KR101949414B1 - Scaffolding structure for architecture - Google Patents

Abstract

The present invention relates to a scaffolding structure for a building, in which a connecting pin of a wave earth is slidably coupled along an elongated hole of a retaining pin so that the retaining pin can be accurately guided to an assembling and disassembling position.

Description

{SCAFFOLDING STRUCTURE FOR ARCHITECTURE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a scaffolding structure for a building, and more particularly, to a scaffolding structure for a building which is capable of accurately guiding the engaging pin to an assembling and disassembling position, will be.

In general, a scaffold is installed inside or outside a building to make it safe and efficient to work on a high part of a certain building during new construction or maintenance work of the building.

The scaffold structure includes a plurality of vertically installed vertical beams, a horizontal beam horizontally installed on the vertical beams, and a fastening member for assembling the vertical beams and the horizontal beams. In addition, the vertical beam and the horizontal beam may be additionally provided with foot plates or the like having a predetermined width so that the operator can be positioned.

Here, the fastening member of the skeletal structure is composed of a connector serving as an intermediary for connecting one end of the vertical beam and the horizontal beam, and a fastening member for coupling the connector with the vertical beam and the horizontal beam.

In the conventional scaffold structure, a horizontal beam and a vertical beam are coupled to a connector serving as an intermediary for connecting the vertical beam and the horizontal beam. At this time, a plurality of coupling members are used to connect the horizontal beam and the vertical beam And the coupling member are coupled to each other.

However, in the conventional scaffolding structure, it takes a lot of time to assemble the vertical beam and the horizontal beam using a plurality of fastening members, and it takes a long time to disassemble the vertical beam and the horizontal beam and the connecting member after assembly , A scaffold structure capable of maintaining the assembly strength while ensuring ease of assembling and disassembling work is required.

In addition, the conventional scaffolding structure has a problem that it is troublesome to accurately grasp the quantity and size of the fastening member during assembly and disassembly, and it is troublesome to adjust the height because it is necessary to further connect the vertical beam when changing the height.

A prior art related to the present invention is Korean Patent Laid-Open No. 10-2012-0066568 (Jun. 22, 2012), which discloses a system scaffold and its construction method.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a constructional scaffolding structure in which a connecting pin of a wave earth is slidably coupled along an elongated hole of a retaining pin so that the retaining pin can be accurately guided to an assembling and disassembling position.

Another object of the present invention is to connect the connecting plate of the vertical beam and the waveguide of the horizontal beam by male and female, and then by connecting the connecting plate and the waveguide by using the engaging pin, the engaging pin can be fastened without a separate tool Which can easily be assembled and disassembled, and a plurality of horizontal beams can be connected using one connecting plate, thereby simplifying a connection structure.

The scaffolding structure according to the present invention includes a plurality of vertical beams installed vertically and spaced apart from each other in a horizontal direction and a plurality of horizontal beams spaced apart in the vertical direction between the vertical beams, A plurality of coupling plates spaced from each other in the vertical direction of the vertical beam and having a plurality of coupling holes radially formed in the vertical direction with reference to a vertical center axis line, A plurality of tapered grooves formed on the upper and lower surfaces of the connecting plate so that the side ends of the connecting plate are correspondingly inserted through the pin insertion holes formed in the upper and lower portions and one end thereof is inserted through the upper end of the pin insertion hole into the coupling hole, And a latching pin for latching the plate and the waveguide in the horizontal direction.

The vertical beams are disposed at positions facing each other to form four corners along the horizontal direction, and the horizontal beams are disposed between the vertical beams to have four vertices along the horizontal direction. It is preferable to form a four-sided frame.

In addition, the connection plate and the horizontal beam are preferably spaced apart from each other along the vertical direction of the vertical beam.

Preferably, the horizontal beams are perpendicular to each other along a horizontal direction with respect to a vertical center line of the connecting plate.

Further, it is preferable that the horizontal beam further connects the vertical beams corresponding to the diagonal direction at both ends thereof by diagonal lines.

In addition, it is preferable that the left and right sides of the waveguide are formed with inclined surfaces so that the width in the left and right direction gradually decreases toward the front.

