DE3617471A1 - Preform made of concrete for dewatering structures - Google Patents

Abstract

In order to dewater structures, in particular in the field of underground construction, for example of cable ducts (19), a moulded brick (10) is used whose lower part (collection part 12) consists of water-tight concrete and whose upper part (filter part 11) consists of water-permeable concrete (light-grained concrete). The moulded brick (10) which is formed in this way is installed in the ground directly next to the structure which is to be kept free of water. <IMAGE>

Description

The invention relates to a molding made of concrete or the like Material for the drainage of structures in the Soil, the upper part of which is permeable to water Concrete (single-grain concrete) and its lower part made of waterproof Concrete is there.

Concrete pipes are known for the drainage of soil, the upper half (in the installed state) or Half-shell made of water-permeable concrete (single-grain concrete) and its lower half or half shell made of water-impermeable Concrete is there. Such pipes become Drainage purposes laid in the ground.  

The invention is primarily concerned with drainage of structures in the ground, especially with the Drainage of cable ducts, such as in Railway superstructure can be used. Beyond that also thought of the drainage of other structures, e.g. B. of sidewalk areas, garage facilities and parking spaces.

The invention has for its object, a particular fitting suitable for the above application propose that a higher stability and a greater safety in the installed state against displacement has than the known drainage pipes.

To achieve this object, the molding according to the invention characterized by training as a shaped stone with polygonal cross-section and molded (round) Flow channel.

The fitting according to the invention is therefore an elongated one Shaped stone with a rectangular cross-section in particular. Depending on the area of application, the length can be about 100 cm, the width between 10 and 20 cm and the height up to 40 cm, especially for dewatering the Soil in the area of cable ducts.

The shaped block according to the invention therefore consists of a upper part made of water-permeable concrete (single-grain concrete) - hereinafter referred to as the filter part - and a lower one Part made of waterproof concrete - hereinafter as a collecting part designated. Filter part and collecting part form an integral, one-piece unit (molded stone). A boundary layer between Filter part and collecting part is expedient formed obliquely, namely funnel-shaped towards Flow channel descending. The proportions are preferred chosen so that the lower collecting part is less Construction height has than the filter part, in particular the ratio is about 1: 3.  

According to a particular embodiment of the invention the flow channel through an embedded in the stone Pipe or partial pipe formed. Are particularly suitable Plastic pipes, e.g. B. PVC. That the flow channel forming tube is in the upper area or in the upper Half of cross section water-permeable, preferably by arranging holes, slots or other Water passage openings in the pipe jacket. Alternatively can also be a partial pipe, e.g. B. a pipe half, only in the area of the collecting part to limit the flow channel embedded in the lower half of the cross-section be. The pipe acts as "lost formwork".

The shaped stones formed in the sense of the invention come preferably for securing channels, especially cable channels, against water ingress. For railway superstructures are often cable ducts next to the ballast bed relocated. The shaped stones according to the invention are to secure these cable ducts against water ingress immediately next to the same, especially under annex one side wall, laid, one after the other and connecting the flow channels with each other. Because of of slope of the floor surface occurs (surface) Water into the shaped stones and is drained through them, before it gets to the cable duct.

Further features of the invention relate to the configuration the shaped stones, their connection with each other and the Installation of the same.

Embodiments and forms of application of the invention are explained below with reference to the drawings. Show it:

Fig. 1 shows a shape for drainage purposes, in vertical section,

Fig. 2 shows another embodiment of a fitting, also in vertical section,

Fig. 3 shows a longitudinal section III-III to the mold piece of Fig. 2,

Fig. 4 is a molded piece in the installed state in cross section,

Fig. 5 shows a further embodiment of a fitting in the application similar to Fig. 4, also in cross section,

Fig. 6 shows a longitudinal section through successive form pieces having interconnecting flow channels,

Fig. 7 is a longitudinal section through successive fittings with an alternative connection of the flow channels, and

Fig. 8 is a detail VIII of FIG. 7 in the region of the connection of the flow channels of adjacent molded blocks in an enlarged scale.

The described embodiments of fittings serve in general for the drainage of buildings in the Civil engineering, with fittings on the water-carrying side of the building in question are arranged such that the water, especially surface water, cannot approach the structure.

For this purpose, the shaped pieces are designed as shaped stones 10 with a polygonal, in particular rectangular or trapezoidal cross-section.

