KR100694888B1 - Prefabricated Wall Structure for Water Treatment Plant - Google Patents

Abstract

The present invention provides a prefabricated wall structure coupled to a flow channel such as a sewage treatment plant or a tap water treatment plant for filtering and purifying a fluid.

The prefabricated wall structure for a water treatment plant according to the present invention includes one or more panels arranged in a direction crossing the flow path direction of the flow channel, and a coupling member for coupling one end of the panel to the inner wall or the bottom surface of the flow channel. In the prefabricated wall structure for a water treatment plant, the coupling member is spaced apart by the thickness of the panel and the bottom plate is coupled so that one surface is in close contact with the inner wall or the bottom surface of the flow channel by anchors fastened to the left and right ends of the width direction. Arranged in parallel so that one end includes a pair of protrusions coupled between the anchoring point of the other side of the bottom plate, the panel is inserted and coupled between the pair of protrusions.

The prefabricated wall for the water treatment plant according to the present invention has an advantage in that the construction for coupling the panel to the flow channel is simple, and even if a large water pressure is applied, the panel is separated from the flow channel or the panel is broken or deformed.

Description

Prefabricated wall structure for water treatment plant {STRUCTURE OF PARTITION WALL FOR WATER DISPOSAL PLANT}

1 is a perspective view of a first embodiment of a conventional prefabricated wall.

2 is a perspective view of a second embodiment of a conventional prefabricated wall.

3 is an exploded perspective view showing a panel-to-panel coupling structure of a conventional prefabricated wall.

4 is an exploded perspective view showing a reinforcing structure of a conventional prefabricated wall.

5 is an exploded perspective view of a first embodiment of a prefabricated wall structure for a water treatment plant according to the present invention.

6 is an exploded perspective view of a second embodiment of a prefabricated wall structure for a water treatment plant according to the present invention.

7 to 9 are exploded perspective views showing the panel connection structure included in the prefabricated wall structure for a water treatment plant according to the present invention.

10 is an exploded perspective view showing a reinforcing structure included in the prefabricated wall structure for a water treatment plant according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: running water 100: panel

200: coupling member 210: bottom plate

220: protrusion plate 230: connection plate

300: fastening bolt 400: anchor

510: flat type connecting member 520: 'ㄷ' shaped connecting member

530: 'L' shaped connecting member

The present invention relates to a prefabricated wall structure coupled to a flow channel such as a sewage treatment plant or a tap water treatment plant for filtering and purifying a fluid, and more specifically, a panel and a flow channel coupling and a coupling between two different panels are more robust. The present invention relates to a prefabricated wall structure configured to enhance the strength of the panel itself.

The sewage treatment plant or the tap water treatment plant is provided with a prefabricated wall for forming a water channel to increase the water purification effect.

In the sewage treatment plant or tap water treatment plant, a plurality of concrete prefabricated walls are partitioned and installed in a zigzag at regular intervals to make a prefabricated wall, and a flow channel is formed between the concrete prefabricated walls. Made to be more efficient.

However, the prefabricated wall installed in the sewage treatment plant or the tap water treatment plant, assembling formwork one by one, places the unhardened concrete on site, and after the uncured concrete is cured and cured, performs a cumbersome and difficult installation work. Since the construction period and construction cost required to install the prefabricated wall, there was a problem that takes too much.

In order to solve this problem, there has been proposed a prefabricated wall configured to improve the workability by improving the working conditions of installing the prefabricated wall.

Hereinafter, a conventional prefabricated wall will be described with reference to the accompanying drawings.

1 is a perspective view of a first embodiment of a conventional prefabricated wall, and FIG. 2 is a perspective view of a second embodiment of a conventional prefabricated wall.

As shown in FIG. 1, a conventional prefabricated wall includes a plurality of panels 20 arranged to be perpendicular to the flow path direction of the flow channel 10, and one end of the panel 20 is connected to the flow channel 10. It consists of a pair of L-shaped steel 32 couple | bonded with an inner wall.

