LT5582B - Filter tube - Google Patents

Abstract

The invention relates to a filter tube, especially for drainage of water-carrying soils/soil layers. The filter tube comprises at least three sections (10, 26, 12) which are located in succession in the direction of the lengthwise axis (L) of the filter tube, specifically: a first end section (10) with a coupling part (18) for direct or indirect connection to another tilter tube or well tube, at least one tilter section (26) with at least one filter part (25) which has permeability to water in the radial direction of the filter tube, a second end section (12) with a coupling part (18) for direct or indirect connection to a filter tube or well tube.

Description

Technical field

FIELD OF THE INVENTION The present invention relates to water collection and distribution devices, and more particularly to a filter tube, especially for drainage of water-bearing soil / soil layers.

State of the art

Common filter tubes are perforated or notched plastic or steel. The ends of adjacent filter tubes are screwed to each other, for example by means of a corresponding thread. Such a well filter is described in U.S. Patent No. 1,997,718 (A). In order to drain the soil / soil layers they are located in the well area near the wells. Separate filter pipes can also be installed in line with conventional manhole pipes or inside a conventional pipeline (for example, drainage or tunnel drainage). The use is similar to a pump manhole.

The wells are drilled to a certain depth and therefore a large number of filter tubes are connected to each other. Therefore, the tensile force increases for each tube. Installed lowered pipes must be able to handle high tensile loads; this cannot often be achieved with threaded joints.

Also known in the art are gravel compound filters. A manhole filter tube so prepared is described in DE 1786014 (Al). They are made by mixing gravel with epoxy resin and covering the entire outer peripheral surface of the filter tubes. The connecting element partially connects the gravel so that the radial permeability to groundwater in the filter tubes increases.

The problem in this case is that the composition of the gravel (grains) must match the holes in the filter tube and the soil surrounding it.

Filter tubes are used in lignite mining. Lignite deposits in West Germany contain up to 50% water, so very large amounts of water must be pumped out before lignite mining. Open pit shafts drainage, these sites are equipped with many drilled wells. Well orifice wells with filter tubes are installed in the well bores.

The essence of the invention

It is an object of the present invention to provide a filter tube with a high tensile strength limit and to provide a simple tube with the desired water permeability.

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The present invention provides a filter tube particularly suited for use in well construction for drainage of soil / soil layers, such as lignite deposits or tunnels, is easy to install, well drained and has a high tensile strength.

This filter tube has at least three sections arranged in series along the axis of the filter tube, specifically:

- a front end section with connection piece for direct or indirect connection with another filter pipe or manhole pipe,

- at least one filter section with at least one filter section having a water permeability, radially in the direction of the filter tube,

- a second end section with connection portion for direct or indirect communication with the filter tube or manhole tube.

The end sections of the filter tube have a connection with another filter tube, due to the respective connection part. The filter section between the end sections is used for drainage.

The end sections, which are usually waterproof, can be made of a material with a high tensile strength limit. FIELD OF THE INVENTION The present invention relates to glass fiber reinforced plastics, in particular duroplastics, of the following group: unsaturated polyesters, epoxides, vinyl esters, polyurethanes in a proportion from 5 to 50 (5-15; 30-50)% by weight of the glass fibers from 5 to 75 ( 25-50) mm and average diameter (dso) from 8 to 20 (10-14) microns (Possible alternative limits are given in parentheses).

In order to make the entire filter tube with a high tensile strength limit, there must be at least one filter section with a plurality of rod-shaped elements arranged parallel to the filter tube axis and each having a tensile strength limit of> 50 MPa (e.g.> 100 or> 250 MPa with a characteristic upper limit of 300 MPa or 280 MPa). Watertight portions of the filter are located adjacent to or between these rod-shaped elements. These parts of the filter must have adequate force, in particular the pre-bending pressure obtained by suction on a conveyor pump in the well. Rod shaped elements are most responsible for the strength, especially the tensile strength limit.

The filter tube with the filter part is of the cage type.

In order to produce a uniform volume of the filter tube and to achieve uniformly distributed mechanical loads, the rod-shaped elements may be distributed in a symmetrically variable manner along the axis of the filter tube.

