KR101990350B1 - Flow guide wall structure using PDF panel to prevent dead water in water storage facilities - Google Patents

Abstract

The present invention relates to a structure of a training wall of a PDF panel, for preventing dead water in a water storage facility. The structure of the training wall of the PDF panel includes the PDF panel and a support member. The PDF panel includes: a front panel; a rear panel installed to be parallel with the front panel by being spaced from the front panel; and multiple ribs connecting the front panel and the rear panel in an inner space formed between the front panel and rear panel. The support member includes: a separated pair of parallel side walls; and a bottom unit connecting the lower part of the pair of side walls. A short protrusion unit supporting a lower end of the PDF panel is individually formed on both sides of the bottom unit. A discharge hole discharging water from the bottom unit to the side wall is formed at an edge of the bottom unit. Thus, the support member is installed on the bottom in which the training wall is installed. The lower part of the PDF panel is connected by being inserted between the pair of side walls of the support member. A lower end of the PDF panel is supported on the short protrusion unit by being spaced at fixed intervals from the bottom unit of the support member. Also, the water flowing into the PDF panel and the support member is discharged through the discharge hole.

Description

Flow guide wall structure using PDF panel to prevent dead water in water storage facilities}

The present invention relates to a structure of a ditch wall for inducing water flow using a PDF panel, and more particularly, to a structure of a ditch wall of a PDF panel for preventing shooters in a water storage facility such as a water purification plant.

In general, water storage facilities, such as sewage treatment plants or water purification plants, are provided with walls on the walls to induce water flow. The distillation wall is installed at the boundary part that flows into the sedimentation basin after the coagulation process in the water treatment process to distribute the water flow evenly, and also to induce water flow in the water purification plant by zigzag to increase the residence time of the flowing water to disinfect It also maximizes the settling time of impurities.

Wood, PVC panels, or PDF (Polyethylene Double Frame) panels are used for these walls. Among them, PDF walls are panels extruded from polyethylene, which are easy to mass-produce, and less corrosive by water or chlorine. It is widely used.

A conventional drip wall structure using such a PDF panel is shown in Figs. 1 is a plan view of a concrete water purification plant in which a ditch wall of a conventional PDF panel is installed, and FIG. 2 is a detailed view of a PDF panel installed between concrete columns in FIG. As shown in FIG. 1, water flows through the inlet 1c and is rectified by alternately installing the ditch walls 2 on one side wall and an opposite wall facing the square structure concrete body 1 forming a water purification plant. After passing through the wall (3), it moves in a zigzag along the ditch wall (2) and is discharged through the discharge port (1d) installed on the opposite side.

FIG. 2 is a detailed view of the ditch wall 2, and the PDF panel 20 is installed between the concrete pillars 1a and 1b. The PDF panel 20 has a dual panel body 21 having a front panel and a rear panel, and an inner space 21c is formed between the front panel and the rear panel, and the front panel and the rear panel are located in the inner space 21c. A plurality of reinforcing ribs 22 are formed at regular intervals. Then, a protrusion is formed on one side of the PDF panel 20 and a groove 21b is formed on the other side of the PDF panel 20.

Therefore, the conductive wall of the PDF panel 20 has a strong corrosion resistance and a rib-reinforced double frame structure, which has a strong water pressure and is widely used.

By the way, in the case of the flow walls using the PDF panel 20 as described above, the lower end of the PDF panel 20 is supported on the bottom of the water purification plant, and water is passed between the lower end and the bottom surface of the PDF panel 20 in the PDF panel 20. Inflow into the inner space (21c) of the), as the water introduced into the inner space (21c) of the PDF panel 20 does not fall well, there is a problem that the water can rot, thereby contaminating the surrounding water.

Accordingly, the present invention has been made in order to solve the problems of the prior art, to prevent the contamination of the shooter and water by the water discharged into the inside of the PDF panel to be quickly discharged to prevent the shooter of the water storage facility is improved hydraulic pressure bearing capacity The aim is to provide a PDF panel ditch wall structure for the purpose.

PDF panel drip wall structure for preventing the shooter of the water storage facility according to the present invention is the front panel 111, and the rear panel 112 is disposed in parallel with the front panel 111 spaced from the front panel 111 and PDF panels 110 having a plurality of ribs 113 connecting the front and rear panels 111 and 112 to the inner space 114 formed between the front panel 111 and the rear panel 112. A pair of sidewalls 131 spaced apart from each other and formed in parallel with each other, and a bottom portion 132 connecting lower portions of the pair of sidewalls 131, and both sides of the bottom portion 132 are provided with the PDF. Stepped portions 133 are formed to support the lower ends of the panel 110, and discharge holes 134 are discharged from the bottom portion 132 to the side walls 131 at edges of the bottom portion 132. The PDF panel 110 is formed by including a support member 130 is formed is formed on the bottom 102, the ditch wall 100 is installed The lower portion of the support member 130 is sandwiched between the pair of side walls 131 are coupled to each other, the lower end of the PDF panel 110 is spaced apart from the bottom portion 132 of the support member 130 by a predetermined interval. It is supported by the stepped portion 133 in the state characterized in that the water introduced into the support member 130 and the PDF panel 110 is discharged through the discharge hole 134.

