KR101829663B1 - Unit module of pendant type scaffoldings and safety handrail assembly for power boiler maintenance - Google Patents

Abstract

The present invention relates to, in a system scaffolding built around an internal wall of a furnace, a safety handrail assembly, which is able to make it easy to assemble a foothold with a safety handrail and to allow a worker to rapidly and easily build the system scaffolding in the pendant-type furnace through a simple work of holding the safety handrail assembly assembled with the foothold on a foothold fixture connected to a part in between divided-type rope connection apparatuses of the system scaffolding, and a unit scaffolding module structure of the system scaffolding in the pendant-type furnace having the same. According to the present invention, the safety handrail assembly of the system scaffolding in the pendant-type furnace built in multiple layers around an internal wall of the furnace comprises: a foothold; and a safety handrail which comprises a plurality of vertical members placed in a longitudinal direction of the foothold, and a horizontal member connecting the plurality of vertical members, wherein the horizontal member is combined with one side surface or two side surfaces of the foothold. A bottom end of the vertical members is combined with a fastening bracket in contact with a side surface of the foothold.

Description

Technical Field [0001] The present invention relates to a pendant type non-interior system scaffold unit, a scaffold module, and a safety railing assembly,

[0001] The present invention relates to a safety railing assembly of a pendant type furnace system scaffold and a unit scaffolding module having the safety scaffold assembly. More particularly, it relates to a safety handrail assembly which is easy to assemble a safety guardrail on a side surface of a scaffold, A safety rail assembly of a pendant type in a non-pendent type cabinet and a unit scaffolding module including the same, which can perform the installation work of the system scaffolds quickly and easily by only a simple operation of mounting the scaffolds connected between the split type rope connection devices will be.

As is well known, a thermal power plant is a power generation facility that produces electric energy by rotating a turbine with high-temperature and high-pressure steam generated by burning fuel such as coal, oil, and natural gas in a boiler.

In the operation of such a thermal power plant, it is necessary to regularly inspect and repair the inside of a large-sized boiler furnace. In such a thermal power plant, inspection and maintenance work of the thermal power plant is first carried out using a scaffold, Inspecting and repairing the interior, and dismantling the installed scaffold when the work is finished.

However, since the boiler room of such a power plant usually has a height of several tens of meters (m), when a workbench is installed using a scaffold and a worker performs work, the load is concentrated at the lower part of the structure, There is a possibility of occurrence.

In order to solve the above problems, in a prefabricated scraping device disclosed in Korean Utility Model Registration No. 20-0408501, a frame having a plurality of horizontal bars installed between a pair of vertical bars, and a frame And a length connecting member for connecting and fixing the contact portions of the frames so that a plurality of frames can be used in a longitudinal direction can be formed and the frames can be connected to each other using a side connecting member so as to be overlapped with each other A plurality of frames are longitudinally connected to each other using a length connecting member so that the operator can reach the working position, and then the assembled frame is inserted between the screen tubes, It is implemented to be mounted on a tube.

The conventional prefabricated scaffold having the above-described structure is composed of a frame, a side connecting member, a long connecting member, and the like. When the urgent operation due to the rupture of the vertical tube or the hole occurs, There is an advantage in that it can be easily carried into the furnace.

However, the conventional assembled scaffold having such a structure has a disadvantage in that it is not excellent in accessibility to the boiler furnace and can not be operated by a plurality of workers at the same time. In addition, since the height of the boiler is usually several tens of meters, It is necessary to connect the plurality of frames in the longitudinal direction by using the length connecting member, so that the operation stability and the scaffold durability are deteriorated.

Meanwhile, in order to improve the disadvantages of the prior art as described above, in the system scaffolding apparatus disclosed in Patent Registration No. 10-1236184, a vertical rope of a scaffold structure is replaced with a wire rope to install an upper load supporting structure and a wire rope, So that the total load is concentrated on the upper boiler tube, so that the load can be dispersed upward and downward when used in combination with the existing scaffold, so that the load can be prevented from concentrating only on the lower portion.

However, in the conventional scaffold system, a wire rope having a length of tens of meters is hanged on a wire fixing portion welded on a channel located on the upper side of the furnace of the boiler, and the wire rope is hanged from the upper portion to the lower portion inside the furnace. A structure in which a footrest is connected to a scaffolding pipe fixing plate of a joining member fixed at a predetermined interval on the outer surface, and a footrest is installed, wherein the length of the wire rope fixed to the upper wire fixing portion in the furnace is usually several tens of meters And since the weight of the wire rope is large, the time and cost involved in installation of the wire rope are large, and the work is troublesome and the stability is very weak due to the danger. In addition, when a portion of a long wire rope reaching several tens of meters is broken, the entire wire rope must be replaced, which is disadvantageous in that it is costly to replace the wire rope.

