KR101204036B1 - The water-storage tank of assembly type - Google Patents

Abstract

PURPOSE: A rainwater storage tank with prefabricated members is provided to maximize efficiency by assembling blocks according to the capacity of the storage tank and to easily manage the inside of the storage tank by maximizing the interval between columns. CONSTITUTION: A rainwater storage tank with prefabricated members comprises a lower slab group(100), a side wall group(200), columns(300), girders(400), and upper slabs(500). The lower slab group comprises multiple lower slabs. The lower slabs are assembled to form a lower slab assembly depending on the capacity of the storage tank. The side wall group comprises multiple side walls and is assembled in the edge of the lower slab assembly. The columns are vertically assembled in the lower slab assembly. The girders connect the tops of the columns to each other and the side walls and the columns to each other. The upper slabs are assembled on the tops of the girders.

Description

The water-storage tank of assembly type

The present invention relates to a rainwater storage tank, and more particularly, to a member-assembly type PC rainwater storage tank, which is easy to install and easy to transport, since each member constituting the storage tank is configured as a member assembly type.

In recent years, with the increase of buildings and the increase of the packing rate of the surface, the tendency of the rainwater to flow directly into the sewer or the river without infiltration into the underground is increasing. In addition, flooding may occur if the flow rate to the sewer or river exceeds the allowable amount due to the amount of precipitation. On the other hand, if the amount of water penetrated into the ground is small, the underground water becomes insufficient. This causes problems such as the drought, and the water quality of the river is reduced due to the dry season.

Thus, in recent years, rainwater storage tanks, etc., capable of storing rainwater and allowing it to flow out into rivers have been installed.

The rainwater storage tank as described above has a method of constructing by pouring concrete in the field and a method of assembling pre-fabricated concrete storage blocks in the field. However, the method of constructing the concrete by installing the concrete on the site increases the construction time, increases the construction cost, and increases the probability of occurrence of the safety accident. Therefore, the use of the method of assembling and constructing in the field using the manufactured PC concrete block is increased have.

1 is a view showing one embodiment of a rainwater storage tank using a conventional PC concrete block. Rainwater storage tank 50 of Figure 1 is buried underground, the storage block 10 shown in Figure 2 is made of a combination.

The storage block 10 shown in FIG. 2 is provided with pillars 16 at each corner of the upper slab 12 and the lower slab 14 in a rectangular shape, Holes are formed in the upper and lower portions of the columns 16 and a plurality of through holes formed in the inner side are formed on the upper and lower sides of the pillars 16. On the other hand, Are formed on the outer surface.

Therefore, the storage blocks 10 are coupled to and fixed to each other through bolts (not shown) formed in the upper and lower portions of each column 16 to form a rainwater storage tank 50, provided on the outer circumference of the rainwater storage tank The storage block 10 has two pillars 16 and one side wall formed between the upper slab 12 and the lower slab 14, as shown in the storage block 10 shown in FIG. Using to configure the outer surface of the rainwater storage tank (50).

However, the conventional rainwater storage tank as described above is difficult to assemble if the storage block is not high by assembling the storage block continuously to build the rainwater storage tank, and the column 16 formed in the storage block 10 is the rainwater storage tank 50. There is a problem of reducing the effective storage space by overlapping the inside of the.

Meanwhile, in order to solve this problem, a member-assembled rainwater storage tank has been developed as in Patent No. 10-0988806 as shown in FIG. 3.

Such a member assembly type rainwater storage tank is composed of a member such as an upper slab 61, a side wall 62, a lower slab 63, a pillar 64, a closed block plate 65, and the like.

Then, each member is assembled by connecting it with a bolt, a PC steel wire, and an anchor steel bar.

However, the rainwater storage tank according to the prior art also has a block size is determined by the width of the trailer loading width of 2.3m, because a large number of pillars are installed inside the storage capacity is reduced, the distance between the pillars inside the storage tank is close to cleaning and There was a problem that it is difficult to operate equipment such as excavators, trucks that should be put into management.

In addition, since the side wall and the bottom slab are integrally manufactured, it is difficult to manufacture a large-sized member, and the spacing of the pillars at the four sides of the outer periphery is reduced to half compared with the spacing of the pillars at the center of the storage tank.

In addition, all the members are made of PC steel wire connection and anchor steel wire connection, so that it is difficult to maintain the watertightness at the connection part between the member and the member.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems and drawbacks of the prior art, and an object of the present invention is as follows.

First, an object of the present invention is to provide a member-assembled PC rainwater storage tank that can be assembled to fit the storage tank having various capacities to be used.

Second, the present invention is to provide a member assembled PC rainwater storage tank that can maximize the storage capacity by minimizing the number of pillars therein.

Third, the object of the present invention is to provide a member-assembled PC rainwater storage tank that can enable the operation of the equipment for cleaning and management of the interior by maximizing the installed pillar spacing.

Fourth, an object of the present invention is to provide a member-assembled PC rainwater storage tank that can be applied, improved by minimizing the change of the member when building the storage tank having a different installation height.

Fifth, an object of the present invention is to provide a member-assembled PC rainwater storage tank which can be assembled smoothly even if the level of the base portion is reduced or the precision of product manufacturing is poor.

Sixth, an object of the present invention is to provide a member-assembled PC rainwater storage tank that can be flexibly responded to changes in the load of the load applied to the upper portion of the rainwater storage tank.

Seventh, an object of the present invention is to provide a member-assembled PC rainwater storage tank to minimize the production volume of the member to facilitate the production, storage, transportation, assembly of the member.