In a simple embodiment of the shaped block 10 according to FIG. 1, it is rectangular in cross section. An upper part of the shaped block, namely a filter part 11 , is permeable to water, namely it consists in particular of single-grain concrete. A lower part serves to receive and drain the collected water, namely a collecting part 12 made of water-impermeable concrete. Filter part 11 and collecting part 12 form a one-piece, integral molded block 10 . In the area of an interface 13 , filter part 11 and collecting part 12 , that is to say concrete of different structure, adjoin one another. A flow channel 14 is formed in the vertical longitudinal center plane, preferably with a round or circular cross section. The flow channel 14 lies in the area of the interface 13 , preferably centrally to this. As further shown, in this exemplary embodiment the interfaces 13 are formed on both sides of the flow channel 14 in a funnel shape, so that the water supplied through the filter part 11 is conducted into the flow channel 14 . This conveys the water in the longitudinal direction. The filter part 11 has a greater structural height than the collecting part 12 . The ratio is about 3: 1. As a result, the flow channel 14 is also in the lower third of the cross section.

The shaped block 10 according to FIG. 2 is basically designed in a similar manner. A side surface 15 facing away from the building to be drained is provided with a bevel 16 in the upper region, namely in the filter part 11 . The shaped block 10 thereby has a trapezoidal cross section. The bevel 16 enlarges the outer surface of the shaped block 10 available for the absorption of water or places it in a more favorable position relative to the water that flows in essentially from above.

A further special feature of this shaped block 10 is that the flow channel 14 is formed within a tube 17 which is embedded in the shaped block 10 in the region of the interface 13 . The tube is preferably made of plastic, e.g. B. PVC. For the inflow of water into the flow channel 14 , the tube 17 is water-permeable in the upper cross-sectional area surrounded by the filter part 11 . In the exemplary embodiment shown, water passage openings, namely slits 18, are formed in the tube jacket in the upper cross-sectional area. A particularly smooth and powerful flow channel 14 is generated by the embedded pipe 17 . The slots 18 can be suitably distributed in the jacket of the tube 17 , for. B. with offset in the longitudinal direction ( Fig. 3).

FIGS. 4 and 5 show a preferred embodiment of the invention, namely the protection of built-in into the ground channels, in this case a cable channel 19, against water ingress. The cable duct 19 itself can also consist of concrete moldings which are placed against one another in the longitudinal direction. In the exemplary embodiments shown, this cable duct 19 is laid flush with the ground surface 20 in the superstructure (dam) of a railway line. The cable duct 19 runs next to a ballast bed 21 . As shown, the molded block 10 for receiving (surface) water is installed in the area between the ballast bed 21 and the cable duct 19 , namely by abutting against a side wall 22 of the cable duct 19 . The arrangement is also such that the shaped block 10 - like the cable duct 19 - is flush with the ground surface 20 . The height of the shaped block 10 corresponds to that of the cable duct 19 . The ground surface 20 , as is customary in railway superstructures, has a slight slope away from the ballast bed 21 to the edge of the dam. Surface water in the area between ballast bed 21 and cable duct 19 is largely absorbed by the molded block 10 or its filter part 11 and drained downward into the flow duct 14 . The cable duct 19 is thereby protected against water ingress.

In the embodiment according to FIG. 5, molded blocks 10 of lower structural height are installed in a partial area of the cable duct 19 , namely in the area of a cable connection 23 in the area of the side wall 22 . The shaped block 10 has a height in this area such that the cable outlet 23 is exposed.

The shaped blocks 10 are put together in the longitudinal direction to form a continuous drainage system and connected to one another ( FIG. 6). For this purpose, end faces 24 and 25 of the shaped blocks 10 are provided with projections and depressions which engage in a form-fitting manner in the installed state. In the illustrated embodiment, one end face 24 is provided with a trapezoidal depression 26 and the opposite end face 25 is provided with a correspondingly designed projection 27 .

Additionally or alternatively, the shaped blocks 10 are connected to one another in the region of the flow channel 14 . Correspondingly dimensioned connecting pipe pieces 28 made of plastic, in particular hard PVC, are inserted into the ends of the flow channels 14 of the adjacent shaped blocks 10 . These not only effect a continuous flow channel 14 , but also secure the shaped blocks 10 in their relative position to one another. This embodiment is particularly advantageous if - as shown in FIG. 6 - the flow channel 14 is formed by a tube 17 . In this case, the connecting pipe pieces 28 enter the end regions of the adjoining pipes 17 of the adjacent shaped blocks 10 .

