KR20200057273A - System Scaffolding - Google Patents

Abstract

The present invention relates to a system scaffold which can be installed in an optimal state in accordance with the length and angle of a building wall. The system scaffold comprises: a vertical member installed vertically; a horizontal member horizontally connected to the vertical member; a standard footplate horizontally connected to the vertical member or the horizontal member, and formed to prevent a horizontal and a vertical length from changing when viewed from above; a variable-length footplate horizontally connected to the vertical member or the horizontal member, and formed to allow a horizontal length to change when viewed from above; and a variable-angle footplate horizontally connected to the vertical member or the horizontal member, formed in a fan shape when viewed from above, and formed to allow an angle formed by both straight lines of the fan shape to change.

Description

System Scaffolding

The present invention relates to a scaffold that is installed to secure a worker's working space during construction, and more particularly, to a system scaffold that can be installed in an optimal state according to the length and angle of a building wall.

Temporary work scaffolding for construction work is also commonly referred to as scaffolding, and refers to a temporary installation that is installed so that workers can work at the construction site, and is installed to move workers and transport materials or secure work space.

The scaffold for building construction consists of a horizontal material that is horizontal to the ground and installed horizontally and vertically, a vertical material that vertically connects the horizontal materials so that the horizontal material can be multi-layered, and a rectangular scaffold installed between the horizontal materials, , When viewed in plan, a predetermined distance is formed along the shape of the outer wall or inner wall of the building, and the scaffolding is installed, and the vertical and horizontal members fix the scaffold.

Recently, due to the development of building technology, various shapes and angles of buildings can be built, and scaffolds installed along the outer walls of these buildings do not follow the speed of development of construction technology. It is pointed out as a problem.

Looking at the problems of the conventional scaffolding as follows. First, assuming that there is a building in which the walls are formed in a circular shape when viewed from a plane, the conventional scaffold installs a scaffold of a rectangular shape at a predetermined distance from the wall, thereby exposing the problem that the scaffold cannot be installed at regular intervals with the wall of the building. .

In order to solve the above-mentioned problems, a scaffold having a fan shape disposed between rectangular scaffolds is disclosed, but since it is a fixed fan shape that cannot change an angle between both sides of the fan, it cannot be used in accordance with various shapes and sizes of building walls. There is this.

Looking at the other problems of the above-described conventional scaffolding as follows. It is assumed that the wall is formed at a predetermined distance along the X-axis when viewed in a plane, and bent at 90 degrees to form a predetermined distance along the Y-axis. When a conventional scaffold is installed along such a wall, a situation occurs in which the end of the last scaffold does not coincide with the end of the X-axis of the wall among rectangular scaffolds that are continuously installed along the X-axis.

When the above problem occurs, an economic waste of preparing the scaffold in various lengths in advance to match the tip of the scaffold and the end of the wall, and the hassle of finding and installing a scaffold of an appropriate length occur.

Republic of Korea Patent Publication No. 10-2014-0068641 Republic of Korea Registered Patent Publication No. 10-1556066

The present invention is to solve the conventional problems as described above, its object is to provide a system scaffold optimized for the length and angle of the building wall.

The system scaffolding according to the present invention is a vertical member installed vertically, a horizontal member connected in the horizontal direction with the vertical member, and connected in the horizontal direction with the vertical member or the horizontal member, but is formed so as not to change the length in the horizontal direction and the vertical direction when viewed in a plane. It is connected in a horizontal direction with the standard footboard and the vertical or horizontal member, but is formed in a flat shape when connected in a horizontal direction with the vertical or horizontal member and the variable length scaffold formed so that the vertical length can be changed when viewed from a plane. It is characterized in that it comprises a variable angle foot plate formed so that the angle formed by both sides of the fan-shaped straight line can be changed.

The present invention is composed of a standard scaffold with a fixed length in the horizontal direction when viewed from a plane, a variable length scaffold with variable length in the horizontal direction, and a variable angle scaffold that can change the connection angle between the standard scaffold and the variable length scaffold. It has the effect of installing an optimized scaffold on any shape of the building wall.