In addition, each side wall 131 of the support member 130 is formed to be inclined inwardly characterized in that the distance between the side wall 131 is narrowed toward the upper side of the side wall 131.

In addition, the bottom portion 132 of the supporting member 130 is formed to be spaced apart from the lower side of the upper side of the side wall 131, so that the bottom portion 132 of the supporting member 130 is installed on the ditch wall 100. Spaced space 135 is formed between the bottom 102 is characterized in that the space 135 is in communication with the outside of the side wall 131 by the discharge hole 134.

In addition, the bottom of the bottom portion 132 is characterized in that the support leg 136 is supported on the bottom 102, the ditch wall 100 is installed.

In addition, the discharge hole 134 of the support member 130 is inclined downward from the edge of the bottom portion 132 is characterized in that it is formed to the side wall 131.

In addition, the bottom portion 132 of the supporting member 130 is characterized in that the anchor 142 for fixing to the bottom 102, the ditch wall 100 is installed.

In addition, the support member 130 is coupled to both side wall 131 and the through-bolt 140 penetrating through the PDF panel 110 in the state in which the PDF panel 110 is coupled, and through bolts on one side wall 131. The nut 141 is coupled to 140.

In addition, an upper coupling member 150 is coupled to an upper portion of the PDF panel 110, and the upper coupling member 150 is a pair of sidewalls 151 formed to be spaced apart from each other in parallel and both sidewalls 151. It includes a top plate portion 152 connecting the top of the, and both sides of the top plate portion 152 is formed with a stepped portion 153 for supporting the upper end of the PDF panel 110, both sides of the top plate portion 152 The through-hole 154 through which the air from the upper plate 152 to the side wall 151 is characterized in that it is formed.

In addition, the upper coupling member 150 is coupled to the through bolts penetrating both the side wall 151 and the PDF panel 110 in the state in which the PDF panel 110 is coupled, the nut on the through bolt in one side wall 151 It is characterized in that the combined.

In addition, the front and rear panels 111 and 112 of the PDF panel 110 to couple and fix the PDF panel 110 to the upper plate 103 formed on the column 101 is coupled to the side of the PDF panel in the water storage facility. The upper plate coupling member 180 is coupled to the upper portion is further provided,

The upper plate coupling member 180 has a lower panel coupled to each of the front and rear panels 111 and 112 and extended to the upper plate 103, and a side extension portion bent at right angles from the panel coupling portion 181. 182 is formed integrally,

The panel coupling part 181 of each upper panel coupling member 180, the side wall 151 of the upper coupling member 150, and the through bolt 185 penetrating through the PDF panel 110 are combined and one upper panel coupling member is coupled. The nut 186 is coupled to the end of the through bolt 185 at 180.

In addition, the front and rear panels 111 and 112 of the PDF panel 110, the horizontal reinforcing member 160 is extended to extend along the longitudinal direction of the PDF panel 110, respectively, each horizontal reinforcing member 160 And a through bolt 165 penetrating through the PDF panel 110 and a nut 166 coupled to an end of the through bolt 165 in the horizontal reinforcing member 160.

In addition, the front and rear panels 111 and 112 of the PDF panel 110 are coupled to the side engaging members 170 extending vertically, respectively, the side coupling members 170 to the front and rear panels 111 and 112, respectively. The panel coupling portion 171 is in contact with each other, and the column coupling portion 172 is bent at right angles from the panel coupling portion 171 to be in contact with the concrete pillar 101 is formed integrally, the front, rear of the PDF panel 110 The through bolts 173 through the panel coupling portion 171 of the side coupling member 170 and the PDF panel 110 coupled to the panels 111 and 112, respectively, are coupled and the through bolts 173 from one side coupling member 170. Nut 174 is coupled to the end of the), the column coupling portion 172 of the side coupling member 170 is characterized in that the anchor 175 for fixing to the pillar 101 is coupled.

In addition, the column 101 to which the PDF panel 110 is coupled is further provided with a column fixing plate 190 for fixing the PDF panel 110 to the column 101, the column fixing plate 190 is The first panel coupling portion 191 and the first panel coupling portion 191 coupled to the PDF panel 110 coupled to the left side of the pillar 101 in the form of a strip, part of the pillar 101. The second panel coupling part 193 coupled to the PDF panel 110 coupled to the right side of the pillar 101 by bending at the column coupling part 192 and the pillar coupling part 192 is formed integrally. The first panel coupling part 191 and the PDF panel 110 of the two pillar fixing plates 190 coupled to the front and rear of the pillar 101 are coupled to each other by the through bolts 195, and the pillar 101. The second panel coupling portion 192 and the PDF panel 110 of the two column fixing plates 190 coupled to the front and rear of the) is coupled to each other by a through bolt (195) do.

