KR101099777B1 - Prefabricated rain-water retaining facility - Google Patents

Abstract

PURPOSE: A prefabricated rainwater storing facility is provided to reduce the construction period by easily and rapidly being constructed. CONSTITUTION: A prefabricated rainwater storing facility comprises a main water storage unit(100) and a sub water storage unit(200). The main water storage unit comprises four manhole portions(110) and a connection portion(120). The sub water storage unit is installed in the inner side of the main storage unit. The sub water storage unit is composed in the inner side of the girth formed with the connection portion and is formed by stacking and connecting a plurality of sub blocks.

Description

Prefabricated Rain-water Retaining Facility

The present invention relates to a prefabricated rainwater storage system, and more particularly, to a prefabricated rainwater storage system that can be constructed quickly and easily, and is structurally stable and can be purified in a storage space.

In general, storage tanks store rainwater that temporarily blows up and gradually discharge it to prevent backflow of rivers or flooding of rivers, or to gradually drain water stored in the dry season to prevent depletion of rivers. It is a well-known fact that it is a facility for various purposes such as tree water for landscaping, road cleaning or fire protection.

Recently, due to the rapid urbanization, the surface pavement rate increases due to various buildings, roadways, sidewalks, etc., so rainwater cannot be submerged underground but is discharged to sewers or rivers. Therefore, there is a problem in the rainy season suddenly a large amount of rainwater discharged to the sewer or river, the backflow of the sewage or flooding of the river.

In addition, during the dry season, there is a problem that the vegetation or trees in the surroundings die as the river is easily depleted because it does not absorb enough moisture into the ground.

In particular, during the dry season, water cannot be supplied from rivers for preventing landscaping of apartment complexes or landscaping in urban areas, or water for various purposes such as road cleaning.

Therefore, in order to solve the above problems, a storage tank that can store and discharge rainwater has been constructed.

However, looking at the construction method of such a conventional storage tank is usually to form a formwork for pouring cement concrete on the floor after digging and mining, and then the cement concrete in the formwork to cure, in this case form the formwork in the field It is not only very cumbersome to do, but also causes various problems such as the time required for curing the concrete after pouring cement.

The present invention has been made to solve the above problems, the construction can be easily and quickly construction can shorten the air, and provides a prefabricated rainwater storage facility including a purification device capable of purifying the stored rainwater. There is a purpose.

The prefabricated rainwater storage system according to the present invention for achieving the above object is a manhole portion having a passage extending vertically, and the connecting portion for providing a passage for moving the water stored by interconnecting the manhole portion; main storage unit including a And a storage block including a plurality of panel members coupled to each other to form a polygonal pillar and stacked and connected to each other.

The main storage unit is formed to connect the plurality of manholes spaced apart from the connecting portion in the form of a frame, it is preferable to further include an auxiliary storage unit formed by an auxiliary block laminated and connected to each other inside the edge formed by the connecting portion. Do.

The panel member forming the storage block has a coupling protrusion protruding outward on one side, and a coupling groove into which the coupling protrusion can be fitted is formed on the other side, and the locking groove has an entry direction into which the coupling protrusion enters. Since the coupling protrusion is spaced apart from the protruding direction by a predetermined angle, it is preferable that the panel members are formed to be connected by being bent at a predetermined angle when the panel members are connected to each other.

In addition, the panel member may include a first panel member having an outer circumferential surface and an inner circumferential surface blocked, a second panel member having a through hole penetrating through the outer circumferential surface and an inner circumferential surface, and a through hole crossing the through hole of the second panel member. And a third panel member having a plurality of connection bars, and the storage block may be formed by mutually coupling four panel members selected from the first to third panel members, and the panel member may be formed at an edge of an outer circumferential surface thereof. Coupling grooves are formed in the upper and lower surfaces and the side surfaces of the panel member connected to the outer circumferential surface and the outer circumferential surface of the panel member, respectively. One block fastening member may be further provided.

