KR20120136321A - A rainwater storage tank - Google Patents

Abstract

PURPOSE: A rainwater reservoir tank is provided to improve the durability of a water storage tank by increasing the connectivity between the upper slab and a wall, and minimize the leakage of the detained rainwater by enhancing the waterproof efficiency of the bottom slab. CONSTITUTION: A rainwater reservoir tank(100) comprises a bottom slab, multiple walls(120), multiple columns(130), multiple girders(140), and multiple upper slabs(150). The bottom slab includes a first floor reinforcement corresponding to the lower end of a wall, a second floor reinforcement corresponding to the lower end of a column. The bottom slab is formed on the top surface of the floor concrete layer with constant thickness. The wall includes a bent part and a top stopper. The bent part includes reinforcing steel connected to the first bottom surface reinforcing steel. Either the upper slab or one end of the girder is put on the top stopper. The wall is fixed on the top surface of the bottom concrete layer in order to form the outside wall part. The column includes vertical reinforcement connected to one end of the second bottom surface reinforcing steel, and fixed on the bottom slab. The girder includes a horizontal enforcement and shear reinforcement. The upper slab is arranged both on the top stopper and the upper end of the girder, thereby they are contiguous each other.

Description

Rainwater Storage Tank

The present invention relates to a storage tank for storing rain water, and more particularly, to increase the durability of the storage tank by increasing the bonding force between the wall and the upper slab, and to increase the waterproof efficiency of the floor slab to maximize the leakage of stored rain water to the outside. It relates to an excellent storage tank that can be prevented.

As buildings increase and the surface pavement rate increases, rainwater does not flood into the basement during heavy rains. As such, when rainwater flows in at one time and exceeds the inflow allowance, flooding may occur.

On the contrary, if less rainwater flows into the river, the water quality of the groundwater is deteriorated and the groundwater is also depleted. In order to prevent this, in recent years, rainwater is stored in an excellent storage tank and discharged into a river to control the flow rate of rainwater.

Republic of Korea Patent No. 10-0952605 (2010.4.6) is a precast floor slab having a slab reinforcement partially exposed to the upper side in a position corresponding to the position of the first support wall and the first pillar, and It is made of Precast Concrete (PC), has a rectangular shape and is fixed on the floor slab to become a part of the outer wall, and a central groove is formed in the inner central part so that the inner edge protrudes, and a first seating jaw is formed in the upper part. A plurality of first support walls having a reinforcement groove formed at a position corresponding to the slab reinforcement, and made of precast concrete (PC), which are fixed on the floor slab and formed by the first support walls A plurality of first pillars disposed spaced apart from each other and having reinforcement grooves formed at positions corresponding to the slab reinforcement, and made of precast concrete (PC), A plurality of connecting grooves formed on both ends of the first pillars and having horizontal reinforcing bars disposed in the longitudinal direction, and connecting grooves formed at both ends to expose the horizontal reinforcing bars to provide a space in which concrete is placed in the field. It is made of a first beam and Precast Concrete (PC), disposed adjacent to each other and disposed over the upper end of the first seating jaw and the first beams to form a first slab, a plurality of hollows in one direction therein The slab reinforcement discloses an excellent storage tank including a plurality of first slab members fixed to the reinforcement groove by non-contraction mortar.

However, such a conventional rainwater storage tank has a problem in that durability after construction is lowered because the member coupling force between the upper end of the support wall and the end of the slab member mounted thereon is weak.

Since the waterproofing of the floor slab on which the support wall is constructed is not perfect, there is a problem in that rainwater filled in the internal space of the storage tank flows out to the bottom.

(Patent Document 1) KR10-1056395 B1

The present invention is to solve the problems as described above, the purpose is to increase the coupling force between the wall and the upper slab can improve the durability of the storage tank, the rainwater is stored to the outside to increase the waterproof efficiency of the floor slab to the outside It is to provide an excellent storage tank that can prevent the most.