The first curved surface having a length in the vertical direction is arranged along the horizontal direction on the outer surface of the vertical beam and the second curved surface is arranged on the inner circumferential surface of the connection plate so as to correspond to the first curved surface desirable.

Preferably, the engaging pin has a tapered shape gradually narrowing in width toward the bottom. When the engaging pin is inserted into the pin insertion hole, an upper end of the engaging pin is engaged with an upper end of the pin insertion hole.

In addition, the connecting pin is horizontally installed in the pin insertion hole, the connecting pin is horizontally inserted into the engaging pin, and the elongated hole is horizontally penetrated so that the connecting pin is vertically or horizontally rotated .

Further, a joint is further coupled to the upper portion of the vertical beam, and the upper end of the joint extends to the upper end of the vertical beam, and the lower end of the additional vertical beam is coupled to the upper end of the joint.

In addition, a height adjusting beam is further provided at a lower end of the vertical beam, the upper end of the height adjusting beam is coupled to the lower end of the vertical beam in a threaded manner, and the length of the height adjusting beam is adjusted to protrude downward. .

Further, it is preferable that a rotation lever is protruded to the outside so that the vertical beam can rotate horizontally when the height is adjusted.

Further, both ends of the reinforcing beam are rotatably connected to the rear ends of the auxiliary waveguides by the fastening members, and the reinforcing beams supporting the vertical beams with diagonal lines may be further coupled.

In addition, the auxiliary waveguide may have a holding groove formed in a front surface thereof so as to correspond to a side end of the connecting plate, a pin insertion hole formed vertically through the upper and lower surfaces thereof, And the auxiliary plate is further provided with an auxiliary latch pin for latching the auxiliary plate and the auxiliary plate.

According to the present invention, since the engaging pin is rotated in the engaging and disengaging direction with respect to the connecting pin provided on the wave guide, loss of the engaging pin can be prevented, and the engaging pin is rotated within a predetermined rotating range. .

And, by joining the connecting plate of the vertical beam and the waveguide of the horizontal beam with male and female, the connecting plate and the waveguide are fitted together by using the engaging pin, so that the engaging pin can be fastened without a separate tool, And a plurality of horizontal beams can be connected to each other using one coupling plate, thereby simplifying the connection structure.

Further, by providing a joint and a height adjusting beam in the vertical beam, the sizes of the vertical beam and the horizontal beam can be easily expanded, and the installation height can be easily changed through the rotation operation.

In addition, by forming a curved surface on the outer surface of the vertical beam, the horizontal beam, and the reinforcing beam, the grip feeling can be improved, and it is possible to prevent slippage in the hand.

1 is a side view for illustrating a scaffolding structure according to the present invention.
2 is a plan view showing a scaffolding structure according to the present invention.
FIG. 3 is a perspective view for showing a coupling state of a connection plate and a wave earth of a scaffolding structure according to the present invention.
FIG. 4 is a side view for showing a state prior to coupling the connection plate and the wave earth of the scaffolding structure according to the present invention.
FIG. 5 is a plan view showing a state in which a connection plate of a scaffolding structure according to the present invention is combined with a wave earth.
FIG. 6 is a side view showing a state in which engaging fins of a building skeleton structure according to the present invention are engaged.

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

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving it will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims.

In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 1 is a side view showing a scaffolding structure according to the present invention, FIG. 2 is a plan view showing a scaffolding structure according to the present invention, FIG. 3 is a cross- And FIG.

FIG. 4 is a side view for showing a state prior to coupling the connection plate and the wave earth according to the present invention. FIG. 5 is a cross- Fig.

FIG. 6 is a side view for showing a state in which engaging fins of a building skeleton structure according to the present invention are engaged.

1 to 6, the architectural scaffold structure according to the present invention includes a plurality of vertical beams 100, a plurality of horizontal beams 200, a plurality of connection plates 300, And a plurality of latching pins (500).

In addition, a footrest (not shown) or the like may be installed within the connection structure of the vertical beam 100 or the vertical beam 100 and the horizontal beam 200, such that the operator can elevate the vertical beam 100 to a predetermined height.

First, the vertical beam 100 is installed at a predetermined length perpendicular to the mounting surface 10, and the vertical beam 100 may be formed into a cylindrical shape having a circumferential shape in the transverse direction.