The auxiliary block is formed in a hexagonal column shape, each side is formed with a flow hole penetrating the inner peripheral surface and the outer peripheral surface, the auxiliary blocks can be interconnected in a honeycomb structure to form the auxiliary storage unit, the auxiliary block Is formed in the top and bottom of each side of the insertion groove which is inserted downward and upward, respectively, and has a diameter corresponding to the insertion groove to be inserted into the insertion groove so as to connect the auxiliary blocks vertically and horizontally It is preferable to further include a second block fastening member including an insertion portion formed to have a length twice the thickness of the auxiliary block side wall, and a vertical portion formed at both ends of the insertion portion so as to extend in parallel with the side wall of the auxiliary block.

The four manholes are formed to be spaced apart from each other, and the connecting portion interconnects the four manholes to form a square rim shape, one of the manholes is connected to the inlet pipe to which rainwater is introduced, the inlet pipe is The uppermost storage block of the manhole portion to be connected is provided with a filtration screen for filtering foreign matter contained in the rainwater flowing in, the lower portion of the filtration screen is provided with a filtration layer filled with elvan rock, and is not connected to the inlet pipe The remaining manhole portion is preferably provided with an oxygen supply portion for supplying oxygen to the inside and a discharge pump for pumping the stored rainwater to the outside.

Prefabricated rainwater storage facility according to the present invention can be made easily and quickly construction can minimize the time and cost of construction, there is an advantage that easy maintenance.

1 is a perspective view showing a prefabricated rainwater storage system according to the present invention,
2 is a cross-sectional view of the prefabricated rainwater storage device of FIG.
3,

Hereinafter, with reference to the accompanying drawings will be described in detail the prefabricated rainwater storage facility according to the present invention.

1 to 7 illustrate a preferred embodiment of the prefabricated rainwater storage system 10 according to the present invention. Referring to the drawings, the prefabricated rainwater storage system 10 includes a main storage unit 100 and the main storage. It includes an auxiliary storage unit 200 is installed inside the unit 100.

To install a protective sheet and a waterproof sheet for protection and waterproof in the installation space formed for the construction of the prefabricated rainwater storage facility 10 of the present invention, the main storage unit 100 is installed inside the main storage The unit 100 includes four manhole parts 110 formed by stacking the storage blocks 130 and a connection part 120 formed by connecting the storage blocks 130 to interconnect the manhole parts 110. The connection portion 120 is formed in the shape of a square border.

The manhole part 110 is formed by stacking three storage blocks 130 up and down, and one of the four manhole parts 110 is connected to an inflow pipe 111 into which rainwater flows. For convenience, when the manhole part 110 connected to the connection pipe is referred to as the inflow manhole part 110a, the rainwater flowing through the inflow pipe 111 is introduced into the uppermost storage block 130 of the inflow manhole part 110a. Filter screen 112 is formed for filtration of foreign matter contained in. In addition, the storage block 130 connected to the lower portion of the uppermost storage block 130 is formed with a filtration layer 113 in which elvan is filled to supply far infrared rays and anions to the rainwater during the rainwater flow.

Of course, the filtration layer 113 may be a natural material that emits far infrared rays and anions such as germanium, tourmaline, biotite, biotite, jade in addition to the elvan.

Except the inflow manhole portion 110a, the remaining manhole portion 110 is provided with a ladder 114 to allow an operator to enter the inside of the manhole portion 110 for maintenance and cleaning. An oxygen supply unit 115 is provided to supply oxygen for purification. And the discharge pump 116 and the discharge pipe 117 for discharging the rainwater in the storage is installed so that it can be used to pump the rainwater in the storage if necessary.

The connection part 120 is to provide a passage for connecting the manhole parts 110 to each other to partition the storage space, and to connect the manhole parts (110).

The connecting portion 120 is also formed by connecting the storage block 130, the storage block 130 is laminated in two layers to connect and connects the four manholes 110 to form a rectangular border.

The storage block 130 constituting the manhole part 110 and the connection part 120 is formed by coupling a plurality of panel members 131 to each other as shown in FIG. 3.

The panel member 131 is formed in a plate shape, one end of the coupling protrusion 134 is formed to protrude so as to extend in the vertical direction, the other end of the coupling groove 136 into which the coupling protrusion 134 can be fitted. ) Is formed. Therefore, when the panel members 131 are coupled to each other, the coupling protrusion 134 of the one side panel member 131 is inserted into the fastening groove 136 of the other panel member 131 to which the panel protrusions 131 are connected.