In order to achieve the above object, the present invention includes a plurality of lower slabs, the lower slab group of the selected lower slab among the plurality of lower slabs is assembled according to the low capacity, and comprises a lower slab assembly and a plurality of sidewalls are included. And a side wall group assembled to a periphery of the lower slab assembly, a pillar assembled vertically upwardly to the lower slab assembly, and an upper side of the girder and the upper girder assembled to connect the side wall and the pillar or the pillar and the upper pillar. And an upper slab group assembled to the lower slab group, and the lower slab group forms a quadrangular shape, and forms a quadrangular shape with a first edge lower slab that forms one corner portion of one side and a corner portion thereof diagonally in the lower slab assembly. The other edge of one side of the lower slab assembly and the edge thereof diagonally And a second edge lower slab, and a first edge lower slab and a second edge lower slab positioned between the first edge lower slab and the second edge lower slab in the lower slab assembly. The side wall has a rectangular shape and at the same time is provided with a fixing groove on one side and at the same time provides a member-assembled PC rainwater storage tank characterized in that the fixing hole is in communication with the fixing groove.
Here, the first edge lower slab may be provided with a sidewall on an upper side of an outer circumference of the first edge lower slab on the basis of the lower slab assembly, and a step may be provided to support an inner lower portion of the installed sidewall. have.
In addition, the first edge lower slab may be provided with a water ring installation groove for the water ring installation to form a watertight maintenance with the side wall.
In addition, the first edge lower slab may be provided with an anchor reinforcing bar to be assembled with the side wall to the outside of the step, the side wall may be provided with an anchor reinforcing groove corresponding to the anchor bar.
In addition, the lower slab forms a rectangular plate-shaped block, and the fixing groove is provided on the upper side of the lower slab so as to be assembled with the adjacent lower slab, and the fixing hole communicating with the fixing groove may be provided on the side of the lower slab. have.
In addition, the second edge lower slab may be provided with a sidewall on an upper side of an outer circumference of the second edge lower slab on the basis of the lower slab assembly, and a step may be provided to support an inner lower portion of the installed sidewall. have.
In addition, the second edge lower slab may be provided with a water ring installation groove for the water ring installation to form a watertight maintenance with the side wall.
In addition, the second edge lower slab may be provided with an anchor reinforcing bar to be assembled with the side wall to the outside of the step, the side wall may be provided with an anchor reinforcing groove corresponding to the anchor bar.
The first circumferential lower slab may have a sidewall installed at an upper side of an outer circumference based on the lower slab assembly, and a step may be provided to support an inner lower portion of the installed sidewall.
In addition, the first slab lower slab is provided with an anchor reinforcing bar to be assembled with the side wall to the outside of the step, the side wall may be provided with an anchor reinforcing groove corresponding to the anchor bar.
In addition, the first slab lower slab may be provided with a unit pillar installation unit for assembling the pillar to one side of the opposite side of the one side formed with the stepped.
In addition, the unit pillar mounting portion may be provided with anchor reinforcement is inserted into the lower portion of the column.
The first slab lower slab may be provided with an index ring installation groove for installing the index ring to achieve watertightness with the side wall.
In addition, the second periphery lower slab may be provided with the side wall on the upper side of the outer circumference relative to the lower slab assembly, and a stepped portion may be provided to support the inner lower side of the installed side wall.
The second circumferential lower slab may be provided with anchor bars for assembling with the side walls to the outside of the step, and the side walls may be provided with anchor reinforcing grooves corresponding to the anchor bars.
In addition, the second slab lower slab may be provided with a unit pillar mounting portion for assembling the pillar to one side of the opposite side of the one side formed with the stepped.
In addition, the unit pillar installation unit may be provided with anchor reinforcement is inserted into the lower portion of the column.
In addition, the second periphery lower slab may be provided with a water ring installation groove for the water ring installation to form a watertight maintenance with the side wall.
The lower slab group may include a central lower slab formed in a quadrangular shape and surrounded by the first slab slab and the second slab slab in the lower slab assembly.
In addition, the central lower slab may be provided with a unit pillar installation unit to which the pillar is assembled.
And, the side wall may be provided with a stepped end is installed one end of the girder.
In addition, the stepped jaw is provided with anchor reinforcement, the girder may be provided with anchor reinforcing bar installed to cross each other on the anchor reinforcement of the step.
In addition, the unit pillar mounting portions may be provided with concave grooves inward, respectively, and a lower portion of the pillar may be provided with a protrusion installed in the concave groove.
In addition, anchor reinforcement inserted into the inside of the pillar may be provided in the concave groove.
The girder may include an insertion groove formed in a state in which both sides of the girder are closed in the longitudinal direction, and anchor bars may be provided in the insertion groove.
In addition, the girders may be further provided with auxiliary anchor reinforcing bar in the direction perpendicular to the longitudinal direction of the girder at both ends.

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Referring to the effect of the present invention, the member-assembled PC rainwater storage tank configured as described above are as follows.

First, according to the present invention, by providing 12 types of the member to be used to build the construction of the block suitable for any storage tank size of any size, the effect can be maximized cost and efficiency.

Second, according to the present invention, it is possible to maximize the low capacity by minimizing the number of pillars in the storage tank.

Thirdly, according to the present invention, the number of pillars can be minimized and the interval between the pillars can be maximized, thereby cleaning and managing the inside of the storage tank and facilitating the operation of the equipment.

Fourth, according to the present invention, it is possible to minimize the change of the member, such as the formation of the storage tank by changing only the sidewall and column height in the case of constructing the storage tank with different installation heights.

Fifth, according to the present invention, assembly can be smoothly performed even if the horizontality of the base portion is lowered or the accuracy of product production is reduced.

Sixth, according to the present invention, after assembling a plurality of members, the waterproofing can be maintained at the same time as auxiliary reinforcement effect by separately injecting mortar.

Seventh, according to the present invention, it is possible to easily cope with the change of the floor load applied to the upper portion of the rainwater storage tank by the selection of various slab members and the concrete reinforcement part pouring.

Eighth, according to the present invention, the production volume of the member is minimized, thereby facilitating the production, storage, transport, and assembly of the member.

