KR102132069B1 - Truss Scaffolding System - Google Patents

Abstract

The present invention relates to a truss scaffolding system, a truss scaffolding system for working on an inner wall of a large structure, comprising: a plurality of first pillars installed near the inner wall of the large structure; A truss structure fixedly installed in a multi-layer on the first pillar; A fixing device detachably coupled to the truss structure and slidably mounted along the first column to install or disassemble the truss structure at a corresponding position; And a jack-up device detachably coupled to the fixing device and slidably mounted along the first column so as to elevate the fixing device in a state in which the truss structure is coupled.

Description

Truss Scaffolding System

The present invention relates to a truss scaffolding system.

According to recent technology development, liquefied gas such as Liquefied Natural Gas (LNG) and Liquefied Petroleum Gas (LPG) has been widely used to replace gasoline or diesel.

Liquefied natural gas is liquefied by cooling the methane obtained by refining natural gas collected from a gas field. It is a colorless transparent liquid with very little pollutant and high heat, making it an excellent fuel. On the other hand, liquefied petroleum gas is a fuel made of liquid by compressing gas composed mainly of propane (C ₃ H ₈ ) and butane (C ₄ H ₁₀ ) with oil in the oil field at room temperature. Liquefied petroleum gas, like liquefied natural gas, is colorless and odorless, and is widely used as fuel for household, business, industrial, and automobile applications.

The liquefied gas is stored in a liquefied gas storage tank installed on the ground or in a liquefied gas storage tank provided in a transportation means sailing the ocean, and the liquefied natural gas is reduced to a volume of 1/600 by liquefaction, Liquefied petroleum gas has the advantage of high storage efficiency by reducing the volume of propane to 1/260 and butane to 1/230 by liquefaction.

For example, liquefied natural gas (LNG) is obtained by cooling natural gas to an extremely low temperature (approximately -163°C), and its volume is reduced to approximately 1/600 compared to natural gas in the gas state, so long-distance transportation through the sea Very suitable for.

LNG carriers for loading LNG and unloading LNG to land demand by operating the sea, or similarly, LNG RV (Regasification Vessel) loading LNG and operating the sea to arrive at land demand and regasify the stored LNG to unload in natural gas. , LNG FPSO (Floating, Production, Storage and Offloading) used to liquefy and store the produced natural gas directly at sea, and transfer the stored LNG to an LNG carrier if necessary, and store LNG unloaded from the LNG carrier at sea The LNG FSRU (Floating Storage and Regasification Unit) that vaporizes LNG as needed and supplies it to an on-demand customer includes a storage tank (also referred to as a'cargo') capable of withstanding the cryogenic temperature of LNG.

As such, a storage tank for storing LNG in a cryogenic liquid state is installed in a merchant ship or an offshore structure such as an LNG carrier, LNG RV, LNG FPSO, and LNG FSRU that transports or stores liquefied gas such as LNG at sea.

Such storage tanks can be classified into an independent tank type and a membrane type according to whether a load of a cargo directly acts on an insulating material. Normally, the membrane type storage tank is divided into NO 96 type and Mark III type, and the independent tank type storage tank is divided into spherical MOSS type and prismatic column type SPB type depending on the shape.

The membrane-type storage tank that is integral to the vessel including the merchant ship or offshore structure is formed in the vessel during the drying process of the vessel, and the truss scaffolding system is provided so that the operator can easily perform the formation of the membrane-type storage tank in the vessel. Is used.

Here, the truss scaffolding system is installed before a large structure such as a storage tank of the LNG carrier described above is completed to provide a space for easy access and work of the worker. These truss scaffolding systems are divided into scaffolding devices for external work that are installed outside of large structures for working with large structures such as buildings, and scaffolding devices for internal work that are installed for internal construction of large structures such as pressure vessels, tanks, and domes. And these are somewhat different in terms of work type, installation structure, etc.

The truss scaffolding system according to the prior art is composed of a pillar installed in various places of a large structure so as to extend upward from the bottom of the large structure, a truss structure installed in the pillar, and a lifting device for material loading and operator boarding. The truss structure is installed in multiple layers.

