, and the second shaft is parallel to the surface of the first pivoting plate at the other end of the first pivoting plate. Can be installed.

According to the membrane structure suspension according to an embodiment of the present invention, it is easy to adjust the installation angle of the wire due to the complex rotation of the first, second, and third axes, and each axis is spaced apart from each other to distribute the load. In addition, there is an effect of reducing manufacturing cost by using a simple structure without a complex screw connection structure or a complex structure shaft.

1 is a perspective view of a membrane structure suspension according to an embodiment of the present invention.
2 is an exploded perspective view of a membrane structure suspension according to an embodiment of the present invention.
3 is a perspective view of a second rotating plate of a membrane structure suspension.
4 is a view showing the installation form of the first shaft and the second shaft of the membrane structure suspension.
5 is a view showing the state of the third rotating plate.

Hereinafter, a membrane structure suspension according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described below, but may be implemented in various different forms, and the following description is provided to completely inform the scope of the invention.

1 is a perspective view of a membrane structure suspension according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of a membrane structure suspension according to an embodiment of the present invention, and FIG. 3 is a perspective view of a second rotating plate of the membrane structure suspension. 4 is a view showing the installation form of the first and second shafts of the membrane structure suspension, and FIG. 5 is a view showing the appearance of the third rotating plate.

1 to 5, the membrane structure suspension according to an embodiment of the present invention includes a main frame 1 fixed to the ground and a first rotatably coupled to the main frame 1 at one end. A first rotating plate 100 having a shaft 10 formed and a second shaft 20 rotatably coupled to the first shaft 10 at the other end thereof, and one end of the second shaft 20 ), the second pivoting plate 200 having a third shaft 30 pivotably coupled to the second shaft 20 at the other end, and one end of the third shaft It is configured to include a fixed pipe 400, which is coupled to the other end of the third rotating plate 300 and the third rotating plate 300, which is rotatably coupled around 30, and into which a wire W is inserted. .

In addition to this, a connection plate that mediates between the first and second rotation plates 100 and 200 and is integrally rotatably coupled with the second rotation plate 200 to reinforce the second rotation plate 200 ( It is preferable to further include 500).

The main frame 1 is a type of support base installed on the ground or a structure equivalent thereto, and is configured to support the tensile force of the wire W and the membrane structure connected thereto. The specific shape of the main frame 1 or the installation method on the first shaft 10 and the ground is not particularly limited, but includes, for example, a bearing or a load absorbing structure in which the first shaft 10 is inserted and can rotate. can do.

The first rotation plate 100 is rotatably coupled to the main frame 1, and this rotation may be performed around the first axis 10.

More specifically, a first shaft 10 is installed at one end of the first pivoting plate 100 perpendicular to the surface of the first pivoting plate 100, and a first shaft 10 is installed at the other end of the first pivoting plate 100. The second shaft 20 may be installed parallel to the surface of the rotating plate 100.

Through this structure, the first rotation plate 100 and the main frame 1 are coupled to be rotatable in contact with each other so as to be interviewed.

The second rotation plate 200 is formed in a direction perpendicular to the first shaft 10 and is coupled to be rotatable around the second shaft 20 installed at the other end of the first rotation plate 100, It serves as a kind of base for connecting each structure of the membrane structure suspension according to the present invention, and is provided in the form of a plate material forming an arc shape toward the installation direction of the wire W in the main frame 1.

The second rotating plate 200 may be directly coupled to the second shaft 20, but more preferably the second shaft 20 is coupled to the connection plate 500 to be described later, and the connection plate 500 and It is preferable to install the second rotating plate 200 so that it can rotate integrally. A detailed coupling structure of the second rotating plate 200 and the connection plate 500 will be described later.

Although not specifically shown, a separate housing member surrounding the suspension of the membrane structure according to the present invention may be installed on the second rotating plate, if necessary.

The third rotating plate 300 is rotatably coupled to the second rotating plate 200, and is rotatably coupled around the third shaft 30 provided in a direction perpendicular to the surface of the second rotating plate 200 do.

A fixing pipe 400 into which a wire W can be inserted is installed in the third rotating plate 300, and the fixing pipe 400 is integrally coupled to the third rotating plate 300 to form a separate rotating structure. Do not have.