In addition, a pillar fixing plate 190 for fixing the PDF panel 110 to the pillar 101 is provided on the right side of the pillar 101 to which the PDF panel 110 is coupled, and the pillar fixing plate 190 is provided. The first panel coupling portion 191 and the first panel coupling portion 191 coupled to the PDF panel 110 coupled to the upper side of the pillar 101 is formed in a strip shape of the pillar 101 A pillar coupling portion 192 surrounding a part and a second panel coupling portion 193 which are bent at the pillar coupling portion 192 and coupled to the PDF panel 110 coupled to the lower side of the pillar 101 are integrally formed. The upper and lower left sides of the pillars 101 to which the PDF panel 110 is coupled are provided with additional pillar fixing plates 190a for fixing the PDF panel 110 to the pillars 101, respectively. The additional column fixing plate 190a is formed in a strip shape and is coupled to the first panel PDF panel 110 coupled to the upper or lower side of the column 101. The joint portion 191a, the pillar coupling portion 192a that is bent at the first panel coupling portion 191a and surrounds the edge of the pillar 101, and the left side surface of the pillar 101 being bent at the pillar coupling portion 192a. The second panel coupling portion 193a coupled to the PDF panel 110 coupled to the formed integrally formed, the first panel coupling portion 191a of the additional pillar fixing plate 190a is the pillar fixing plate ( One of the first and second panel coupling parts 191 and 192 of 190 and the PDF panel 110 coupled between them are coupled to each other through a through bolt 195, and coupled to the upper and lower left sides of the column 101. The second panel coupling portion 193a of each of the additional pillar fixing plates 190a is coupled to each other by a through bolt 195 together with the PDF panel 110 coupled therebetween.

According to the present invention is provided a PDF panel ditch wall structure for preventing the shooter of the water storage facility to prevent the contamination of the shooter and water by improving the discharge of water introduced into the PDF panel quickly.

1 is a plan view of a concrete water purification plant equipped with a conventional wall of PDF panels,
Figure 2 is a detailed view of the PDF panel installed between the concrete pillars in Figure 1,
3 is a front view of a ditch wall using a PDF panel according to the present invention;
4 is a cross-sectional view of FIG.
5 is a detailed view of a PDF panel used in the present invention.
FIG. 6 is a detailed view of a lower portion of the PDF panel, which is part A of FIG. 3, and a supporting member coupled thereto, according to the present invention.
7 is a detailed view of the upper portion and the upper coupling member coupled to the upper part of the PDF panel B of Figure 3 in the present invention,
8 is a cross-sectional view taken along line X-X 'of FIG. 4 in the present invention, showing a detailed cross-sectional view of an intermediate portion of the PDF panel.
FIG. 9 is a view showing a coupling structure between a PDF panel, which is part C of FIG. 4, and a concrete column or wall forming a ditch wall in the present invention; FIG.
10 is a front view of a ditch wall using a PDF panel according to another embodiment of the present invention;
FIG. 11 is a detailed view of a lower portion of the PDF panel, part D of FIG. 10, and a support member coupled thereto;
12 is a detailed view of an upper portion of the PDF panel, which is part E of FIG. 10, and an upper coupling member coupled thereto;
Figure 13 is a view showing a coupling structure of the PDF panel and the concrete pillar in Figure 10,
14 is a view showing another coupling structure of the PDF panel and the concrete column in FIG.
15 shows an example of a water storage facility to which a ditch wall using the PDF panel according to the present invention is applied.

PDF panel ditch wall structure for preventing the catchment of the water storage facility according to the present invention will be described in detail with reference to the preferred embodiment.

FIG. 3 is a front view of the flow barrier wall using the PDF panel according to the present invention, FIG. 4 is a cross sectional view of FIG. 3, FIG. 5 is a detailed view of the PDF panel used in the present invention, and FIG. A detailed view of the lower portion of the PDF panel, which is part A, and the supporting member coupled thereto, and FIG. 7 is a detailed view of the upper portion of the PDF panel, which is part B of FIG. 4 is a cross-sectional view taken along the line X-X 'of the present invention in detail, and FIG. 9 is a view of the PDF panel of FIG. 15 is a view showing a coupling structure, and FIG. 15 shows an example of a water storage facility to which a ditch wall using a PDF panel according to the present invention is applied.

Fig. 15 is an overall structural diagram showing an example of a water purification plant 105 to which a ditch wall structure using a PDF (Polyethylene Double Frame) panel according to the present invention is applied. The water purification plant 105 includes a concrete wall 106 having a rectangular shape. In order to guide the water flowing through the inlet to the zigzag, the drip wall 100 is installed and the drip wall 100 is between the concrete pillars 101 or between the column 101 and the wall 106 PDF panel 110 ) Is combined. However, FIG. 15 shows an example in which the dike wall structure of the present invention is applied, and may be applied to water storage facilities such as water and sewage treatment plants in which the dike wall 100 is installed as well as the water purification plant 105. 3 is a view illustrating a part of the conductive wall 100 in FIG. 15, in which the PDF panel 110 is coupled between the concrete pillars 101 in the conductive wall 100. The PDF panel 110 applied to the flow barrier wall 100 has a double frame structure, the front panel 111 and the rear panel 112 spaced apart from the front panel 111 and disposed in parallel with the front panel 111, A plurality of ribs 113 connecting the front and rear panels 111 and 112 are formed at regular intervals in the inner space 114 formed between the front panel 111 and the rear panel 112 (see FIG. 5). ). Each rib 113 is formed vertically from the top to the bottom of the PDF panel 110, whereby the interior space 114 between the front and rear panels 111 and 112, and also the plurality of interior spaces 114 by the vertical ribs 113. Is divided into

In addition, a protrusion 121 is formed at the right end of the PDF panel 110 and a groove 122 is formed at the left end of the PDF panel 110. The protrusion 121 is formed at the right end of one PDF panel 110 as shown. Is coupled to the groove portion 122 formed at the left end of the adjacent PDF panel 110, a plurality of PDF panels 110 are connected to each other and are coupled between the concrete pillars 101.

