SK50412015A3 - Infiltration or retention modular system - Google Patents

Abstract

Infiltration or retention modular system is jigsaw puzzle from a plastic pressed parts of the infiltration or retention module (1) for the infiltration of rainwater into underground storage. Bridge or tubular channels (2) the infiltration or retention modules (1) along the mutual connection creates passageways for water inlet, inspection and transfer to the adjacent infiltration or retention module (1). Vertical reinforcing holes (3) with the mounted reinforcing tube (4) allow passage of the camera to the interconnected infiltration or retention module (1). Engaged reinforcing tube (4) for the static additives enhance of the infiltration or retention modules (1) can possibly fill by mass (5) for other static amplification, such as aggregates.

Description

Infiltration or retention modular system

Technical field

The invention relates to an underground infiltration or retention modular system for infiltration of rainwater or wastewater into the subsoil, or their retention, for the purpose of their further utilization. The invention falls into the field of water management and construction.

Prior art

Retention and infiltration systems are currently being redesigned, and many manufacturers offer infiltration blocks or tunnels that are located below ground level and for investments that pay off quickly and allow rainwater and possibly biologically treated wastewater to infiltrate. The systems are so sophisticated that they do not even need a large plot of land, as the modules from which they are folded can be stacked on top of each other in several layers, do not take up space on the plot and are even mobile by cars with certain design requirements. With the help of known calculations and a geological report on the subsoil, the size of the system can be oversized to capture two-, five-, ten-, fifty- and even centuries-old water from the roof without the risk of the system being undersized, or unnecessarily oversized and expensive.

The use of infiltration wells, pipe perforated systems, tunnel systems or block infiltration systems of various shapes and dimensions of predominantly cuboid shape for infiltration of rainwater and wastewater continues to have certain disadvantages. The disadvantage of existing systems is their high price in wells, in piping systems and tunnels a large area of the affected area, in block systems fixed fixed height of blocks with the impossibility to additionally adjust the block height at any time directly on site as needed, predetermined and sometimes no place to connect supply pipes , often required additional adapter for pipe connection, constant static strength of blocks, impossibility of additional and additional increase of static load capacity of blocks, with currently sold blocks impossibility of internal 3D dimensional inspection of infiltration system, or impossibility of making necessary cutouts in body of infiltration blocks on site. From the state of the art, infiltration tanks composed of plastic blocks coated with geotextile and retention tanks coated with impermeable foil are known, which offer a maximum usable volume of up to 95%. Before entering the retention tank, filter, sedimentation shafts are installed, which must be regularly monitored from the point of view of operation. . . «« ♦! * * Ϊ Í * · ··

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* ’* E * β e · ·» <· <·· check and clean. The assembly of the retention tank consists in unfolding the plastic blocks to the required shape and volume. Subsequently, the entire tank is wrapped in geotextile and impermeable foil, which is firmly welded and forms a closed retention system together with the blocks. Countless modules are known, blocks in the form of plastic moldings from which infiltration or retention systems are assembled. For example, published patent application EP 1932975 discloses the construction of a retention module with a grate base and four webs or published patent application EP 1932974 discloses the construction of a cube-shaped retention module with large openings on all sides of the cube. Similarly, the construction of a retention module is known as described in published patent application EP 1607534. The disadvantage of these modules is either the impossibility of introducing a monitoring system into the body of the retention system or the need for additional reinforcement and securing the upper surface of the retention system or the absence of openings in the second perpendicular walls. . Furthermore, the constructions of the retention modules described in published patent applications EP 1743984 and EP 2107172 are known. The disadvantage of these modules is the absence of vertical openings in the grate bases of these modules and thus the impossibility of introducing a monitoring system into the body of the retention system. walls. Finally, the construction of the retention module is known, which is described in the published patent application EP 2142714. The disadvantage of these modules is the impossibility of later insertion of engineering networks perpendicular to the infiltration resp. retention system without violent disruption of retention modules. The shortcomings of prior art retention system solutions have led to the effort to design a modular segment of a retention system that would meet the requirements for retention systems and in addition provide 3D monitoring of the internal volume of the retention system, increase static load on the retention system and allow variability. module storage. The result of this effort is the further described construction of an underground infiltration or retention modular system for infiltration of rainwater or biologically treated wastewater into the subsoil or their retention for the purposes of their further use.

The essence of the invention

Said drawbacks are eliminated by the construction of a module of an underground infiltration or retention modular system for infiltration of rainwater or wastewater into the subsoil, or their retention for the purposes of their further use according to the invention.

