KR102213930B1 - Elastic body for supporting large event tent structures - Google Patents

Abstract

The present invention relates to an elastic body for supporting a large tent structure for an event, which comprises: a base plate (310) fixed to the bottom surface with a fixing bolt (330); two mounting flanges (320) vertically protruding at a predetermined interval from the upper surface of the base plate (310); and rotating holes (321) formed on the two mounting flanges, respectively. An end portion of a vertical frame (100), which forms a tent structure, is mounted in the rotating holes (321) of the two mounting flanges (320) to be able to rotate up and down by a rotating pin (325), and first vibration absorption units (350) having a vibration absorption function are installed in the rotating holes (321) of the mounting flanges (320). The present invention has a structure that absorbs vibrations caused by strong winds or vibrations transmitted from the lower part to improve durability by applying a flow structure and a vibration absorption structure.

Description

Elastic body for supporting large event tent structures

The present invention relates to an elastic body for supporting a large-sized tent structure for events, and more particularly, to an elastic body for supporting a large-sized tent structure for an event and a large-sized tent structure using the same.

Large-scale events such as large international events and fairs use large tents to accommodate large numbers of people. A large tent can be provided by assembling a large space without pillars in a short time, so it is easy to apply to event venues that need to be installed for a short period of time, and can be dismantled in a short time after use for a required period.

The large-sized tent has a structure including a tent structure fixed to the floor and a tent paper that is coupled to the tent structure to shield the inside and the outside. This tent structure is made of a steel structure, and the tent has a waterproof coating, water-repellent treatment, and UV protection, and uses a fabric that is difficult to ignite in case of fire through flame-proofing.

Since such a large tent is large in size and heavy in weight, it is firmly fixed to the floor to withstand wind loads. However, if a large tent is firmly fixed to the floor surface, the binding force of the fixing means fixing the tent structure to the floor surface is weakened by the vibration generated by the strong wind or the vibration generated from the bottom surface. There is a concern that a collapse of the tent structure may occur due to separation from the unit.

The present invention has been conceived to solve the above problems, and an object of the present invention is to reduce the binding force generated by the vibration by absorbing the vibration generated by the strong wind or the vibration generated from the bottom after the tent is completed. It is to provide a large-sized tent structure supporting elastic body for events and a large-sized tent structure to which the same is applied to prevent the collapse of the tent structure due to separation from the floor by preventing damage to the floor surface.

A large tent structure supporting elastic body for an event according to an embodiment of the present invention for solving the above problems, and a large tent structure to which the same is applied are a base plate fixed with a fixing bolt on the bottom surface and vertically at a predetermined interval on the upper surface of the base plate. It includes two protruding mounting flanges and a pivoting hole respectively formed on the two mounting flanges, and an end of a vertical frame forming a tent structure is mounted in a pivoting hole of the two mounting flanges so as to be rotatable up and down by a pivot pin. , A first vibration absorbing means having a vibration absorbing function is installed in the rotating hole of the mounting flange.

The base plate has a plurality of through-holes, and is fixed to the floor by the fixing bolts fastened to the floor through the through-holes, and the base plate and the mounting flange are connected with a reinforcing plate to reinforce strength. , The reinforcing plates form a pair of two arranged side by side at a predetermined interval, and a coupling hole communicating with each other is formed in the pair of reinforcing plates.

The pivoting hole is located between the two reinforcing plates.

The through hole is located outside the two reinforcing plates.

The fixing bolt is a cement floor expansion bolt.

The two mounting flanges further have a fixed length hole formed on the upper side of the rotation hole, and the fixed length hole is selectively communicated with a communication hole formed in the vertical frame.

The first vibration absorbing means includes a pressing portion installed in a mounting hole formed in the mounting flange to be opened into the rotating hole, and a spring installed in the mounting hole to provide an elastic force in a direction in which the pressing portion protrudes into the rotating hole. And a gripping portion pulling the pressing portion downward so that the pressing portion is inserted into the mounting hole while pressing the spring.

The pressing portion has an upper surface formed in a curved surface, so that the pivot pin inserted into the pivot hole is in close contact with the pivot hole.