As a specific means for achieving the above object, the present invention, rainwater storage tank having a predetermined size of the interior space in which rain water is stored, including a floor slab, a plurality of walls, a plurality of pillars, a plurality of girders and a plurality of upper slabs. The floor slab is provided with a first floor reinforcement at a position corresponding to the lower end of the wall, and a second floor reinforcement at a position corresponding to the lower end of the column, the floor slab is provided with a predetermined thickness on the floor concrete layer. The plurality of walls may include a bent portion having a reinforcing bar connected to the first floor reinforcing bar at a lower end thereof, and an upper hooking jaw at which one end of the upper slab or the girder is mounted at an upper end thereof to form an outer wall part. It is fixed to the plurality of pillars are spaced apart inward from the wall to the second floor reinforcement It is fixed to the floor slab so that the lower end is connected, the plurality of girders are both ends of the engaging jaw formed in the wall and the upper end of the pillar, horizontal reinforcement is disposed in the longitudinal direction therein, the upper surface An outer exposed shear reinforcement, wherein the plurality of upper slabs are disposed to be adjacent to each other across the engaging jaw of the wall and the upper end of the girder, and an upper end of the vertical reinforcement provided in the plurality of walls is exposed. The upper recess of the upper slab is formed in the upper groove recessed with the concrete filled to form the upper concrete layer, wherein the vertical reinforcement in the upper groove is connected to the horizontal reinforcement embedded in the upper concrete layer Provides an excellent reservoir.

Preferably, the bottom concrete layer is a first and second bottom concrete layer provided with a predetermined thickness laminated on the upper surface of the flat rubble layer, and a wall embedded in the second floor concrete layer to support the lower end of the wall A waterproof protective wall interposed between a support beam and the first and second floor concrete layers, the waterproof sheet extending from an outer end thereof to cover the outer surface of the wall, and a waterproof protective wall extending from the first floor concrete layer to fix the waterproof sheet; It includes.

Preferably, the vertical reinforcement and the horizontal reinforcement is connected to the end of the right angle reinforcement inclined at a predetermined angle, the right angle reinforcement is connected to the bending deformation portion of the horizontal reinforcement bent to the vertical reinforcement side via the connecting reinforcement .

Preferably, the wall is provided with a plurality of U-shaped connecting bars in the recesses formed on both sides of the outer surface, the adjacent walls are arranged by vertically inserting the joint bar between the U-shaped connecting bars facing each other, and facing each other It includes a non-shrink mortar filled in the space formed between the grooves.

Preferably, the lower surface of the column facing the floor slab is inclined to a horizontal angle after the inclined outward from the contact surface in contact with the floor slab so as to form a space that can be filled with non-contraction mortar filled incision surface It is provided.

Preferably, a corner portion in which the non-shrink mortar is filled by the end of the plurality of girders spanning the top of the pillar, and the end portion of the girder adjacent to each other is in contact with the rectangular plate in contact with the outer surface of the end of the girder; It is provided with a reinforcing material consisting of a fixed plate fixed to the pillar.

Preferably, the upper slab is provided with a hollow body in the longitudinal direction inside the body.

Preferably, the upper slab is provided with a shear reinforcement is embedded in the upper concrete layer extending vertically to the upper surface of the upper slab so as to bind the horizontal reinforcement connected to the vertical reinforcement of the wall and the end is bent downward.

The present invention as described above has the following effects.

(1) By forming an upper groove in which the concrete of the upper concrete layer is filled at the upper end of the wall where one end of the slab is spread, and having the right reinforcing bar connected to the vertical reinforcement of the wall and the horizontal reinforcement of the upper concrete layer in the upper groove. In addition, since the bonding force between the wall and the upper slab and the bonding force between the wall and the upper concrete layer can be increased, the structural stability of the storm storage tank can be improved.

(2) By providing a waterproof sheet between the bottom concrete layer and the wall, it is possible to prevent the stored rainwater from leaking to the outside, thereby increasing the reliability of the excellent storage tank.

(3) At the upper end of the column where the ends of the plurality of girders span, the non-contraction mortar filled in the space is provided to the outside by providing a reinforcing material which forms the space where the non-contraction mortar is filled, and the corner portion where the ends of the adjacent girders contact each other. Since the fall of the girder can be prevented while preventing leakage, the safety of constructing the storm storage tank can be increased, and the construction period can be shortened.

1 is a plan view showing a storm storage tank according to a preferred embodiment of the present invention.
Figure 2 is a block diagram showing a storm reservoir according to a preferred embodiment of the present invention.
Figure 3 is a longitudinal sectional view showing the storm reservoir according to a preferred embodiment of the present invention.
Figure 4 is a perspective view showing a construction state of the wall provided in the storm storage tank according to a preferred embodiment of the present invention.
FIG. 5 is a partial detailed view of portion A of FIG. 3.
FIG. 6 is a partial detailed view of the portion B of FIG. 3.
FIG. 7 is a detailed view of part C of FIG. 1.
FIG. 8 is a detailed view of part D of FIG. 3.
FIG. 9 is a partial detailed view of portion E of FIG. 2.
FIG. 10 is a partial detailed view of part F of FIG. 3.
FIG. 11 is a partial detailed view of part G of FIG. 1.
12 is a plan view, a front view, and a sectional view of the upper slab provided in the storm storage tank according to the preferred embodiment of the present invention.

