DE3523218A1 - Well filter pipe and process for the production thereof - Google Patents

Abstract

In a well filter pipe, the actual filter tube section 3 is configured as a jacketed filter. It is composed of metal sheet tubing 5, furnished on its periphery at least over the major part of its length with wall perforations 4, and tubing 6 arranged concentrically thereto, made of helically coiled wire having a clearance 8 between the neighbouring windings 7. It is important in this case that the wire coil tubing 6 is inserted under elastic prestress radially and axially into the metal sheet tubing 5 and is expanded against its interior circumference and that at least the two ends of each wire coil are fixed against stops 9 on the metal sheet tubing (Fig. 2). <IMAGE>

Description

The invention relates to a well filter tube with double jacket filter, consisting of one on its circumference and at least for most of its length with wall perforated sheet metal tube body and a concentrically arranged tubular body helically wound wire with gap between two adjacent turns.

The invention also relates to a method for Manufacture of such filter tubes.

There are already well filter tubes with double jacket filters this genus is known, such as this from the manual "Schaubstahl filter tubes", pages 86 and 87. Here are the helically wound flat wire with gap between the adjacent turns formed tubular body stabilized in that the one individual turns of the wire winding in their position by a Large number of axially parallel connecting rods fixed who those who are fixed inside by resistance welding the.

These consist of a wire coil and a variety of lengthways running connecting rods formed gap filter Tubular bodies are coaxial on the outer circumference of the with the Metal sheet tubular body provided with wall openings  pushed, the axially parallel connecting rods Support pads for the gap filter tube body on the Me Form tallblech-tubular body and for the purpose of Lagensi at least partially welded to it can be.

Such double-jacketed well filter tubes not only have a significantly greater resistance to the Pressure of the surrounding earth as that also known well filter tubes with the so-called slot bridge perforation, but there is also one improved filter effect through the use of the gap filter tube body.

However, it is obvious that the well-known Doppelman tel well filter tubes due to their system-related con structure require considerable manufacturing effort and consequently also considerable procurement costs causes.

The invention has for its object for a fountain filter tube of the type specified at the beginning Specify training that is while maintaining the be standing advantages - high resilience and good Filter effect - with considerably reduced manufacturing effort can be realized and therefore accordingly low lower production costs.

An inventive well filter tube, which is the solution serves this task is characterized according to claim 1 records that the wire winding radially and axially under ela static prestress standing in the sheet metal tube body used and spread against its inner circumference and that at least the two ends of each wire winder against stops on the sheet metal tubular body sets are.  

This inventive design of a well filter rohres not only has the advantage that the previously in re relatively large number of axially parallel connections required Extension rods for stabilizing and fixing the wire rope kels and the resulting one Large number of welds is avoided. Rather is it also no longer needs a given wrap diameter for the individual turns of the wire winding to be followed exactly.

However, the absence of the axially parallely has an advantageous effect select connecting rods, namely insofar as the in Radial direction against the inner circumference of the sheet metal tube body spread turns of the wire winding on the entire circumference evenly and continuously to the support system come and therefore the resilience of the well fil against the pressure of the soil. In addition, the gaps are between each Wire winding turns completely within the perimeter area of the sheet metal tube body and are so on lower the well filter tube into the well bore against clogging by the grains of the pouring fill or of the grown soil.

According to the further developing inventive feature of claim 2 it is intended that the stops for the ends of each wire at least over limited circumferential sections of the sheet metal tube body and each extend the tube inner facing support surfaces for the ends of the wire have winding.

According to claim 3, these stops can either be turned on set arched strips or consist of rings.  According to claim 4, however, the possibility is also provided that the stops of circumferential indentations of the sheet metal Tube body itself are formed.

Training has proven particularly useful according to the invention the well filter tube, in which according to claim 5 several Wire coils of limited axial length in a row the sheet metal tubular body inserted and their ends each supported or fixed on intermediate spacer rings are. For example, the use of wire wrapping is recommended, each with a winding length of 500 mm, that in a well filter tube of, for example, 6000 mm in length Within the metal sheet tube body twelve identical wires be placed one behind the other and then through this stabilize their radial preload considerably.