Further comprising a second vibration absorbing means having a vibration absorbing function between the bottom surface and the bottom surface of the base plate, wherein the second vibration absorbing means is disposed on the bottom surface of the base plate and communicates with the through hole of the base plate A plurality of buffer members disposed between the formed support plate and the base plate and the support plate, each having a connection hole each formed between the base plate and the support plate and communicated with the through hole of the base plate and spaced apart from each other, and between the base plate and the support plate It is located at and includes a bridge member connecting the plurality of buffer members.

The buffer member has a coupling groove with one side open, and the bridge member has a coupling protrusion corresponding to the coupling groove protruding, the bridge member has a reinforcing strip member coupled to the coupling protrusion, and the bridge member comprises the In a state in which the reinforcing strip member is coupled to the coupling protrusion, the coupling protrusion is coupled to the coupling groove of the buffer member.

The buffer member and the bridge member are formed of a material having a buffer function, the reinforcing strip member is formed of a metal material, the support plate is formed of the same material as the base plate, and the base plate and the mounting flange are It is formed integrally, the base plate and the mounting flange is formed of a steel material, the vertical frame is formed of an aluminum alloy material.

The present invention has a structure capable of absorbing vibration by having one or more vibration absorbing means on the elastic body supporting the tent structure, so the vibration absorbing means absorbs the vibration generated by strong wind or the vibration generated from the bottom after the tent is completed. Thus, it is possible to prevent the weakening of the binding force between the base plate and the floor surface caused by vibration or the weakening of the binding force between the mounting flange and the vertical frame, and there is an effect of preventing the collapse of the tent structure.

1 is a view showing a tent structure to which an elastic body supporting a large tent structure for an event according to an embodiment of the present invention is applied.
FIG. 2 is a partially enlarged view showing part A of FIG. 1, and is a view illustrating a state in which a vertical frame is assembled and erected on an elastic body supporting a tent structure.
3 is a view showing a state before the vertical frame is assembled to the elastic body supporting the tent structure of FIG. 2.
4 is a view showing a state in which a vertical frame is assembled to an elastic body supporting a tent structure and laid on the floor.
5 is a cross-sectional view showing a state in which a vertical frame is assembled and erected on an elastic body supporting a tent structure according to an embodiment of the present invention.
6 is a cross-sectional view showing a state in which a vertical frame is assembled and erected on an elastic body supporting a tent structure according to another embodiment of the present invention.
7 is a perspective view showing a second vibration absorbing means of FIG. 6.
8 is a perspective view showing a part of a tent structure according to an embodiment of the present invention.
9 is a partial enlarged view showing portion B of FIG. 1.
FIG. 10 is a view showing a state before the combination of FIG. 9(c).
11 is a partially enlarged view showing a state in which a connecting rod is installed in a tent structure according to an embodiment of the present invention.
12 and 13 are views showing a state in which a tent is installed by installing a wire on the connecting rod of FIG. 11.
14 is a view showing a tent is completed by installing a tent on the tent structure.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a tent structure to which an elastic body supporting a large tent structure for an event according to an embodiment of the present invention is applied.

As shown in FIG. 1, a large tent structure for an event (hereinafter, a tent structure) 10 is a plurality of horizontal frames connecting between a plurality of vertical frames 100 and vertical frames 100 having a curved structure ( 200) to form a tunnel shape.

The vertical frame 100 and the horizontal frame 200 are formed of an aluminum alloy material to be a lightweight structure.

For example, a large tent structure for events has a considerable size because it can be installed long by extending it in a width of 29m to 40m, a height of 15m to 17m, and a length of about 5m. Therefore, when the vertical frame 100 and the horizontal frame 200 forming the skeleton are made of a steel structure having a high load, many various factors must be considered in order to stably fix the vertical frame 100 to the floor surface due to the high load. For the above reasons, when the vertical frame 100 and the horizontal frame 200 are formed of a lightweight structure, relatively fewer factors may be considered than the steel structure in order to stably fix the vertical frame 100 to the floor surface.