1 is a perspective view showing one form of a rainwater storage tank according to the prior art;
2 is a perspective view showing a storage block forming the rainwater storage tank of FIG.
Figure 3 is a perspective view showing a member assembly rainwater storage tank according to the prior art;
Figure 4 is a perspective view showing the combined state of each of the components constituting the assembled PC rainwater storage tank according to the present invention;
Figure 5 is a perspective view showing a lower slab group 100 that constitutes the present invention the assembled PC rainwater storage tank;
Figure 6 is a perspective view of the lower slab for the first corner;
Figure 7 is a perspective view of the lower slab for the second corner;
8 is a perspective view showing a first slab lower slab;
9 is a perspective view showing a second periphery lower slab;
10 is a perspective view of the central lower slab;
11 is a view for explaining the coupling structure between the lower slab using a curved bolt in the fixing hole and the fixing groove;
12 is a view for explaining the coupling structure between the lower slab using a PC steel wire in the fixing hole and the fixing groove;
13 is an enlarged view for explaining a fixing fixing mechanism;
14 is a plan view showing side walls with stepped portions;
15 is a side view of the side wall;
16 is a top plan view of the side;
17 is a side view showing a side wall without girders;
18 is a side view of a column;
19 is a bottom plan view of the column;
20 is a top plan view of the column;
21 is a plan view of the girder;
22 is a side view of the girder;
23 is a side view showing one form of an upper slab;
24 is a plan view showing one side of the closed block;
25 is a side view of the closed block;
26 is a plan view showing the other side of the closed block;
Figure 27 is an exploded side view showing the assembly process of the present invention the assembled PC rainwater storage tank in the form of girder-mounted side walls are installed on both sides;
Figure 28 is a side view showing the appearance of the girder according to the other form at the same time the auxiliary reinforcing portion is constructed above the upper slab in the member assembled PC rainwater storage tank of the present invention; And
29 is a perspective view showing another form of the closed block.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

First, with reference to the accompanying drawings will be described the configuration of the member-assembled PC rainwater storage tank according to the present invention.

Figure 4 is a perspective view showing the combination of each of the components constituting the assembled PC rainwater storage tank according to the present invention.

PC assembly rainwater storage tank according to the present invention includes a lower slab group 100, side wall group 200, pillar 300, girder 400 and the upper slab (500).

Figure 5 is a perspective view showing a lower slab group constituting the present invention the assembled PC rainwater storage tank. As shown, the lower slab group 100 includes a plurality of lower slabs 110, 120, 130, 140, and 150, and selected lower slabs 110, 120, 130, 140, and 150 are assembled according to a low capacity to form a lower slab assembly 101.

Here, the lower slab group 100 constituting the lower slab assembly 101 according to the present invention is the first edge lower slab 110, the second edge lower slab 120, the first peripheral portion lower slab 130 ), The second peripheral portion lower slab 140 and the central lower slab 150 is configured.

  Each of the lower slabs 110, 120, 130, 140, and 150 may have a quadrangular shape. Accordingly, the lower slab assembly 101 formed by assembling the lower slabs 110, 120, 130, 140, and 150 may also have a quadrangular shape.

Next, each lower slab constituting the lower slab group will be described with reference to the accompanying drawings.

First, Figure 6 is a perspective view showing a lower slab 110 for the first corner.

The first edge lower slab 110 is formed in the lower slab assembly 101 in which a plurality of lower slabs are assembled to form one corner portion of one side and a corner portion diagonally thereto. Referring to FIG. 5, the upper left corner of the X-axis and a corner thereof diagonally formed are formed.

Referring back to FIG. 6, the first edge lower slab 110 includes a block portion 112 having a rectangular plate shape, and the block portion 112 is positioned outside the lower slab assembly 101. Sidewalls (to be described later) are assembled along the longitudinal direction of two adjacent sides.

At this time, the first edge lower slab 110 is provided with a stepped 114 so that the inner side of the assembled sidewall is supported. The stepped 114 has a "b" shape bent along the longitudinal direction of two adjacent sides of the block portion 112.

In addition, the first edge lower slab 110 is provided with an index ring 77 (see Fig. 11) to form a watertight maintenance after the side wall is assembled. At this time, the water ring installation groove 116 is provided in the first edge slab 110 so that the water ring is installed.

Since the side wall is installed along the longitudinal direction of the two sides in the first edge lower slab 110, the water ring installation groove 116 also along the longitudinal direction of the two sides of the first edge lower slab 110. Is formed. As shown, it will be preferable to have two or more installed to maximize the watertight retention effect.

In addition, the first edge lower slab 110 is provided with an anchor reinforcement 80 to the position where the outer side wall of the step 114 is installed. The anchor reinforcement 80 is configured to be inserted into the lower portion of the side wall. An illustration and a detailed description thereof will be provided later.

In addition, the first edge lower slab 110 is provided with a fixing groove 118 to be assembled with the lower slab adjacent to the upper side. The fixing groove 118 is formed such that a PC steel wire is fixed or a bolt is fixed, and a nut or a PC wire fixing device is accommodated in the inside. In addition, a fixing hole 119 is provided at a side of the first edge lower slab 110 in a structure in communication with the fixing groove 118.

In addition, the first edge slab 110 is provided with an index ring installation groove 116 on the side of the block portion 112 to maintain watertightness with the lower slab is adjacently assembled. As shown, the water ring installation groove for the watertight maintenance with the side wall and the water ring installation groove of the adjacent lower slab is formed in a connected form, the installation is applied in the form of one water ring connected to the watertight maintenance and work Will be advantageous.

Figure 7 is a perspective view showing a second edge slab in the member assembly PC rainwater storage tank of the present invention.

The second edge lower slab 120 forms an edge portion opposite to the other edge portion of one side of the lower slab assembly 101.