When the scaffold system is dismantled, the wire rope hanging from the wire fixing part is separated and wound around the drum. In this case, a plurality of joining members, which are connected to the outer surface of the wire rope, It is not easy to wind the wire rope in a state where a plurality of joining members are coupled to the drum even when the wire rope is to be wound and stored while the joining members are not separated. The wire rope wrapped around the drum is subject to severe deformation, damage, and cutting of the steel wire. In addition, there is a drawback in that the wire rope has a large wound volume, which causes inconvenience in storage and transportation work for storing and reinstalling is very troublesome.

In addition, since the wire rope passing through the center portion of the scaffold pipe fixing plate is fastened and fixed by a plurality of fastening keys having a wedge shape, the fastening force of the fastening key causes the wire rope to be deformed and damaged, Corrosion of the wire rope due to the deformation of the wire rope is caused by corrosion of the wire rope due to the oxidizing action, And the breakage of the wire rope can be easily caused thereby.

In addition, in the conventional scaffold system, a rail structure is installed to prevent a worker from falling down during maintenance and inspection of the inside of a furnace in a high-rise building. Such a rail structure carries a guide rail, which is a horizontal member, The installation and demolition work of the railing structure is very cumbersome and takes a lot of time, and the construction efficiency is greatly reduced.

Patent Registration No. 10-1236184 (2013.02.18)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a safe rail assembly that can be easily assembled to a side portion of a footrest in a pendant type furnace system framework installed around the inner wall of a furnace, The present invention provides a safety rail assembly and a unit scaffolding module for a scaffolding system of a pendant type in which a safety guardrail installation work such as a scaffolding can be performed quickly and easily by only a simple operation that is mounted on a scaffolding stand portion connected between rope connecting apparatuses have.

It is another object of the present invention to provide a safety railing assembly in which a safety railing assembly pre-assembled at the bottom of a scaffold of a pendant type furnace is lifted to an installation target floor and connected to a footrest fixing part connected between split rope connecting devices The present invention provides a safety rail assembly and a unit scaffolding module of a pendant type non-in-system system scaffold which can quickly and easily construct floor scaffold structures through work.

According to an aspect of the present invention, there is provided a safety railing assembly for a pendant type non-ventilating system, the safety railing assembly being installed in an upper and lower multilayered structure around an inner wall of a furnace. And a safety rail coupled to one or both sides of the footrest, the safety rail including a plurality of vertical members arranged along the longitudinal direction of the footrest and a horizontal member connecting between the plurality of vertical members, And a fastening bracket to be engaged with the side surface of the foot plate is coupled to the lower end.

Here, the side surface of the foot plate to be coupled with the fastening bracket is formed to have a cross-sectional shape of a 'D' shape having an upper end and a lower end extended outwardly by a predetermined width, and the fastening bracket has a shape corresponding to the side surface of the foot And may be configured to be symmetrical with the side surface of the foot plate and to be fastened to the side surface of the foot plate through a fastening member.

At this time, a protruding portion protruding upward is formed on the side lower side of the foot plate, and a bent end of the bent bracket is formed at a lower end of the fastening bracket with a catching groove for catching the protruding portion. The upper end of the fastening bracket can be engaged with the upper end of the foot plate and fastened through the fastening member in a state of being hooked to the lower end of the foot plate through the fastening end.

In this case, the latching end may be formed in a shape of folding the protrusion part a plurality of times.

The fastening member may be fastened through an upper end of the fastening bracket and a side upper end of the foot plate in contact with the fastening bracket.

In addition, as the footrest, a stepped footstep that connects the upper or lower layers in a stepwise manner may be applied.

According to the safety railing assembly of the pendant type in-door system scaffold of the present invention and the unit scaffolding module structure having the safety scaffold assembly of the present invention constructed as described above, the assembling operation of the safety railing is performed on the side scaffold of the system scaffolding installed around the inner wall of the furnace There is an advantage that it can be easily and easily performed.

In addition, the safety railing assembly including the footrest and the safety railing is lifted to the installation target floor, and the installation of the safety railing including the footrest is performed quickly by a simple operation of mounting the pedestal fixing part connected between the split rope connecting devices And safety hazards that may occur in the process of assembling the safety railing to the footrest portion in the high-level position can be solved.

Also, in the installation work of the stepped footrest, the safety railing is assembled in advance on the side of the stepped footrest, and then the upper end of the stepped footrest is mounted on the footrest fixing base of the lower floor and the upper end is mounted on the footrest fixing member of the upper floor There is an advantage that the safety rail installation work including the stepped scaffolding can be performed quickly and easily at once.

Further, a plurality of unit units constituted by two split rope connecting apparatuses having a unit length and one footrest fixing unit are horizontally arranged along the inner wall of the furnace, and each of the footrest fixing units provided in each adjacent unit unit structure A plurality of unit scaffolding modules are connected to each other in the horizontal direction in such a manner that the scaffolds are mounted on both ends of the scaffold.

In addition, it is possible to construct a scaffolding structure in a vertical direction by connecting the divided rope connecting devices of another layer adjacent to the dividing rope connecting device of the scaffolding structure installed on one floor sequentially, It has the advantage of being able to build quickly and effectively.