The vertical frame 100 is a curved structure forming both sidewalls and roof slopes, and the roof end has a pointed shape, so that a visually beautiful effect can be provided. The length of the tent structure 10 may be determined according to the number of vertical frames 100.

Both ends of the vertical frame 100 are fixed to the floor by an elastic body 300 supporting a large tent structure for an event, and may be laid or erected on the floor surface.

The tent structure 10 is a vertical frame in which one end of the horizontal frame 200 is fixed to the laid vertical frame 100 at regular intervals, and the other end of the horizontal frame 200 is first erected while erecting the laid vertical frame 100 It is installed in a way that is fixed to (100). The number of horizontal frames 200 connecting the vertical frames 100 may be determined in consideration of the total load or size of the tent structure 10.

FIG. 2 is a partially enlarged view showing part A of FIG. 1, and is a view showing a state in which a vertical frame is assembled and erected on a tent structure supporting elastic body, and FIG. 3 is a state before the vertical frame is assembled to the tent structure supporting elastic body of FIG. 4 is a view showing a state in which a vertical frame is assembled to an elastic body supporting a tent structure and laid on the floor.

As shown in FIGS. 2 to 4, a large tent structure support elastic body for an event (hereinafter, a tent structure support elastic body) 300 includes a base plate 310, a mounting flange 320, and a rotation hole 321.

The base plate 310 is formed in a flat plate shape having a predetermined thickness and is fixed to the bottom surface with a fixing bolt 330.

Mounting flange 320 is formed of two vertically protruding from the upper surface of the base plate 310 at a predetermined interval. The mounting flange 320 is formed in a plate shape having a predetermined thickness, and a rotation hole 321 is formed in each of the two mounting flanges. The rotation holes 321 formed in the two mounting flanges 320 are in communication with each other, and the rotation pins 325 are coupled.

The ends of the vertical frame 100 forming the tent structure 10 in the pivoting holes 321 of the two mounting flanges 320 are coupled through the pivot pins 325. The end 110 of the vertical frame 100 is mounted so as to be able to rotate up and down by a rotation pin 325 in the rotation hole 321 of the two mounting flanges 320.

The end 110 of the vertical frame 100 is formed through a rotation hole 111 corresponding to the rotation hole 321, and a communication hole 361a is further formed on the top of the rotation hole 111. The communication hole 361a communicates with the fixed length hole 323 of the mounting flange 320 to be described later. A locking pin (not shown) may be coupled through the fixing hole 323 of the mounting flange 320 and the communication hole 361a of the vertical frame 100. The locking pin may be coupled by passing through the fixing hole 323 of the mounting flange 320 and the communication hole 361a of the vertical frame 100 for solid fixation while the vertical frame 100 is erected on the floor. have.

The base plate 310 is formed with a plurality of through-holes (refer to 201 of FIG. 6 ), and is fixed to the bottom surface by fixing bolts 330 that are fastened to the bottom surface through the through-holes 361a. The floor may be ground (grass, soil) or cement (concrete). The fixing bolt 330 is a cement floor expansion bolt. For example, the cement floor expansion bolt may be an anchor bolt with an anchor cap coupled to the outer periphery, a screw bolt with an outer diameter extension coupled to the outer periphery, an anchor with a wedge formed on the outer periphery, or a screw or concrete spanner with a calblock coupled to the outer periphery. The concrete spanner may be a galvanized spanner or a stainless steel spanner. In the embodiment, it is shown that a screw-type anchor with a wedge formed on the outer circumference of the fixing bolt 330 is used. However, it is not necessarily limited thereto, and expansion anchors or concrete spanners may be used. The expansion anchor may improve the fixing force of the base plate 310 fixed to the ground by applying a double expansion anchor.

The base plate 310 and the mounting flange 320 are connected by a reinforcing plate 340 to reinforce strength. Two reinforcing plates 340 are arranged side by side at regular intervals to form a pair, and a coupling hole 341 communicating with each other is formed in the pair of reinforcing plates 340. In the embodiment, the reinforcing plate 340 is formed in a triangular plate shape in which one edge is integrally connected with the base plate 310 and the other edge perpendicular to the one edge is integrally connected with the mounting flange 320. In the coupling hole 341, a connecting rod 400 for installing a tent paper 500 to be described later is coupled.