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The essence of the invention is that it is an infiltration or retention module system with a stack arrangement of infiltration or retention modules with a shaped grate base, wherein in the stack arrangement and multiple side-by-side infiltration or retention modules with recesses in the edge walls are these recesses along the entire length and the width of the infiltration or retention modules formed by the intersecting horizontal bridge or pipe channels for monitoring or for guiding the engineering networks. In this case, the stack arrangement of the infiltration or retention modules in the vertical direction comprises a set of monitoring and reinforcement openings. It is also possible to implement a reinforcing tube or a plurality of tubes, or a plurality of tubes which can be filled with a reinforcing load mass, into at least a part of the set of reinforcing openings in a stack arrangement of infiltration or retention modules. Infiltration or retention modules with a square or rectangular shaped grate base consist of adjoining edge walls with at least two recesses on each edge wall and bridges formed between adjacent recesses. In the bridging lines from the grate base of the infiltration or retention module, a set of struts protrudes at the ends with alternately fitted pins and openings which fit into each other within the adjacent infiltration or retention modules. A set of connecting surfaces and / or cut-outs is fitted around the circumference of the grate base of the infiltration or retention module, the at least one surface or cut-out on each side being located exactly in the middle of the edge of the grate base. There are cut-outs around the circumference of the grate base of the infiltration or retention module into which the connecting couplings with the central bridge are inserted for connecting the adjacent infiltration or retention modules.

The advantages and operation of the underground infiltration or retention modular system according to the invention consist in a plastic molding - modules of a defined shape, which advantageously allows the modules to be interconnected by a dual connection option, opposite each other and to each other. This allows you to create a compact block of any height. At least two parallel half-channels intersecting in the modules formed in the modules, extending over the entire length of the module in one direction and at least two parallel two-channels intersecting in the transverse direction, intersecting with each other and half-channels, preferably semicircular, and preferably different radii corresponding to , are made in such a way that in case of modules connected to each other four or more internal through holes are preferably cylindrical, interconnected and intersecting, which allows free inspection of the inspection camera in the whole volume of the module block and at the same time its free passage to connected adjacent modules. , thus enabling visual inspection of the entire system, the volume of modules assembled into a complete unit, preferably a block. At the same time, there is the possibility of unrestrained inflow of rainwater into the entire volume of modules and connection to adjacent modules and thus into the entire system of modules. In the case of connecting the modules in a manner on top of each other by dome mounting, resp. The bridge mounting is the passage of the camera into the individual layers through a central vertical tubular part, an opening preferably cylindrical in shape with an inner diameter preferably corresponding to the outer diameter of standard tubes, which has cutouts in the wall to allow the camera to pass vertically. This tubular-cylindrical central part, of which there can be several, in several suitable parts of the module, can also advantageously serve for static reinforcement of the block by later insertion of a tube, tubes of the same diameter made of any material, preferably a plastic tube , with the required wall thickness and thus a defined strength, which has the task of strengthening the load-bearing capacity of the infiltration block. In the event of a greater need for static load-bearing capacity, the additional pipe can be further strengthened by filling with aggregate, dry concrete or by inserting a solid pipe, and thus the block can be reinforced up to the required load-bearing capacity as required. A tube can be folded over some integrated channels of the infiltration block as a protector, and a supply cable, pipes and the like can be additionally laid in it without the need to excavate the infiltration device.

Overview of figures in the drawings

The accompanying drawings show embodiments of an underground infiltration or retention module according to the invention, as well as constructional details of the infiltration or retention module itself. In FIG. 1 schematically shows a retention module system in a base cell consisting of two opposing retention modules. In FIG. 2 schematically shows the stacking of retention modules in a retention already extended module system consisting of two opposing but also mutually oriented retention modules. In FIG. 3 schematically shows the vertical insertion of the reinforcing tube into the reinforcing hole. In FIG. 4 schematically shows the filling of a vertically inserted reinforcing tube into the reinforcing hole in the retention module with gravel or aggregate. In FIG. 5 schematically shows a variant with five reinforcing tubes in a retention module. In FIG. 6 is a detailed view of the construction of the retention module in three elevations. In FIG. 7 is a detailed axonometric view of the construction of the retention module. In FIG. 8 shows an example of the passage of engineering networks through the module through the folded cover without the need for any disassembly of the module. In FIG. 9 shows a connecting coupling with a recess for better connecting of adjacent blocks - modules through cut-outs made in the middle.

Examples of embodiments of the invention

The individual embodiments of the invention are presented by way of illustration and not by way of limitation of the technical solutions. Those skilled in the art will find, or be able to ascertain using no more than routine experimentation, many equivalents to specific embodiments of the invention. Such equivalents will also fall within the scope of the following claims. For those skilled in the art, it cannot be a problem of optimal design, so these features have not been addressed in detail.