As a result, it is proposed that these filter parts be made curved to the shape of the filter tube cylinder. Each part of the filter then has a cylindrical segment. Alternatively, the filter portion may protrude radially outwardly above the rod-shaped elements (tie rods). This may be, for example, cylindrical on the peripheral side, whereby the compound may be used to cover rod-shaped elements.

But it is also possible to wrap individual parts of the filter between rod-shaped elements.

The filter portions between the rod-shaped elements may be arranged in a symmetrically variable longitudinal axis of the filter tube, particularly in the form of strips extending parallel to the longitudinal axis of the filter tube.

The parts of the filter (between the rod-shaped elements) can be made identical. But the basis of the invention is to make different parts of the filter. For example, it may be useful, depending on the application, to produce a part of the filter with different porosity or leakage, or different size capillaries for water to pass through. The specific soil properties can then be taken into account to drain, for example, clayey soil with a uniform particle size or coarse-grained soil material.

The rod-shaped elements according to their shape are securely fixed to the filter tube sections which are connected along the filter tube through the rod-shaped elements. For example, rod-shaped elements may be anchored. Suitable coupling members include epoxy resin coupling and methyl acrylic coupling. It is also possible to process the finished pipe by cutting the spaces between the rod-shaped elements so that the entire main body corresponds to the shape of the filter pipe.

In most cases, the filter tube consists of only three sections (two end sections and a filter section). In this case, the rod-shaped elements can be mounted directly on the end sections of the filter tube.

For this purpose, the rod-shaped elements may be connected to the respective sections of the filter tube in different ways, for example by connection or welding. Connection / fixing is possible using screws, anchors, clamps and 1.1.

In one embodiment, zones are provided where the end sections are adjacent to the filter section with axial incisions that are open in the axial direction and in which respective end sections of rod-shaped elements are inserted and secured as described above. The rod-shaped elements may terminate flush with the outer peripheral surface of the end sections. In this case, the outer diameter of the filter tube in the rear section is equal to the outer diameter of the filter tube in the filter section.

However, rod-shaped elements can also protrude inward or outward.

The high tensile strength values of rod-shaped elements depend, for example, on rigid plastics, which are reinforced with fiber, in particular fiberglass, unsaturated polyester, epoxy, vinyl esters. Thermoplastic materials such as polyethylene, polypropylene or polyamide may also be used. They may consist of the same material as the end sections.

The filter portions between the rod-shaped elements may be composed of a piece material, the individual pieces of the piece material being connected by a connector with certain water permeability parameters.

The thickness of the filter portion in the radial direction between adjacent rod-shaped elements may be the same thickness as the rod-shaped element; the filter parts may also protrude inward or outward.

The piece material is composed, for example, of at least one of the following materials: quartz, fused quartz, CaCCb, dolomite, granite, broken glass, broken clay. The size of the piece material may be selected depending on the application. This is, for example, between 1-10 or between 1-7 mm.

Other possible cut sizes are 2 and 5 mm, for example between 3 and 5 mm.

Pieces of the piece material are bonded together, for example, with artificial resin (epoxy resin or strong plastic resin). The proportions of the connector are chosen to provide the desired water permeability. As a result, the surface of the pieces is only wetted so that the openings remain open-holes.

The total porosity of the filter portion may be, for example, between 10 and 70%, for example between 20 and 50%, or between 25 and 40%.

There is another option for determining open porosity: there is a certain geometry of the test piece (for example, cube / cube) and a certain size of the test piece (VI). This value (VI) is within the proportion of size (V2) obtained when the test body is completely immersed in water under atmospheric pressure [open porosity = (V1-V2) 100 / Vlj.

The mechanical properties of the filter part can be determined by bending tests according to

ISO 178. Corresponding values should be between 2 and 10 MPa, usually between 3 and

MPa.

Description of the drawings

The following figures are presented.

FIG. Figure 1 shows a partially finished product used for making a filter tube.

FIG. 2 shows a tool for applying a filter layer to a partially finished product shown in FIG. 1.

The partially finished product is shown in FIG. 1 consisting of a first end section 10 made of fiberglass reinforced plastic, a second end section 12 made of the same material and rod-shaped members 14 which connect the end sections 10 and 12. To this end, the rod-shaped members 14 are secured by attaching the end sections 10, 12. The end sections 10, 12 have a common longitudinal axis L. The rod-shaped members 14 run parallel to this longitudinal axis L. Each end section 10, 12 has a peripheral circumferential groove 18, which forms a part of the joint, near the free end.