The pivot hole 321 is located in the mounting flange 320 corresponding to between the two reinforcing plates 340, and the through hole 361a is located in the base plate 310 corresponding to the outside of the two reinforcing plates 340. Is formed. The position of the through hole 361a allows the base plate 310 to be stably fixed to the bottom surface, and the position of the pivot hole 321 is a position at which the vertical frame 100 becomes the center of gravity of the mounting flange 320 To be fixed to the tent structure support elastic body 300 to stably support the vertical frame 100. Each tent structure supporting elastic body 300 must stably support the vertical frame 100 to secure the overall balance of the tent structure 10 and to secure durability.

The two mounting flanges 320 have a fixed length hole 323 further formed on the upper side of the rotation hole 321, and the fixed length hole 323 is selectively communicated with a communication hole 361a formed in the vertical frame 100. . A locking pin for fixing a state in which the vertical frame 100 is erected with respect to the floor may be coupled through the fixing long hole 323 of the mounting flange 320 and the communication hole 361a of the vertical frame 100. The fixing hole 323 is formed to be elongated to the left and right, and the end portion 110 of the vertical frame 100 is rotatably coupled to the mounting flange 320 to be fixed to a certain portion with fluidity, and the vertical frame 100 against vibration ) To absorb the vibration while flowing left and right as much as the length of the fixed long hole 323.

5 is a cross-sectional view showing a state in which a vertical frame is assembled and erected on an elastic body supporting a tent structure according to an embodiment of the present invention.

As shown in FIG. 5, a first vibration absorbing means 350 having a vibration absorbing function may be installed in the rotation hole 321 of the mounting flange 320 of the tent structure supporting elastic body 300.

The first vibration absorbing means 350 includes a pressing part 351, a spring 353, and a gripping part 355.

The pressing part 351 is installed in the mounting hole 326 formed in the mounting flange 320 so as to be opened through the rotation hole 321. The spring 353 is installed inside the mounting hole 326 to provide an elastic force to the pressing portion 351 in a direction in which the pressing portion 351 protrudes toward the rotation hole 321. The gripping portion 355 may pull the pressing portion 351 downward so that the pressing portion 351 is inserted into the mounting hole 326 while pressing the spring 353. The gripping part 355 protrudes to one side of the mounting flange 320 so that an operator can grip and manipulate it.

The pressing portion 351 has an upper surface formed in a curved surface, so that the rotation pin 325 inserted into the rotation hole 321 is in close contact with the rotation hole 321. The pressing part 351 elastically supports the rotation pin 325 which is rotatably installed in the rotation hole 321, and absorbs the vibration generated when the vertical frame 100 is shaken by strong wind, so that the vibration is reduced to the base plate 310 ) By preventing the base plate 310 from being weakened by the bottom surface and vibration.

In addition, the first vibration absorbing means 350 absorbs the vibration generated from the lower part to prevent the vibration from being transmitted to the vertical frame 100 to prevent the binding force between the vertical frame 100 and the horizontal frame 200 from being weakened. do. That is, the first vibration absorbing means 350 prevents the vibration transmitted to the vertical frame 100 from being transmitted to the base plate 310 through the mounting flange 320, and the vibration transmitted to the base plate 310 The elastic buffer structure is installed between the vertical frame 100 and the mounting flange 320 to prevent transmission to the vertical frame 100 through the mounting flange 320.

6 is a cross-sectional view showing a state in which a vertical frame is assembled and erected in a tent structure supporting elastic body according to another embodiment of the present invention, and FIG. 7 is a perspective view showing a second vibration absorbing means of FIG. 6.

As shown in FIGS. 6 and 7, the tent structure supporting elastic body 300 includes a second vibration absorbing means 360 having a vibration absorbing function between the bottom surface and the bottom surface of the base plate 310.

The second vibration absorbing means 360 includes a support plate 361, a buffer member 363, a bridge member 365 and a reinforcing strip member 367.