In addition, the second edge lower slab 120 includes a block portion 122 having a rectangular plate shape, and is disposed at two adjacent sides positioned outside the block portion 122 in the lower slab assembly 101. Stepped 124 is provided with side walls.

In addition, similar to the first edge slab 110, the second edge slab 120 is also provided with a water ring installation groove 126 for the water ring installation to form a watertight maintenance with the side wall, the step 124 Anchor reinforcement 80 for assembling with the side wall to the outside of the) is provided.

In addition, the second edge lower slab 120 is provided with a fixing groove 128 to be assembled with the adjacent lower slab. The fixing groove 128 is configured to allow the PC steel wire to be fixed, or the bolt is fixed to the inner side is formed to accommodate the nut or PC steel wire fixing part. Further, the fixing hole 129 is formed in a structure communicating with the fixing groove 128.

In addition, there is provided a water ring installation groove 126 for watertight maintenance when assembling with the adjacent lower slab.

8 is a perspective view illustrating the first slab lower slab.

As shown in Figure 5 and Figure 8, the member assembly PC rainwater storage tank of the present invention is the outer edge portion of the lower slab assembly 101, the first edge for the lower slab 110 and the second edge for A first slab lower slab 130 positioned between the lower slabs 120 is included.

The first circumferential lower slab 130 includes a plate-shaped block portion 132, and the block portion 132 has the side wall perpendicular to an upper portion of the circumference portion forming an outer side with respect to the lower slab assembly 101. It is installed upward, and the stepped portion 134 is provided to support the inner lower portion of the installed side wall. In addition, the first slab lower slab 130 is provided with an anchor reinforcement 80 to be assembled with the side wall to the outside of the step 134.

On the other hand, the first circumferential lower slab 130 is provided with a unit pillar mounting portion 137 to which the pillar is assembled to one side of the opposite side on which the step 134 is formed. Here, the unit pillar mounting portion 137 is provided with a recessed groove 135 inward.

In addition, the unit pillar mounting portion 137 and the concave groove 135 is provided with an anchor reinforcement 90 to be inserted into the lower end of the column.

In addition, the first periphery lower slab 130 is provided with a water ring installation groove 136 for the water ring installation to form a watertight maintenance after assembled with the side wall, the block for assembly with the adjacent lower slab to be assembled A water ring installation groove 136 is provided along the circumference of the portion 132. Preferably, the water ring installation groove for watertight maintenance with the side wall and the water ring installation groove for watertight maintenance with the adjacent lower slab are integrally formed.

In addition, the first peripheral lower slab 130 is also provided with a fixing hole 139 in communication with the fixing groove 138 and the fixing groove 138 to be assembled with the adjacent lower slab.

Next, FIG. 9 is a perspective view showing a second slab lower slab.

As shown in Figure 5 and 9, the member assembly type PC rainwater storage tank of the present invention is the outer edge of the lower slab assembly 101, the first edge for the lower slab 110 and the second edge for A second slab lower slab 140 is disposed between the lower slabs 120.

The second peripheral portion lower slab 140 has a plate-shaped block portion 142, the block portion 142 is provided with the side wall on the outer peripheral portion relative to the lower slab assembly 101, The step 144 is provided to support the inner lower portion of the installed side wall.

In addition, the second slab lower slab 140 is provided with an anchor reinforcing bar 80 to be assembled with the side wall to the outside of the step 144.

On the other hand, the second periphery lower slab 140 is provided with a unit pillar mounting portion 147 having a concave groove 145 is assembled to the other side of the opposite side formed with the stepped 144.

Here, the concave groove 145 and the unit pillar installation portion 147 is provided with an anchor reinforcement 90 to be inserted into the lower end of the column. In addition, the second periphery lower slab 140 is provided with a water ring installation groove 146 for the water ring installation to form a watertight maintenance with the side wall and the adjacent lower slab assembled.

In addition, the second peripheral lower slab 140 is also provided with a fixing hole 149 in communication with the fixing groove 148 and the fixing groove 148 to be assembled with the adjacent lower slab.

10 is a perspective view of the central lower slab.

5 and 10, the lower slab group 100 according to the present invention has a quadrangular shape and the first slab slab 130 and the second slab slab in the lower slab assembly 101. A central lower slab 150 that is surrounded and assembled to 140 is included.

The central lower slab 150 forms a plate-shaped block portion 152, and a unit pillar mounting portion 157 having a concave groove 155 in which the pillar is assembled at both corners of one side of the block portion 152. Is provided.

The concave groove 155 and the unit pillar installation portion 157 is provided with an anchor reinforcement 90 to be inserted into the lower end of the column,

In addition, the center lower slab 150 is provided with a fixing hole 159 in communication with the fixing groove 158 and the fixing groove 158 to be assembled with the adjacent lower slab.

In addition, the central lower slab 150 is provided with an index ring fixing groove 156 for watertight maintenance when assembling with the adjacent slab.

As described above, the first periphery lower slab 130, the second periphery lower slab 140, and the central lower slab 150 are all provided with unit pillar mounting portions 137, 147, and 157. At this time, as shown in Figure 5, the unit pillar mounting portion (137, 147, 157), the first peripheral portion lower slab 130, the second peripheral portion lower slab 140, four center lower slab 150 is assembled Pole is configured to form a pillar mounting portion is installed under one column.

In addition, the concave grooves 135, 145, and 155 provided in the slabs are also configured to form one groove by forming the unit pillar mounting parts 137, 147 and 157 connected to each other at the inner central part when one pillar mounting part is assembled.

On the other hand, the configuration of the fixing groove and the fixing hole in each of the above-described slab as described in more detail taking as an example the assembly process of the lower slab as follows. On the other hand, the fixing groove and the fixing hole described below is also applied to the configuration provided with other fixing grooves and fixing holes other than the first edge lower slab and the second circumferential lower slab.