The objects, features and advantages of the present invention described above will become more apparent from the following detailed description. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Rainwater storage tank 100 according to a preferred embodiment of the present invention, as shown in Figures 1 to 4, the floor slab 110, a plurality of walls 120, a plurality of columns 130, Including a plurality of girders 140 and a plurality of upper slab 150 is provided with a predetermined size of internal space to store a predetermined amount of rainwater flowing from the outside is buried deeply below the ground.

The wall 120, the pillar 130, the girder 140, and the upper slab 150 constituting the rainwater storage tank 100 can be manufactured in a field concrete pouring method using formwork, respectively, precast concrete; The example produced by PC) is illustrated.

The bottom slab 110 includes a first bottom reinforcement 112 at a position corresponding to the lower end of the wall 120, and a second bottom reinforcement 114 at a position corresponding to the lower end of the column 130. Equipped with a predetermined thickness on the top surface of the bottom concrete layer 160.

As shown in FIGS. 3 and 5, the bottom concrete layer 160 includes first and second bottom concrete layers 161 and 162 stacked on the upper surface of the rubble layer 165 to have a predetermined thickness, and the wall ( Interposed between the wall support beam 163 and the first and second bottom concrete layers 161 and 162 embedded in the second bottom concrete layer 162 to support the lower end of the wall 120, and an outer end of the wall 120. The waterproof sheet 164 extending to cover the outer surface of the) and the waterproof protective wall 166 extending from the first bottom concrete layer 161 to fix the waterproof sheet.

That is, the first floor concrete layer is first cast in place on the upper surface of the rubble layer 165, cured and cured, and the waterproof sheet 164 is expanded to cover the entire upper surface of the wall ( The wall support beam 163 is disposed at a position corresponding to 120, and the second floor concrete layer 162 is secondly casted and cured as concrete to the height of the wall support beam.

Subsequently, the wall 120 is placed at a position corresponding to the wall support beam 163, and the outer end of the waterproof sheet extending outward from the first and second bottom concrete layers 161 and 162 to the wall 120 side. After folding and fixing, the waterproof sheet 166 is constructed as concrete so that the waterproof sheet is completely fixed to the outer surface of the wall.

Accordingly, it is possible to improve the waterproofness to prevent the rain water stored from the bottom concrete layer 160 is leaked to the outside by the waterproof sheet 164.

The wall 120 has a bent portion 121 having an end of the first bottom reinforcing bar 112 provided in the bottom slab 110 and a reinforcing bar 122 having one end connected through a sleeve at a lower end thereof. It is a vertical structure of a certain height to be provided.

The bottom slab 110 is provided at an upper end of the wall 120 to have an upper locking jaw 124 on which one end of the upper slab 150 or the girder 140 is mounted to be mounted. Before installation, the top surface of the bottom concrete layer 160 is fixedly installed adjacent to each other.

In addition, the upper end of the wall 120 provided on the wall 120 to expose the end of the vertical reinforcement 125, as shown in Figure 6, a predetermined thickness on the upper surface of the upper slab 150 The upper recess 126 filled with concrete to be poured to form the upper concrete layer 170 is recessed to a certain depth.

In the upper groove 126, the upper end of the vertical reinforcement 125 is embedded in the upper concrete layer 170, and assembled in the field to the shear reinforcement 125 exposed to the outside from the upper surface of the upper slab 150 It is connected to the horizontal reinforcement 175 is fixed.

At this time, the outer end of the horizontal reinforcement 175 is bent downward to be connected to the vertical reinforcement 125 and a binding member such as a wire.

In addition, the vertical reinforcement 125 and the horizontal reinforcement 175 is connected to the end of the right angle reinforcing bar 176 inclined at a predetermined angle, the right angle reinforcing bar 176 is connected to the vertical through the connecting bar 177 It is connected to the bending deformation portion of the horizontal reinforcement bar 177 is bent to the reinforcement 125 side.

Accordingly, the connection between the end of the upper concrete layer 170 of a predetermined thickness and the upper end of the wall 120 is cast on the upper surface of the upper slab 150 is the upper groove 126 is filled with concrete By the binding between the horizontal reinforcing bar 175 and the vertical reinforcing bar 125 and the right angle reinforcing bar 176 provided through the connecting reinforcing bar 177 will have a structural rigidity and coupling force.