In addition, instead of the long wire rope which is hanging on the upper part of the existing structure, instead of the long wire rope, a plurality of split rope connecting devices having a predetermined unit length corresponding to the floor height of the system scaffolding layer are sequentially connected in the vertical direction, There is an advantage that the work can be performed quickly and easily.

Particularly, after the split rope connecting device on one side is fastened to the connecting port provided on the end of the single split rope connecting device with the fastening pin, the footrest fastening bar is connected between the split rope fastening devices arranged in the horizontal direction, It is possible to reduce the time and cost according to the entire scaffolding hypothesis as well as to improve the safety.

Further, a plurality of coupling holes are arranged orthogonally to each other in the connecting portion of the split rope connecting device provided in the edge region of the system scaffold, and the end portions of the footrest are fitted to the respective coupling hole portions, It is possible to easily perform the installation work of the footrest and footrest for the foot, and it is advantageous in that it can be easily implemented structurally with low construction cost without installing a separate bracket structure at the corner portion.

In addition, after the dismantling of the system scaffold, the split rope connecting device of the separated unit length is hung on the separate split rope connecting device cradle instead of being wrapped around the drum as before, so that it can be easily stored in one place. It can be easily transported and used.

In addition, by providing reinforcing members for diagonal connecting the unit scaffolding modules of the system scaffolds orthogonal to each other, it is possible to arrange that the divided rope connecting device is shaken during the movement of the operator, It is possible to prevent the phenomenon that the skeletal structure is twisted by the lateral force or the like, thereby improving the structural safety.

Particularly, since the both ends of the reinforcing member are rotatably mounted on the footrest fixing portions of the unit scaffolding modules, which are perpendicular to each other, through the joint brackets, the installation work of the reinforcing members can be easily performed, It is possible to absorb the error through the rotatable joint bracket even if an installation error occurs between the pedestal fixing rods, so that the installation work of the reinforcing member can be prevented from being caused.

In addition, since the wall support which is supported on the inner wall of the furnace can be easily connected to the foot fixing part through the connection bracket, the connection work of the wall support can be performed quickly and easily, So that the structural stability can be improved.

1 is a perspective view showing a system scaffold in a pendant type furnace, which is hypothesized using a split rope connecting device according to the present invention;
Fig. 2 is an enlarged view showing a part of Fig. 1 in an enlarged scale. Fig.
FIG. 3 is a perspective view showing a system scaffolding installed in one layer; FIG.
4 is a perspective view showing a unit unit structure of a system scaffold according to the present invention;
5 is a perspective view showing a unit scaffolding module structure in which a pair of unit units are assembled with a rectangular footrest and a safety guardrail.
6 is a perspective view showing a unit scaffolding module structure in which a rectangular footrest, a stepped footrest, and a safety guardrail are assembled between a pair of unit units.
7 is a perspective view showing the structure of a split-type rope connecting device of a system scaffold according to the present invention.
8 is an exploded perspective view showing the structure of a footstock fastener fastened between connecting ends of a split rope connecting device;
FIG. 9 is a view showing a process in which the head of the end of the footstock is inserted into the first coupling hole of the coupling hole and engaged with the second coupling hole.
10 is a perspective view showing the foot plates are coupled at the same time on both sides of one unit unit.
11 is a perspective view showing a split rope connection device and footrest installation structure for a corner portion of a system scaffold.
FIG. 12 is a detailed view showing the connector portion shown in FIG. 11 in detail; FIG.
13 is a perspective view showing an assembly structure of a footrest and a safety guardrail;
14 is a detailed view of the main part of Fig.
15 is a sectional view showing a cross-sectional view in which a footrest and a safety guardrail are combined.
Fig. 16 is a plan view as seen from above of Fig. 3; Fig.
17 is a perspective view showing the reinforcing member and the wall support fastened to the footrest.
Fig. 18 is a perspective view showing the structure of a split rope connecting device cradle in which the split rope connecting device of the present invention is mounted; Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a safety railing assembly of a system scaffold according to the present invention and a unit scaffold module of a pendant type furnace system scaffold having the safety railing assembly will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The terms used below are terms set in consideration of the functions of the present invention, which may vary depending on the intention or custom of the producer producing the product, so that the definition can be based on the contents throughout the specification.

FIG. 1 is a view showing a system scaffold installed in a power generating boiler furnace through vertical connection of a split rope connecting apparatus according to the present invention, and FIG. 2 is a view showing a part of the system scaffold shown in FIG. Respectively. FIG. 3 shows a system scaffolding structure installed in one layer.

1 to 3, the scaffold of a pendent type furnace according to the present invention is installed in an upper and lower multilayered structure inside a boiler furnace of a power plant, and has a short unit length corresponding to the height of one layer of the system scaffold A plurality of split rope connecting devices 100 having a length of about 2 meters and a length of about 2 meters are connected to a heavy girder (not shown) or a heater tube bundle (not shown) To the lower layer, and then the scaffold structure can be sequentially and rapidly installed from the lower layer to the upper layer.

