KR101816701B1 - Method of suspending scaffold for offshore plant - Google Patents

Abstract

The present invention relates to a method of suspending a scaffold in a structure employing a multi-stage deck, the method comprising: (A) installing a scaffolding module (20) on a side of the deck; (B) connecting the pole 30 and the short-side truss 42 of the first row to the deck set by approaching the footing module 20; (C) connecting a long-side truss (44) and a brace (46) to the pole (30) of the first row; And (D) connecting the pole 30 of the second row between the deck and the long-side truss 44 and joining the foot plate 25.
Accordingly, it is possible to quickly and safely access the worker by installing and dismantling the scaffold for external work based on the modular scaffolding and the inner hanging scaffolding, thereby reducing the number of equipment and installation.

Description

Technical Field [0001] The present invention relates to a method for suspending scaffold for an offshore plant,

The present invention relates to a scaffold for installation / operation / inspection of an offshore plant. More specifically, the present invention proposes a suspension method of a modular scaffold and an inner scaffold scaffold which can be easily installed / dismantled by an external scaffold.

Referring to FIG. 1, the scaffold system 10 of an offshore plant is divided into an external scaffold 11 installed vertically and an internal scaffold 12 installed horizontally in a multistage manner. In the case of a three-stage modular offshore plant, the height of one stage is approximately 5 to 6 meters, and the total height is approximately 15 to 20 meters on the basis of a three-stage module. In total, several tens of thousands of footsteps are required. Under such design conditions, there is an urgent need to improve the convenience of the footrest installation.

Korean Patent Laid-Open Publication No. 2013-0134613 (Prior Art 1) and Korean Patent Publication No. 0598028 (Prior Art 2) are known as prior art documents which can be referred to in connection with scaffolding.

Prior Art 1 includes a base frame for supporting a fixed footrest and a movable footrest; A fixed footrest fixedly seated on one side of the base frame; A movable footrest slidably mounted on the other side of the base frame; And first and second rails mounted on grooves extending from both sides of the base frame. Therefore, it is anticipated that the ease of installation and construction is ensured, and the safety is enhanced by preventing flow.

In the case of the bridge slab formwork and the installation of the public scaffolding required for the bridge construction, the wheel-type hanging scaffold is alternately installed along the rail installed on the beam, the bridge is constructed by pushing and installing the bridge- Installation, and disassembly. Therefore, it is expected to reduce the labor costs by shortening the working time and reduce the expense by repeatedly using the materials.

According to the above-mentioned prior art, although the convenience of a conventional footstep installation can be increased to a certain extent, it is limited to securing the effectiveness of equipment / water saving by applying it to an offshore plant scaffolding system.

1. Korean Patent Laid-Open Publication No. 2013-0134613 entitled " Scaffolding Safety Scaffold Assembly "(Open date: December 10, 2013). 2. Korean Unexamined Patent Publication No. 2006-0116405 entitled "Method of installing and dismounting a rail-type bridge slab hanging scaffold" (published on November 15, 2006).

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-mentioned problems of the related art by providing a marine plant for easily and safely accessing worker's scaffolding by installing and dismantling a scaffold for external work based on a modular scaffolding and a hanging scaffold for internal use And to provide a footrest installation method.

In order to achieve the above object, the present invention provides a method for suspending a scaffold in a structure using a multi-stage deck, comprising the steps of: (A) installing a scaffolding module as a side surface of the deck; (B) connecting the pole of the first row and the short-side truss to the set deck by approaching the footing module; (C) connecting a long-side truss and a brace to the pole of the first row; And (D) connecting the pole of the second row between the deck and the long-side truss and coupling the foot plate.

In the detailed construction of the present invention, the step (A) is characterized by vertically installing a footing module, which corresponds to the floor height of the set deck, in which the floor height of each floor is previously adjusted.

As a detailed configuration of the present invention, the step (B) is characterized in that the pole is fixed by using a flange of an H beam constituted by a deck shape.

As a detailed configuration of the present invention, the pole of the step (B) is characterized by having an upper tightening member capable of engaging with the flange of the H beam with the tightening force of the bolt.

As a detailed configuration of the present invention, at least one of the pole or the truss in the step (C) is characterized in that a lower fastener having a wedge is used for facilitating engagement and disengagement.

In the detailed construction of the present invention, the step (C) is characterized in that the work is carried out with two or three foot plates coupled to the long side truss.