On the other hand, as shown in Figure 4, the inner surface of the wall 120, recessed to form a central groove 123 to expand the storage efficiency and storage space of the excellent storage tank, PS strands 127 of a predetermined length The upper and lower insertion holes 127a, which are inserted in the transverse direction, pass through the upper and lower portions, respectively, and the upper and lower insertion holes 127a are recessed on both outer sides of the wall 120 through which the upper and lower insertion holes 127a are formed. U-shaped connecting bars 128a and 128b protrude outwards and are integrally provided in the recess 128.

Accordingly, the wall 120 which is fixedly installed perpendicular to the upper surface of the bottom concrete layer 160 and disposed adjacent to each other is disposed in the upper and lower insertion holes 127a as illustrated in FIGS. 4 and 7. The PS strand 127 passing through the anchor 127b is pulled outward to have a pretension with the tensioner 127b, and is fixed as the anchorage 127c, and the anchorage 127c is recessed on both sides of the wall 127d. ) Is placed.

At the same time, the walls 120 adjacent to each other are connected by inserting a vertical joint bar 128c between the U-shaped connecting bars 128a that face each other and intersect with each other, and a groove provided with the U-shaped connecting bars 128a is provided. By filling the non-shrink mortar (128d) in the space formed to face each other integrally connected the walls adjacent to each other at the same time to prevent the stored rainwater to flow out of the storage tank or the water from the outside of the storage tank. .

At this time, it is preferable to provide watertightness by providing an index material and a caulking material on the vertical joint surfaces between the adjacent walls 120.

Here, the floor slab 110 is installed by placing the floor concrete layer 160 in the field, and fixed the wall 120 to the upper surface of the bottom concrete layer 160 to form an outer wall portion, the site It is to be constructed by curing the concrete poured in.

The pillar 130 is spaced inward from the outer wall portion formed by the wall 120 and is provided at the bottom slab 110 to mediate one end and the sleeve of the second bottom reinforcement 114 exposed upward. It is a vertical structure that is vertically fixed to the upper surface of the bottom slab 110 having a vertical reinforcement 132 connected to the lower end of the furnace.

As shown in FIGS. 8 and 9, the second bottom reinforcement 114 exposed upward from the bottom slab 110 is connected to the lower end of the vertical reinforcement 132 at the lower end of the pillar 130. The upper end of the coupling groove 134 is formed, and the upper end portion of the vertical reinforcement 132 is exposed at the upper end of the pillar 130 on which the end of the girder 140 is raised.

Here, the bottom surface of the pillar 130 facing the floor slab 110 is inclined at a predetermined angle from the contact surface in contact with the bottom slab 110 to form a space that can be filled with non-contraction mortar. It is preferable to have a cutting surface 136 extending horizontally after the photograph.

In FIG. 8, reference numeral 117 denotes a fixing plate for fixing the second bottom reinforcing bar 114 of the bottom slab 110, and 118 is a reinforcing bar frame for fixing the reinforcing bar reinforced to the bottom slab 110.

2 and 9 and 10, the girder 140, both ends of the engaging jaw 124 formed on the upper end of the wall 120 and the upper end of the pillar 130, respectively, It is a horizontal member of a predetermined length on which the upper slab 150 is raised.

Inside and outside the girder 140, the horizontal reinforcement 142 is disposed in which the left and right ends are exposed to both sides of the girder, and both ends of the horizontal reinforcement 142 are bent at right angles.

Here, the locking jaw 124 of the wall 120 over which the end of the girder 140 spans is positioned at a position relatively lower than the formation position of the locking jaw of the wall 120 over which the end of the upper slab 150 spans. It is preferred to be provided.

The inside of the girder 140 is provided with a shear reinforcement 143 is vertically exposed to the upper surface and then the end is bent downward, the bent top of the shear reinforcement 143 is in the upper concrete layer 170 It is connected to the buried rebar 144 is fixed.

In addition, as shown in FIG. 11, a space where the non-contraction mortar 147 is filled is formed at an upper end of the pillar 130 through which the ends of the plurality of girders extend, and the edges of the girders adjacent to each other are in contact with each other. In the part, a right angle plate 145a in contact with the outer surface of the ends of the girders 140 adjacent to each other so as to prevent the leakage of the non-shrink mortar filled in the space and to prevent the fall of the girder, and the upper surface of the pillar It is preferable to have a reinforcing material 145 made of a fixing plate 134b fixed as a fastening member.

The outer surface of the girder to which the shear reinforcement 143 is exposed is provided with an anchor connection groove 148 to which the anchor provided at the end of the wire is connected when moving the girder using a crane.

The upper slab 150 is disposed so as to be adjacent to each other across the upper end of the engaging jaw 124 and the girder 140 formed on the upper inner surface of the wall 120 to cover and seal the open top of the rainwater reservoir. It is a slab part to form.