1 is a plan view showing the overall configuration of the present invention
Figure 2 is a perspective view showing a standard scaffolding of the present invention
Figure 3 is a plan view showing the coupling state of the scaffolding and horizontal member of the present invention
Figure 4a, 4b is a plan view and a perspective view showing the combined state of the vertical configuration and other components of the standard scaffolding of the present invention
Figure 5a, 5b is a plan view showing a variable-length scaffold of the present invention
Figure 6 is an exploded perspective view showing a variable-length scaffolding of the present invention
Figure 7 is a perspective view showing a state of use of the variable-length scaffolding of the present invention
Figure 8 is a perspective view showing a variable angle footrest of the present invention
Figure 9 is an exploded perspective view showing a variable angle footrest of the present invention
10A and 10B are plan views showing the operation of the variable angle footrest of the present invention.
11 is a plan view showing a state of use of the present invention
12 is a plan view showing another use state of the present invention

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, the known configurations and related operations have been omitted or briefly described, and the size of each component or a specific part constituting the component in the drawings may be exaggerated, omitted, or schematically illustrated for convenience and clarity of description. . In the following description, the horizontal and vertical directions mean directions shown in FIG. 1.

Referring to FIG. 1, the system scaffolding according to the present invention includes a vertical member 100 vertically installed, a horizontal member 200 horizontally connected to the vertical member 100, and the vertical member 100 or horizontal member 200 It is connected in the horizontal direction with the standard scaffold 300 formed so as not to change the length in the horizontal direction and the vertical direction when viewed from the plane, and is connected in the horizontal direction with the vertical member 100 or the horizontal member 200, but in the horizontal direction when viewed from the plane The variable length scaffold 400 is formed so that the length can be changed, and the vertical member 100 or the horizontal member 200 is connected in a horizontal direction, but is formed in a fan shape when viewed in a plane, and an angle formed by both straight lines of the fan shape Characterized in that it comprises a variable-angle foot plate 500 formed to be changeable.

The vertical member 100 includes a pipe formed in a vertical direction and a connection bracket 110 formed on the outer circumference of the pipe. The connecting bracket 110 is formed of a plate body having a predetermined thickness and protrudes in four directions when viewed from a plane for connection with the horizontal member 200, and a through hole to which a wedge W is connected is formed in the protruding portion.

The horizontal member 200 includes a first horizontal member 210 and a second horizontal member 220. The first horizontal member 210 is disposed in a vertical direction and has a long length, and the second horizontal member 220 is disposed in a horizontal direction and has a short length. The coupling of the vertical member 100 and the horizontal member 200 is performed by connecting the connecting bracket 110 to the connecting member 230 formed at both ends of the horizontal member 200, and then connecting the connecting member 230 and the connecting bracket 110. At the same time, the wedges (W) penetrating are connected to each other.

The standard scaffold 300 is a scaffold having a standardized scaffold size and does not change in length in the horizontal and vertical directions. The variable length scaffold 400 is configured such that the length in the horizontal direction does not change and the length in the vertical direction is changeable. The variable angle footrest 500 is formed in a fan shape, and is configured such that the angles formed by both straight lines of the fan shape are changeable.

Referring to Figures 2 and 4 looks at the standard scaffolding. The standard scaffold 300 is composed of a flat foot plate 310 formed to allow an operator to work on it, and a connector 320 formed at both ends in the longitudinal direction of the flat foot plate 310. The connector 320 is one of the first connector 320a or the second connector 320b, and will be described below as the first connector 320a.

The first connector 320a includes a horizontal connecting plate 321 formed to extend in a horizontal direction, two or more upper hooks 323 formed to extend vertically downward from an end of the horizontal connecting plate 321, and the horizontal connection It is formed through the plate 321 and is made of a connecting groove 322 to which the upper hook 323 of the first connector 320a of the standard foot plate 300 or the variable-length foot plate 400 or the variable-angle foot plate is connected.