When the large-scale structure is a storage tank of an LNG carrier, the truss structure is manufactured outside the ship and then installed and installed into the ship before forming the deck of the ship. It is drawn out through the temporarily formed outlet.

The existing scaffolding system forms a space for work near the four walls of the cargo hold for the construction of insulation on the walls of the LNG cargo hold, the tank central part has an empty structure, and the lifting device for transferring personnel/materials in the multi-layer truss structure In this case, an elevator is installed on a pillar supporting a truss structure, and these elevators are inclined to be installed on either side, so that material transfer from the elevator to a specific work position or the movement line of the worker's movement is not only long, but also Since there is no choice but to have a limited loading space, the amount of material transport is limited, so there is a problem that work efficiency is deteriorated.

In particular, in the existing truss scaffolding system, installation and dismantling work is mostly performed manually by an operator, and thus there is a problem that air and air are excessively required due to installation/dismantling.

The present invention was created to solve the problems of the prior art as described above, and the object of the present invention is to reduce airborne and air associated with installation/disassembly, reduce the movement line from the lifting device to a specific work position, and transfer material. It is to provide a truss scaffolding system that can increase the.

A truss scaffolding system according to an aspect of the present invention includes: a truss scaffolding system for working on an inner wall of a large structure, comprising: a plurality of first pillars installed near the inner wall of the large structure; A truss structure fixedly installed in a multi-layer on the first pillar; A fixing device detachably coupled to the truss structure and slidably mounted along the first column to install or disassemble the truss structure at a corresponding position; And a jack-up device detachably coupled to the fixing device and slidably mounted along the first column so as to elevate the fixing device in a state in which the truss structure is coupled.

Specifically, further comprising a lifting device for material loading and operator boarding, the lifting device, a plurality of second pillars installed in the free space of the large structure; A platform installed to elevate along the second column; A fixing device detachably coupled to the platform and slidably mounted along the second column to move the platform to a corresponding position; And a jack-up device detachably coupled to the fixing device and slidably mounted along the second column so as to elevate the fixing device in a state where the platform is coupled.

Specifically, each of the first pillar and the second pillar is installed by connecting a plurality of legs having a predetermined length, and the legs include male threads formed at one end; A female thread corresponding to the male thread and formed on the other end; And an adjustment hole formed at regular intervals along the longitudinal direction.

Specifically, the fixing device, the first upper guide member is detachably coupled to the lower portion of the jack-up device, the first upper guide hole is provided with a first upper guide hole for slidingly receiving the first pillar or the second pillar; A first lower guide member provided with a first lower guide hole for slidably accommodating the first pillar or the second pillar; A pair of supports installed between the first upper guide member and the first lower guide member to fix and support them, and an insertion hole into which the first fixing member is inserted; And a coupling protrusion extending outward from each of the pair of supports and detachably coupled to the truss structure or the platform.

Specifically, the first fixing member is separated from the insertion hole when the truss structure or the platform is elevated, and when the truss structure or the platform is elevated and stopped, the leg of the leg is inserted through the insertion hole. The truss structure or the platform can be secured to the first column or the second column by being inserted to penetrate the adjustment hole.

Specifically, the jack-up device includes: a second upper guide member having a second upper guide hole slidably accommodating the first pillar or the second pillar and a first insertion groove into which a second fixing member is inserted; A second lower guide hole that is detachably coupled to the upper portion of the fixing device and slidably accommodates the first pillar or the second pillar, and a second insertion groove into which a third fixing member is inserted. Lower guide member; And a pair of driving parts installed between the second upper guide member and the second lower guide member so that the second upper guide member and the second lower guide member are alternately raised and fixed.