As a detailed configuration of the present invention, the step (D) is characterized in that the principle of the step (A) to the step (C) is repeatedly applied corresponding to the length of the long side truss.

As described above, according to the present invention, a scaffold for external work can be easily installed and disassembled based on a modular footrest and an inner hanging footrest, thereby enabling quick and safe access by workers, thereby reducing the number of equipment and installation .

1 is a schematic view showing a scaffold system of an offshore plant to which the present invention is applied;
FIG. 2 is a schematic view showing a main part of a scaffold system according to the present invention. FIG.
Fig. 3 is a schematic diagram showing the installation process of the scaffold system according to the present invention

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

The present invention proposes a method for suspending a scaffold on a structure employing a multi-stage deck. FIG. 1 illustrates a state where a multi-layered deck (DK) is provided in a marine plant composed of three stages of production modules (MD). In the new concept scaffolding method according to the present invention, the conventional scaffold 11 and the scaffold 12 are reduced or eliminated.

In FIG. 1, reference numerals SF denote the positions of the footrests for design applied to the scaffold of the present invention.

The step (A) according to the present invention proceeds to the step of installing the footing module 20 on the side of the deck. The scaffolding module 20 is formed in a multi-layered structure by shrinking or replacing the external scaffold 11. On each floor of the scaffolding module 20, a scaffolding 25 of the set standard is installed. The scaffolding module 20 may include a fixture bound to a deck or the like of an offshore structure, and a ladder for lifting and lowering the operator.

In the detailed construction of the present invention, the step (A) is characterized in that the footing module 20 is vertically installed in correspondence with the floor height of the set deck, and the floor height of each floor is adjusted in advance. A scaffolding module (20) is constructed so that the worker and the equipment are accessible to the area of the scaffold of the offshore plant where scaffolding is required. The scaffolding module 20 is formed to have a structure capable of quickly and easily changing the height of the floor scaffold. The scaffolding 25 of the scaffolding module 20 is uniformly applicable to the scaffolding system 10. The scaffolding module 20 may be distributedly installed at a plurality of locations in the construction process.

The step (B) according to the present invention is a process of connecting the pole 30 of the first row and the short-side truss 42 to the set deck by approaching the footing module 20. The pole 30 is formed by a universal steel pipe and is suspended vertically on the bottom surface of the deck. The poles 30 are referred to as the first row and the second row in the order of proximity to the scaffolding module 20. The short-side truss 42 is formed of a steel pipe and a plate material in a ladder structure, and is horizontally suspended using a pole 30. The short side truss 42 corresponds to the left and right sides in the inner scaffold 12 combining the series of foot plates 25 and the long side truss 44 described later corresponds to the front and rear sides.

As a detailed configuration of the present invention, the step (B) is characterized in that the pole 30 is fixed using the flange of the H beam 15 constituted by the deck. The deck of the offshore plant is comprised of a plurality of structural H beams 15, and the standard H beam 15 has a flange protruding from the top and bottom of the plate web. The pole 30 is stably fixed to the flange of the H beam 15 using a binding jig, which will be described later.

The pole 30 of the step (B) is characterized by having an upper tightening member 31 which can be engaged with the flange of the H beam 15 by the tightening force of the bolt 34. [ In FIG. 2, the upper tightening tool 31 illustrates a U-shaped steel plate structure in which the size of the upper opening is varied by the tightening force of the bolts 34. When the upper tightening member 31 fixed to the upper end of the pole 30 is pushed into the flange of the H beam 15 and the bolts 34 are tightened, the coupling is completed. Of course, the structure of the crampic ring is not necessarily limited to the bolt 34.

The step (C) according to the present invention is performed by connecting the long-side truss 44 and the brace 46 to the pole 30 of the first row. The long side truss 44 is formed in a ladder structure in the same manner as the short side truss 42 and suspended horizontally using the pole 30. The brace 46 is formed of a steel pipe as in the case of the pole 30 and is suspended between the pole 30 and the long-side truss 44 in an inclined manner. A well-known fastening clamp (not shown) can be used for the inclined connection of the braces 46. The steel pipe is preferred as the brace 46, but not the steel wire or other members.