The support plate 361 is disposed on the bottom of the base plate, and a through hole 361a communicating with the through hole 361a of the base plate 310 is formed.

The buffer member 363 is located between the base plate 310 and the support plate 361, and a connection hole 363a communicating with the through hole 361a of the base plate 310 is formed one by one and separated from each other. It is formed by a plurality of arranged pieces. In the embodiment, four buffer members 363 are provided and are symmetrical to each other.

The bridge member 365 is positioned between the base plate 310 and the support plate 361 and connects a plurality of buffer members 363 to form one plate shape.

The buffer member 363 has a coupling groove 363b with one side open, and the bridge member 365 has a coupling protrusion 363b corresponding to the coupling groove 363b protruding. Bridge member 365 is a reinforcing strip member 367 is coupled to the coupling protrusion (363b). In the bridge member 365, the coupling protrusion 363b is coupled to the coupling groove 363b of the buffer member 363 while the reinforcing strip member 367 is coupled to the coupling protrusion 363b.

The buffer member 363 and the bridge member 365 are formed of a material having a buffer function, and the reinforcing strip member is formed of a metal material. The material having a buffer function constituting the buffer member 363 and the bridge member 365 may be at least one of a silicone member, an elastic plate member, a rubber plate member, and a plate member having a cushion function. Alternatively, a material with a buffer function can have a load of rubber-coke plate-rubber multi-layered to have elasticity and load-bearing capacity at the same time. The material with the cushioning function has elasticity and can absorb vibration.

That is, the buffer member 363 and the bridge member 365 made of a material having a buffer function absorb vibration transmitted from the vertical frame 100 by strong wind, so that the base plate 310 is fixed to the floor surface. It prevents that the binding force is weakened by shaking by the vibration, and also prevents the vibration generated from the lower part from being transmitted to the base plate 310.

The reinforcing strip member 367 is disposed at the connection portion between the buffer member 363 and the bridge member 365 in order to reinforce the load-bearing capacity, and the reinforcing strip member 367 includes a plurality of buffer members 363 directly It prevents contact and blocks the transmission of vibrations between them.

The support plate 361 is formed of the same material as the base plate 310.

The base plate 310 and the mounting flange 320 are integrally formed, and the base plate 310 and the mounting flange 320 are formed of a steel material. That is, the base plate 310, the mounting flange 320, and the support plate 361 constituting the tent structure supporting elastic body 300 are formed of a steel material having a load and high strength to support the vertical frame 100 The structure 10 can be stably supported.

The vertical frame 100 and the horizontal frame 200 are formed of an aluminum alloy material. Aluminum alloy material is a flexible material that secures vibration resistance and durability, and has no corrosion, so that permanent life and corrosion resistance are secured.The weight of the tent structure 10 can be reduced due to a lighter load compared to steel, and the tent structure support elastic body 300 ) To be able to support the tent structure 10 more stably.

Hereinafter, the vertical frame 100 is assembled to the tent structure supporting elastic body 300 according to an embodiment of the present invention, and the horizontal frame 200 is connected to the vertical frame 100 to complete the tent structure 10, and the tent The process of completing the tent by combining the tent paper with the structure will be described.

8 is a perspective view showing a part of a tent structure according to an embodiment of the present invention.

As shown in FIGS. 2 and 8, both ends of the vertical frame 100 may be assembled to the tent structure supporting elastic body 300 so as to be rotatable vertically and supported on the floor surface.

The vertical frame 100 is fixed in a state in which the fixing pin coupled to the fixing long hole 323 and the communication hole 361a in a state rotatably coupled to the mounting flange 320 is erected on the vertical frame 100 with respect to the floor surface. Since it is fixed with partial fluidity, the vertical frame 100 can absorb vibration while moving left and right by the length of the fixed long hole 323.

In addition, the vertical frame 100 is disposed on the lower surface of the first vibration absorbing means 350 and the base plate 310 installed in the rotation hole 321 to elastically support the rotation pin 325 and the base plate 310 It is provided in the second vibration absorbing means 360 for absorbing vibration while performing a buffer function between the floor surface and the second vibration absorbing means 360 can absorb the vibration.