In particular, the direction in which the coupling protrusion 134 protrudes and the insertion direction of the coupling protrusion 134 introduced into the coupling groove 136 are spaced at right angles. Therefore, when the two panel members 131 are connected to each other, the other panel member 131 is coupled to the one panel member 131 at a right angle. Therefore, when all four panel members 131 are fastened, the upper and lower surfaces are open to form a rectangular pillar.

The coupling protrusion 134 is provided with a fixing hole 135 for fixing after the panel member 131 is fastened, and when the coupling protrusion 134 is inserted into the fastening groove 136 of the other panel member 131, the other side is fixed. From the outer circumferential surface of the panel member 131, the fixing pin 137 is installed to penetrate the fixing hole 135 of the coupling protrusion 134 inserted into the fastening groove 136, thereby separating the two panel members 131 coupled to each other. Is prevented.

In addition, the coupling groove 138 is formed at the edges of three sides except for one side on which the coupling protrusion 134 of the panel member 131 is formed. The coupling groove 138 is an 'b' shaped inlet groove that connects the outer circumferential surface and three sides of the panel member 131, that is, the top, bottom, and side surfaces, and is stored through the first block fastening member 140 to be described later. Used to join blocks 130 to each other. As shown in FIG. 4, the panel members 131 are combined to form the storage block 130, and then the storage blocks 130 are interconnected to form the manhole part 110 or the connection part 120. The first block fastening member 140 having a cross shape is inserted into the coupling groove 138 of the two storage blocks 130 to connect the storage blocks 130 to each other.

And the panel member 131 is formed in three types as shown in FIG. For convenience, if each type of panel member 131 is referred to as the first to third panel members 131a, 131b, and 131c, the first panel member 131a is in a form in which the outer circumferential surface and the inner circumferential surface of the panel member 131 are closed. The second panel member 131b has a form in which a through hole 132 penetrates through an outer circumferential surface and an inner circumferential surface thereof. The third panel member 131c has a shape in which a plurality of connection bars 133 are formed in the second panel member 131b to cross the through hole 132.

The first panel member 131a is applied to form an outer surface of the manhole part 110 or the connection part 120.

The second panel member 131b is applied where it is necessary to form a water passage through which water can pass, such as a connection point between the manhole part 110 and the connection part 120.

The third panel member 131c is applied to the inner circumferential surface side of the edge formed by the connecting portion 120 and used to provide a passage for moving water into the interior of the edge. In this case, a third panel member 131c having a connecting bar 133 formed thereon is applied to prevent the auxiliary block 210 or other foreign matter from flowing into the main storage unit 100.

The storage block 130 is formed by appropriately combining four panel members 131 selected from the first to third panel members 131a, 131b, and 131c according to the installation position and purpose.

As shown in FIGS. 1 and 6, the auxiliary storage unit 200 is provided inside the edge formed by the connection part 120 and is formed by connecting and stacking a plurality of auxiliary blocks 210.

The auxiliary block 210 is formed in a hexagonal column shape, and each surface has two flow holes 211 penetrating the outer circumferential surface and the inner circumferential surface to be spaced up and down, and are respectively downward and upward on the top and bottom of each surface. The insertion groove 212 which is drawn in is provided. Since the auxiliary block 210 is formed in a hexagonal pillar shape, the plurality of auxiliary blocks 210 are connected in a honeycomb structure through the second block fastening member 220 which will be described later.

The second block fastening member 220 is for interconnecting the respective auxiliary blocks 210, and includes an insertion part 221 and a vertical part 222.

The insertion part 221 is installed to be inserted into the insertion groove 212 formed at the top or the bottom of the two surfaces which are in contact with each other when the two auxiliary blocks 210 are connected, the radius of the insertion part 221 is the insertion Since it is formed to correspond to the radius of the groove 212, when the auxiliary block 210 is stacked up and down, the four auxiliary blocks 210 are laminated and connected to each other by the cylindrical hollow formed by the insertion grooves 212 It corresponds to the shape of this insertion part 221.

The vertical parts 222 are formed at both ends of the insertion part 221, respectively, and extend vertically to be perpendicular to the longitudinal direction of the insertion part 221. As described above, when the insertion portion 221 is inserted into the hollow formed by the insertion groove 212 at the connection point of the four auxiliary blocks 210, the vertical portion 222 to support the inner circumferential surface of the four auxiliary blocks 210. As a result, the auxiliary blocks 210 are prevented from being separated by flowing from side to side.