When the standard footrest 300 is continuously connected in the vertical direction, one side first connector 320a of the standard footrest is connected to the other first connector 320a of the other standard footrest 300, and the one side first connector 320a The horizontal connector plate 321 overlaps the horizontal connector plate 321 of the other first connector 320a in the up and down direction, and the upper hook 323 of the first connector 320a on the other side is the first connector 320a on the other side. It is connected to the connection groove 322 of the. 7 is a view showing a longitudinal connection state of the standard footrest 300 and the variable length footrest 400, the connection between the standard footrest 300 and the first connector () is also the same as FIG. The connection method of the above-described standard scaffold 300 is also applied to the variable-length scaffold 400 and the variable-angle scaffold 500, which will be described below.

Referring to FIG. 4, the second connector 320b has the same configuration as the second horizontal member 220 described above. That is, the pipe is coupled to the longitudinal end of the standard footrest 300, and the coupling holes 230 are provided at both ends of the pipe, and the coupling holes 230 are connected to the connection bracket 110 of the vertical member 100. It is coupled through a wedge (W).

When the second connector 320b is coupled to the standard footrest 300, connection grooves 322 having the same configuration and shape as the connection grooves 322 of the first connector 320a are provided at both ends in the longitudinal direction of the flat foot plate 310. Is formed. This is because continuous arrangement in the vertical direction is not possible due to the morphological characteristics of the second connector 320b.

Accordingly, if the second connector 320b is coupled to both ends of the standard foot plate 300 in the longitudinal direction, the standard foot plate 300 to which the second connector 320b is coupled and the standard foot plate 300 continuously arranged in the vertical direction ) Should be a standard footrest 300 with a first connector 320a coupled, and a connection with an upper hook 323 of the first connector 320a connected to a flat foot plate 310 with a second connector 320b coupled to it. The groove 322 should be formed. The above configuration is applied to both the standard footrest 300, the variable length footrest 400, and the variable angle footrest 500 according to the present invention.

The flat foot plate 310 to which the second connector 320b is coupled is directly connected to the vertical member 100, so that the shaking or position movement of the flat foot plate 310 is fundamentally blocked and the installation is robust, and the second connector 320b A flat foot plate 310 coupled with a first connector 320a that is continuously disposed on one side in the longitudinal direction of the flat foot plate 310 is coupled with the first connector 320a being blocked from being shaken or moved at the same time. ) To fill the space between the flat plate 310 to a flat surface to prevent the operator from falling or falling accident of the work tool. Therefore, the continuous coupling of the flat foot plate 310 to which the first connector 320a and the second connector 320b are applied is very robust in installation and prevents safety accidents at the construction site. The operation of the first connector 320a and the second connector 320b is also applied to the flat foot plate 310, the variable length foot plate 400, and the variable angle foot plate 500.

In addition, the first connector 320a is coupled to one end in the longitudinal direction of the standard footrest 300, and the second connector 320b can be coupled to the other end in the longitudinal direction, such a combination being a variable length scaffold 400 and It can also be applied to variable-angle scaffolding.

The variable length scaffold will be described with reference to FIGS. 5 to 7. The variable length scaffold 400 includes a first straight scaffold 410 forming a predetermined length in the horizontal and vertical directions, and a second straight scaffold coupled vertically to the lower part of the first straight scaffold 410 ( 420), and the first straight foot plate 410 and the second straight foot plate 420, the connector 320 coupled to the longitudinal end. The connector 320 may be selected from the first connector 320a or the second connector 320b, and is illustrated as the first connector 320a in the drawings. The first connector 320a or the second connector 320b coupled to the variable length scaffold 400 is the same as the first connector 320a and the second connector 320b of the standard scaffold 300 described above. Omitted.

The first straight scaffolding plate 410 is formed with a first flat plate 411 formed of a plate body having a predetermined length in the horizontal and vertical directions so that an operator can work on the upper portion, and is provided at both end portions in the horizontal direction of the first flat plate 411. A first straight rail 412 having a thick plate body formed in a vertical direction is formed, and a straight cutting groove 413 to which the linear guide 423 of the second straight rail 422 is connected to the first straight rail 412. It is formed.