Another possibility of connecting the shaped blocks to one another in the region of the flow channel 14 is shown in FIGS. 7 and 8. This is about the connection of shaped stones 10 which - as shown in FIGS. 1, 4 and 5 - do not have a continuous tube 17 for forming the flow channel 14 . In this case, the connecting tube piece 35 is inserted into two opposite end pieces 31 , which are embedded in the regions of the end faces 24 , 25 of the shaped blocks 10 .

Such a (short) end piece 31 is assigned to each end face 24 or 25 of the shaped blocks 10 . The end pieces 31 accordingly form the inner wall of short end regions of the flow channel 14 . The end pieces 31 are equally formed in that they consist essentially of a PVC pipe section. The ends of the end pieces 31 directed towards the end faces 24 , 25 of the shaped blocks 10 each have a circumferential (cylindrical) collar 32 which protrudes from the outside diameter thereof. The end pieces 31 are embedded so deeply in the shaped blocks 10 that the free end faces of the collars 32 are approximately flush with the end faces 24 and 25, respectively. The (inner) ends of the end pieces 31 opposite the collar 32 likewise have a collar-shaped end end, namely a circumferential stop 34 with cylindrical openings which projects into the inside of the end pieces 31 . The inside diameter of the stops 34 is dimensioned such that it corresponds approximately to the inside diameter of the connecting tube piece 35 inserted into two end pieces 31 . Finally, the end pieces 31 have an approximately centrally arranged locking ring 33 which protrudes outward from the outer surface of the casing and preferably rotates continuously. It serves to prevent the end pieces 31 from being pulled out of the flow channel 14 of the shaped blocks 10 . Alternatively, a plurality of such locking rings 33 can also be arranged at a distance from one another on the outer circumference of the end pieces 31 .

The connecting pipe section 35 consists of a simple cylindrical PVC pipe, which is dimensioned in length such that it bridges two end pieces 31 of opposing shaped stones 10 , that is to say the outer diameter corresponds approximately to the inner diameter of the end pieces 31 and is slightly shorter than two end pieces 31 minus the end stops 34 is. The stops 34 on the end pieces 31 prevent the connecting pipe piece 35 from pushing out of the area of the end pieces 31 when the molded blocks 10 are pushed together into the flow channel 14 .

The water absorbed and discharged in the flow channel 14 is led into the underground. For this purpose, individual shaped blocks 10 arranged at a greater distance from one another are provided with a channel branch 29 which is directed into the ground, in particular downwards. In the case of the shaped block 10 provided with a pipe 17 for forming the flow channel 14 , this expediently consists of a pipe socket 30 which is embedded in the shaped part 10 in the region of the collecting part 12 , specifically in connection with the flow channel 14 ( FIG. 6).

In the case of a molded block 10 provided only in the areas of the end faces 24 and 25 with end pieces 31 in the flow channels 14 , the channel branch 29 can be molded directly into the collecting part 12 , that is to say it does not have a pipe socket 30 ( FIG. 7).

The shaped block 10 according to the invention is characterized by high resilience, easy installation and above all by a high degree of water absorption.

• 10 Shaped stone
  11 filter part
  12 collecting part
  13 interface
  14 flow channel
  15 side surface
  16 bevel
  17 pipe
  18 slot
  19 cable duct
  20 soil surface
  21 ballast bed
  22 side wall
  23 cable outlet
  24 end face
  25 end face
  26 deepening
  27 head start
  28 connecting pipe piece
  29 channel branch
  30 pipe sockets
  31 end piece
  32 collar
  33 circlip
  34 stop
  35 connecting pipe piece

Claims (21)