Looking in more detail at the coupling structure of the second rotating plate 200 and the third rotating plate 300, the first central hole 210 into which the third shaft 30 is inserted into the other end of the second rotating plate 200 ) And a rotation hole 220 formed in an arc shape around the first center hole 210, and a second center hole 310 into which the third shaft 30 is inserted into the third rotation plate 300, and It is configured to form a fixing hole 320 spaced apart from the second central hole 310 by a predetermined distance.

At this time, the second pivot plate 200 and the third pivot plate 300 are interviewed so that the first central hole 210 and the second central hole 310 are positioned in a straight line, and the third axis 30 ) Is installed so that the third rotation plate 300 can rotate around the third axis 30.

On the other hand, there is a rotation pin 40 is installed in the above-described rotation hole 220 and the fixing hole 320, one end of the rotation pin 40 is fixed in a state inserted into the fixing hole 320, the other end It is inserted and installed so that it can run on the pupil 220.

Through this structure, when the pivot pin 40 reaches the end of the pivot hole 220, the third pivot plate 300 is stopped without further pivoting around the third shaft 30. While the plate 300 is installed to be rotatable with respect to the second rotation plate 200, the rotation angle of the third rotation plate 300 may be limited within the arc angle of the rotation hole 220.

The third rotating plate 300 may be provided in a single plate shape, but may be composed of two plates for a more robust combination. That is, it includes a first plate 301 and a second plate 302 provided to contact both sides of the second rotating plate 200, respectively, the first plate 301 and the second plate 302, respectively, The central hole 310 and the fixing hole 320 are formed.

In this way, by installing the third shaft 30 and the pivot pin 40 with the second pivot plate 200 inserted between the first plate 301 and the second plate 302, the second pivot plate ( It is possible to improve the bonding strength between the 200) and the third rotating plate 300.

On the other hand, the connection plate 500 is a configuration that is rotatably coupled to the first rotating plate 100 about the first shaft 10 and rotatably coupled to the second rotating plate 200 integrally.

Specifically, a pipe shape formed by a pipe-shaped first guide 110 formed at the other end of the first rotating plate 100 and a pipe-shaped second guide 511 formed at one end of the connecting plate 500 In the configuration of, the above-described first shaft 10 may be inserted so that the two configurations can be rotatably coupled.

Preferably, the first guide 110 is provided in the shape of one pipe, the second guide 511 is provided in the shape of a pair of pipes, and the first guide is inserted between the two second guides 511 By doing so, one pipe shape can be achieved. When the first shaft 10 is inserted here, the first rotating plate 100 and the connection plate 500 are rigidly bonded to each other to prevent separation from each other.

The reason why the connection plate 500 is formed in a separate configuration from the second rotating plate 200 is by combining it with the second rotating plate 200 of various shapes using one type of connection plate 500 This is because various types of membrane structure suspension can be provided.

The second rotating plate 200 corresponds to the central portion of the membrane structure suspension and serves to determine the overall layout of the membrane structure suspension. Accordingly, the shape of the second rotating plate 200 may be modified according to the construction environment or a required structure.

At this time, when the connecting plate 500 and the second guide 511 coupled thereto, and the second rotating plate 200 are integrally formed, the size of the mold becomes too large, making it difficult to produce various types of products. have. Accordingly, it is possible to solve the above-described problem by minimizing the size of the second rotating plate 200 and using a connection plate 500 that is provided in a single shape and is compatible with the second rotating plate 200 of various types.

Looking at the shape of the connection plate 500 in more detail, the fixing part 510 formed integrally with the second guide 511 and extending along the surface of the second rotating plate 200 from the fixing part 510 It may be divided into a reinforcing part 520.

As described above, the connection plate 500 and the second rotation plate 200 are coupled to each other so as to be integrally rotatable, and for this purpose, a plurality of fixing members may be installed on the fixing part 510 and the reinforcing part 520 respectively. .

That is, the fixing part 510 of the connection plate 500 and one end of the second rotating plate 200 are coupled through the first fixing member 610, and the reinforcing part 520 of the connection plate 500 and the second The central portion of the rotating plate 200 is coupled through a second fixing member 620.

At this time, a plurality of the first fixing member 610 and the second fixing member 620 are respectively installed to improve the bonding force between the connection plate 500 and the second rotating plate 200, and the connection plate 500 It is possible to prevent rotation based on the two-rotating plate 200.