FIG. 11 is a cross-sectional view showing a portion where the first edge lower slab 110 and the second peripheral portion lower slab 140 are assembled.

As shown, when assembling the first edge lower slab 110 and the second circumferential lower slab 140, the fixing holes 119 and 149 of the respective slabs 110 and 140 are installed to form corresponding positions. That is, in the present invention, the fixing holes are formed at positions corresponding to each other between components assembled to each other.

After matching the positions of the fixing holes 119 and 149 as described above, curved bolts 751 are installed to pass through the fixing holes 119 and 149 of the lower slabs 110 and 140 at the same time. At this time, the curved bolt (751) is formed on both sides of the screw thread, the thread formed portion is to form a state protruding in the fixing grooves (118, 148) provided in the slabs (110, 140).

Both lower slabs 110 and 140 are assembled by fastening the nuts 752 to both ends of the protruding curved bolt 751.

12 is a view for explaining the coupling structure between the lower slab using a PC steel wire in the fixing hole and the fixing groove, Figure 13 is an enlarged view for explaining the fixing fixing mechanism.

That is, the fixing between the lower slab may be made of a PC steel wire 856 and a PC steel wire fixing mechanism 857, as shown in Figs.

The PC steel wire 856 may be made of a wire rope or the like, and can be bent relatively freely so that the fixing holes 119 and 149 may be inserted regardless of whether the fixing holes 119 and 149 are bent, bent or oblique.

The PC wire fixing device 857 may be formed of a socket 858 and a support tab 859, as shown in FIG. 13.

The socket 858 is fastened and fastened to both ends of the PC steel wire 856, respectively, and a fixing hole into which the PC steel wire 856 is inserted is formed on an inner circumferential surface thereof, and the outer circumferential surface of the socket 858 is connected to an end of the PC steel wire 856. It may be tapered so that the diameter is wider toward the facing. Further, the inner circumferential surface of the fixing hole of the socket 858 may be provided with concavities and convexities to increase the fixing force with the PC steel wire 856.

The support tabs 859 are supported on inner surfaces of the fixing holes 118 and 148 of the upper slabs 110 and 140, respectively. At this time, the support tab 589 is provided with an inner hollow, and the hollow is formed so as to be wider toward the end of the PC steel wire 856 so as to correspond to the outer circumferential surface of the socket 858.

The minimum diameter of the inner peripheral surface of the support tab 859 may be smaller than the minimum diameter of the socket 858. In addition, the socket 858 may be formed to be divided into two or more pieces so as to be parallel to the axial direction of the fixing hole for the convenience of mounting.

Accordingly, as shown in FIG. 13, the socket 858 and the support tab 859 are coupled to both ends of the PC steel wire 856 inserted into the fixing holes 119 and 149, and the support tab 859 is connected to the respective ends. When the PC steel wire 856 is tensioned by using a tensioner (not shown) on the surface of the fixing holes 118 and 148 of the lower slabs 110 and 140, the socket 858 may be caused by the tension of the PC steel wire 856. The outer circumferential surface of the socket 858 may be compressed by the tapered hollow of the support tab 859 while being pulled toward the support tab 859, thereby increasing the coupling force between the socket and the PC steel wire 856.

In addition, the method of assembling the lower slabs 110 and 140 described above may be made in a straight line in addition to the curved shape of the curved bolt 751 and the PC steel wire 856.

Hereinafter, the side wall group which comprises the member assembly type PC rainwater storage tank of this invention is demonstrated.

The side wall group according to the present invention is composed of two types of girder-mounted side wall and girder-mounted side wall, Figure 14 is a view showing the inner surface of the girder-mounted side wall provided with a step of the side wall constituting the member-assembled PC rainwater storage tank of the present invention. 15 is a side view of the girder mounting side wall, and FIG. 16 is a top plan view of the girder mounting side wall.

As shown, the girder mounting side wall 210 is provided with a body portion 212 of a square plate, the fixing groove 218 and the fixing hole 219 is provided in communication with the fixing groove 218 is provided. .

In addition, the girder mounting side wall 210 is provided with a body portion 212 forming an appearance, and the water ring installation groove 216 for the water ring installation on the side of the body portion 212.

In addition, the girder mounting side wall 210 is provided with a step 214 on which the girder 400 is installed in the upper portion of the body portion 212. In addition, the stepped jaw 214 is provided with anchor reinforcing bars 280 to be cross-coupled with the anchor reinforcing bars protruding in the girder.

And, the lower side of the body portion 212 is provided with an anchor reinforcing groove 213 into which the anchor reinforcement 80 of the lower slab is inserted. At this time, under the body portion 212 is provided a non-shrink mortar injection groove 217 in a structure in communication with the anchor reinforcing groove 213.

It is a side view of a girder side wall.

The girder-mounted side wall 220 is provided with a rectangular plate-shaped body portion 222, the stepped portion 224 is provided in the upper side of the body portion 222. The step 224 is configured such that the upper slab 500 is installed, the step 224 is located at the upper side by the height of the girder than the step provided in the girder mounting side wall 210.

In addition, the girder mounting side wall 220 is also provided with a fixing hole 229 in a structure in communication with the fixing groove 228 and the fixing groove 228.

In addition, when assembling with the adjacent side wall 216 is provided with a water ring installation groove 226 for watertight maintenance.

And, the lower side of the body portion 222 is provided with an anchor reinforcing groove 223 and the non-shrink mortar injection groove 227 is inserted into the anchor reinforcement 80 of the lower slab.

Figure 18 is a side view showing the pillar constituting the present invention the assembled PC rainwater storage tank, Figure 19 is a bottom plan view of the column, Figure 20 is a top plan view of the column.