Specifically, the second upper guide member and the second lower guide member, any one of the first pillar or the second fixing member or the third fixing member to raise and lower the truss structure or the platform When it is fixed to the second column, the other one is elevated along the first column or the second column, and the second fixing member is separated from the first insertion groove when the second upper guide member is elevated. When the second upper guide member is lifted and stopped, it is inserted through the first insertion groove to penetrate the adjustment hole of the leg and fixes the second upper guide member to the first pillar or the second pillar. The third fixing member is separated from the second insertion groove when the second lower guide member is elevated, and through the second insertion groove when the second lower guide member is raised and stopped. The second lower guide member may be fixed to the first column or the second column by being inserted to penetrate the adjustment hole of the leg.

Specifically, each of the pair of driving parts, a cylinder connected to the lower surface of the second lower guide member; And a piston connected to an upper surface of the second upper guide member and reciprocating inside the cylinder.

Specifically, each of the pair of driving units is operated by a hydraulic device, and the hydraulic device includes: a hydraulic pump that supplies hydraulic pressure to the cylinder; And it may include a control unit for controlling the operation of the hydraulic pump.

Specifically, the large structure may be a membrane-type storage tank provided on the ship.

The truss scaffolding system according to the present invention is detachably coupled with a truss structure and is detachably coupled with a fixing device and a fixing device that is slidably mounted along a first column, and is slidably mounted along a first column and fixed. By configuring the jack-up device for elevating the device, it is possible to reduce the manual work of the operator, thereby reducing air and air for installation/dismantling.

In addition, the truss scaffolding system according to the present invention provides a slidable platform along the second column, and configures the platform to elevate the platform using a fixing device and a jack-up device, thereby allowing the platform to be easily positioned at a desired location of a large structure. Since it can be installed easily, it is possible to reduce the moving line from the lifting device to all working positions.

In addition, the truss scaffolding system according to the present invention can arbitrarily adjust the size of the platform, thereby increasing the amount of material transport.

In addition, the truss scaffolding system according to the present invention can install a first column or a second column using a standardized leg having a predetermined length, thereby efficiently coping with various sizes of large structures.

In addition, when considering the work load, the number of legs of the existing truss structure can be reduced, and work efficiency can be increased due to the expansion of the work area.

1 is an exploded view for explaining a truss scaffolding system according to an embodiment of the present invention.
2 is a combined view for explaining a truss scaffolding system according to an embodiment of the present invention.
Figure 3 is a plan view of a large structure for explaining the installation position of the column and the lifting device of the truss scaffolding system according to an embodiment of the present invention.
4 is a cross-sectional view taken along line A-A' of FIG. 3 showing a state in which a truss scaffolding system according to an embodiment of the present invention is installed in a large structure.

The objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments associated with the accompanying drawings. In addition, it should be noted that, in addition to reference numerals to the components of each drawing in the present specification, the same components have the same numbers as possible, even if they are displayed on different drawings. In addition, in the description of the present invention, when it is determined that detailed descriptions of related known technologies may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

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

1 is an exploded view for explaining a truss scaffolding system according to an embodiment of the present invention, FIG. 2 is a combined view for explaining a truss scaffolding system according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention 3 is a plan view of a large structure for explaining an installation position of a column and a lifting device of a truss scaffolding system according to an embodiment, and FIG. 4 is a view showing a state in which a truss scaffolding system according to an embodiment is installed in a large structure It is a sectional view taken along line A-A'.

1 to 4, the truss scaffolding system 1 according to an embodiment of the present invention may be installed for the inner wall of the large structure 10, the pillar 100, the truss structure It may be configured to include (200), the fixing device 300, the jack-up device 400, the hydraulic device 500, the lifting device 600.

In this embodiment, the large-sized structure 10 is floating on a certain point of the sea or a merchant ship such as an LNG carrier, LNG RV, LNG FPSO, or LNG FSRU that transports or stores liquefied gas such as LNG at sea. It may be a storage tank for storing LNG installed in a ship including an offshore structure in a cryogenic liquid state, in addition, it may be a pressure vessel, tank or dome installed on the ground.

The pillar 100 may be installed to extend from the bottom of the large structure 10 toward the ceiling so that the truss structure 200 to be described later or the lifting device 600 to be described later can be installed, and according to the installation purpose, the first pillar It may be divided into (100a), the second pillar (100b).