And, the support member 130 is coupled to the lower portion of the PDF panel 110 in the present invention. 6 is a detailed view of the lower portion of the PDF panel 110 and the supporting member 130 coupled thereto. In the present invention, the support member 130 is disposed on the bottom 102 having the same length as the PDF panel 110 coupled between the pillars and coupled to the lower portion of the PDF panel 110 so that the ditch wall 100 is installed. And a pair of sidewalls 131 spaced apart from each other and formed in parallel with each other, and a bottom portion 132 connecting lower portions of the pair of sidewalls 131, and on both sides of the bottom portion 132. Stepped portions 133 are formed to support the bottom of the panel 110, respectively, and discharge holes 134 are formed at both edges of the bottom 132 to discharge water from the bottom 132 to the side wall 131. do.

Each side wall 131 of the supporting member 130 is formed to be inclined inwardly so that the distance between the side walls 131 becomes narrower toward the top, and the lower part of the PDF panel 110 is sandwiched between the side walls 131, and then the PDF panel 110. Before and after, the rear panels 111 and 112 are firmly supported by the respective side walls 131. In addition, the upper end portion of the inner circumferential surface of each side wall 131 is formed to gradually decrease in thickness so that the distance between the side walls 131 increases toward the upper portion, thereby facilitating the insertion of the PDF panel 110.

The bottom portion 132 of the supporting member 130 connects the lower portion of the pair of side walls 131, and the discharge hole 134 formed at both edges of the bottom portion 132 includes the supporting member 130 and the PDF panel ( A plurality of discharge holes 134 are formed to be discharged to the outside to the outside to be spaced apart a predetermined interval along the longitudinal direction of the support member 130, each discharge hole 134 is a bottom portion 132 The water flowing into the support member 130 and the PDF panel 110 is quickly discharged to the outside of the side wall 131 by being inclined downward from the edge of the bottom side to the side wall 131.

In addition, both side surfaces of the bottom portion 132 connected to the side wall 131 are formed with stepped portions 133 supporting the lower end of the PDF panel 110, whereby the lower end of the PDF panel 110 is bottomed. Each inner space 114 supported by both step portions 133 and separated by ribs 113 in the PDF panel 110 without being supported by the portion 132 and spaced upwardly from the bottom portion 132. The water introduced into the PDF panel 110 moves to the space between the bottom and the bottom 132 and is discharged through the discharge hole 134, so that the introduced water is discharged more quickly. In addition, since the bottom part 132 is supported by the stepped part 133, it is possible to form the discharge hole 134 less than the number of the internal spaces 114 partitioned by the ribs 113.

In addition, the bottom portion 132 is formed to be spaced apart upward by a predetermined height from the lower end of the side wall 131, not the lower end of the side wall 131, the bottom wall of the bottom portion 132 is provided with a conductive wall 100 A support leg 136 is formed that is supported by the bottom 102. Thus, a space 135 is formed between the bottom portion 132 of the support member 130 and the bottom 102 on which the drip wall 100 is installed, and the space 135 is formed by the discharge hole 134. In communication with the outside of the side wall 131, the water in the space 135 is also discharged to the outside of the side wall 131 through the discharge hole 134.

In addition, an anchor 142 is fixed to the bottom 132 of the supporting member 130 and fixed to the bottom by fixing the anchor wall 142 to the bottom where the PDF wall 110 is disposed between the side walls 131. The through bolt 140 penetrating both side walls 131 and the PDF panel 110 in the state that the PDF panel 110 is coupled to each other and then the nut 141 to the through bolt 140 on one side wall 131. ) To complete the coupling with the support member 130. The support member 130 may be contaminated with water due to corrosion when iron materials such as stainless steel are used, and there is a need for periodic steel surface maintenance, but in the present invention, the support member 140 is a PDF panel 110. It is made of a polyethylene material such as can solve this concern.

As described above, in the present invention, the supporting member 130 having the above configuration is coupled to the lower portion of the PDF panel 110 to firmly support the PDF panel 110, thereby improving structural strength and hydraulic pressure bearing force of the flow barrier wall 100. In addition, the water introduced into the PDF panel 110 is quickly discharged to prevent contamination of the water.

As shown in FIG. 7, the upper coupling member 150 is coupled to the upper portion of the PDF panel 110. The upper coupling member 150 has the same length as the supporting member 130 and is coupled to the upper portion of the PDF panel 110, and is a pair of sidewalls 151 spaced apart from each other and formed in parallel. And a top plate portion 152 connecting the upper portions of the pair of side walls 151, and both side portions of the top plate portion 152 are formed with stepped portions 133 on which upper ends of the PDF panels 110 are supported. At both edges of the upper plate part 152, a through hole 154 through which air is vented from the upper plate part 152 to the side wall 151 is formed.