As shown, the pillar 300 includes a pillar portion 310 having a predetermined length and an upper portion 320 provided on an upper end of the pillar portion 310. The upper end portion 320 is preferably formed wider than the width of the pillar portion 310 to facilitate the installation of the girder to be described later.

And, the lower portion of the pillar 300 is provided with anchor reinforcing grooves (313,314) for inserting the anchor reinforcement 90 of the column installation portion is configured when the lower slab is assembled.

At this time, the lower portion of the pillar 300 is provided with a protrusion 315 corresponding to the concave grooves 135, 145, and 155 of the pillar mounting portion, so that the assembly of the pillar mounting portion and the pillar is configured to be firm.

On the other hand, the anchor reinforcement 380 is provided in the upper direction of the upper end 320 of the pillar 300.

Next, FIG. 21 is a plan view illustrating the girder, and FIG. 22 is a side view of the girder illustrated in FIG. 21.

As shown, the girder 400 is provided with a body portion 401 having a predetermined length, the receiving groove portion 430 is provided in a form in which both ends are opened and closed based on the longitudinal direction and both sides are closed. Anchor reinforcement 480 is provided in the same direction in the longitudinal direction of the girder into the groove portion 430. Here, the anchor reinforcing bar 480 has a bent end portion.

On the other hand, the girder 400 is divided into a girder connecting between the pillar 300 and the pillar 300 and the girder connecting between the side wall 210 and the pillar 300.

The girder for connecting the pillar and the girder for connecting the pillar and the side wall are different in length, but the basic structure is the same. Hereinafter, the same reference numerals will be used for the convenience of illustration and description.

23 is a side view showing one form of the upper slab.

The upper slab 500 to be applied to the assembled PC rainwater storage tank of the present invention is preferably composed of a hollow concrete panel having an internal hollow portion 510, as shown, a solid concrete panel, half slab (half) Slabs of various other materials and shapes, such as slabs) and steel deck plates, may also be applied.

24 to 26 are inside and outside plan views and side views showing a closed block portion.

As shown, the member assembly PC rainwater storage tank of the present invention further comprises a closed block portion 600 installed at the periphery of the lower slab assembly. The closed block part 600 serves to block a space that cannot be closed by one side wall of the corner portion of the rainwater storage tank of the present invention (see FIG. 4).

The closed block portion 600 forms a block portion 602 having a rectangular shape, and the water ring installation groove 616 is provided at a position capable of maintaining watertightness with the side walls 210 and 220 to be installed.

In addition, a fixing hole 605 is formed through the inside and outside of the block portion 602 for assembling the side walls 210 and 220.

Referring to the assembly method of the present invention, the member assembly type PC rainwater storage tank configured as described above are as follows.

First, select the lower slab to be assembled according to the storage capacity of the storage tank. Hereinafter, for convenience of description, a form for assembling the lower slab assembly as shown in FIG. 5 will be described as an example.

Next, the process of assembling the selected lower slab.

That is, the first slab lower slab 110, the second corner lower slab 120, the first peripheral lower slab 130 and the second peripheral lower slab 140 using the lower slab assembly 101 of the lower slab assembly (101). Assembled to form a circumference, the central portion is assembled by placing the central lower slab 150.

On the other hand, in order to maintain the watertight prior to assembling each of the lower slabs in order to maintain the watertight ring mounting grooves (116, 126, 136, 146, 156) provided in each of the lower slabs (110, 120, 130, 140, 150) in advance.

11 and 13, the assembly between the lower slabs 110, 120, 130, 140, and 150 is assembled using bolts or PC steel wires, which are already described above, and thus detailed description thereof will be omitted.

Meanwhile, after the assembly of the lower slabs 110, 120, 130, 140 and 150 is completed using bolts or PC steel wires, the bonding force is increased by filling the fixing grooves 118, 128, 138, 148 and 159 with the non-contraction mortar or epoxy resin in the lower slabs. At the same time, water is prevented from leaking through each of the fixing grooves and the fixing holes.

In addition, the watertightness can be supplemented by filling non-shrink mortar or epoxy resin between the water ring 77 and the water ring 77 provided on the side surfaces of the lower slabs 110, 120, 130, 140, and 150.

When the assembly of the lower slab assembly 101 is completed as described above, a process of installing side walls along both sides of the lower slab assembly 101 is performed.

FIG. 27 is a side view showing the state in which the respective components of the assembly-type PC rainwater storage tank of the present invention are assembled based on the form in which the girder-mounted side walls 210 are positioned at both sides.

4 and 27, the girder mounting side wall 210 is installed at one side and the other side parallel to the lower slab assembly 101, and the girder mounting side wall 220 is installed at the other two sides. do.

Meanwhile, before the side walls 210 and 220 are installed, the water ring 77 is installed along the outer circumference of the lower slab assembly 101, and the water ring 77 is also provided in the side water ring installation grooves 216 and 226 of the side wall. Is installed.

In addition, the anchor reinforcing grooves 213 and 223 provided at the lower portions of the side walls 210 and 220 are installed to be inserted into the anchor reinforcement 80 provided outside the stepped portions 114, 124, 134 and 144 of the lower slabs 110, 120, 130 and 140.

In addition, the side wall and the adjacent side wall is assembled, which is applied to the fixing grooves 218 and 228 and the fixing holes 219 and 229 provided in the side walls 210 and 220 as in the assembly process of the lower slab described above. By doing so.

Next, by injecting non-contraction mortar or silicon through the non-contraction mortar injection grooves (217,227) provided in the lower side of each side wall (210,220) to increase the coupling force between the side walls (210,220) and the lower slab assembly 101 and leaks To prevent.

In this case, the watertightness can be compensated by filling the watertight ring 77 and the watertight ring 77 with an anhydrous mortar or an epoxy resin, such as the lower slabs 110, 120, 130, 140, and 150, between the sidewalls 210 and 220 and the sidewalls 210 and 220.