The pair of L-shaped steel 32 is one side is coupled to both sides of one end of the panel 20, the other side is coupled to the inner wall of the flow channel (10). At this time, the panel 20 and the L-shaped steel 32 is coupled by the fastening bolt 50, the flow channel 10 and the L-shaped steel 32 is coupled by the anchor 40.

The operator pre-couples the pair of L-shaped steels 32 to the panel 20, and arranges the panel 20 to which the L-shaped steels 32 are coupled in the flow channel 10, and then the L-shaped steels ( The panel 20 is fixed to the channel 10 by coupling 32 to the channel 10.

However, in the conventional prefabricated wall configured as described above, the L-shaped steels 32 must be coupled to both sides of the panel 20 in order to couple one panel 20. There is a problem.

In order to solve such a problem, as shown in FIG. 2, a prefabricated wall configured to couple the panel 20 to the flow channel 10 using one section steel, that is, the U-shaped section 34 may be used. The c-shaped steel 34 has a pair of wings 34a spaced apart so that one end of the panel 20 is fitted, and both ends thereof are connected to the pair of wings 34a, and an outer surface thereof is an oil channel 10. It is configured to include a bottom portion 34b coupled to the inner wall of the. At this time, the panel 20 and the U-shaped steel 34 are coupled by the fastening bolt 50, and the U-shaped steel 34 and the water flow passage 10 are coupled by the anchor 40.

Thus, when the section steel for coupling the panel 20 to the flow channel 10 is formed in a C shape, the panel 20 may be coupled to the flow channel 10 with a single beam so that the panel 20 is flow channel ( 10) has the advantage of reducing the number of processes combined in.

However, since the C-shaped steel 34 has no supporting portion protruding toward the front or the rear of the panel 20, the C-shaped steel 34 and the flow channel 10 are coupled as the hydraulic pressure is applied to the front of the panel 20. If shear and rotational stresses are generated at the site, the U-shaped steel 34 and the panel 10 may be separated from the flow channel 10.

FIG. 3 is an exploded perspective view showing a coupling structure between panels of a conventional prefabricated wall, and FIG. 4 is an exploded perspective view showing a reinforcement structure of a conventional prefabricated wall.

In order to connect the ends of the two different panels 20 included in the conventional prefabricated wall, first, the outer surface of the bottom 34b of the two C-shaped steel 34 is welded, and the respective C-shaped steel ( 34) After inserting the ends of the different panels 20 between the wings (34a) to combine the panel 20 and the c-shaped steel 34 using the fastening bolt 50.

However, since the process of welding the two U-shaped steels 34 is essential, the coupling structure between the panels 20 having the above structure has a disadvantage in that it is difficult to combine the two panels 20.

In addition, the outer surface of the panel 20 can be further coupled to the L-shaped steel 32 is arranged long in the horizontal direction to reinforce the widthwise bending strength, there is a problem that can not obtain sufficient strength.

The present invention has been proposed in order to solve the above problems, the construction is easy to connect the panel to the flow channel, the water treatment is configured so that even if a large hydraulic pressure is applied, the panel is separated from the flow channel or breakage and deformation does not occur The purpose is to provide an enteric wall structure.

Prefabricated wall structure for a water treatment plant according to the present invention for achieving the above object,

In the prefabricated wall structure for a water treatment plant comprising at least one panel arranged in a direction crossing the flow path direction of the flow channel, and a coupling member for coupling one end of the panel to the inner wall or the bottom surface of the flow channel,

The coupling member has a bottom plate coupled to be in close contact with the inner wall or the bottom surface of the flow channel by anchors fastened to both ends in the width direction left and right, and one end is arranged in parallel so as to be spaced apart by the thickness of the panel. It is configured to include a pair of protrusion plate coupled between the point of the anchor of the other side of the plate,

The panel is inserted and coupled between the pair of protruding plates.

The coupling member is applied to a section steel whose cross section forms a 'ㅛ' shape.

The coupling member is configured to further include a coupling plate, one surface of which is welded to the other surface of the bottom plate, and one end of the pair of protruding plates is coupled to both side ends thereof.