Each sidewall 151 of the upper coupling member 150 is formed to be inclined inwardly so that the distance between the sidewalls 151 becomes narrower toward the lower side, and the upper part of the PDF panel 110 is sandwiched between the sidewalls 151 and then the PDF panel ( The front and rear panels 112 of 110 are firmly supported by each side wall 151. In addition, the lower end portion of the inner circumferential surface of each side wall 151 is formed to gradually decrease in thickness so that the distance between the side walls 151 is further lowered to facilitate the insertion of the PDF panel 110.

The upper plate portion 152 of the upper coupling member 150 connects the upper portions of the pair of side walls 151 and the through holes 154 formed at both edges of the upper plate portion 152 include the upper coupling member 150 and the PDF panel 110. A plurality of through holes 154 are formed to be spaced apart at regular intervals along the longitudinal direction of the upper coupling member 150, and each through hole 154 is inclined upward from the edge of the upper plate portion 152. By forming the side wall 151, the air inside the upper coupling member 150 and the PDF panel 110 is vented to the outside of the side wall 151.

In addition, stepped portions 153 on which upper ends of the PDF panel 110 are supported are formed at both side surfaces of the upper plate portion 152 connected to the side wall 151, whereby an upper portion of the PDF panel 110 is formed on the upper plate portion ( The air in each of the internal spaces 114, which are not supported by the 152 but is spaced downward from the upper plate 152 and supported by both stepped portions 153 and partitioned by the ribs 113 in the PDF panel 110, After moving to the space between the upper portion of the PDF panel 110 and the upper plate 152 is quickly vented through the through-hole 154. In addition, the upper plate portion 152 is supported by the stepped portion 153 to form the through hole 154 less than the number of the internal space 114 partitioned by the ribs 113.

In addition, the upper plate portion 152 is formed by being spaced downward by a predetermined height from the upper end of the side wall 151, not the top of the side wall 151, and is supported by the upper structure of the water purification plant 105 in the center of the upper surface of the upper plate portion 152 The support protrusion 156 is formed. Therefore, a spaced space 155 is formed between the upper plate 152 and the upper structure of the upper coupling member 150 and the spaced space 155 is in communication with the outside of the side wall 151 by the through hole 154 to the spaced space ( 155 internal air is also vented outside the sidewall 151 through the aperture 154.

The upper coupling member 150 is inserted through the PDF panel 110 between the side wall 151 and coupled to each other, and through bolts penetrating both side walls 151 and the PDF panel 110 in a state where the PDF panel 110 is coupled. 157 is combined, and then the nut 158 is coupled to the through bolt 157 on one side wall 151 to complete the coupling with the upper coupling member 150. In the present embodiment, the upper coupling member 150 is made of polyethylene.

As described above, in the present invention, the upper coupling member 150 having the above configuration is coupled to the upper portion of the PDF panel 110 so as to firmly support the PDF panel 110 so as to provide structural strength and hydraulic pressure bearing force of the conductive wall 100. In addition, the air inside the PDF panel 110 is ventilated to prevent contamination of water introduced into the PDF panel 110.

As shown in FIG. 8, the horizontal reinforcement member 160 is coupled to the middle of the PDF panel 110. The horizontal reinforcement member 150 has the same length as the PDF panel 110 and is coupled to the middle of the PDF panel 110, and the PDF panel 110 horizontally in the middle of the front and rear panels 112 of the PDF panel 110. Horizontal reinforcement member 160 extending along the longitudinal direction of each is coupled. Each horizontal reinforcing member 160 has a cross-section 'b' shaped horizontal extension portion 162 bent at a right angle from the panel support portion 161 and the panel support portion 161 in contact with the front, rear panels (111, 112). ) Is formed integrally, the through-bolt 165 penetrating through the panel support 161 and the PDF panel 110 of each horizontal reinforcing member 160 and the through-bolt 165 in one horizontal reinforcing member 160 The nut 166 is coupled to the end of the. In this embodiment, the horizontal reinforcement member 160 is similarly made of polyethylene, and the horizontal reinforcement member 160 reinforces the coupling force between the PDF panels 110, and similarly, improves the structural strength and the hydraulic pressure bearing force of the flow barrier wall 100. It plays a role.

In addition, the side panel member 170 is coupled to the side of the PDF panel 110, the PDF panel 110 is coupled to the concrete column 101 of the concrete column 101 or the water purification plant 105 forming the ditch wall 100. do. 9 is a view showing a coupling structure between the PDF panel 110 and the concrete column 101 in the present invention.

The side coupling member 170 is fixed to the concrete pillar 101 or the wall 106 that is coupled to the side of the PDF panel 110 to form the ditch wall 100, the front and rear of the PDF panel 110 Side coupling members 170 extending from the bottom to the top of the PDF panel 110 are joined at left and right ends of the panels 111 and 112, respectively. Each side coupling member 170 has a cross-section made of 'A' shape and bent at a right angle at the panel coupling portion 171 and the panel coupling portion 171 in contact with the front and rear panels 112 and the concrete pillar ( The column coupling portion 172 in contact with the 101 is formed integrally, the panel coupling portion 171 of each side coupling member 170 and the through bolt 173 penetrating through the PDF panel 110 is coupled and one side The nut 174 is coupled to the end of the through bolt 173 in the coupling member 170. In addition, the column coupling portion 172 of each side coupling member 170, the anchor 175 for fixing to the concrete pillar 101 is coupled. In the present embodiment, the side coupling member 170 is made of polyethylene.