As described above, after all of the assembly between the side wall and the lower slab assembly is completed, the column is installed in the column mounting portion formed inside the lower slab assembly.

It is installed so that the anchor reinforcement 90 of the pillar mounting portion is accommodated in the anchor reinforcing groove receiving grooves (313,314) of the lower portion of the pillar 300, wherein the protrusion 315 of the pillar in the concave grooves (135, 145, 155) forming the pillar mounting portion. Will automatically settle down.

In addition, the lower slab assembly 101 and the pillar 300 are integrated by injecting the non-shrink mortar through the non-shrink mortar injection groove 315 provided in the lower portion of the pillar 300.

After all the installation of the pillar 300 is completed, the girder 400 is installed to connect between the pillar 300 and the pillar 300 and between the pillar 300 and the side wall 210. Meanwhile, in the present invention, the girder connecting the pillar 300 and the pillar 300 and the girder connecting the pillar 300 and the side wall 210 may have different lengths, but the same reference numerals are used to describe the same. The description is as described above.

The anchor reinforcement 480 disposed inside the insertion groove 430 of each girder 400 and the anchor reinforcement 380 vertically upwardly projecting from the upper portion of the column 300 are arranged so as to intersect with each other Shrinkage mortar is inserted into the insertion groove 430 so that the connection portion is firmly fixed.

In addition, the insertion groove 430 of the girder 400 is positioned so as to surround the upper anchor reinforcement 280 of the stepped portion 214 of the girder-mounted side wall 210, but the anchored reinforcement 280 of the stepped portion 214 is located. ) And the anchor reinforcing bar 480 of the girder 400 cross each other, and after curing the non-shrink mortar is cured to achieve a completely fixed state.

After the installation of the girder is completed, the upper slab 500 is installed in the form of connecting the girder and the girder and the girder and the girder side wall.

The upper slab 500 is installed to the upper side of the girder 400 in a continuous parallel form, as shown in Figure 4 and 27.

And, as shown in Figure 4, the closed block portion 600 is installed to block the space that can not be closed to the side wall side edge portion of the rainwater storage tank of the present invention. At this time, since the closed block part 600 is installed outside the side wall 210, the upper slab 500 may not be installed as much as the width of the side wall 210, and thus a portion of the upper portion of the storage tank may be opened. In this case, it will be desirable to close the open portion using concrete or the like.

On the other hand, Figure 28 is a side view showing a girder according to the other form at the same time the reinforcement structure is applied to the upper slab in the member assembly type PC rainwater storage tank of the present invention.

When the installation of the upper slab 500 is completed, the upper slab 500 alone may be difficult to bear the overburden load. In this case, a reinforcement structure 990 is installed to reinforce the reinforced concrete 909 by placing the concrete 900 on the upper side of the upper slab.

At this time, the girder 400 is preferably provided with a separate auxiliary anchor reinforcing bar 490 vertically upward in the longitudinal direction of the girder, so as to be coupled to the concrete on the upper slab 500, the structural coupling force is increased.

At this time, it is also possible to reinforce the upper side of the upper slab 500 to reinforce the structure.

PC assembly rainwater storage tank of the present invention configured as described above is the first slab bottom slab, the second edge bottom slab, the first circumferential bottom slab, the second circumferential bottom slab, the center bottom slab, the girder mounting side wall, girder Dummy-mounted side walls, pillars, columns for connecting pillars and columns, girders for connecting columns and side walls, upper slabs, closed blocks, and 12 types of components, allowing construction to be made by assembling blocks that fit any size of storage tank. The cost and efficiency can be maximized.

In addition, according to the present invention, it is possible to maximize the low capacity by minimizing the number of pillars in the storage tank, it is also provided to install a single column in the unit pillar installation effect to supplementally strengthen the assembly state between the lower slab. .

Furthermore, by applying a mortar injection groove or the like to the exponent ring and the anchor reinforcing bars and the joint portion, the assembly can be smoothly performed even if the level of the base portion is reduced or the precision of the product manufacturing is decreased.

It will be apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is obvious to them. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and thus, the present invention is not limited to the above description and may be modified within the scope of the appended claims and their equivalents.

For example, as shown in FIG. 29, in the closed block portion 650, the width of both sidewalls 210 is reduced from the width of the sidewalls 210 to the inside of the block portion 602 by the thickness of the sidewalls 210. Protruding block portion 606 of the protruding form is formed, it may be possible to prevent the open portion is generated only by the installation of the closed block portion 650. In addition, the water ring installation grooves 616 are provided in the protruding block portion 606 and the block portion 602 corresponding to the positions in which the sidewalls 210 and 220 are in close contact with the upper slab 500 and the lower slab 110. It may be provided with a closed block portion 650 formed. Of course, the fixing block 605 is provided in the closed block 650 as well.

77: Exponent ring
101: Lower slab assembly
110: lower slab for the first corner
120: lower slab for second corner
130: first circumference lower slab
140: second circumferential lower slab
150: lower center slab
112,122,132,142,152: block portion
114,124,134, 144: step
116,126,136,146,156: Index ring mounting groove
118,128,138,148,158: settlement home
119,129,139,149,159: settlement hall
200: side wall group
210: girder mounting side wall
220: pile mounting side wall
213,223: Anchor reinforcing bar receiving groove
217,227: Non-shrink mortar injection grooves
214,224: stepping for side walls
216,226: Expansion ring installation groove for side wall
218, 228:
219,229: Fixation hole
300: Column
400: girder
500: upper slab
600: closed block portion

Claims (36)