In this case, the system scaffold connects the footrest 160 between the lower ends of the pair of split rope connecting devices 100 spaced apart from each other by a predetermined distance in the direction perpendicular to the inner wall of the furnace, The safety railing 300 is assembled to one side of the footrest 210 after the pedestal 210 is mounted between a pair of footrests 160 arranged in a direction And a stepping bracket 160, which is capable of forming a system skeleton structure, and which is connected to the divided rope connecting device 100 of the lower layer interconnected with the split rope connecting device 100 of the upper layer, The safety guardrail 210 and the safety guardrail 300 are installed to sequentially form the system scaffolding structure of the lower layer, so that the entire system scaffold can be constructed. In this case, the safety guardrail 300 may be assembled on both sides of the footrest 210 as occasion demands.

4 shows a unit architecture BA of a system scaffold composed of a pair of split rope connectors 100 and a footstock fixture 160,

4, the unit unit BA includes a pair of split rope connecting devices 100 spaced apart at regular intervals along a direction perpendicular to an inner wall of a furnace (not shown) And a footrest fixing part 160 connected between the lower ends of the pair of split rope connecting devices 100.

In this case, both ends of the footrest fixing unit 160 are fitted to and joined to the connection ports 120 provided at the lower ends of the pair of divided rope connecting apparatuses 100 spaced from each other, so that the U-shaped unit units BA ) Structure.

The U-shaped unit units BA are arranged horizontally at predetermined intervals along the inner wall of the furnace, and each of the U-shaped unit units BA includes a pair of U- 5 by mounting the rectangular pedestal 210 at both ends of the pedestal 160 and assembling the safety railing 300 on one side of the pedestal 210, .

In this case, the unit scaffolding module 400 of the type shown in FIG. 5 is structured such that two rectangular footrests 210 are placed side by side between a pair of unit units BA disposed along the inner wall of the furnace, And a safety guardrail 300 is assembled to the side surface of the safety guard 210.

A plurality of unit scaffolding modules 400 of this type are connected in a horizontal direction along the inner wall of the furnace to form a single unit scaffold structure as shown in FIG.

In addition, the unit scaffold structure shown in FIG. 3 is sequentially installed upward or downward through the interconnection work between the upper and lower split rope connecting apparatuses 100, thereby forming a system scaffold structure as shown in FIG. 1 It can be constructed.

In order to allow the system scaffold according to the present invention to move smoothly from the lower layer to the upper layer, or from the upper side to the lower layer, one of the two scaffolds 210 of the unit scaffolding module 400 shown in FIG. Can be installed as a stepped foot plate 230 connecting upper and lower layers. FIG. 6 shows the structure of the unit scaffolding module 400 in which the stepped footrest 230 is installed.

The system scaffold according to the present invention may be configured such that the safety guardrail 300 is attached to the side of the rectangular scaffolding 210 or the stepped scaffold 230 in the same manner as the unit scaffolding module 400 shown in FIG. And assembling the pedestal 210 and the safety railing 300 to the upper part of the pedestal 200 through a separate lifting device to mount the assembled pedestal 210 and the safety railing 300 on the pedestal 150 The pedestal 210 and the safety guardrail 300 can be installed quickly and easily.

In addition, in the case of the power-lifting pendant type furnace system scaffold, after the end of the wire rope fixed to the heavy girder or the like is lowered to a separate work space, the split rope connecting device 100 and the scaffold of Fig. The system scaffold 800 can be quickly and easily laid down in a series of the same manner of connecting the split rope connector 100 and the footplate of Figure 3 in this work space.

Meanwhile, FIG. 7 is a perspective view showing in detail a structure of a split rope connecting device 100 that enables quick and easy provisioning of a system scaffold according to the present invention.

As shown in FIG. 7, the split rope connecting device 100 used in the system scaffolding according to the present invention has a unit length corresponding to one stratum in a system scaffold that is installed in a multi-layer structure (for example, It is made in a length of about 2 meters, but can be adjusted if necessary).

The upper and lower ends of the split rope connecting device 100 are provided with annular rings 112 and 114 so as to be connected to the divided rope connecting device 100 adjacent to the upper or lower side.

In this case, the hooks 112 and 114 are formed by deforming both end portions of the split rope connecting device 100 into an annular shape and then binding them with a binding device 115, respectively.

The upper and lower ring portions of the split rope connecting device are connected to the lower ring portion 114 of the split rope connecting device 100 so that the upper ring portion of the lower split rope connecting device can be connected to each other. The connection port 120 is connected.

Here, the connector 120 has a pair of ring connection portions 121 and 122 having the same shape as the 'C' shape and disposed symmetrically with respect to each other at regular intervals, and the pair of ring connection portions 121 and 122 And a footstock fixing part coupling part 123 formed of a plate in which an end of the footstrap fixing part 160 is inserted.

At this time, the lower end ring part 114 of the split rope connecting device 100 is inserted into the insertion groove 121a formed in the upper side ring connecting part 121 to connect the bolt 124, which is the fastening member, 121 and the lower end claw 114 to be fastened and fixed.