A plurality of first pillars 100a may be installed in the interior of the large structure 10 near the inner wall surface. The truss structure 200 to be described later may be installed in multiple layers by the fixing device 300 to be described later and the jack-up device 400 to be described later in the first pillar 100a.

The second pillar 100b may be installed in a plurality of free spaces of the large structure 10, for example, in a central space of the large structure 10. A lifting device 600 to be described later may be installed on the second pillar 100b by a fixing device 300 to be described later and a jack-up device 400 to be described later.

Each of the above-described first pillars 100a and second pillars 100b may be installed by connecting a plurality of legs 110 having a predetermined length.

The leg 110 is a male screw mountain 111 formed at one end, a male screw mountain 112 corresponding to the male screw mountain 111, and an adjustment hole formed at regular intervals along the longitudinal direction. It may be configured to include 113. The plurality of adjustment holes 113 may be formed at intervals corresponding to the elevation widths between the second upper guide member 410 and the second lower guide member 420 of the jack-up device 400 to be described later.

The truss structure 200 may provide a space for an operator to work and a space for transporting materials, and may be fixedly installed in multiple layers on the first pillar 100a. The truss structure 200 is composed of at least two or more mainframes 210, a reinforcement frame 220 installed between the mainframes 210, and a coupling piece 230 provided at an end of the mainframe 210. Can be.

The truss structure 200 is manufactured from the outside of the large structure 10 and drawn into the inside, and can be installed from a low layer to a high layer by a fixing device 300 and a jack-up device 400, which will be described later. When the inner wall work of (10) is completed, it is disassembled and taken out through the outlet (20) provided on the lower side wall of the large structure (10).

When the large-scale structure 10 is a membrane-type storage tank provided on a ship, the truss structure 200 may be installed in 8 to 10 layers, and 2 or 3 layers may be used as a base layer. At this time, the outlet 20 may be temporarily provided on the sidewall where the base layer is formed.

The fixing device 300 may be detachably coupled to the truss structure 200 so as to install or disassemble the truss structure 200 at a corresponding position, and may be slidably mounted along the first pillar 100a.

In addition, the fixing device 300 is detachably coupled to the platform 610 so as to elevate the platform 610 of the platform 600, which will be described later, to the corresponding position, so as to be slidable along the second pillar 100b. Can be mounted.

The fixing device 300 is detachably coupled to the lower portion of the jack-up device 400 to be described later, and can be moved up and down along the first pillar 100a or the second pillar 100b, and the first upper guide member 310 , It may be configured to include a first lower guide member 320, the support 330, the engaging projection 340.

The first upper guide member 310 may be detachably coupled with the second lower guide member 420 of the jack-up device 400, which will be described later, and the first pillar 100a or the second pillar 100b is sliding. A first upper guide hole 311 that can be accommodated may be provided.

The first lower guide member 320 may be connected to the first upper guide member 310 by a support 330, which will be described later, and slidably accommodates the first pillar 100a or the second pillar 100b. A first lower guide hole 321 may be provided.

The support 330 may be supported and fixed between the first upper guide member 310 and the first lower guide member 320, and a pair may be installed therebetween. An insertion hole 331 into which the first fixing member 701 is inserted may be provided in each of the pair of supports 330.

In the above, the first fixing member 701 is separated from the insertion hole 331 when the truss structure 200 or the platform 610 of the lifting device 600, which will be described later, is elevated, so that the lifting can be free. In addition, the first fixing member 701 is inserted to penetrate the adjustment hole 113 of the leg 110 through the insertion hole 331 when the truss structure 200 or the platform 610 is lifted and stopped. The truss structure 200 or the platform 610 may be secured to the first pillar 100a or the second pillar 100b.

Of course, the first fixing member 701 may be manufactured separately from the pair of supports 330 or integrally with the pair of supports 330.