The second straight scaffolding plate 420 is formed with a second flat plate 421 formed of a plate body having a predetermined length in the horizontal and vertical directions so that an operator can work on the upper portion, and is provided at both ends in the horizontal direction of the second flat plate 421. A second straight rail 422 is formed with a thick plate body formed in a vertical direction, and the second straight rail 422 is a straight guide 423 connected to the straight cutting groove 413 of the first straight rail 412. Is formed, the linear guide 423 is formed through the wedge groove (H) in the vertical direction, the wedge groove (H) is connected to the wedge (W).

In the variable length scaffold 400, the second straight scaffold 420 is disposed under the first straight scaffold 410, and the width of both sides of the second straight rail 422 in the horizontal direction is the width of the first straight rail 412. It is formed narrower than the width on both sides in the direction, and the straight guide 423 of the second straight rail 422 is connected to the straight cutting groove 413 of the first straight rail 412. The variable length scaffold 400 has a telescopic method in which the first straight scaffold 410 or the second straight scaffold 420 moves to change the length in the vertical direction, and to the wedge groove H of the straight guide 423. When the wedge W is press-fitted, the longitudinal length of the variable-length footrest 400 is fixed.

Referring to Figures 8 to 10 looks at the variable angle footrest. The variable-angle footrest 500 has a fan-shaped first linear footrest 510, a fan-shaped second linear footrest 520, and a hinge 530 connecting the first linear footrest and the second linear footrest 520. ), And a connector 320 disposed at one end of the first linear footrest 510 and the second linear footrest 520. The connector 320 may be selected from the first connector 320a or the second connector 320b, and is illustrated as the second connector 320b in the drawings.

The first linear scaffolding 510 has a fan shape and a first linear plate 511 formed with a predetermined thickness is formed, and a first linear rail 512 having a circular arc shape and a straight shape are formed below the first linear plate 511. The first 1-rail 514 is coupled, and the linear cutting groove 513 to which the linear guide 523 of the second linear rail 522 is connected is formed through the first linear rail 512.

The second linear scaffolding 520 has a fan shape and a second linear plate 521 formed to a predetermined thickness is formed, and a second linear rail 522 having a circular arc shape and a straight shape are formed below the second linear plate 521. In the 2-2 rail 524 is coupled, the second linear rail 522 is formed with a linear guide 523 connected to the linear cutting groove 513 of the first linear rail 512, the linear The guide 523 is formed through the wedge groove (H) in the vertical direction, the wedge groove (H) is connected to the wedge (W).

The first linear footrest 510 and the second linear footrest 520 are mutually coupled with hinges 530 formed at the ends of the first-first rail 514 and second-second rail 524, and the second linear footrest The linear guide 523 of 520 is connected to the linear cutting groove 513 of the first linear scaffold 510, and the second linear scaffold 520 is disposed under the first linear scaffold 510 and hinged. When the second linear plate 521 rotates around 530, the second linear rail 522 moves in the inner direction of the first linear rail 512. The variable-angle footrest 500 acts in such a way that the angle formed by the connector 320 of the first linear scaffold 510 and the connector 320 of the second linear scaffold 520 around the hinge 530 increases or increases. Then, when the wedge (W) is pressed into the wedge groove (H) of the linear guide 523, the angle of the variable angle footrest 500 is fixed.

The operation and effects of the present invention will be described with reference to FIGS. 11 and 12. 11 is a plan view showing a state using a system scaffolding according to the present invention along a wall of a 90-degree refracted building. In the state where the standard scaffold 300 is continuously arranged from the A1 point to the A2 point of the wall, and the variable angle scaffold 500 is disposed at the A2 point, the distance between the standard scaffold 300 and the variable angle scaffold 500 is standard. When it is formed shorter than the longitudinal length of the footrest 300, the variable length footrest 400 is disposed.

As shown in FIG. 11, the variable-length footrest 400 according to the present invention is conveniently used when it is impossible to match the end of the standard footrest 300 with the end of the wall or the end of the wall. In addition, the connection parts of the standard footrest 300, the variable-length footrest 400, and the variable-angle footrest 500 are flattened by the first connector 320a and the second connector 320b, resulting in operator accidents and tools. Safety accidents such as falling accidents are also prevented.