In this manner, the split rope connecting device 100 in which the connecting rope 120 is fastened to the lower rope 114 forms a split rope connecting device 100 having a unit length corresponding to one rope.

A bolt 124 or a fastening pin 125 is directly in contact with an inner surface of the hooks 112 and 114 on the inner periphery of each of the upper and lower hooks 114 of the split rope connecting device 100, The reinforcing member 116 having a higher abrasion resistance and higher strength than the rings 112 and 114 can be padded to prevent deformation and breakage of the portions 112 and 114. [

The connecting portion 120 is connected to the lower end of the split rope connecting device 100. The connecting portion 120 is formed at the center of the plate- And an engaging hole 126 to which the end portion is fitted is formed.

As shown in FIG. 8, the footrest 160 is formed in a hollow pipe shape. At both ends of the footrest 160, a coupling shaft 161 is inserted, and a mechanical bonding system such as fastening and pressing with a bolt 163, .

The coupling shaft 161 is composed of a body portion 164, a head portion 166 and a neck portion 167 formed between the body portion 164 and the head portion 166.

The body portion 164 is inserted into both ends of the hollow pipe type footrest fixing table 160 and is formed on the outer circumferential surface thereof with a fastening hole 165 through which the bolt 163 can be fastened. Another body 162 is formed on the outer circumferential surface of the body 162 so as to correspond to the body 162. The body 164 is fitted to the respective fastening holes 162, And the bolts 163 are fastened and engaged.

The head portion 166 is formed to have a diameter smaller than the diameter of the body portion 164 and larger than the diameter of the neck portion 167. The foot rest 163 is fixed to the foot portion 166 through the head portion 166, The neck portion 167 is inserted into the coupling hole 126 formed in the fixed base coupling portion 123 and the head portion 166 is hooked around the coupling hole 126 while the neck portion 167 is supported in the coupling hole 126 The coupling is made.

7, the shape of the coupling hole 126 into which the head portion 166 of the footrest fixing table 160 is inserted is formed to have a large diameter so as to fit the head portion 166, The diameter of the neck portion 167 is smaller than that of the head portion 166 and the diameter of the neck portion 167 is larger than that of the neck portion 167 so that the neck portion 167 having a diameter smaller than (or equal to) The first and second coupling holes 126a and 126b are formed to communicate with each other.

9, the head 166 of the footrest fixing bracket 160 is fitted in the first engaging hole 126a in the horizontal direction, and then is moved vertically downward again, The neck portion 167 is inserted into and supported by the small second coupling hole 126b so that the connection between the foot fixing base 160 and the foot fixing base engaging portion 123 is performed. The foot 166 is hooked around the second engagement hole 126b having a small diameter so that the footrest fixing member 160 is not separated from the footrest fixing member 123.

At this time, the footrest 160 may be constructed by simplifying the shape of the hollow pipe without omitting the coupling shaft 161. In this case, a blind flange is formed at both ends of the hollow pipe, The plate of the shape can be attached and fixed. That is, a blanket flange in which a hole is machined at the center of the circular plate is fitted to the outer peripheral surfaces of both ends of the hollow pipe using the hole and welded, or a circular flange in the form of a circular plate, And is engaged with the coupling hole 126 of the coupling hole 120 in the same manner, thereby preventing the foot plate 160 from being separated.

10 shows a state in which the footrest 210 is simultaneously engaged at one side of one unit unit BA in which the footrest fixing unit 160 is coupled to the connection port 120 of the split rope connection unit 100 .

10, when the footrest 210 is horizontally connected to the unit scaffolding modules 400 at both sides of the unit unit BA composed of the pair of divided rope connecting devices 100 and the footrest fixing unit 160, Is mounted on the foot fixing table 160 at the same time.

In this case, as shown in an enlarged view of FIG. 14 to be described later, a pair of mounting brackets 211 are coupled to both ends of the foot plate 210 so as to be mounted on the foot fixing base 160, 211 and the like are formed on the upper and lower sides of the pedestal fixing table 160 and the pedestal fixing table 160 is formed around the lower fixing groove 212 by forward and backward rotation A separate fastener 213 is coupled to enlarge or reduce the entrance area of the receiving groove 212 into which the receiving groove 212 is inserted.

At this time, a guide groove 213a which can be guided in a state where the shaft 215 coupled to the mounting bracket 211 is passed through during the forward and backward movement of the fastening opening 213 is formed inside the fastening opening 213 A handle 216 is formed on an upper end of the fastening hole 213 so that the handle 216 can be held by hand. An opening 214 formed in the inside of the mounting bracket 211 is provided on the opposite side of the handle 216. A stopper 217 is formed so that the fastener 213 is not moved downward any more. In addition, a seating groove 218 is formed at one side of the inner surface of the opening 214 to allow the stopper 217 to be inserted therein.