A plurality of lower slabs are included, the lower slab group of the plurality of lower slabs is assembled according to the low capacity to form a lower slab assembly, and a plurality of sidewalls are included in the periphery of the lower slab assembly. A side wall group, a pillar assembled vertically upwardly to the lower slab assembly, a girder assembled to connect the side wall and the pillar or the pillar and the upper pillar, and an upper slab assembly assembled to the upper portion of the upper girder,
The lower slab group forms a quadrangular shape, and the first edge lower slab forms one corner portion of one side of the lower slab assembly and a corner portion diagonally opposite thereto, and forms a quadrangular shape and the other edge portion of one side of the lower slab assembly. And a second edge lower slab forming a corner portion opposite thereto, and a first edge lower slab and a second edge positioned between the first edge lower slab and the second edge lower slab in the lower slab assembly. Bouillon lower slab,
The side wall has a rectangular shape and at the same time the fixing groove is provided on one side and at the same time the member assembly PC rainwater storage tank, characterized in that the fixing hole is in communication with the fixing groove. delete The method of claim 1,
The first edge lower slab,
The side wall is installed above the outer peripheral portion of the lower edge slab for the first edge relative to the lower slab assembly;
PC assembly rainwater storage tank, characterized in that the step is provided so that the inner bottom of the side wall is installed. The method of claim 3,
The first edge lower slab,
PC-type rainwater storage tank, characterized in that the water ring installation groove for installing the water ring to achieve watertight maintenance with the side wall. The method of claim 3,
The first edge lower slab,
Anchor bars for assembling with the sidewalls are provided on the outside of the step;
The side wall is a member assembled PC rainwater storage tank, characterized in that the anchor reinforcing groove corresponding to the anchor reinforcement is provided. The method of claim 1,
The lower slab forms a rectangular plate block,
PC assembly rainwater storage tank, characterized in that the fixing groove is provided on the upper side of the lower slab to be assembled with the adjacent lower slab and the fixing hole in communication with the fixing groove on the side of the lower slab. delete The method of claim 1,
The second corner lower slab,
The side wall is installed above the outer peripheral portion of the lower slab for the second edge relative to the lower slab assembly;
PC assembly rainwater storage tank, characterized in that the step is provided so that the inner bottom of the side wall is installed. 9. The method of claim 8,
The second corner lower slab,
PC-type rainwater storage tank, characterized in that the water ring installation groove for installing the water ring to achieve watertight maintenance with the side wall. 9. The method of claim 8,
The second corner lower slab,
Anchor bars for assembling with the sidewalls are provided on the outside of the step;
The side wall is a member assembled PC rainwater storage tank, characterized in that the anchor reinforcing groove corresponding to the anchor reinforcement is provided. delete The method of claim 1,
The first peripheral portion lower slab,
The side wall is installed above the outer peripheral portion relative to the lower slab assembly;
PC assembly rainwater storage tank, characterized in that the step is provided so that the inner bottom of the side wall is installed. The method of claim 12,
The first peripheral portion lower slab,
Anchor bars for assembling with the sidewalls are provided on the outside of the step;
The side wall is a member assembled PC rainwater storage tank, characterized in that the anchor reinforcing groove corresponding to the anchor reinforcement is provided. The method of claim 13,
The first peripheral portion lower slab,
PC rainwater storage tank, characterized in that the unit is provided with a unit pillar installation unit for assembling the pillar to one side of the opposite side of the one side is formed. 15. The method of claim 14,
The unit pillar mounting portion,
PC assembly rainwater storage tank, characterized in that the anchor reinforcement is inserted into the lower portion of the column. The method of claim 12,
The first peripheral portion lower slab,
PC-type rainwater storage tank, characterized in that the water ring installation groove for installing the water ring to achieve watertight maintenance with the side wall. delete The method of claim 1,
The second peripheral portion lower slab,
The side wall is installed above the outer peripheral portion relative to the lower slab assembly;
PC assembly rainwater storage tank, characterized in that the step is provided so that the inner bottom of the side wall is installed. 19. The method of claim 18,
The second peripheral portion lower slab,
Anchor bars for assembling with the sidewalls are provided on the outside of the step;
The side wall is a member assembled PC rainwater storage tank, characterized in that the anchor reinforcing groove corresponding to the anchor reinforcement is provided. 20. The method of claim 19,
The second peripheral portion lower slab,
PC rainwater storage tank, characterized in that the unit is provided with a unit pillar installation unit for assembling the pillar to one side of the opposite side of the one side is formed. 21. The method of claim 20,
The unit pillar mounting portion,
PC assembly rainwater storage tank, characterized in that the anchor reinforcement is inserted into the lower portion of the column. delete The method of claim 1,
The lower slab group,
PC-shaped rainwater storage tank, characterized in that the bottom slab assembly comprises a central lower slab assembled in the first slab for slab and the second slab for slab assembly. 24. The method of claim 23,
The central lower slab,
PC assembly rainwater storage tank, characterized in that the unit is provided with a unit pillar installation unit to be assembled. delete The method of claim 1,
The side wall is,
PC assembly rainwater storage tank, characterized in that the stepped end is provided with one end of the girder. The method of claim 26,
Said step being provided with an anchor steel;
The girder member PC-type rainwater storage tank, characterized in that the anchor reinforcement is installed to cross each other on the anchor reinforcement of the step. The method according to any one of claims 14, 20 or 24,
Each of the unit pillar mounting portions is provided with a recessed groove inward;
PC assembly rainwater storage tank, characterized in that the lower portion of the pillar is provided with a projection which is provided in the concave groove. 29. The method of claim 28,
PC-type rainwater storage tank, characterized in that the anchor reinforcement is inserted into the recess provided in the concave groove. The method of claim 1,
The above-
Wherein both end portions are provided with insertion grooves formed in a state in which both sides thereof are closed along the longitudinal direction;
PC-type rainwater storage tank, characterized in that the anchor groove is provided in the insertion groove. The method of claim 1,
The above-
A member-assembled PC rainwater storage tank, characterized in that the auxiliary anchor is further provided in the vertical direction in the longitudinal direction of the girder at both ends. delete delete delete delete delete

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