12 is a view showing a state using the system scaffolding according to the present invention along the outer circumference of the circular wall. The scaffolding plate 300 and the variable-angled scaffolding plate 500 are connected sequentially in the clockwise direction from 6 o'clock in FIG. 12 to install a scaffold along the circumference of the circular wall, rotated one turn, and finally installed with the standard scaffolding 300 Between the installed standard footrest 300, a variable-length footrest 400 and a variable-angle footrest 500 are installed.

12, the system scaffolding according to the present invention connects the standard scaffold 300 and the variable angle scaffold 500 along the circular wall without the need to calculate the circumference of the circular wall and the length of the standard scaffold 300, and finally The scaffold 300 may be disposed at a position where the variable-length scaffold 400 is arranged to conveniently and quickly install the scaffold along the circumference of the circular wall.

As described above, only the specific examples of the present invention have been described in detail, but it is obvious to those skilled in the art to which the present invention pertains that various changes or modifications can be made within the spirit and scope of the present invention. Will belong to the appended claims.

100: vertical 110: connecting bracket
200: horizontal material 210: first horizontal material
220: second horizontal member 230: joint
300: Standard footing 310: Flat footing
320: connector 320a: first connector
321: horizontal connecting plate 322: connecting groove
323: upper hook 320b: second connector
400: variable length scaffolding 410: first straight scaffolding
411: 1st flat plate 412: 1st straight rail
413: straight incision groove 420: second straight scaffolding
421: 2nd flat plate 422: 2nd straight rail
423: Linear guide H: Wedge groove
W: Wedge 500: Variable angle scaffolding
510: first linear scaffolding 511: first linear scaffolding
512: first linear rail 513: linear cutting groove
514: Rail 1-1 520: 2nd linear scaffolding
521: 2nd linear plate 522: 2nd linear rail
523: Linear guide 524: Rail 2-2
530: hinge

Claims (3)

Vertical material 100 is installed vertically,
The horizontal member 200 is connected to the vertical member 100 in the horizontal direction,
A standard footrest 300 which is connected to the vertical member 100 or the horizontal member 200 in a horizontal direction, but is formed so that the length in the horizontal and vertical directions does not change when viewed in a plane,
The vertical member 100 or the horizontal member 200 is connected in the horizontal direction, but the variable length scaffold 400 is formed so that the vertical length can be changed when viewed in a plane,
It is connected to the vertical member 100 or the horizontal member 200 in a horizontal direction, but is formed in a fan shape when viewed in a plane, and includes a variable angle plate 500 that is formed so that the angles formed by both sides of the fan can be changed. System scaffolding.
The method according to claim 1,
The vertical member 100 includes a pipe formed in a vertical direction and a connection bracket 110 formed on the outer circumference of the pipe,
The horizontal member 200 is composed of the first horizontal member 210 and the second horizontal member 220, but the first horizontal member 210 is disposed in a vertical direction and is formed to have a long length, and the second horizontal member 220 is in a horizontal direction Placed and short in length,
Standard scaffolding 300 is a system scaffold characterized in that it consists of a flat foot plate (310) formed to allow the operator to step on, and a connector (320) formed at both ends in the longitudinal direction of the flat foot plate (310).
The method according to claim 1,
The variable length scaffold 400 includes a first straight scaffold 410 forming a predetermined length in the horizontal and vertical directions,
A second straight scaffold 420 movably coupled to the lower portion of the first straight scaffold 410;
It is made of a connector 320 coupled to the longitudinal end of the first straight foot plate 410 and the second straight foot plate 420,
The variable-angle footrest 500 includes a fan-shaped first linear footrest 510,
The fan-shaped second linear scaffolding (520),
A hinge 530 connecting the first linear scaffold and the second linear scaffold 520,
A system scaffold comprising a connector 320 disposed at one end of the first linear footrest 510 and the second linear footrest 520.

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