Here, the lower end of the vertical beam 100 may be coupled to the mounting surface 10 by a separate fastening member, and a support plate 110 having a predetermined width may be further formed at a lower end of the vertical beam 100 have.

The lower end of the support plate 110 can be seated on the installation surface 10 and can be fixed to the installation surface 10 by penetrating the fastening member through the support plate 110.

The vertical beam 100 can be manufactured to have a predetermined length by using a metal (aluminum or the like) material. On the outer surface of the vertical beam 100, a curved surface 120 extending in the longitudinal direction is formed along a plurality of Lt; / RTI >

The curved surface 120 of the vertical beam 100 is in close contact with the inner circumferential surface of the connecting plate 300 to be described later and is engaged with the inner circumferential surface of the connecting plate 200, Can be further improved.

Since the curved surface 120 of the vertical beam 100 protrudes in the lateral direction of the horizontal beam 200, it is possible to improve grip feeling and prevent slippage in the hand during the operation.

2, two vertical beams 100 may be arranged side by side on one side, and a pair of vertical beams 100 may be arranged in a direction corresponding to the pair of vertical beams 100. In this case, The beams 100 may be arranged correspondingly.

At this time, the vertical beams 100 may form four corner portions along the horizontal direction and are connected to the vertex portions of the horizontal beam 200 to be described later to form one assembly.

Of course, the vertical beam 100 may be formed of various types of assemblies by applying various numbers of horizontal beams 200 to be described later.

The horizontal beams 200 are installed horizontally and horizontally between the vertical beams 100 and the horizontal beams 200 may be horizontally spaced along the vertical direction between the vertical beams 100 .

Here, the horizontal beam 200 may be formed to have a predetermined length by using a metal (aluminum or the like) material, and the vertical beam 100 may be formed into a cylindrical shape having a circumferential circumference.

A plurality of longitudinally extending curved surfaces 210 may be arranged along the lateral direction on the outer surface of the vertical beam 100.

Since the curved surface 210 of the horizontal beam 200 protrudes in the lateral direction of the horizontal beam 200, it is possible to improve grip feeling and prevent slippage in the hand during operation.

2, the number of the horizontal beams 200 and the number of the vertical beams 100 is not limited, and various numbers of the horizontal beams 200 and the vertical beams 100 may be used.

For example, the horizontal beam 200 can be installed in a total of four as shown in FIG. 2, in which the horizontal beam 200 is disposed between the vertical beams 100, and four vertices along the horizontal direction And can be formed into a quadrangular frame.

At this time, the horizontal beam 200 may be disposed at the upper and lower portions of the vertical beam 100 together with the coupling plate 300 and the waveguide 400, which will be described later, as shown in FIG.

Alternatively, the horizontal beam 200 may be arranged in a state that two or more vertical beams 100 are separated from each other along with the connecting plate 300 and the wave guide 400, which will be described later.

As such, the horizontal beams 200 may form four corner portions so that four vertexes are formed along the horizontal direction as shown in FIG.

At this time, the horizontal beam 200 is perpendicular to the vertical center line of the connecting plate 300, which will be described later, and the pair of horizontal beams 200 can be positioned in parallel with each other.

2, the horizontal beam 200 may be further connected to the vertical beams 100 whose both ends are positioned corresponding to each other in a diagonal direction.

In this case, the wave quadrants 400 of the horizontal beams 200 forming the quadrangular frame are respectively coupled to the perpendicular direction of the coupling plate 300, and the wave quadrants 400 of the horizontal beams 200 connected by diagonal lines May be coupled between wave quadrants (400) of horizontal beams (200) forming a quadrilateral frame.

At this time, the wave earth 400 of the horizontal beam 200 connected to the oblique line is coupled in a diagonal (about 45 degrees) direction to one end of a connection plate 300 to be described later.

Therefore, by further joining the horizontal beam 200 in the oblique direction, the coupling strength between the horizontal beam 200 and the vertical beam 100 can be further improved.

Since the horizontal beam 200 stably supports the vertical beams 100, the vertical beams 100 are prevented from being deformed or deformed due to a load acting on the vertical beams 100.

The connection plate 300 is for connecting the vertical beam 100 and the horizontal beam 200 and the connection plate 300 may be spaced apart from the vertical beam 100 in the longitudinal direction.