FIG. 2 shows a tool 20 having a substantially cylindrical portion. Inside is a cylindrical cavity of two different widths. The lower portion 20u is smaller in diameter than the upper portion 20o.

FIG. In the position shown in Fig. 2, the height of the lower section 20u corresponds to the length of the 10 or 12 axes of the rear sections. In other words, the wider section 20o includes the area of the partially prepared article shown in Figs. 1 and consisting only of rod-shaped elements 14. The cylindrical movable (removable) core 22 is housed in a partially finished article and is positioned inside the rod-shaped elements 14 or end sections 10, 12. The circular cavity 24 is filled with grained piece material. The filter tube section formed from the piece material forms a filter portion 25 which, together with the rod-shaped elements 14, forms a real filter section 26.

The rod-shaped members 14 are made of the same fiberglass reinforced plastic as the end sections. All have a tensile strength of approximately 200 MPa (as determined by ISO 527).

The inner diameter of the lower portion 20u corresponds to the end sections 10 and 12 of FIGS. 1 outer diameter so that they can be evenly spaced into the appropriate section 20u.

The partially finished article with the second end section 12 protrudes above the tool 20.

The cavity between the partially prepared article and the inner wall 20i of the upper section 20o of the device 20 is filled with a grained piece of material based on grained fused silica, after mixing with 6% epoxy resin. This material is filled in a circular cavity 24, not only is there a space between the rod-shaped elements 14, but also a circular cavity 24.

Thus, the cavity is filled only where the rod-shaped element 14 is free, and where the grooves 16 are not filled with the mixture.

The tool 20 is then heated to secure the epoxy resin. The tool is then removed from the tool with a finished filter tube consisting of two end sections 10, 12, rod-shaped members 14 and a filter layer formed of a piece of material.

The filter tube section formed by the piece material forms a filter part 25 which together with the rod-shaped elements 14 forms a real filter section 26 which, depending on the particle size of the material and the amount of epoxy resin used, has different porosity (= water permeability) it is possible to direct water externally through the filter part 25.

Implementation of the invention

The invention is elaborated using one example.

One embodiment of the present invention, a filter tube, is described below.

Made from a known fiberglass reinforced plastic tube, for example, EP360758 A2 or CH684326 A5, these tubes are initially cut into sub-segments.

In each sub-segment, one end portion has recesses which are open to the free end of the rear section. These notches can be cut. Preferably, the distribution of the incisions is made uniformly (symmetrically in a circle) along the peripheral tube segment.

The two tube segments thus prepared are disposed on one axis at a distance from each other such that the end portions with the notches are spaced on different sides.

Thereafter, the rod-shaped elements, which may be composed of the same composite material of which the pipe segments are composed, are inserted into the respective end sections so that each rod-shaped element runs parallel to the axis of the pipe segments. The rod-shaped members are embedded into the respective notches by means of a coupling member based on epoxy resin (either polyisocyanate or acrylate). The profiles may also contain a combination of a fiberglass-resistant plastic resin, such as an epoxy resin.

In this way, the rod-shaped elements are formed into a cage-like cylindrical shape which, at a distance from one another, are complementary to an imaginary cylindrical peripheral surface.

The assembled element is then mounted on a cylindrical core, the outer diameter of the core being dependent on the inner diameter of the prefabricated component. In other words: the inner surfaces of the tube segments and the rod-shaped elements are substantially flush with the peripheral surface of the core. The connector consisting of the core and prefabricated component is then fed to a heated forming tool. The forming tool is approximately cylindrical with an internal diameter of two steps. The inside diameter of the closed lower end of the forming device depends on the outside diameter of the prefabricated component. This section is used to support the rear section of the component. The cover portion is larger in diameter so that a gap remains between the component and the molding unit. This annular space is then filled with a mixture of granular material and epoxy resin to form a filter section in the space between the end section of the component which is the component. In this joint, a mixture of grained material and resistant plastic resin material fills the area between adjacent bridge-shaped members. It is possible to make a circular cavity with a larger inside diameter so that the grained material also covers the rod-shaped elements.