1.Fitting made of concrete or similar material for the drainage of structures in the ground, the upper part of which is made of water-permeable concrete (single-grain concrete) and the lower part of which is made of waterproof concrete, characterized by the formation as a molded block ( 10 ) with a polygonal cross section and molded (round) flow channel ( 14 ). 2. Fitting according to claim 1, characterized due to an approximately rectangular cross-section with a larger one Height as width.   3. Molding according to claim 1 or 2, characterized in that the flow channel ( 14 ) below a (imaginary) horizontal central plane of the shaped block ( 11 ) in the region of an interface ( 13 ) between an upper, water-permeable filter part ( 11 ) and a lower, water-impermeable collecting part ( 12 ) is arranged, in particular in the lower third of the cross section of the shaped block ( 10 ). 4. Molding according to claim 1 and one or more of the further claims, characterized in that the interface ( 13 ) between the filter part ( 11 ) and the collecting part ( 12 ) to the flow channel ( 14 ) is formed funnel-shaped. 5. Molding according to claim 1 and one or more of the further claims, characterized in that the shaped block ( 10 ) is designed as a one-piece, integral unit. 6. Fitting according to claim 1 and one or more of the further claims, characterized in that in the region of the collecting part ( 12 ) a downwardly or laterally directed channel branch ( 19 ) is integrally formed on the flow channel ( 14 ), in particular in the shaped block ( 10 ) embedded (plastic) pipe socket ( 30 ) opening into the flow channel ( 14 ). 7. Molding according to claim 1 and one or more of the further claims, characterized in that the shaped block ( 10 ) in the region of the filter part ( 11 ) or in the upper region thereof is formed with an upwardly decreasing cross-section, in particular with a bevel ( 16 ). 8. Molding according to claim 1 and one or more of the further claims, characterized by the arrangement (system) immediately to the side next to or on a structure to be protected against water ingress, in particular on at least one side of a (cable) channel ( 19 ). 9. fitting according to claim 8, characterized by the same height as the building to be protected (cable duct 19 ). 10. Fitting according to claim 8 or 9, characterized by flush termination of the top of the shaped block ( 10 ) with the structure to be protected or with the soil (surface 20 of the earth). 11. Fitting according to claim 8 and one or more of the further claims, characterized by the arrangement of consecutive and consecutive shaped blocks ( 10 ) in the longitudinal direction between a cable duct ( 19 ) and a ballast board ( 21 ) of a railway superstructure. 12. Molding according to claim 1, as well as one or more of the further claims, characterized in that adjacent end faces ( 24 , 25 ) of the shaped blocks ( 10 ) are formed with matingly engaging projections ( 27 ) and depressions ( 26 ), in particular with a trapezoidal projection ( 27 ) and corresponding recess ( 20 ). 13. Molding according to claim 1 and one or more of the further claims, characterized in that the (round) flow channel ( 14 ) in the regions of the end faces ( 24 , 25 ) has molded end pieces ( 31 ), in particular made of hard PVC. 14. Fitting according to claim 13, characterized in that the end pieces ( 31 ) correspond in their inner diameter approximately to the inner diameter of the flow channel ( 14 ). 15. Fitting according to claim 13 and 14, characterized in that the end pieces ( 31 ) on the outer circumference protruding locking members, in particular a flush with the end faces ( 24 and 25 ), surrounding collar ( 32 ) and / or at least one at a distance from Have collars ( 32 ) arranged on the outer circumference, circumferential locking ring ( 23 ). 16. Fitting according to claim 13 and one or more of the further claims, characterized in that the end pieces ( 31 ) have at their mutually facing (inner) ends an over the inner diameter (inward) outstanding stop ( 34 ). 17. Fitting according to claim 13 and one or more of the further claims, characterized in that in the longitudinal direction adjoining shaped blocks ( 10 ) by a in two adjacent end pieces ( 31 ) inserted, dimensionally stable connecting pipe piece ( 35 ), in particular made of hard PVC, with each other are connected, the connecting tube piece ( 35 ) being designed to correspond to the end pieces ( 31 ) arranged in the flow channels ( 14 ). 18. Fitting according to claim 17, characterized in that the length of the connecting pipe piece ( 35 ) is slightly less than the length of two end pieces ( 31 ) minus the width of both stops ( 34 ). 19. Molding according to claim 1 and one or more of the further claims, characterized in that the flow channel ( 14 ) is formed by a (cylindrical) tube ( 17 ) embedded in the shaped block ( 10 ), which is at least in one of the filter part ( 11 ) surrounding cross-sectional area is water-permeable. 20. Fitting according to claim 19, characterized in that the flow cross section is formed by a tube ( 17 ) embedded in the molded block ( 10 ) made of plastic, in particular PBV, which is provided in the upper cross-sectional area with recesses for the passage of water, in particular with slots ( 18 ) extending in the longitudinal direction of the tube ( 17 ). 21. Fitting according to claim 19 and one or more of the further claims, characterized in that in the longitudinal direction adjoining shaped blocks ( 10 ) by dimensionally stable connecting pipe pieces ( 28 ), in particular made of hard PVC, are connected to one another, the connecting pipe pieces ( 28 ) in the flow channels ( 14 ) of adjacent shaped stones ( 10 ) enter appropriately.