In order to couple the connection plate 500 and the second rotating plate 200 through the first fixing member 610 and the second fixing member 620, the fixing part 510 of the connection plate 500 has a first A plurality of first fixing member coupling holes 611 into which the fixing member 610 is inserted is formed, and a plurality of first reinforcing member coupling holes 621 into which the second fixing member 620 is inserted in the reinforcing part 520 Is formed, and at one end of the second rotating plate 200, a plurality of second fixing member coupling holes 612 into which the first fixing member 610 is inserted are formed, and in the center of the second rotating plate 200 A plurality of second reinforcing member coupling holes 622 into which the second fixing member 620 is inserted are formed.

The first fixing member 610 and the second fixing member 620 may be provided with a bolt-nut coupling, a rivet coupling, a welding rod for welding, etc. depending on the working environment or necessity.

The fixing part 510 and the reinforcing part 520 of the connection plate 500 may be provided in a single configuration, or may be provided in separate configurations. The reason for separating the fixing part 510 and the reinforcing part 520 of the connection plate 500 into separate configurations is similar to the reason for separating the connection plate 500 and the second rotating plate 200 described above.

When the fixing part 510 and the reinforcing part 520 are separated, the first fixing member 610 has a three-layer configuration of the fixing part 510, the reinforcing part 520, and the second rotating plate 200. It would be desirable to have it penetrate and engage. Through this coupling structure, the fixing part 510, the reinforcing part 520, and the second rotating plate 200 may be firmly bound.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features. You can understand.

Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting. The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or altered forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. .

1: mainframe 10: 1st axis
20: 2nd axis 30: 3rd axis
100: first rotating plate 200: second rotating plate
300: 3rd rotating plate 400: fixed pipe
500: connecting plate 610: first fixing member
620: second fixing member W: wire

Claims (6)

As a membrane structure suspension that fixes a wire that imparts tensile force to the membrane structure,
A mainframe fixed to the ground;
A first pivoting plate having a first shaft rotatably coupled to the main frame at one end and a second shaft rotatably coupled to the first shaft at the other end;
A second pivoting plate having one end rotatably coupled to the second axis and having a third shaft rotatably coupled to the second axis at the other end;
A third pivoting plate whose one end is rotatably coupled about the third axis;
A fixing pipe coupled to the other end of the third rotating plate and into which the wire is inserted; And
Including; a connecting plate interposed between the first rotating plate and the second rotating plate, and integrally rotatably coupled with the second rotating plate,
A pipe-shaped first guide is formed at the other end of the first rotating plate, and a pipe-shaped second guide is formed on the connection plate, and the second shaft is inserted into the first guide and the second guide. The membrane structure suspension, characterized in that the first rotating plate and the connection plate are rotatably coupled.
The method according to claim 1,
At the other end of the second pivoting plate, a first central hole into which the third shaft is inserted, and a pivoting hole formed in an arc shape around the first central hole are formed,
In the third rotating plate, a second central hole into which the third shaft is inserted and a fixed hole spaced apart from the second central hole are formed,
A membrane structure suspension comprising: a pivoting pin installed to penetrate the pivoting hole and the fixing hole to limit the pivoting angle of the third pivoting plate to the arc angle of the pivoting hole.
The method according to claim 2,
The third rotating plate includes a first plate and a second plate provided to respectively contact both surfaces of the second rotating plate,
The membrane structure suspension, characterized in that the second central hole and the fixing hole are formed in the first plate and the second plate, respectively.
delete The method according to claim 1,
The connection plate is divided into a fixing part integrally formed with the second guide, and a reinforcing part extending along the surface of the second rotating plate from the fixing part,
The connection plate and the second rotation plate are coupled through a plurality of first fixing members and a plurality of second fixing members, and the first fixing member is installed through the fixing part of the connection plate and the second rotation plate. And the second fixing member is installed through the reinforcing portion of the connection plate and the second rotating plate.
The method according to claim 1,
The first shaft is installed at one end of the first pivoting plate perpendicular to the surface of the first pivoting plate, and the second shaft is parallel to the surface of the first pivoting plate at the other end of the first pivoting plate. Membrane structure suspension, characterized in that it is installed.

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