It then heats the forming tool to harden the resin and connect the filter part. Then pull out the finished filter tube.

The resultant element consists of two closed watertight end sections and a filter part therebetween which is a rod-shaped element and a filter layer consisting of a piece of granular material. Pieces of grain material are partially bonded with epoxy resin, the amount corresponding to the coating size of the pieces, while the amount of epoxy resin used elsewhere is such as to maintain a defined permeability (open porosity) to the water. These are the spaces between the grains of the piece material, depending on the amount of resin.

As a final working step, a peripheral annular groove is formed in the rear section area, forming a single connection piece, each designed to connect adjacent filter tubes when laying. This groove could also have been prepared in advance.

One method of production is to assemble the sleeves of the filter, place it on the filter net of the specified rod-shaped elements and attach it.

In order to connect the two pipes, the ring is directed to the end section of the pipe to be connected, inside the ring there are circular recesses which are made according to the respective circumferential grooves of the end sections and extend at least in one place through the walls. Thanks to these apertures, connecting elements, such as a flexible rod of metal or plastic, cable or chain, may be used, the intersection sections approximately corresponding to the common intersections of the respective circular grooves of the filter tube and the ring end section.

Part of this connecting element is in the circumferential groove of the filter tube and the other part is in the circumferential groove of the other ring and both are completely joined to each other.

The advantage of this coupling technology is that the coupling is tensile and can be released again by removing the coupling.

The well system comprises one or more filter tubes, as mentioned in the description of the invention, which are lowered into water by transferring the soil layer. To increase the tensile strength, adjacent tubes are connected to each other as described in the description.

The filter tube described can be used analogously to a pump manhole.

Claims (15)

DEFINITION A filter tube for drainage comprising a perforated tube having a diverter having at least three sections (10, 26, 12) successively extending along the axis (L) of the filter tube, a first end section (10). a connecting part (18) for direct or indirect connection to another filter tube, at least one filter section with at least one filter part (25) having water permeability in the radial direction of the filter tube, the other end section (12) for direct or indirect connection; for indirect connection to a filter tube or a well tube. 2. A filter tube according to claim 1, wherein at least one end section (10, 12) is impermeable to water. 3. A filter tube according to claim 1, characterized in that at least one filter section (26) has a plurality of rod-shaped members (14) extending parallel to the longitudinal axis of the filter tube with a tensile strength greater than 50MPa, including a water-permeable filter portion. 25). 4. A filter tube according to claim 3, characterized in that the filter parts (25) are arranged symmetrically to the longitudinal axis of the filter tube. 5. A filter tube according to claim 3, characterized in that the filter portions (25) extend in strips parallel to the longitudinal axis of the filter tube. 6. A filter tube according to claim 3, characterized in that the rod-shaped elements (14) are connected to the filter-tube sections (10, 12) which are connected by rod-shaped elements (14) in the longitudinal direction (L) of the filter-tube. 7. A filter tube according to claim 3, characterized in that the rod-shaped elements (14) are connected to the filter-tube sections (10, 12) which are connected to the rod-shaped elements (14) in the longitudinal direction (L) of the filter-tube. 8. A filter tube according to claim 1, characterized in that the rod-shaped elements (14) consist of combined profiles of fiberglass-resistant glass-fiber epoxy. 9. A filter tube according to claim 1, characterized in that at least one part (25) of the filter consists of a grained piece of material, the grains of the piece material being interconnected to form a defined water permeability. 10. A filter tube as claimed in claim 8, wherein the lump material comprises at least one quartz material, fused quartz, CaCCb, dolomite, granite, disintegrated glass. 11. A filter tube according to claim 8, characterized in that the particle size is between 1 and 10 mm. 12. A filter tube according to claim 8, characterized in that the grains of the piece material are bonded to an artificial resin. 13. A filter tube as claimed in claim 1, wherein the filter portion (25) has an open porosity of between 10 and 70%. 14. A filter tube according to claim 1, wherein at least one end section (10, 12) is made of fiberglass reinforced plastic. 15. A filter tube according to claim 1, characterized in that the connecting part (18) has a circumferential groove on at least one end section (10, 12) extending on the peripheral surface.