Example 1

In this example of a specific embodiment of the subject of the invention, the construction of the infiltration or retention module shown in FIG. 6 and 7. The infiltration or retention module 1 has a square shaped grate base 6, to which four edge walls 7 are connected. The infiltration or retention module 1 is a plastic molding. Each edge wall 7 comprises at least two recesses 8 and formed bridges 9 between adjacent recesses 8. In the lines of the bridges 9 from the grate base 6 of the infiltration or retention module 1, a set of struts 10 protrude at the ends by alternately fitted pins and openings. A set of connecting surfaces and / or cut-outs U is fitted around the circumference of the grate base 6 of the infiltration or retention module 1. The cut-outs 11 are located exactly in the middle of the module edges for straight (linear) holding the shape of the whole connected system.

Example 2

In this example of a particular embodiment of the invention, the construction of the infiltration or retention modular system shown in FIG. 2 to 4. The infiltration or retention modular system has a stack arrangement of infiltration or retention modules 1 with a shaped grate base 6. The stacking arrangement of infiltration or retention modules 1 forms mutually intersecting horizontal bridge or tube modules.

Λ *, · «« · · * Λ, · * ⁶ ; ·· · :. ^"· ·: ···» · et <· · · "channel 2. In this case, the stack arrangement of the acquisition or retention modules 1 in vertical direction and comprises a set of monitoring holes stiffener 3 to the strengthening of the system of the holes 3 in the stacked configuration of the acquisition, or of the retention modules 1, the vertically inserted reinforcing tubes 4 are filled with a load mass 5, for example aggregate. When mounting the infiltration or retention modules 1 at the ends of the struts 10, the alternately located pins and openings engage, thus forming a firm and at the same time detachable connection of the two infiltration or retention modules L. In the center of the grate base 6, a circular strut 10 is erected with side openings for the camera entrance, and at the same time this circular strut 10 serves to insert the reinforcing tube 4. To connect adjacent infiltration or retention modules 1, connecting cut-outs 11 are used to connect couplings and grooved surfaces for wedging the alternative clip connection. The connecting connectors 12 are designed so that there is a bridge in the middle of them for easier connection of two adjacent modules. Due to the precise holding of the system shape on each edge of the module, the connecting cut-outs H are located exactly in the middle of the edge of the module as shown in FIG. 8 and 9.

Industrial applicability

The infiltration or retention module system is designed for infiltration of rainwater into the subsoil. Once built into the ground, it is wrapped in geotextile, connected to a water supply and backfilled. The individual blocks of the required height are placed on a level surface and connected to each other with connectors in a predetermined square shape. Additionally, the static load capacity of the device can be increased and the cable or sewer can be routed through the device at any time by inserting a protective cover.

Claims (7)

PATENT CLAIMS Infiltration or retention module system with a stack arrangement of infiltration or retention modules with a shaped grate base, characterized in that in the stack arrangement and multiple arrangement of infiltration or retention modules (1) side by side with recesses (8) in the edge walls (7) these recesses (8) form mutually intersecting horizontal bridge or tube channels (2) over the entire length and width of the infiltration or retention modules (1), the stack arrangement of the infiltration or retention modules (1) in the vertical direction comprising a set of monitoring or reinforcement openings (3). Infiltration or retention module system according to Claim 1, characterized in that a reinforcement tube (4) is inserted vertically into at least part of the set of reinforcement openings (3) in the stack arrangement of infiltration or retention modules (1). Infiltration or retention module system according to claims 1 and 2, characterized in that the vertically inserted reinforcement tube (4) is filled into the at least part of the set of reinforcement openings (3) in the stack arrangement of infiltration or retention modules (1) by a load mass (5). ). Infiltration or retention module system according to at least one of Claims 1 to 3, characterized in that the infiltration or retention module (1) with a square or rectangular shaped grate base (6) consists of adjoining edge walls (7) with at least two recesses. (8) on each edge wall (7) and formed bridges (9) between adjacent recesses (8). Infiltration or retention module system according to at least one of Claims 1 to 4, characterized in that in the bridging lines (9) from the grate base (6) of the infiltration or retention module (1) a set of struts (10) protrudes at the ends alternately pins and holes. Infiltration or retention module system according to at least one of Claims 1 to 5, characterized in that a system of connecting surfaces and / or cut-outs (11) is fitted around the circumference of the grate base (6) of the infiltration or retention module (1), at least one face or cut-out (11) on each side is located exactly in the middle of the edge of the grate base (6). Infiltration or retention module system according to at least one of Claims 1 to 6, characterized in that connecting connectors (12) are inserted into the cut-outs (11) arranged around the circumferences of the grate bases (6) of adjacent infiltration or retention modules (1) with central bridge.