The coupling member is made of any one of glass fiber reinforced resin, stainless steel, epoxy coated structural steel, aluminum.

The prefabricated wall structure for the water treatment plant according to the present invention,

It further includes a connecting member for connecting two different panels in a row.

The connecting members are formed in a flat plate shape and are provided in pairs so as to cover both sides of the connecting portions of two different panels.

The connection member includes a flat bottom portion and a bent portion formed at both ends of the bottom portion, and the bottom portion is provided in pairs so as to cover both sides of the connection portions of two different panels.

The connecting member is composed of two 'L' shaped steels, one end of which is respectively coupled to different panels and the other end of which is coupled to each other, and is provided in pairs so as to cover both sides of the connection portions of two different panels.

The connecting member is made of any one of glass fiber reinforced resin, stainless steel, epoxy coated structural steel, aluminum.

The prefabricated wall for the water treatment plant according to the present invention,

At least one reinforcing member is arranged to have a length in the width direction of the panel coupled to one surface of the panel.

The reinforcing member is formed in the shape of any one of the 'c' shaped steel, 'C' shaped steel, flat plate.

The reinforcing member is made of any one of glass fiber reinforced resin, stainless steel, epoxy coated structural steel, aluminum.

Hereinafter, an embodiment of a prefabricated wall structure for a water treatment plant according to the present invention will be described with reference to the accompanying drawings.

Figure 5 is an exploded perspective view of a first wall structure for a water treatment plant according to the present invention, Figure 6 is an exploded perspective view of a second wall structure for a water treatment plant according to the present invention.

Prefabricated wall structure for a water treatment plant according to the present invention, as shown in Figure 5, one or more panels 100 arranged in a direction crossing the flow path direction of the flow channel 10, and one end of the panel 100 It is configured to include a coupling member 200 for coupling to the inner wall or bottom surface of the flow channel (10). In this case, the prefabricated wall for the water treatment plant includes both a barrier wall and a ditch wall applied to a water treatment plant and a sewage treatment plant to purify water.

The coupling member 200 may include a bottom plate 210 coupled to be in close contact with the inner wall of the flow channel 10, and a pair of protrusion plates 220 coupling the panel 100 to the bottom plate 210. It is configured to include). The bottom plate 210 is coupled so that one surface is in close contact with the inner wall of the water flow path 10 by anchors 400 fastened to both ends in the width direction of the left and right, and the pair of protrusion plates 220 are the panel ( It is arranged in parallel, that is parallel to each other so as to be spaced apart by the thickness of 100) one end is coupled between the point where the anchor 400 is fastened among the other side of the bottom plate (210). In addition, the panel 100 is inserted between the pair of protrusion plates 220 and coupled by a plurality of fastening bolts 300 fastened to penetrate the pair of protrusion plates 220 and the panel 100. . In this case, since the coupling member 200 has the greatest strength when the bottom plate 210 and the protrusion plate 220 are integrally formed, the coupling member 200 is a shape steel forming a '자' shape. Preferably applied.

Thus, the prefabricated wall structure for the water treatment plant according to the present invention, since the coupling member 200 is composed of one component, not only the manufacture of the coupling member 200 but also the panel coupling construction is simplified. In addition, the outer side portion of the coupling member 200 is coupled to the water flow path 10 by the anchor 400 than the portion to which the panel 100 is coupled, so that the hydraulic pressure is applied to the panel 100. Even if the rotational stress is generated there is an advantage that there is no fear that the coupling member 200 is rotated. That is, since the bottom plate 210 serves to block the rotational movement of both side ends to which the anchor 400 is coupled, as the panel 100 rotates, the coupling member 200 is separated from the flow channel 10. There is no concern.