The tent structure supporting elastic body 300 having one or more vibration absorbing means absorbs the vibration generated by strong wind or the vibration generated from the bottom after the tent is completed, and the base plate 310 and the floor It is possible to prevent collapse of the tent structure 10 by preventing weakening of the bonding force of the surface or weakening of the bonding force between the mounting flange 320 and the vertical frame 100.

In addition, the tent structure 10 connects the vertical frames 100 to the horizontal frames 200. Since the length of the horizontal frame is adjustable, the distance between the vertical frame 100 and the vertical frame 100 can be adjusted. For example, the length of the horizontal frame 200 can be adjusted in a range of 5m to 6m, and the tent structure 10 may be installed so that the distance between the vertical frame 100 and the vertical frame 100 is in the range of 5m to 6m. The horizontal frame 200 is a hole of the installation plate 210 in a state in which the installation plate 210 provided at the end of the horizontal frame 200 is abutted to the fixing holes 115 formed at regular intervals on both sides of the vertical frame 100 The end of the horizontal frame 200 may be fixed to the vertical frame 100 by fastening a bolt to the fixing hole 115 of the vertical frame 100. The shape of the fixing hole 115 formed in the vertical frame 100 may be referred to (b) of FIG. 9.

FIG. 9 is a partially enlarged view showing part B of FIG. 1, FIG. 9(a) is a view showing a state in which a horizontal frame is coupled to a pointed portion of a roof end of a vertical frame, and FIG. 9(b) is a vertical It is a view showing the appearance before the straight vertical frame is joined to the lower surface of the pointed portion of the roof end of the frame, and Fig. 9(c) is the appearance of the straight vertical frame joined to the lower surface of the pointed portion of the roof end of the vertical frame It is a view showing, and FIG. 10 is a view showing a state before the combination of FIG. 9C.

The vertical frame 100 includes a straight vertical frame forming both side walls and roof slopes, a curved vertical frame corresponding to a pointed portion of the roof end, a curved vertical frame connecting both side walls and the roof slope, and a column-shaped vertical frame It may include.

9A to 9C, the vertical frame 100 includes a straight vertical frame 100a forming a roof slope and a curved vertical frame 100b corresponding to a pointed portion of the roof end. ) And a columnar vertical frame (100c).

A straight vertical frame 100a is assembled on both sides of the curved vertical frame 100b to form a vertical frame 100 having a shape including a pointed portion of the roof end and both side slopes.

The curved vertical frame 100b has fixing holes 115 formed at the front and rear surfaces, and the horizontal frame 200 is fixed to the fixing holes 115. That is, one end of the horizontal frame 200 may be fixed to the vertical frame 100 by fastening bolts to the hole 115 and the fixing hole 115 of the mounting plate 210 formed at the end of the horizontal frame 200. The method in which the horizontal frame 200 is fixed to the vertical frame 100 at predetermined intervals is the same as the above method. In the embodiment, four fixing holes 115 are formed in a pair and formed on both sides of the vertical frame 100 at a predetermined interval. A reinforcing plate 220 is provided between the horizontal frame 200 and the installation plate 210 to reinforce the strength of a connection portion between the horizontal frame 200 and the vertical frame 100.

On the lower surface of the curved vertical frame 100b, a hinge portion 117 having a hinge hole is formed to protrude. A columnar vertical frame 100c is coupled to the hinge portion 117 via a hinge pin 118. The columnar vertical frame 100c is for supporting the pointed portion of the end of the roof from the bottom surface. The columnar vertical frame 100c is installed only in the front and rear of the tent structure 10 to support the pointed portion of the end of the roof.

The columnar vertical frame 100c is formed with a hinge hole 117c corresponding to the hinge hole of the hinge portion 117, and the hinge hole and the curved shape of the corresponding hinge portion 117c of the columnar vertical frame 100c By coupling the hinge pin 118 to the hinge hole of the hinge portion 117 of the vertical frame 100b, it is possible to fix the columnar vertical frame 100c to the lower surface of the curved vertical frame 100b in a flowable manner. This is to fix the curved vertical frame (100b) to the uppermost end of the column-shaped vertical frame (100c) to allow a certain portion of the flow so that the hinge parts (117, 117c) can absorb the vibration caused by strong wind.