The inner circumferential surface of the connecting plate 300 and the outer circumferential surface of the vertical beam 100 are welded or joined together using a separate fastening member, .

The connecting plate 300 may be formed in a circular plate shape having a side end forming a circumference and vertically penetratingly connected to the vertical center line of the connecting plate 300 such that the center line of the vertical beam 100 is aligned.

As shown in FIG. 2, the coupling plate 300 is formed with a plurality of locking holes 310 in the upper and lower directions radially with reference to the central axis line thereof.

The latching hole 310 is for engaging a latching pin 500 to be described later. The latching hole 310 is formed of four pieces in the front, rear, left and right 90 degrees direction, four pieces in the oblique direction, It is preferable to form them in the number of.

Here, the latching hole 310 may have a shape corresponding to the latching pin 500 described later, and the latching hole 310 may have a rectangular hole shape or the like.

Of course, the latching hole 310 can be applied in various angles and numbers as necessary, and the shape and size of the latching hole 310 can be variously applied.

The curved surface may be arranged on the inner circumferential surface of the connection plate 300 so as to be coupled to the curved surface 120 of the vertical beam 100 described above.

That is, the curved surface formed on the inner circumferential surface of the connection plate 300 and the curved surface 120 of the vertical beam 100 described above may be hung horizontally.

Since the coupling plate 300 has a plurality of coupling holes 310 arranged radially with respect to the vertical center line, the coupling plate 300 can connect the waveguide 400 and the horizontal beam 200, which will be described later, have.

The wave earth 400 is for horizontally connecting one end of the horizontal beam 200 with the connection plate 300 as shown in FIGS. 4A and 4B and FIGS. 5A and 5B, Earth 400 is coupled to both ends of horizontal beam 200, respectively.

Here, the gripping grooves 410 are concavely formed on the front surface of the waveguide 400 so that the side ends of the connecting plate 300 are correspondingly inserted as shown in FIGS.

The gripping groove 410 has a shape corresponding to the side end of the connecting plate 300 and has a shape in which the front end and the left and right directions are opened so that the side end of the connecting plate 300 can be inserted.

That is, as shown in FIG. 2, the upper and lower surfaces of the gripping grooves 410 may be engaged with the upper and lower surfaces of the connecting plate 300, respectively.

A pin insertion hole 420 is formed in the upper surface and the lower surface of the grip groove 410 so as to vertically penetrate the engaging pin 500 to be described later.

6, when the lower end of the latching pin 500 to be described later is inserted through the upper end of the pin insertion hole 420, the lower end of the latching pin 500 is inserted into the latching hole 310 .

In addition, the left and right sides of the waveguide 400 may be formed with inclined surfaces 430 so that the width in the left and right direction gradually decreases toward the front.

When the plurality of waveguides 400 are coupled along the side surface of the connection plate 300, the inclined surface 430 of the waveguide 400 has an inclination angle corresponding to the side surface of the adjacent waveguide 400 It is possible to eliminate mutual interference.

In addition, one end of the horizontal beam 200 may be inserted into the lower end of the waveguide 400 in a corresponding manner, and may be coupled by a separate fastening member B.

For example, when the horizontal beam 200 is applied in a quadrangular frame shape as shown in FIG. 2, the wave quadruple 400 is coupled to one end of the coupling plate 300 in a direction perpendicular to one end thereof, And can be connected to the plate 300 at an angle of 90 degrees.

The engaging pin 500 is inserted into the engaging hole 310 through the upper end of the pin inserting hole 420 as shown in FIGS. 6A and 6B to connect the connecting plate 300 and the wave guide 400 to the engaging position .

Here, the retaining pin 500 may have a tapered shape gradually narrowing in width as it goes down as shown in FIGS. 2, 5 and 6.

For example, when the latching pin 500 is inserted into the pin insertion hole 420, the upper end of the latching pin 500 is engaged with the upper end of the pin insertion hole 420 as shown in FIG. 6 (2) .

The connecting pin 440 may be horizontally installed in the pin insertion hole 420 and the elongated hole 510 may be horizontally connected to the engaging pin 500 such that the connecting pin 440 can be horizontally inserted into the hole. As shown in FIG.