In addition, the coupling member 200, the bottom plate 210 and the protrusion plate 220 is made of a separate member, one side is welded to the other surface of the bottom plate 210 and the pair of the both ends One end of the protrusion plate 220 may be configured to further include a connection plate 230 is coupled. In the prefabricated wall structure for the conventional water treatment plant shown in FIG. 2, the 'c' shaped steel 34 is coupled to the flow channel 10 in a structure that is coupled to the flow channel 10 by the anchor 40, that is, a point coupling structure. Therefore, when the hydraulic pressure is applied there was a fear to be separated from the flow channel (10). However, in the embodiment shown in FIG. 6, since both ends of the bottom plate 210 are coupled to the water flow path 10 by the anchor 400, and the connecting plate 230 is coupled to the bottom plate 210 by a welding method, FIG. Compared to the case shown in 2 has the effect that the fastening force of the panel 100 is significantly improved. In addition, since the bottom plate 210 is wider than the connection plate 230, when the hydraulic pressure is applied to the panel 100, the bottom plate 210 serves to block the rotational stress.

In addition, the coupling member 200 is preferably made of a material which has a certain strength or more, such as glass fiber reinforced resin, stainless steel, epoxy coated structural steel, aluminum, and the like, even if it is in contact with water for a long time.

7 to 9 are exploded perspective views showing the connection structure of the panel 100 included in the prefabricated wall structure for a water treatment plant according to the present invention.

When the size of the flow channel 10 is large, the panel 100 is coupled to two or more bars and should be installed on the flow channel 10. The prefabricated wall structure for the water treatment plant according to the present invention has two different panels 100. It may be configured to further include a connecting member for connecting in series. The connecting members are applied in pairs so as to cover the front and rear surfaces of the areas where the two different panels 100 are in contact with each other. In this embodiment, the connection member and the panel 100 are configured to be coupled by a fastening bolt 300 fastened to penetrate the connection member and the panel 100. However, the connection member and the panel 100 are coupled to each other. In addition to the fastening bolt 300 may be combined with a variety of coupling means.

The connection member may be applied to a flat connection member 510 having a flat plate shape as shown in FIG. 7 to facilitate the manufacture of the connection member and assembly of the fastening bolt 300.

In addition, the connection member, a 'c' shaped connecting member 520 having a 'c' shaped steel shape including a flat bottom portion 524 and the bent portion 522 formed at both ends of the bottom portion 524. May be applied. As described above, when the connecting member is manufactured in a 'c' shaped steel shape, when bending stress is applied to the connecting member in a direction of bending back and forth, the bent portion 522 shows great rigidity and the bending direction When bending stress is applied to the connecting member, the bottom portion 524 exhibits great rigidity, and thus has an advantage of having great rigidity in bending stress regardless of the direction.

In addition, the connecting member is composed of two 'L' shaped connecting member 530 of the two 'L' shaped steel is coupled to each other panel 100, the other end is coupled to each other as shown in Figure 9 As a result, they may be provided in pairs to cover both sides of the connection portions of the two different panels 100.

In such a case, since the 'L'-shaped connecting members 530 may be respectively coupled to both ends of each panel 100 in the step of preparing the panel 100, the' L 'corresponding to each other in the flow channel 10 may correspond to each other. 'Only the work of fastening the coupling member 530 to the fastening bolt 300. Therefore, if the connecting member is configured as shown in Figure 9, there is an effect that can simplify the work process on the job site.

In addition, if the connecting member is configured as shown in Figure 9, there is an advantage that the disassembly process between the panel 100 is also very simple.

At this time, the connecting member, like the coupling member 200, glass fiber reinforced resin, stainless steel, epoxy coated structural steel, preferably made of any one of aluminum.

10 is an exploded perspective view showing a reinforcing structure included in the prefabricated wall structure for a water treatment plant according to the present invention.

Prefabricated wall for the water treatment plant according to the present invention is arranged to have a length in the width direction of the panel 100, as shown in Figure 10 to increase the horizontal bending strength of the panel 100, one surface of the panel 100 It may be configured to further include one or more reinforcing members coupled to. In the panel 100 in which only the coupling member 200 and the coupling member shown in FIGS. 5 to 9 are coupled, only the longitudinal bending stiffness is improved, but as shown in FIG. 10, a reinforcing member having a length in the horizontal direction is added. When combined with, it has the effect of improving the horizontal bending stiffness.