Next, the PDF panel ditch wall structure for preventing the catchment of the water storage facility according to the second embodiment of the present invention will be described in detail with reference to the accompanying drawings. FIG. 10 is a front view of a ditch wall using a PDF panel according to a second embodiment of the present invention. FIG. 11 is a detailed view of a lower portion of the PDF panel, which is part D of FIG. 10, and a supporting member coupled thereto, and FIG. Figure 10 is a detailed view of the upper portion of the PDF panel and the upper coupling member coupled to the E part of Figure 10, Figure 13 is a view showing a coupling structure of the PDF panel 110 and the concrete pillar 101 in Figure 10, Figure 14 Figure 10 shows the different joining structure of PDF panel and concrete column.

The second embodiment of the present invention applies the Muangka method that is not anchored to the bottom 102 and the column 101 of the ditch wall 100. When the second embodiment is different from the first embodiment, the bottom portion 132 of the supporting member 130 is fixed to the bottom by the anchor 142 in the first embodiment, but the embodiment shown in FIG. As shown, do not fix the support member 130 with an anchor.

Meanwhile, FIG. 12 is a detailed view of the upper portion of the PDF panel 110 and the upper coupling member 150 coupled thereto. In this embodiment, the upper panel coupling member 180 in addition to the upper coupling member 150 is disposed on the upper portion of the PDF panel 110. Is further provided. The upper plate coupling member 180 is to couple and fix the PDF panel 110 to the upper plate 103 formed on the column 101 in the structure of the water purification plant 105, and the front and rear panels of the PDF panel 110. The upper plate coupling members 180 are coupled to the upper portions 111 and 112, respectively. Each upper plate coupling member 180 has a cross-section of a '-' shape and the lower panel is coupled to the front and rear panels 111 and 112 to extend to the upper plate 103 and the panel coupling portion 181 and the panel coupling portion ( Side extension portion 182 bent at a right angle at the 181 is formed integrally, the through-bolt 185 penetrating the panel coupling portion 181 and the PDF panel 110 of each upper plate coupling member 180 is coupled. And the nut 186 is coupled to the end of the through-bolt 185 in one upper plate coupling member 180. The through bolt 185 penetrating all of the panel coupling unit 181, the upper coupling member 150, and the PDF panel 110 is additionally coupled. The material of the upper plate coupling member 180 is made of stainless steel and welded to a steel plate fixed to the upper plate 103.

In addition, in the present embodiment, the column fixing plate 190 is further coupled to the PDF panel 110 in addition to the side coupling member 170. FIG. 13 illustrates a coupling structure of the PDF panel 110 and the pillars 101 in the second embodiment, and shows a form in which the PDF panel 110 is coupled to both sides of the pillars 101.

As shown, the column fixing plate 190 is made of stainless steel and has a width of about 5 cm to form a band bent a plurality of times to fix the PDF panel 110 to the column 101, the column ( The first panel coupling part 191 coupled to the PDF panel 110 coupled to the left side with the center 101 as the center, and the column coupling part bent from the first panel coupling part 191 surrounding a part of the pillar 101. 192 and the second panel coupling portion 193, which is bent from the pillar coupling portion 192 and coupled to the PDF panel 110 coupled to the right side of the pillar 101, are integrally formed and fixed with two pillars. Plate 190 is coupled to the front and rear of the pillar 101, respectively.

In addition, the through-bolt 195 penetrating the first panel coupling portion 191, the PDF panel 110 and the side coupling member 170 of each of the pillar fixing plate 190 coupled to the front and rear of the pillar 101. ) Is coupled and the nut 196 is coupled to the end of the through-bolt 195 in one of the first panel coupling portion 191, the second panel coupling portion 193 of each column fixing plate 190, PDF panel A through bolt 195 penetrating through the 110 and the side coupling member 170 is coupled, and a nut 196 is coupled to an end of the through bolt 195 at one side of the second panel coupling portion 193 to fix the column fixing plate ( 190 is fixed to each other.

In this embodiment, the column fixing plates 190 are coupled to both PDF panels 110 so that both PDF panels 110 are fixed to the pillars 101 without being directly anchored to the pillars 101.

Meanwhile, FIG. 14 shows another coupling structure of the PDF panel 110 and the pillar 101 in the second embodiment, and shows a form in which the PDF panel 110 is coupled to three surfaces of the pillar 101. . In the coupling structure of the PDF panel 110 and the pillar 101 shown in FIG. 14, the PDF panel 110 is further coupled to one side of the pillar 101 in the coupling structure shown in FIG. 13.

Accordingly, the pillar fixing plate 190 coupled to the right side of the pillar 101 in FIG. 14 is the same as that shown in FIG. 13, except that the additional pillar fixing plate 190a is on the left side of the pillar 101. It is coupled to the lower side.