Coupling projections 340, a pair of supports 330 may extend outward from each of a certain length, part of the truss structure 200 or a part of the platform 610 of the lifting device 600 to be described later detachably Can be combined. Specifically, the engaging projection 340 may be detachably coupled with the engaging piece 230 provided at the end of the truss structure 200, and also the platform 610 may be composed of the truss structure 200 described above. In this case, the coupling piece 230 of the truss structure 200 may be detachably coupled.

The jack-up device 400 may be detachably coupled with the fixing device 300 in a state in which the truss structure 200 is coupled to be slidably mounted along the first pillar 100a. When the jack-up device 400 is applied to the installation work of the truss structure 200, the jack-up device 400 is separated from the fixing device 300 when the truss structure 200 is fixed by the fixing device 300 at the installation position. It can be put into the installation work of the other truss structure 200.

In addition, the jack-up device 400 is detachably coupled to the fixing device 300 in a state in which the platform 610 of the lifting device 600 to be described later is coupled to be slidably mounted along the second pillar 100b. Can. When the jack-up device 400 is applied to the lifting device 600, unlike the installation work of the truss structure 200, the jack-up device 400 and the fixing device 300 until the lifting device 600 is dismantled. Together, it remains as one component of the lifting device 600.

The jack-up device 400 is detachably coupled with the upper portion of the fixing device 300 to be elevated along the first column 100a or the second column 100b, and the second upper guide member 410, It may be configured to include a second lower guide member 420, the driving unit 430.

The second upper guide member 410 includes a second upper guide hole 411 for slidably receiving the first pillar 100a or the second pillar 100b and the second fixing member 702. One insertion groove 412 may be provided.

The second lower guide member 420 may be detachably coupled with the first upper guide member 310 of the fixing device 300, so that the first pillar 100a or the second pillar 100b is slidable. A second lower guide hole 421 to be accommodated, and a second insertion groove 422 into which the third fixing member 703 is inserted may be provided.

The driving unit 430 may be driven such that the second upper guide member 410 and the second lower guide member 420 are alternately elevated and fixed, and the second upper guide member 410 and the second lower guide member A pair may be installed between 420.

Each of the pair of driving parts 430 is connected to a cylinder 431 connected to a lower surface of the second lower guide member 420 and an upper surface of the second upper guide member 410, and the cylinder 431 interior It may be configured to include a reciprocating piston 432, in this case it can be operated by a hydraulic device 500 to be described later.

In the jack-up device 400 configured as described above, the second upper guide member 410 and the second lower guide member 420 include the truss structure 200 or the platform 610 of the lifting device 600 to be described later. In order to elevate, when either one is fixed to the first pillar 100a or the second pillar 100b by the second fixing member 702 or the third fixing member 703, the other one is in operation of the driving unit 430. By the first pillar (100a) or the second pillar (100b) can be elevated.

The second fixing member 702 is separated from the first insertion groove 412 in a state where the second upper guide member 410 is elevated, and is first in a state where the second upper guide member 410 is elevated and stopped. It is inserted through the insertion groove 412 to penetrate the adjustment hole 113 of the leg 110 so that the second upper guide member 410 is fixed to the first pillar 100a or the second pillar 100b.

In addition, the third fixing member 703 is separated from the second insertion groove 422 when the second lower guide member 420 is elevated, and when the second lower guide member 420 is elevated and stopped, It is inserted through the second insertion groove 422 to penetrate the adjustment hole 113 of the leg 110 so that the second lower guide member 420 is fixed to the first pillar 100a or the second pillar 100b. .

The second fixing member 702 may be manufactured separately from the second upper guide member 410 or integrally formed with the second upper guide member 410, as well as the third fixing member 703. Of course, it may be manufactured separately from the second lower guide member 420 or integrally with the second lower guide member 420. In addition, the second fixing member 702 and the third fixing member 703 may be configured to be manually operated or automatically operated. In addition, when automatically operated, automatic detection devices, control devices, etc. It may be possible by building a system.

The hydraulic device 500 may drive a pair of driving units 430, a hydraulic pump 510 for supplying hydraulic oil to the cylinder 431, and a control unit 520 for controlling the operation of the hydraulic pump 510 It may be configured to include.