Therefore, when the footrest 210 is mounted on the footrest fixing base 160 through the mounting bracket 211, the fastening member 213 is lifted up to a certain width by using the knob 216, 217 are seated in the seating recess 218 formed in the opening 214, the entrance area of the seating recess 212 is widened by upward movement and rotation of the fastener 213, The stopper 217 can be easily inserted into the mounting groove 212 by operating the fixing member 213 after the footrest fixing member 160 enters the mounting groove 212. [ 218 and then is hooked on one side of the inner surface of the original opening 214 to reduce the entrance area of the mounting groove 212 so that the foot fixing table 160 is fixed to the mounting groove 212 of the mounting bracket 211, Can be prevented from being separated.

Fig. 11 is an enlarged view of the portion "A" in Fig. 3, showing the coupling structure for the corner portion of the system scaffold.

11, a corner stool 220 having a triangular shape is installed at a corner of the system scaffold according to the present invention. The corner stool 220 includes a rectangular pedestal 210, And is mounted on the footrest fixing portion 160. [

In this case, the split rope connecting device 100 structure in which the connecting holes 130 of the shape shown in FIG. 12 are coupled to the lower ends so that the respective ends of the two pedestal fixing rods 160 orthogonal to each other can be fitted and used do.

12, the split rope connecting device 100 installed in the edge region of the system scaffold has a connecting hole 130 coupled to the lower ring portion 114 of the split rope connecting device 100 The lower ring portion 114 of the split rope connecting device 100 and the upper ring portion of another split rope connecting device can be respectively inserted into the upper and lower sides of the connecting hole 130, The bolts 124 and the fastening pins 125 are formed on the outer side of the coupling 130 in a state where the lower ends and the upper ring portions 114 and 112 are inserted into the insertion slots 131 and 132, 125, respectively.

At this time, a coupling hole 126 having the same shape as the coupling hole 126 shown in FIG. 7 is formed on the other side adjacent to one side of the coupling hole 130, And the coupling holes 126 formed on the surfaces are formed at intervals of 90 degrees.

Therefore, the end portions of the footrest fixing members 160 are inserted into the two coupling holes 126 arranged on both sides of the coupling hole 130 in a manner orthogonal to each other, A footrest fixing table 160 can be installed and the rectangular footrest 210 and the corner footrest 220 can be mounted on the two orthogonal footrest fixing tables 160 together.

12 may be applied to the split rope connecting device 100 of the type shown in FIG. 7. In this case, the connecting rope 130 shown in FIG.

In this embodiment, the coupling holes 126 are formed on the two adjacent side surfaces of the coupling hole 130, but the coupling holes 126 may be formed on all or three of the coupling holes 130 It is also possible.

13 to 15 illustrate the structure of the safety railing assembly HA in which the safety railing 300 is assembled on one side of the foot plate 210. As shown in FIG.

13 to 15, the safety railing assembly HA according to the present invention can be assembled in the form of one structure in which the safety railing 300 is coupled to one side of the foot plate 210. [

The safety guard 300 prevents the operator from falling down the footboard during work or walking. The safety guard 300 includes a plurality of vertical members 310 arranged along the longitudinal direction of the footrest 210, And a plurality of horizontal members 320 vertically connecting between the horizontal members 320.

At this time, in a state where the safety rails 300 are directly contacted with the side surface of the footrest 210 at the lower ends of the vertical members 310 of the safety railing 300 so as to be able to be fastened on one side surface of the footrest 210, The fastening bracket 330 to be fastened is engaged.

Specifically, the side surface 210a of the foot plate 210 to be fastened to the fastening bracket 330 has a 'U' -shaped cross-sectional structure in which the upper end 210b and the lower end 210d are extended in the outward direction by a predetermined width, respectively Respectively.

At this time, the end of the side upper end 210d of the foot plate 210 extending outwardly is bent 90 degrees downward and then bent 90 degrees inward to be bent to the inner side of the fastening bracket 330 as shown in FIG. And the end of the lower end 210b of the foot plate 210 extending outwardly is bent upward by 90 degrees in the form of a protrusion 210c as shown in FIG. .

The fastening bracket 330 fastened to the side surface 210a of the foot plate 210 has a bent U-shaped cross-sectional structure corresponding to the side surface of the foot plate 210, and the foot plate 210 And is coupled to the lower end of the vertical member 310 through the bolts 312 and the nut 314. [

The bent lower end 331 of the fastening bracket 330 is formed with a protruding portion 210c so as to be hung on a protruding portion 210c formed at a lower side edge 210b of the foot plate 210 A plurality of bending end portions 332 are formed.

At this time, due to the formation of the latching end 332 like the above-mentioned structure, the protrusion 210c is fitted to the lower side of the latching end 332, The engaging groove 333 is formed.

When the fastening bracket 330 coupled to the lower end of the vertical member 310 is fastened to the side surface 210a of the foot plate 210, the fastening bracket 330 is fastened to the fastening bracket 330 The upper end 210d of the foot plate 210 is fitted to the lower end 210b of the foot plate 210 and the lower end 210b of the foot plate 210 is fitted to the upper end 210d of the foot plate 210, The safety railing 300 can be quickly and easily coupled to the side surface of the foot plate 210 with a rigid structure through a simple method of passing the eye bolt 316 through the eye 334 with the nut.