That is, the additional column fixing plate 190a is similarly made of stainless steel and has a width of about 5 cm and has a band shape bent many times to fix the PDF panel 110 to the column 101, as shown in the drawing. The first panel coupling portion 191a coupled to the PDF panel 110 coupled to the upper side or the lower side with the centered pillar 101 as the center, and the pillar including a corner bent at the first panel coupling portion 191 ( A pillar coupling portion 192a surrounding a portion of the 101 and a second panel coupling portion 193a which are bent at the pillar coupling portion 192a and coupled to the PDF panel 110 coupled to the left side of the pillar 101 are integrated. The first panel coupling portion 191a of the additional pillar fixing plate 190a is formed of the PDF panel 110, the side coupling member 170, and the first and second panel coupling portions of the pillar fixing plate 190. Through bolts 195 penetrating one of the (191,192) is coupled and the nut 196 is coupled to the end of the through bolts 195 It is fixed to.

In addition, the additional column fixing plate 190a is similarly coupled to the lower edge portion of the left side of the column 101, and is similarly coupled by the through bolt 195.

Then, the second panel coupling portion 193a of each of the additional pillar fixing plates 190a coupled to the upper and lower left sides of the pillar 101 is a PDF panel 110 coupled therebetween, and a side coupling member ( The through bolts 195 penetrating the 170 together are coupled and the nut 196 is coupled to the ends of the through bolts 195 to be fixed to each other.

Other configurations and effects are the same as in the previous embodiment, and a detailed description thereof will be omitted here.

The present invention has been described above with reference to preferred embodiments, but the present invention is not limited thereto, and various modifications may be made by those skilled in the art without departing from the scope of the present invention as set forth in the claims below. There will be.

100: ditch wall 101: pillar
102: floor 103: top plate
105: water purification plant 106: wall
110: PDF panel 111: front panel
112: rear panel 113: rib
114: internal space 130: support member
131: side wall 132: bottom
133: step 134: discharge hole
150: upper coupling member 160: horizontal reinforcing member
170: side coupling member 180: top plate coupling member
190: pillar fixing plate

Claims (14)