The lifting device 600 may be installed for material loading and operator boarding. The lifting device 600 is provided with a free space of the large structure 10, for example, the truss structure 200, which is roundly disposed along the inner wall so as to minimize material transfer to all work positions and movement movement of workers. In the case, it may be installed in the central portion of the large structure 10, it may be configured to include a second pillar (100b), the platform 610, the fixing device 300, the jack-up device 400.

The second pillar 100b may be installed in plural in the free space of the large structure 10, and may support the platform 610, which will be described later. The second pillar 100b may be installed by connecting a plurality of legs 110 as described above.

The platform 610 may be slidably mounted along the plurality of second pillars 100b, and may be installed to be elevated by the fixing device 300 and the jack-up device 400.

The platform 610 may be formed of the same or similar structure to the above-described truss structure 200, and accordingly, the structure constituting the platform 610 may be arbitrarily changed in size according to the surrounding environment, and the structure According to the size of the second pillar (100b), the fixing device 300 and the jack-up device 400 may be installed, so the loading space is not limited as in the conventional elevator.

The fixing device 300 may be detachably coupled to the platform 610 so as to lift the platform 610 to a corresponding position, as described above, and may be slidably mounted along the second column 100b.

As described above, the jack-up device 400 is detachably coupled with the fixing device 300 so as to elevate the fixing device 300 in a state where the platform 610 is coupled along the second pillar 100b. It can be mounted slidably.

As described above, this embodiment is detachably coupled to the truss structure 200 and detachably coupled to the fixing device 300 and the fixing device 300 which are slidably mounted along the first pillar 100a. It is slidably mounted along the pillar (100a), by configuring the jack-up device 400 for lifting the fixing device 300, it is possible to reduce the manual work of the operator, it is possible to reduce the air and air due to installation / disassembly have.

In addition, in the present embodiment, a sliding platform 610 that is slidable along the second pillar 100b is provided, and the lifting device is configured to lift the platform 610 using a fixing device 300 and a jack-up device 400 ( By constructing 600), the lifting device 600 can be easily installed at a desired position of the large-scale structure 10, so that the moving line from the lifting device 600 to all working positions can be reduced.

In addition, in the present embodiment, since the size of the platform 610 can be arbitrarily adjusted, the amount of material transport can be increased.

In addition, in the present embodiment, the first column 100a or the second column 100b can be installed using the standardized leg 110 having a predetermined length, thereby effectively coping with various sizes of the large structure 10. Can.

In addition, in the present embodiment, when considering the work load, it is possible to reduce the number of multiple legs of the existing truss structure, and increase the work efficiency due to the expansion of the work area.

In the above, the present invention has been described based on the embodiments of the present invention, but this is merely an example and does not limit the present invention, and those skilled in the art to which the present invention pertains will not depart from the essential technical content of the present embodiment. It will be appreciated that various combinations or variations and applications not illustrated in the examples are possible in the scope. Accordingly, technical contents related to modifications and applications that can be easily derived from the embodiments of the present invention should be interpreted as being included in the present invention.

1: truss scaffolding system 10: large structure
20: Exit
100: pillar 100a: first pillar
100b: second pillar 110: leg
111: male thread 112: female thread
113: adjustment hole 200: truss structure
210: main frame 220: reinforcement frame
230: coupling piece 300: fixing device
310: first upper guide member 311: first upper guide hole
320: first lower guide member 321: first lower guide hole
330: support 331: insertion hole
340: engaging projection 400: jack-up device
410: second upper guide member 411: second upper guide hole
412: first insertion groove 420: second lower guide member
421: 2nd lower guide hole 422: 2nd insertion groove
430: drive unit 431: cylinder
432: piston 500: hydraulic system
510: hydraulic pump 520: control unit
600: lifting device 610: platform
701: first fixing member 702: second fixing member
703: third fixing member

Claims (10)