15, the bottom surface of the lower end 210b of the footrest 210 and the bottom surface of the lower end 3310 of the fastening bracket 330 are flush with each other on the same plane And the structure of the portion where the side surface 210a of the foot plate 210 and the fastening bracket 330 are coupled forms a hollow rectangular frame structure, And an efficient coupling structure can be obtained.

In addition, since a plurality of nuts fastened to the bolts 312 and 316 can be received in the inner space surrounded by the side surface 210a of the foot plate 210 and the fastening bracket 330, The appearance can be realized.

The lower end 331 of the fastening bracket 330 provided at the lower end of the vertical member 310 of the safety guardrail 300 is inserted into the side lower end 210b of the footrest 210 The safety railing 300 is mounted on the foot plate 210 by a simple operation of fastening the side upper end 210d of the foot plate 210 and the upper end 334 of the fastening bracket 330 with the eye bolts 316. [ And the safety railing assembly HA assembled as described above is mounted on the footrest fixing part 160 connected between the split rope connecting devices 100 to be coupled with the pedestal 210, It is possible to quickly perform the installation of the safety railing 300 and it is possible to eliminate the safety risks that may occur as a result of assembling the safety railing to the footrest at the high floor position.

Meanwhile, a plurality of unit scaffolding modules 400 including the split rope connecting device 100, the scaffolding frame 160, the scaffolding 210, and the safety guardrail 300 are horizontally connected along wall surfaces inside the furnace Thereby forming a scaffold structure of one layer as shown in Fig.

16, the mutually orthogonal unit scaffolding modules 400 are connected to each other through the reinforcing member 580. In this case, both ends of the reinforcing member 580 are connected to each other through the reinforcing member 580. In this case, as shown in the plan view of the scaffolding structure shown in FIG. And may be connected to each footrest fixing part 160 of the unit scaffolding module 400 orthogonal to each other through a joint bracket.

17 shows a state in which the reinforcing member 580 and the wall support 170 are fastened to the footrest fixing part 160 of the unit scaffolding module 400.

17, the end of the reinforcing member 580 is fixed to the one side of the footrest fixing table 160 on which the footrest 210 is mounted through the joint bracket 180. As shown in FIG.

In this case, the joint bracket 180 is formed such that two clamps having the same shape are mutually rotatably coupled to each other by a joint axis. This is because the reinforcement member 580 is interposed between the unit scaffold modules 400 The joint bracket 180 coupled to the foot plate 160 in such a manner that both clamps are rotatable is used to connect the reinforcement member 580 and the foot plate 160 to each other It can be easily connected.

By connecting the unitary scaffold modules 400 orthogonal to each other with the reinforcing member 580, it is possible to suppress the shaking of the divided rope connecting device 100 in the process of walking by the operator, And can be prevented from being turned by the lateral force.

In addition, wall support members 170 supported on the inner wall of the furnace are connected to each other through the connection bracket 190 at the footrest fixing part 160 of each unit scaffolding module 400.

In this case, the joint bracket 180 of the above-described type having two clamps mutually rotatable may be used as the connection bracket 190. However, since the footrest 160 and the wall support 170 are arranged parallel to each other It is preferable to apply a connecting bracket 190 having both side clamps fixed in parallel to each other in addition to the structure of the rotatable joint bracket 180. [

Since the wall support 170 that can be supported on the inner wall of the furnace is installed through the connection bracket 190 on the foot fixing table 160 as described above, the connection work of the wall support 170 can be performed quickly and easily Accordingly, the system scaffold suspended from the ceiling can stably support the inner wall of the furnace through the wall support 170 without stagnation, thereby enhancing the structural stability of the system scaffold.

18 shows a structure of a split rope connecting device holder 500 capable of mounting a system scaffold split rope connecting device 100 according to the present invention,

When dismounting the temporarily installed system scaffold for maintenance and inspection in the furnace, it is necessary to collect or disassemble the plurality of disassembled rope connecting devices 100 in one place and reuse them in the next construction site.

Conventionally, in the case of dismantling a scaffold, a wire rope having a length of several tens of meters must be wound and stored by a separate winding device such as a drum, so that deformation and damage of the wire rope occur, And the volume and weight of the wire rope wound on the drum was large, which made it difficult to store and transport the wire rope.

However, since the split rope connecting device 100 of the present invention is manufactured in a short unit length (about 2 meters in length) that facilitates the work of carrying and installing the apparatus, The rope connecting device 100 can be easily assembled in a single place by hanging the rope connecting device 500 made in the form shown in FIG. 18, and can be conveniently transported to a construction site at the time of reuse.

The structure of the split rope connecting device 500 includes a base frame 510 having a wheel 540 movable on a lower surface thereof, A frame 520 and a plurality of mounting arms 550 arranged on the horizontal member 530 located at the top of the vertical frame 520 and on which the divided rope connecting device 100 is mounted.