As shown in FIG. 10, a straight vertical frame 100a is assembled on both sides of a curved vertical frame 100b to form a vertical frame 100 having a shape including a pointed portion of the roof and both side slopes. .

Both sides of the curved vertical frame 100b are formed with end portions of a cross-sectional area that can be fitted into the inside of the straight vertical frame 100a, and fixing holes 115 are formed at the ends thereof. Fixing holes communicating with fixing holes at both ends of the curved vertical frame 100b are also formed at the ends of the straight vertical frame 100a, and the fixing holes 115 and the curved vertical frame 100b of the straight vertical frame 100a ) By fastening the fastening bolts 116 to the fixing holes 115 at both ends of the straight vertical frame 100a on both sides of the curved vertical frame 100b.

The curved vertical frame 100b is further coupled with a reinforcing plate member 119 surrounding the upper surface to reinforce the strength of the pointed portion of the roof. The reinforcing plate member 119 is formed with a fixing hole communicating with the fixing hole 115 of the curved vertical frame 100b, and is integrally fixed by a horizontal frame 200 fixed to the curved vertical frame 100b and a bolt Can be.

FIG. 11 is a partially enlarged view showing a state in which a connecting rod is installed in a tent structure according to an embodiment of the present invention, and FIGS. 12 and 13 are views illustrating a state in which a tent is installed by installing a wire on the connecting rod of FIG. 11, 14 is a view showing a tent is completed by installing a tent on the tent structure.

11, the vertical frame 100 is installed on the tent structure supporting elastic body 300, the horizontal frame 200 is fixed to the vertical frame 100, and then the vertical frame 100 is erected and erected vertically. When the frames 100 are connected, the tent structure 10 is completed.

When the tent structure 10 is completed by the above method, the connecting rod 400 is connected to the neighboring tent structure supporting elastic bodies 300. The connecting rod 400 has one end and the other end coupled to the coupling hole 341 of the reinforcing plate 340 of the tent structure supporting elastic body 300 to connect the neighboring tent structure supporting elastic bodies 300.

Next, as shown in FIG. 12, the wire 450 is coupled to both sides of the tent paper 500, and the wire 450 is inserted into the bottom of the connecting rod 400, and then the connecting rod 400 and the mounting flange ( It is drawn to the top through the space between 320 and moves to the tent structure supporting elastic body 300 located on the opposite side so as to be in close contact with the front surface of the horizontal frame 200. The wire moved to the tent structure supporting elastic body 300 located on the opposite side passes through the space between the mounting flange 320 and the connection rod 400 and is drawn out through the lower portion of the connection rod 400. When the tent is moved to the position of the elastic body 300 supporting the tent structure on the opposite side by the above method, the wires at both ends are fixed to the connecting rod 400 and the tent paper 500 between the vertical frame 100 and the vertical frame 100 ) Can be installed.

If the tent paper 500 is continuously installed between the adjacent vertical frame 100 and the vertical frame 100 by the above-described method, as shown in FIG. 14, both side walls of the tent 1 500) can be wrapped to shield the inner space of the tent (1) from the outside.

A method of fixing the tent paper 500 on the front and rear surfaces of the tent 1 may be fixed by binding the edges to the vertical frame 100 and the horizontal frame 200 with a wire.

The tent paper 500 may be formed of a opaque material, and may have a light transmittance of less than 1% by a triple coating. In addition, the tent paper 500 may be formed to prevent external contamination by coating the surface.

The large tent structure to which the above-described large-sized tent structure supporting elastic body for events is applied, and the tent by applying the same is a structure that absorbs vibration caused by strong winds or vibration transmitted from the lower part by applying a flow structure and a vibration absorbing structure, thereby ensuring durability. Therefore, there is an advantage of solving the problem that the binding force is weakened by vibration caused by the conventional strong wind, and the structure collapses due to separation from the floor surface due to the weakening of the binding force. The large tent structure to which the above-described large tent structure supporting elastic body is applied can be used as an event hall for various exhibitions and events, and an indoor gym.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and various modifications and equivalent other embodiments are possible from those of ordinary skill in the art. The scope of technical protection should be determined by the technical idea of the appended claims.