The long hole 510 has a length along the longitudinal direction of the engagement pin 500, that is, in the direction of assembly and disassembly. When the engagement pin 500 is vertically inserted as shown in (2) of FIG. 6, The pin 500 is inserted into the pin insertion hole 420 and the locking hole 310 so that the connection pin 440 is engaged with the upper end of the long hole 510.

6 (1), when the engaging pin 500 is rotated horizontally, the engaging pin 500 is separated from the pin inserting hole 420 and the engaging hole 310 so that the lower end of the elongate hole 510 The connecting pin 440 is engaged.

The latching pin 500 prevents the coupling plate 300 and the waveguide 400 from being easily separated by a force acting in the horizontal direction.

Since the waveguide 400 is positioned above and below the connection plate 300, the vertical beam 100 and the horizontal beam 200 are not separated by a force acting in the vertical direction.

On the other hand, a connecting joint 130 may be further coupled to the upper portion of the vertical beam 100, and the upper end of the joint 130 extends to the upper end of the vertical beam 100.

At this time, the lower end of the vertical beam may be coupled to the upper end of the joint 130 to increase the length of the vertical beam 100 in the vertical direction.

The joint 130 may be formed in a cylindrical shape having a diameter smaller than that of the vertical beam 100 and may be made of the same metal as the vertical beam 100.

The fastening holes may be horizontally inserted into the upper and lower ends of the joint 130, and the fastening member B may be coupled through the fastening holes to connect the vertical beams 100.

Thus, since the structure of the vertical beam 100 and the horizontal beam 200 can be selectively expanded by using the joint 130, it is possible to minimize the work delay due to the height change during the operation.

The height adjustment beam 140 may be coupled to the lower end of the vertical beam 100 in a threaded manner to the lower end of the vertical beam 100, The protruding length can be adjusted.

The height adjustment beam 140 is formed in a cylindrical shape so as to be horizontally rotatable in a state of being inserted in the lower end of the vertical beam 100 and is formed on the outer circumference of the vertical beam 100 and the outer circumference of the height adjustment beam 140 Corresponding threads are formed.

In addition, a rotation lever 141 may protrude outward from the lower end of the vertical beam 100 so as to rotate horizontally when the height of the vertical beam 100 is adjusted.

That is, the rotation lever 141 can be rotated in the forward or reverse direction to easily adjust the protruding length of the height adjusting beam 140.

Therefore, the vertical height of the vertical beam 100 and the horizontal height of the horizontal beam 200 can be variably controlled by controlling the length of the height adjustment beam 140 protruded.

1 and 2, the auxiliary waveguide 600 may be coupled to the side of the coupling plate 300. The auxiliary waveguide 600 may have the same shape as the waveguide 400 described above Lt; / RTI >

A grasping groove 610 is formed on the front surface of the auxiliary waveguide 600 so that the side edge of the connecting plate 300 is correspondingly inserted into the front surface of the auxiliary waveguide 600, The pin insertion hole 620 can be formed vertically so as to be vertically coupled.

The gripping grooves 610 of the auxiliary waveguide 600 have a shape corresponding to the side ends of the connecting plate 300 and the gripping grooves 620 are formed in the front side of the connecting plate 300, And the left and right directions are opened.

That is, as shown in the enlarged view of FIG. 2, the upper and lower surfaces of the gripping grooves 610 can be engaged with the upper and lower surfaces of the connecting plate 300.

The auxiliary waveguide 600 may be positioned between the waveguides 400 coupled to the coupling plate 300 in a direction perpendicular to the coupling plate 300 so that the reinforcing beam 700 to be described later may be inclined.

A reinforcing beam 700, which is connected to the outer ends of the vertical beams 100 and connected to the rear ends of the auxiliary waveguides 600 at both ends, supports the vertical beams 100 in a diagonal direction.

The reinforcing beam 700 is rotatably coupled to the rear ends of the auxiliary waveguides 600 whose both ends are different in height. The opposite ends of the reinforcing beam 700 are connected to a connecting plate 300 respectively.

The reinforcing beam 700 may be formed to have a predetermined length by using a metal (aluminum or the like) material. A curved surface 710 extending in the longitudinal direction may be formed on the outer surface of the reinforcing beam 700, Lt; / RTI >

More specifically, the auxiliary waveguide 600 is coupled to the coupling plate 300 located at the upper end of one of the vertical beams 100, and the coupling plate 300, which is positioned lower in the other vertical beam 100, It is possible to couple the auxiliary wave earth 600 to the waveguide 300.