In this case, the mounting arm 550 has a structure in which a plurality of the mounting arms 550 are arranged on both sides of the horizontal member 530 located at the upper end of the vertical frame 520 in a symmetrical manner with a predetermined distance therebetween, The plurality of divided rope connecting devices 100 can be mounted for each of the mounting arms 550 arranged on both sides of the connecting rod 530.

In this case, when the split rope connecting device 100 is mounted on each of the mounting arms 550, the upper ring part (not shown) of the split rope connecting device 100 112 are mounted on the mounting arm 550 so that the center of gravity of the split rope connecting device 100 is located at the lower portion and structurally stable mounting is possible. By forming the latching portion 560, it is possible to prevent the split type rope connecting device 100 from being caught by the latching portion 560 and easily separated from the latching arm 550 when the latching portion 560 is inserted.

As described above, a large number of split rope connecting devices 100, which have been disassembled from the system scaffold, can be easily accommodated in one place by hooking the split rope connecting device 500, which is manufactured separately, It can be easily moved through the wheel 540 and can be easily transported to a storage place or a re-installation place.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the embodiments set forth herein. Will be possible.

100: Split rope connecting device 112.114:
116: stiffener 120, 130:
121, 122: Link connection part 123:
124: bolt 125: fastening pin
126: coupling holes 126a, 126b: first and second coupling holes
131, 132: insertion groove 160:
161: coupling shaft 162, 165:
164: body portion 166: head portion
167: neck 180: joint bracket
170: Wall support 210: Scaffold
211: mounting bracket 212: mounting groove
213: fastener 213a: guide groove
217: stopper 218: seat groove
220: edge scaffold 230: step scaffold
400: unit scaffolding module 580: reinforcing member
300: safety guardrail 310: vertical member
316: Eye bolt 320: Horizontal member
330: fastening bracket 332: fastening end
333: Retaining groove 500: Split type rope connecting device holder
510: Base frame 520: Vertical frame
530: Horizontal member 540: Wheel
550: Mounting arm 560:
580: Reinforcing member 800: Pendant type In-furnace system scaffold

Claims (9)

A safety railing assembly of a pendant type furnace internal system scaffold which is installed in an upper and lower multilayered manner around an inner wall of a furnace,
A scaffold;
And a safety rail coupled to one or both sides of the footrest, the safety rail including a plurality of vertical members arranged along a longitudinal direction of the footrest and a horizontal member connecting between the plurality of vertical members,
A lower end of the vertical member is coupled with a fastening bracket which is in contact with a side surface of the foot plate,
The side surface of the foot plate, which is fastened to the fastening bracket, is formed so as to have a cross-sectional structure of a 'C' shape having an upper end and a lower end,
Wherein the fastening bracket has a shape corresponding to a side surface of the foot plate and is symmetrical with the side surface of the foot plate and is fastened to the side surface of the foot plate through a fastening member,
A protruding portion protruding upward is formed on the side lower end of the foot plate,
The fastening bracket has a bent end formed at a lower end thereof with a fastening groove for fastening the fastening portion,
And the lower end of the fastening bracket is engaged with the lower end of the foot plate through the protruding portion and the engaging end, and the upper end of the fastening bracket is engaged with the upper end of the foot plate and is fastened through the fastening member. Safety railing assembly of my system scaffold.
delete delete 2. The safety railing assembly of claim 1, wherein the latching end is folded a plurality of times to wrap the protrusion.
The safety railing assembly of claim 1, wherein the fastening member is fastened through an upper end of the fastening bracket and a side upper end of the foot plate abutting the fastening bracket.
The safety railing assembly of claim 1, wherein the footrests are stepped footsteps connecting the upper or lower layers in a stepped manner.
A unit scaffolding module of a pendant type furnace system scaffold which is installed in an upper and lower multilayer manner around an inner wall of a furnace,
The upper and lower ends of each of the upper and lower ring members are provided with a pair of legs extending in the longitudinal direction and extending in a direction perpendicular to the longitudinal direction, A splitter-type rope connecting device provided with a connector for connecting the spools;
A footrest fixing unit connecting between the plurality of split rope connecting devices spaced apart from each other in a direction perpendicular to an inner wall of the furnace;
A safety railing assembly according to any one of claims 1, 4, 5 and 6 which is mounted on the footrest;
A unit scaffolding module of a pendant type furnace system scaffold including a plurality of pegs.
8. The pendant type portable terminal according to claim 7, wherein an insertion groove into which the annular portion is inserted is formed at both ends of the connector, and a coupling hole is formed at the center of the connector, Unit system scaffold unit of scaffold system.
The connector according to claim 8,
A first engagement hole in which a head portion provided at an end of the footrest fixing frame is fitted;
And a second engaging hole having a cross-sectional area smaller than or equal to that of the head portion and in which a neck portion connected to the head portion is fitted,
Wherein the first coupling hole and the second coupling hole form a structure communicating with each other.

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