At this time, the reinforcing member, 'C' shape reinforcing member 610 having a 'c' shape steel shape or 'C' shape reinforcement shape having a 'C' shape steel shape so as to exhibit greater rigidity in bending stress in each direction It may be made of the member 620, it may be made of a flat plate-shaped reinforcing member 630 having a flat plate shape in order to improve the workability.

At this time, the reinforcing member, like the coupling member 200 or the connection member, preferably made of any one of glass fiber reinforced resin, stainless steel, epoxy coated structural steel, aluminum.

As mentioned above, although this invention was demonstrated in detail using the preferable embodiment, the scope of the present invention is not limited to a specific embodiment, Comprising: It should be interpreted by the attached Claim. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

The prefabricated wall for the water treatment plant according to the present invention has an advantage in that the construction for coupling the panel to the flow channel is simple, and even if a large water pressure is applied, the panel is separated from the flow channel or the panel is broken or deformed.

Claims (12)

At least one panel 100 arranged in a direction crossing the flow path of the flow channel 10, and a coupling member 200 for coupling one end of the panel 100 to an inner wall or the bottom surface of the flow channel 10. In the prefabricated wall structure for a water treatment plant comprising: The coupling member 200, the bottom plate 210 is coupled to one surface is in close contact with the inner wall or the bottom surface of the flow channel 10 by the anchor 400 is fastened to both ends in the width direction left and right, and the panel ( 100 is arranged in parallel to be spaced apart by a thickness of one end is configured to include a pair of protrusion plate 220 coupled between the point of the anchor 400 of the other side of the bottom plate 210, The panel 100 is a prefabricated wall structure for a water treatment plant, characterized in that the inlet is coupled between the pair of protrusion plates 220. The method of claim 1, The coupling member 200 is a prefabricated wall structure for a water treatment plant, characterized in that the cross section is formed in the shape of a section steel forming a 'ㅛ' shape. The method of claim 1, The coupling member 200 further includes a connection plate 230 having one surface welded to the other surface of the bottom plate 210, and one end of the pair of protrusion plates 220 coupled to both side ends thereof. Prefabricated wall structure for a water treatment plant. The method according to any one of claims 1 to 3, The coupling member 200, prefabricated wall structure for a water treatment plant, characterized in that made of any one of glass fiber reinforced resin, stainless steel, epoxy coated structural steel, aluminum. The method of claim 1, Prefabricated wall structure for a water treatment plant, characterized in that it further comprises a connection member for connecting two different panels 100 in a row. The method of claim 5, The connecting member is formed in a flat plate shape, prefabricated wall structure for a water treatment plant, characterized in that provided in pairs to cover both sides of the connection portion of the two different panels 100, respectively. The method of claim 5, The connection member may include a flat bottom portion and a bent portion formed at both ends of the bottom portion, and the bottom portions may be provided in pairs so as to cover both sides of the connection portions of two different panels 100. Prefabricated wall structure for water treatment plant. The method of claim 5, The connecting member is composed of two 'L' shaped steels, one end of which is coupled to the other panel 100 and the other end of which is coupled to each other, in pairs so as to cover both sides of the connection portions of the two different panels 100, respectively. Prefabricated wall structure for a water treatment plant, characterized in that provided. The method according to any one of claims 5 to 8, The connecting member, glass fiber reinforced resin, stainless steel, epoxy coated structural steel, prefabricated wall structure for a water treatment plant, characterized in that made of any one of aluminum. The method of claim 1, Prefabricated wall structure for a water treatment plant, characterized in that it further comprises at least one reinforcing member is arranged to have a length in the width direction of the panel 100 is coupled to one surface of the panel (100). The method of claim 10, The reinforcing member is a prefabricated wall structure for a water treatment plant, characterized in that formed in the shape of any one of the 'c' shaped steel, 'C' shaped steel, flat plate. The method according to claim 10 or 11, wherein The reinforcing member is a prefabricated wall structure for a water treatment plant, characterized in that made of any one of glass fiber reinforced resin, stainless steel, epoxy coated structural steel, aluminum.

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