In this state, the outer surface of the vertical beam 100 can be reinforced by inclining both ends of the reinforcing beam 700 to the connecting plates 300 having different height.

For example, the rear end of the auxiliary waveguide 600 and both ends of the reinforcing beam 700 may be coupled by a separate fastening member B, which fastens the reinforcing beam 700 as shown in FIG. And may be horizontally coupled to the rear end of the auxiliary waveguide 600 through one end of the auxiliary waveguide 600.

At this time, the fastening member B can form a horizontal rotation center so that the reinforcing beam 700 can be rotated in the vertical direction, and the reinforcing beam 700 can be inclined.

That is, since the reinforcing beam 700 is reinforced in an inclined form between the vertical beams 100, the coupling strength of the vertical beam 100 of the horizontal beam 200 can be further improved.

The pin insertion hole 620 of the auxiliary waveguide 600 is inserted into the coupling hole 310 of the coupling plate 300 through the upper end of the coupling plate 300, And an auxiliary latching pin 800 for latching the latching pin.

Here, the auxiliary waveguide 600 has the same shape as the waveguide 400 described above, and a connection pin (not shown) may be installed horizontally in the pin insertion hole 620.

In addition, the connection pin may be horizontally inserted into the auxiliary locking pin 800, and may be horizontally inserted into the auxiliary locking pin 800 such that the connection pin is vertically or horizontally rotated.

For example, when the lower end of the auxiliary locking pin 800 is inserted through the upper end of the pin insertion hole 620, the lower end of the auxiliary locking pin 800 is inserted into the locking hole 310 of the coupling plate 300 Can be inserted.

In addition, the right and left sides of the auxiliary waveguide 600 may be formed with inclined surfaces 630 such that the lateral width gradually decreases toward the front.

The inclined surface 630 of the auxiliary waveguide 600 may be formed to have an inclination angle corresponding to the inclined surface 430 of the waveguide 400 when the waveguide 400 is coupled to the side edge of the connection plate 300 have.

The inclined surface 630 of the auxiliary waveguide 600 prevents interference with the adjacent waveguide 400.

As a result, in the present invention, the connection plate 300 of the vertical beam 100 and the wave guide 400 of the horizontal beam 200 are coupled with each other by using male and female engaging pins 500, The earth 400 can be engaged.

The present invention can prevent the latch pin 500 from being lost by allowing the latch pin 500 to rotate in the latching and latching direction with respect to the connecting pin 440 provided on the latching portion 400, Since the engagement pin 500 is rotated within the rotation range, the ease of assembly can be ensured.

Since the engaging pin 500 can be fastened without a separate tool, it is easy to assemble and disassemble, and a plurality of horizontal beams can be connected using one connecting plate 300, so that the connection structure can be simplified.

The vertical beam 100 and the horizontal beam 200 can be easily expanded in size by providing a joint and a height adjustment beam 140. The vertical height of the vertical beam 100 and the horizontal beam 200 can be easily expanded, Can be varied.

In addition, by forming a curved surface on the outer surface of the vertical beam 100, the horizontal beam 200, and the reinforcing beam 700, it is possible to improve grip feeling and prevent slippage in the hand.

Although specific embodiments of the architectural scaffold structure of the present invention have been described so far, it is apparent that various modifications can be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be construed as being limited to the embodiments described, but should be determined by the scope of claims of the patent as well as the claims of the patent registration described later.

That is, it should be understood that the above-described embodiments are illustrative and non-restrictive in all aspects and that the scope of the present invention is defined by the appended claims rather than the detailed description, Ranges and equivalents thereof are to be construed as being included within the scope of the present invention.