An inner panel formed between the front panel 111 and the rear panel 112 spaced apart from the front panel 111 and disposed in parallel with the front panel 111, and between the front panel 111 and the rear panel 112. PDF panel 110 in which a plurality of ribs 113 connecting the front and rear panels 111 and 112 are formed in the space 114,
A pair of sidewalls 131 spaced apart from each other and formed in parallel with each other, and a bottom portion 132 connecting lower portions of the pair of sidewalls 131, and both sides of the bottom portion 132 are provided with the PDF. Stepped portions 133 are formed to support the lower ends of the panel 110, and discharge holes 134 are discharged from the bottom portion 132 to the side walls 131 at edges of the bottom portion 132. It is formed to include a support member 130 is disposed on the bottom 102 is installed on the ditch wall 100, the lower portion of the PDF panel 110 is a pair of side walls 131 of the support member 130 It is sandwiched between and coupled, the lower end of the PDF panel 110 is supported by the step portion 133 in a state spaced apart from the bottom portion 132 of the supporting member 130 by the supporting member 130 And water introduced into the PDF panel 110 is discharged through the discharge hole 134,
The bottom portion 132 of the supporting member 130 is formed to be spaced apart from the lower end of the side wall 131 to the upper side, the bottom portion 132 and the bottom of the dripping wall 100 of the supporting member 130 is installed. A space 135 is formed between the 102 and the space 135 is communicated with the outside of the side wall 131 by the discharge hole 134,
A support leg 136 is formed on the bottom of the bottom part 132 to be supported by the floor 102 on which the drip wall 100 is installed.
The discharge hole 134 of the support member 130 is inclined downward from the edge of the bottom portion 132 to the side wall 131, PDF panel ditch wall structure for preventing shooters of water storage facilities . The method of claim 1,
Each side wall 131 of the support member 130 is formed to be inclined inwardly so that the distance between the side wall 131 is narrowed toward the top of the side wall 131, PDF for preventing water storage facility Panel ditch wall structure. delete delete delete The method of claim 1,
The bottom panel 132 of the support member 130, the anchor panel 142 for fixing to the bottom 102, the ditch wall 100 is installed, the PDF panel for preventing shooters of water storage facilities, characterized in that coupled Crush wall structure. The method of claim 1,
The support member 130 is coupled to both side wall 131 and the through-bolt 140 penetrating through the PDF panel 110 in the state in which the PDF panel 110 is coupled and the through bolt 140 in one side wall 131. PDF panel ditch wall structure for preventing shooters of water storage facility, characterized in that the nut 141 is coupled to the). The method of claim 1,
An upper coupling member 150 is coupled to an upper portion of the PDF panel 110, and the upper coupling member 150 is spaced apart from each other to form a pair of sidewalls 151 and upper portions of both sidewalls 151. It includes a top plate portion 152 for connecting the upper side of the top plate 152, the stepped portion 153 is formed to support the upper end of the PDF panel 110, respectively, on both edges of the top plate 152 A through hole 154 through which air is vented from the upper plate part 152 to the side wall 151 is formed. The method of claim 8,
The upper coupling member 150 is coupled to the through bolts passing through both side walls 151 and the PDF panel 110 in a state where the PDF panel 110 is coupled, and a nut is coupled to the through bolts at one side wall 151. PDF panel ditch wall structure for preventing shooters in water storage facilities, characterized in that the. The method of claim 8,
On the front and rear panels 111 and 112 of the PDF panel 110 to couple and fix the PDF panel 110 to the upper plate 103 formed on the column 101 to which the side of the PDF panel is coupled in the water storage facility. The upper plate coupling member 180 to be coupled is further provided,
The upper plate coupling member 180 has a lower panel coupled to each of the front and rear panels 111 and 112 and extended to the upper plate 103, and a side extension portion bent at right angles from the panel coupling portion 181. 182 is formed integrally,
The panel coupling part 181 of each upper panel coupling member 180, the side wall 151 of the upper coupling member 150, and the through bolt 185 penetrating through the PDF panel 110 are combined and one upper panel coupling member is coupled. PDF panel dwell wall structure for preventing shooters in water storage facilities, characterized in that the nut 186 is coupled to the end of the through-bolt 185 at 180. The method of claim 1,
The front and rear panels 111 and 112 of the PDF panel 110 are coupled to the horizontal reinforcement member 160 extending along the longitudinal direction of the PDF panel 110 horizontally, respectively, each of the horizontal reinforcement member 160 and PDF Through bolt 165 penetrating through the panel 110 is coupled and the nut 166 is coupled to the end of the through bolt 165 in the horizontal reinforcing member 160, PDF for preventing shooters in water storage facilities Panel ditch wall structure. The method of claim 1,
The side coupling members 170 extending vertically are coupled to the front and rear panels 111 and 112 of the PDF panel 110, respectively.
The side coupling member 170 is a panel coupling portion 171 in contact with the front, rear panels 111 and 112, and the column coupling portion 172 bent at a right angle from the panel coupling portion 171 to contact the concrete pillar 101. Is formed integrally,
The panel coupling portion 171 of the side coupling member 170 coupled to the front and rear panels 111 and 112 of the PDF panel 110 and the through bolt 173 penetrating through the PDF panel 110 are coupled to one side. The nut 174 is coupled to the end of the through-bolt 173 in the coupling member 170,
The column coupling portion 172 of the side coupling member 170 is a PDF panel ditch wall structure for preventing shooters in the water storage facility, characterized in that the anchor 175 for fixing to the pillar 101 is coupled. The method of claim 1,
The pillar 101 to which the PDF panel 110 is coupled is provided with a pillar fixing plate 190 for fixing the PDF panel 110 to the pillar 101.
The pillar fixing plate 190 is formed in a strip shape, the first panel coupling portion 191 and the first panel coupling portion 191 coupled to the PDF panel 110 coupled to the left side around the pillar 101. The second panel coupling portion which is bent to surround a portion of the pillar 101, and the second panel coupling portion 192 that is bent at the pillar coupling portion 192 and coupled to the PDF panel 110 coupled to the right side of the pillar 101 ( 193) is formed integrally,
The first panel coupling portion 191 and the PDF panel 110 of the two column fixing plates 190 coupled to the front and rear of the column 101 are coupled to each other by a through bolt 195,
Water storage, characterized in that the second panel coupling portion 192 and the PDF panel 110 of the two column fixing plates 190 coupled to the front and rear of the pillar 101 are coupled to each other by a through bolt 195. PDF panel ditch wall structure to prevent shooter of facility. The method of claim 1,
The right side of the column 101 to which the PDF panel 110 is coupled is provided with a column fixing plate 190 for fixing the PDF panel 110 to the column 101,
The pillar fixing plate 190 is formed in a band shape, the first panel coupling portion 191 and the first panel coupling portion 191 coupled to the PDF panel 110 coupled to the upper side about the pillar 101. A second panel coupling portion that is bent to surround a portion of the pillar 101 and the second panel coupling portion 192 that is bent at the pillar coupling portion 192 and coupled to the PDF panel 110 coupled to the lower side of the pillar 101 ( 193) is formed integrally,
The upper and lower sides of the left side of the pillar 101 to which the PDF panel 110 is coupled are provided with additional pillar fixing plates 190a for fixing the PDF panel 110 to the pillar 101, respectively.
The additional pillar fixing plate 190a is formed in a strip shape and is coupled to the first panel coupling portion 191a and the first panel coupling portion 191a coupled to the PDF panel 110 coupled to the upper or lower side of the pillar 101. The second panel is bent at the column coupling portion 192a surrounding the edge of the pillar 101 and the second panel is bent at the column coupling portion 192a and coupled to the PDF panel 110 coupled to the left side of the pillar 101. Coupling portion 193a is formed integrally,
The first panel coupling portion 191a of the additional pillar fixing plate 190a may include a PDF panel 110 coupled between one of the first and second panel coupling portions 191 and 192 of the pillar fixing plate 190. Are coupled together with through bolts 195,
The second panel coupling portion 193a of each additional pillar fixing plate 190a coupled to the upper and lower left sides of the pillar 101 is a through bolt 195 together with the PDF panel 110 coupled therebetween. PDF panel ditch wall structure for preventing shooters in water storage facilities, characterized in that coupled to each other.

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