In the prefabricated rainwater storage system 10 according to the present invention described above, the main storage unit 100 and the auxiliary storage unit 200 are formed by stacking and connecting the storage block 130 and the auxiliary block 210 in the field, respectively. Therefore, the construction period of the storage tank is shortened, and construction is easy. In particular, since the panel member 131 constituting the storage block 130 can be transported in a separated state, it is possible to reduce the transport cost of the manufactured parts.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10; Prefab Rainwater Storage Facility
100; Main storage unit
110; Manhole portion 120; Connection
130; Undercurrent Block
131; A panel member 140; 1st block fastening member
200; Auxiliary Storage Unit
210; Auxiliary block 220; 2nd block fastening member

Claims (8)

delete A manhole portion having a passage extending vertically;
It is provided with a main storage unit including a; connecting portion for providing a passage for moving the stored water by interconnecting the manhole,
The manhole part and the connection part are formed by stacking and connecting the storage blocks including a plurality of panel members coupled to each other to form a polygonal column.
The main storage unit is formed to connect the plurality of manholes in which the connecting portions are spaced apart in a rim shape,
Prefabricated rainwater storage system characterized in that it further comprises an auxiliary storage unit formed by the auxiliary block is laminated and connected to each other inside the edge formed by the connecting portion. The method of claim 2,
The panel member forming the storage block is formed with a coupling protrusion protruding outward on one side, the coupling groove is formed to be fitted to the other side,
The fastening groove is a prefabricated type, characterized in that the entry direction into which the engaging projection enters is spaced apart from the projecting direction in which the engaging projection is projected by a predetermined angle when the panel members are connected to each other, bent at a predetermined angle. Rainwater Storage. The method of claim 3, wherein
The panel member may include: a first panel member having an outer circumferential surface and an inner circumferential surface blocked; a second panel member having a through hole penetrating through the outer circumferential surface and an inner circumferential surface; and a plurality of transverse through holes formed in the through hole of the second panel member. A third panel member having two connecting bars formed therein,
The storage block is a prefabricated rainwater storage facility, characterized in that formed by combining the four panel members selected from the first to third panel members. The method of claim 4, wherein
The panel member is formed at the edge of the outer peripheral surface of the coupling grooves which are inserted into the upper and lower surfaces and side surfaces of the panel member connected to the outer peripheral surface and the outer peripheral surface of the panel member, respectively,
And a cross-shaped first block fastening member inserted into a coupling groove of an adjacent storage block to couple the storage blocks to each other. The method of claim 2,
The auxiliary block is formed in a hexagonal column shape, each side is formed with a flow hole penetrating the inner circumferential surface and the outer circumferential surface,
Prefabricated rainwater storage facility, characterized in that the auxiliary blocks are interconnected in a honeycomb structure to form the auxiliary storage unit. The method of claim 6,
The auxiliary block is formed in the top and bottom of each side wall insertion groove which is inserted downward and upward, respectively,
An insertion portion having a diameter corresponding to the insertion groove so as to be inserted into the insertion groove so as to connect the auxiliary blocks vertically and horizontally, and having a length twice the thickness of the side wall of the auxiliary block; Prefabricated rainwater storage system further comprises a second block fastening member including a vertical portion formed to extend parallel to the side wall of the block. A manhole portion having a passage extending vertically;
It is provided with a main storage unit including a; connecting portion for providing a passage for moving the stored water by interconnecting the manhole,
The manhole part and the connection part are formed by stacking and connecting the storage blocks including a plurality of panel members coupled to each other to form a polygonal column.
The four manholes are formed to be spaced apart from each other, and the connection portion forms a rectangular border shape by connecting the four manholes to each other,
One of the manholes is connected to an inflow pipe to which rainwater is introduced, and a filtration screen for filtering foreign substances contained in the rainwater to be introduced is installed in the uppermost storage block of the manholes to which the inflow pipes are connected. The lower part of the filter bed is filled with elvan rock,
Prefabricated rainwater storage facility, characterized in that the remaining manhole portion that is not connected to the inlet pipe is formed with an oxygen supply unit for supplying oxygen to the inside, and a discharge pump for pumping the stored rainwater to the outside.

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