As a truss scaffolding system for working inside walls of large structures,
A plurality of first pillars installed near the inner wall surface of the large structure;
A truss structure fixedly installed in a multi-layer on the first pillar;
A fixing device detachably coupled to the truss structure and slidably mounted along the first column to install or disassemble the truss structure at a corresponding position; And
And a jack-up device detachably coupled to the fixing device and slidably mounted along the first column so as to elevate the fixing device in a state in which the truss structure is coupled,
It further includes a lifting device for material loading and operator boarding,
The lifting device,
A plurality of second pillars installed in the free space of the large structure;
Truss scaffolding system, characterized in that it comprises a platform that is installed to elevate along the second column. According to claim 1,
The lifting device,
A fixing device detachably coupled to the platform and slidably mounted along the second column to move the platform to a corresponding position; And
A truss scaffolding system further comprising the jack-up device detachably coupled to the fixing device and slidably mounted along the second column so as to elevate the fixing device in a state where the platform is coupled. According to claim 2, Each of the first pillar and the second pillar,
It is installed by connecting a plurality of legs having a certain length,
The leg,
Male thread formed on one end;
A female thread corresponding to the male thread and formed on the other end; And
Truss scaffolding system comprising a control hole formed at regular intervals along the longitudinal direction. According to claim 3, The fixing device,
A first upper guide member detachably coupled to a lower portion of the jack-up device and provided with a first upper guide hole slidably accommodating the first pillar or the second pillar;
A first lower guide member provided with a first lower guide hole for slidably accommodating the first pillar or the second pillar;
A pair of supports installed between the first upper guide member and the first lower guide member to fix and support them, and an insertion hole into which the first fixing member is inserted; And
Truss scaffolding system, characterized in that it comprises a coupling protrusion that extends a predetermined length outwardly from each of the pair of supports and is detachably coupled to the truss structure or the platform. The method of claim 4, wherein the first fixing member,
The truss structure or the platform is detached from the insertion hole when the platform is elevated, and when the truss structure or platform is elevated and stopped, the truss structure is inserted through the insertion hole to penetrate the control hole of the leg. Or truss scaffolding system, characterized in that to secure the platform to the first column or the second column. According to claim 3, The jack-up device,
A second upper guide member which is provided with a second upper guide hole for slidingly accommodating the first pillar or the second pillar and a first insertion groove into which a second fixing member is inserted;
A second lower guide hole that is detachably coupled with the upper portion of the fixing device and slidably accommodates the first pillar or the second pillar, and a second insertion groove into which a third fixing member is inserted. Lower guide member; And
And a pair of driving parts installed between the second upper guide member and the second lower guide member so that the second upper guide member and the second lower guide member are alternately elevated and fixed. Truss scaffolding system. The method of claim 6, wherein the second upper guide member and the second lower guide member,
In order to elevate the truss structure or the platform, when one is fixed to the first column or the second column by the second fixing member or the third fixing member, the other is the first column or the second It goes up and down along the pillar,
The second fixing member is separated from the first insertion groove when the second upper guide member is elevated, and when the second upper guide member is raised and stopped, the second fixing member is moved through the first insertion groove. Is inserted so as to penetrate the adjustment hole to secure the second upper guide member to the first pillar or the second pillar,
The third fixing member is separated from the second insertion groove when the second lower guide member is elevated, and when the second lower guide member is elevated and stopped, the leg of the leg is moved through the second insertion groove. Truss scaffolding system, characterized in that the second lower guide member is fixed to the first column or the second column by being inserted through the adjustment hole. The method of claim 6, wherein each of the pair of driving units,
A cylinder connected to a lower surface of the second lower guide member; And
A truss scaffolding system connected to the upper surface of the second upper guide member and comprising a piston reciprocating inside the cylinder. The method of claim 8, wherein each of the pair of driving units,
It is operated by hydraulic system,
The hydraulic device,
A hydraulic pump that supplies pressure oil to the cylinder; And
Truss scaffolding system comprising a control unit for controlling the operation of the hydraulic pump. The method of claim 1, wherein the large structure,
Truss scaffolding system, characterized in that the membrane-type storage tank provided in the ship.

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