10: Mounting surface 100: Vertical beam
110: Support plate 120: Curved surface
130: joint 140: height-adjustable beam
141: rotation lever 200: horizontal beam
210: curved surface 300: connecting plate
310: Jam hole 400: Earth district
410: Finger groove 420: Pin insertion hole
430: slope 440: connecting pin
500: engaging pin 510: long hole
600: auxiliary wave region 610: gripping groove
620: pin insertion hole 630: inclined surface
700: reinforcing beam 710: curved surface
800: auxiliary locking pin B: fastening member

Claims (15)

A plurality of vertical beams installed vertically and spaced apart from each other in a horizontal direction, a plurality of horizontal beams installed horizontally and spaced apart from each other in the vertical direction between the vertical beams, A plurality of coupling plates spaced apart from each other and having a plurality of locking holes radially formed in a radial direction with reference to a vertical center axis line so that the coupling plates are coupled to both ends of the horizontal beam, And a pin insertion hole formed vertically through the upper and lower sides of the pin insertion hole, and one end of the pin insertion hole is coupled to the engagement hole through the upper end of the pin insertion hole, Wherein the connection pin is horizontally installed in the pin insertion hole, and the connection pin is horizontally inserted into the engagement pin, The vertical holes are horizontally penetrated so that the connection pins are vertically or horizontally rotated in a coupled state. The vertical beams are arranged at positions facing each other, and four corners are formed along the horizontal direction And the horizontal beam is disposed between the vertical beams to form a quadrangular frame so as to have four vertexes along the horizontal direction, and the horizontal beams are formed by diagonally arranging the vertical beams whose both ends are positioned in the diagonal direction Connect,
Wherein the horizontal beams are perpendicular to each other along a horizontal direction with respect to a vertical center line of the connection plate and auxiliary beams are respectively coupled to the side ends of the connection plates so as to vary in height, Wherein the reinforcing beam is coupled to the rear end of the auxiliary waveguide by a fastening member so as to be pivotally connected to each other and supports the vertical beams in a diagonal direction, and both ends of the reinforcing beam are coupled to the connecting plates And a pin insertion hole is formed in an upper portion and a lower portion of the pin insertion hole so as to penetrate through the pin insertion hole. The pin insertion hole is inserted into a locking hole through an upper end of the pin insertion hole, The connecting pin is further provided with an auxiliary locking pin for locking the auxiliary wave earth, and a connecting pin is horizontally installed inside the pin insertion hole Wherein the connection pin is horizontally inserted into the auxiliary locking pin and the elongated hole having a length along the assembly and disassembly direction is horizontally penetrated so that the connection pin is vertically or horizontally rotated in a coupled state,
The left and right sides of the waveguide are each formed with inclined surfaces so that the width in the left and right direction gradually decreases toward the front side. A joint having a diameter smaller than that of the vertical beam is further coupled to the upper portion of the vertical beam, Extending to an upper end of the vertical beam, the lower end of an additional vertical beam being coupled to the upper end of the joint,
Wherein a plurality of longitudinally extending bent surfaces are arranged along the lateral direction on the outer surface of the vertical beam, the inner circumferential surface of the connecting plate is coupled to the bent surface of the vertical beam in a corresponding shape, A plurality of longitudinally extending curved surfaces are arranged along the lateral direction,
Wherein the engaging pin is engaged with the pin at an upper end of the elongated hole when inserted perpendicularly to the pin insertion hole and the engaging hole and separated from the pin insertion hole and the engaging hole at the time of horizontally rotating, And the auxiliary pin is inserted into the pin insertion hole and the locking hole and is inserted into the upper end of the insertion hole when the pin is inserted horizontally, And the connecting pin is engaged with the lower end of the long hole separated from the fastening hole. delete The method according to claim 1,
Wherein the connecting plate and the horizontal beam
Wherein a plurality of the vertical beams are spaced apart from each other along a vertical direction of the vertical beams. delete delete delete delete delete The method according to claim 1,
Wherein,
Wherein the pin insertion hole has a tapered shape gradually becoming narrower toward the bottom, and when inserted into the pin insertion hole, the upper end is engaged with the upper end of the pin insertion hole to restrict the insertion position. delete The method according to claim 1,
At the lower end of the vertical beam,
A height adjustment beam is further provided,
The height-
And a lower end of the vertical beam is coupled to the lower end of the vertical beam in a threaded manner so as to be protruded downward, and the lower end is supported on the mounting surface. The method of claim 11,
At the lower end of the vertical beam,
Wherein the rotary lever is protruded outward so as to be horizontally rotatable when the height is adjusted. delete delete delete

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