The upper slab 150 has a hollow body 151 made of an elastic body such as EPS (Expandable Polystrene) so as to reduce the weight of the weight inside the body as shown in FIG.

The upper slab 150 is vertically extended to the upper surface of the upper slab 150 to bury the horizontal reinforcement 175 embedded in the upper concrete layer 170 and connected to the vertical reinforcement 125 of the wall. It has a shear reinforcement 155, the end of which is bent downward.

Here, the ends of the shear reinforcement 155 facing each other are preferably bent in a direction corresponding to each other.

In addition, the upper concrete layer 170 is a coating layer covering the upper slab by filling concrete on the upper surface of the slab portion formed by the upper slab 150 disposed adjacent to each other, and filled in the upper groove.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

110: floor slab 112,114: first and second floor reinforcement
120: wall 121: bent portion
124: engaging jaw 125: vertical reinforcement
126: upper groove 127: PS stranded wire
130: pillar 132: vertical reinforcement
134: coupling groove 136: incision surface
140: girder 142: horizontal reinforcement
145: reinforcement 150: upper slab
160: bottom concrete layer 170: upper concrete layer

Claims (8)

In the storm storage tank having a predetermined internal space in which rain water is stored, including a floor slab, a plurality of walls, a plurality of pillars, a plurality of girders and a plurality of upper slabs,
The floor slab is provided with a first floor reinforcement at a position corresponding to the lower end of the wall, a second floor reinforcement at a position corresponding to the lower end of the column is provided with a predetermined thickness on the floor concrete layer,
The plurality of walls may include a bent portion having a reinforcing bar connected to the first floor reinforcing bar at a lower end thereof, and an upper hooking jaw at which one end of the upper slab or the girder is mounted at an upper end thereof to form an outer wall part. Fixed on the floor,
The plurality of pillars are spaced inward from the wall and fixed to the floor slab so that the second floor reinforcement and the lower end are connected.
The plurality of girders are provided with a shear reinforcing bar is formed on the wall and both ends across the upper end of the pillar, the horizontal reinforcement is disposed in the longitudinal direction, the outer surface is exposed on the upper surface,
The plurality of upper slabs are disposed to be adjacent to each other across the upper end of the engaging jaw and the girder of the wall,
The upper end where the end of the vertical reinforcement provided in the plurality of walls is exposed to recess the upper groove filled with the concrete to be poured to form the upper concrete layer on the upper surface of the upper slab, the vertical reinforcement in the upper groove Excellent storage tank, characterized in that connected to the horizontal reinforcement embedded in the upper concrete layer. The method of claim 1,
The bottom concrete layer may include first and second bottom concrete layers stacked on the upper surface of the flat rubble layer at a predetermined thickness, and a wall support beam embedded in the second bottom concrete layer to support the lower end of the wall. A waterproof sheet interposed between the first and second floor concrete layers, an outer end extending to cover an outer surface of the wall, and a waterproof protective wall extending from the first floor concrete layer to fix the waterproof sheet; Excellent storage tank, characterized in that. The method of claim 1,
The vertical reinforcement and the horizontal reinforcement is connected to the end of the right angle reinforcement inclined at a predetermined angle, the right angle reinforcement is connected to the bent deformation portion of the horizontal reinforcement bent to the vertical reinforcement side via the connecting reinforcement Excellent reservoir. The method of claim 1,
The wall is provided with a plurality of U-shaped connecting bars in the recesses formed on both sides of the outer surface, the adjacent walls are arranged by vertically inserting the joint bar between the U-shaped connecting bars facing each other, and between the grooves facing each other Storm water storage tank comprising a non-shrink mortar filled in the space to be formed. The method of claim 1,
The lower surface of the column facing the floor slab is provided with an incision surface extending horizontally after inclined outward at an angle from the contact surface in contact with the floor slab so as to form a space that can be filled by filling the non-shrink mortar Excellent storage tank, characterized in that. The method of claim 1,
A corner plate which forms a space where the non-shrink mortar is filled by the end of the plurality of girders spanning the upper end of the pillar, and the end portion of the girder adjacent to each other is in contact with the right angle plate in contact with the outer surface of the end of the girder, and the pillar Excellent storage tank comprising a reinforcing material consisting of a fixed plate fixed to the. The method of claim 1,
The upper slab is excellent storage tank, characterized in that provided with a hollow body in the longitudinal direction inside the body. The method of claim 1,
The upper slab is embedded in the upper concrete layer is characterized in that it comprises a shear reinforcement extending vertically to the upper surface of the upper slab so as to bind the horizontal reinforcement connected to the vertical reinforcement of the wall and the end is bent downward Excellent reservoir.

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