As a detailed configuration of the present invention, at least one of the pole 30 or the trusses 42 and 44 of the step (C) uses a lower fastening port 32 having a wedge 36 to facilitate the engagement and disengagement . In FIG. 2, the lower fastener 32 illustrates a structure in which the wedge 36 is coupled to one side of the inner surface of the U-shaped body so that the wedge 36 can move in and out. At least one of the short side truss 42 or the long side truss 44 is partly worn and the wedge 36 is prevented from being arbitrarily disengaged when the lower fastening hole 32 is fixed to the lower end surface of the pole 30. Conversely, although omitted in the drawings, the lower fastening opening 32 may be provided on at least one of the short side truss 42 or the long side truss 44. [

In this case, a structure of a hinge (not shown) may be applied to a portion where the pole 30 and the long-side truss 44 are connected to increase the ease of installing the long-side truss 44 having a relatively long length. For example, the hinge and the pipe may be integrally fixed to the end of the long-side truss 44 and the pipe may be coupled to the lower fastening port 32 of the pole 30. [ Thus, the long-side truss 44 is inserted in the same direction as the short-side truss 42, and then rotated at 90 degrees to continue the construction in the above-described manner.

On the other hand, if the pole 30 is formed to have a structure capable of varying the height, it is advantageous to apply the present invention to a case where there are many interferences. For example, the pole 30 may be ducted in this split structure and a plurality of through holes and pins may be applied to the connection site. As another example, the length (height) of the pole 30 and the upper tightening member 31 can be varied by the rotation of the pole 30 by engaging them in a spiral structure.

In the detailed construction of the present invention, the step (C) is characterized in that the work is carried out with two or three foot plates 25 joined to the long side truss 44. Referring to FIG. 3 (b), a state in which two foot plates 25 are provided on the opposite long side trusses 44 is illustrated. This means that the worker installs the minimum footrest 25 for proceeding with the following work. The foot plate 25 can be combined with a structure having inverted U-shaped hooks on both sides so that the foot plate 25 can be pushed and installed. However, proper sliding friction force is maintained so as not to arbitrarily flow in a state where two or three foot plates 25 are separated from each other.

Step (D) according to the present invention proceeds with connecting the pole 30 of the second row between the deck and the long-side truss 44 and joining the foot plate 25. 3 (c), two second pole columns 30 are fixed to the bottom surface of the H beam 15, a long-side truss 44 is coupled to the bottom of the second pole columns 30, The footrests 25 are all installed. Thus, the construction of the footrest 25 is completed between the poles 30 of the first and second rows.

As a detailed configuration of the present invention, the step (D) is characterized by repeatedly applying the principle of the step (A) to the step (C) corresponding to the length of the long side truss (44). 3 (c) illustrates a state in which the footrest 25 is installed between the pole 30 of the second row and the third row. Even if the pole bars 30 of the third row or more are formed corresponding to the length of the long side truss 44, the principle of steps (A) to (C) is repeated in the same manner.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

10: Scaffolding system 11: External scaffolding
12: inner scaffold 15: H beam
20: Footstep module 25: Footstep
30: pole 31, 32: fastener
34: bolt 36: wedge
42: Short side truss 44: Long side truss
46: Brace

Claims (7)

CLAIMS What is claimed is: 1. A method for suspending a scaffold on a structure employing a multi-stage deck comprising:
(A) installing a footing module (20) on the side of the deck;
(B) connecting the pole 30 and the short-side truss 42 of the first row to the deck set by approaching the footing module 20;
(C) connecting a long-side truss (44) and a brace (46) to the pole (30) of the first row; And
(D) connecting the pole 30 of the second row between the deck and the long-side truss 44 and coupling the foot plate 25,
The pole 30 of step (B) has a U-shaped upper tightening member 31 which can be engaged with the flange of the H beam 15 by the tightening force of the bolt 34,
At least one of the pole 30 or the trusses 42 and 44 of the step (C) uses a lower fastening port 32 having a wedge 36 to facilitate engagement and disengagement,
Wherein the step (C) is carried out while the plurality of foot plates (25) having inverted U-shaped hooks are pushed on the long side truss (44) and engaged. The method according to claim 1,
Wherein the step (A) comprises vertically installing a scaffolding module (20) corresponding to the height of the set deck, the scaffolding module (20) pre-matching the height of the scaffold of each layer. The method according to claim 1,
Wherein said step (B) fixes the pole (30) using a flange of the H beam (15) which is in the form of a deck. delete delete delete The method according to claim 1,
Wherein the step (D) repeatedly applies the principles of steps (A) to (C) corresponding to the length of the long-side truss (44).

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