10: tent structure 100: vertical frame
110: end of the vertical frame 111: rotary hole
113: communication hole 115: fixed hole
116: fastening bolts 117,117c: hinge portion
118: hinge pin 119: reinforcing plate member
100a: straight vertical frame 100b: curved vertical frame
200: horizontal frame 210: mounting plate
220: reinforcement plate
300: elastic body supporting a large tent structure for events
310: base plate 311: through hole
320: mounting flange 321: rotary hole
323: fixed length 326: mounting hole
325: rotation pin 330: fixing bolt
340: reinforcing plate 341: coupling hole
350: first vibration absorbing means 351: pressing part
353: spring 355: holding portion
360: second vibration absorbing means 361: support plate
361a: through hole 363: buffer member
363a: connecting hole 363b: coupling groove
365: bridge member 363b: coupling protrusion
367: reinforcement strip member 400: connecting rod
450: wire 500: tent paper
1: tent

Claims (2)

A base plate fixed to the bottom by fixing bolts;
Two mounting flanges protruding vertically on the upper surface of the base plate at regular intervals; And
A pivot hole formed in each of the two mounting flanges;
Including,
In the pivoting holes of the two mounting flanges, the end of the vertical frame forming the tent structure is mounted so as to be able to rotate up and down by a pivot pin,
A first vibration absorbing means having a vibration absorbing function is installed in the rotating hole of the mounting flange,
The base plate,
A plurality of through holes are formed and fixed to the bottom surface by the fixing bolts fastened to the bottom surface through the through holes,
The base plate and the mounting flange are connected with a reinforcing plate to reinforce strength,
Two of the reinforcing plates are arranged side by side at regular intervals to form a pair, and a coupling hole communicating with each other is formed in the pair of reinforcing plates,
The rotating hole is located between the two reinforcing plates,
The through hole is located outside the two reinforcing plates,
The fixing bolt is a cement floor expansion bolt,
The two mounting flanges,
A fixed long hole is further formed on the upper side of the rotating hole, and the fixed long hole is selectively communicated with a communication hole formed in the vertical frame,
The first vibration absorbing means,
A pressing portion installed in a mounting hole formed in the mounting flange to be opened through the pivoting hole;
A spring installed in the mounting hole to provide an elastic force in a direction in which the pressing portion protrudes into the rotation hole; And
A gripping portion pulling the pressing portion downward so that the pressing portion is inserted into the mounting hole while pressing the spring;
Including,
The pressing portion has an upper surface formed in a curved surface, so that a rotation pin inserted into the rotation hole is in close contact with the rotation hole,
Further comprising a second vibration absorption means having a vibration absorption function between the bottom surface and the bottom surface of the base plate,
The second vibration absorbing means
A support plate disposed on a bottom surface of the base plate and having a through hole communicating with a through hole of the base plate;
A plurality of buffer members positioned between the base plate and the support plate, each having one connecting hole communicating with the through hole of the base plate, and spaced apart from each other;
A bridge member positioned between the base plate and the support plate and connecting the plurality of buffer members;
Including,
The buffer member has a coupling groove with one side open, and the bridge member has a coupling protrusion corresponding to the coupling groove protruding,
The bridge member is a reinforcing strip member is coupled to the coupling protrusion,
The bridge member is coupled to the coupling protrusion of the buffer member in a state in which the reinforcing strip member is coupled to the coupling protrusion,
The buffer member, the bridge member is formed of a material having a buffer function,
The reinforcing strip member is formed of a metal material,
The support plate is formed of the same material as the base plate,
The base plate and the mounting flange are integrally formed,
The base plate and the mounting flange are formed of a steel material,
The vertical frame is formed of an aluminum alloy material,
Elastic for supporting large tent structures for events. delete

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