The use of wire wrapping has been recommended proven value, where the gap distance between neighboring beard turns at least 0.5 mm and at most 4 mm carries, while wire cross sections are used that are at least 3 mm in diameter or side length but are also preferably larger.

In a further embodiment of the inventive concept is after Claim 6 provided that the individual turns of the or the wire winding with the sheet metal tubular body in at least ver two diametrically opposite circumferential areas welded or soldered. According to claim 7 the welding points on two axes for the sake of simplicity parallel lines and each one of them preferred be provided at the edge of a wall opening.

According to claim 8, however, there is also the possibility concluded that the welds of two continuous, axially parallel resistance welds are formed, the  preferably along a wall free of perforations section of the sheet metal tubular body.

The utility value of filter tubes according to the invention can be also optimize in that according to claim 9 each end of the or all wire wrapping with the wall of the sheet metal Pipe body is welded firmly.

But it is also recommended if according to the teaching of claim 10 of the sheet metal tubular body as a wall has only round or slot perforations, because these are much easier to manufacture than that so-called slot bridge perforations, blind perforations or the like.

According to claim 11 it is also provided that the round or slot perforations both in the longitudinal direction and in Circumferential direction lie in rows and on the sheet metal tube continuous wall areas between these rows of holes are formed so that the sheet metal tubular body both in the longitudinal as well as in the circumferential direction, not has perforated areas, although with a possible large proportion of perforations is provided.

For the production of well filter tubes with double jackets filter - with one with its scope and at least Wall perforations over most of its length Send sheet metal tube body unscrew a tube body shaped wire with gap between the be neighboring turns is connected is according to the invention provided in terms of process technology according to claim 12, that the wire winding is initially radially and axially inwards under elastic preload, then in the sheet metal Tube body inserted axially and finally in its inserted end position is released radially and axially.  

A particularly simple production of well filter tubes is with high side pressure stability in this way guaranteed.

Further features and advantages of the invention will follow explained in detail using a drawing. It demonstrate

Fig. 1 in a schematically simplified side view of a portion of a well filter tube,

Fig. 2 on a larger scale the marked in Fig. 1 with II subsection of a well filter tube, half in section and half in side view and

Fig. 3 in side view of the longitudinal section of the well filter tube according to Fig. 2, wherein the sheet metal tube body and the associated wire winding tube body can be seen by at the beginning of their assembly.

In Fig. 1 of the drawing, the upper end section of a well filter tube 1 is shown in a purely schematic representation, which comprises a sleeve 2 and the actual filter body 3 .

In Fig. 2 it can be seen that the actual filter tube section from 3 of the well filter tube 1 is designed as a so-called double jacket filter, which consists of a on its circumference and at least over most of its length with wall openings 4 , for example round holes or slots , Provided sheet metal tubular body 5 and a concentrically arranged tubular body 6 , which consists of helically wound wire and in which a gap 8 remains free between the individual wire windings 7 . Since the tubular body 6 designed as a wire winding extends over the entire length of the sheet metal tubular body 5 , the gap distance 8 remaining between the individual windings 7 accordingly extends helically over the entire length of the tubular body 6 .

From Fig. 2 it is clear that the wire winding tube body 6 is axially inserted into the sheet metal tube body 5 . He is under radial and axial tension before elastic. This ensures that the wire-wound tubular body 6 spreads against the inner circumference of the sheet metal Rohrkör pers 5 , so that he lies firmly against it and the sheet metal tubular body 5 stabilizes considerably from the inside. It is important that the two ends of each wire winding of the wire-wound tubular body 6 can be set against stops on the sheet metal tubular body 5 , some of which are indicated in FIG. 2. These stops 9 should extend at least over limited circumferential sections of the tall sheet metal tubular body and each have the support surfaces facing the inside of the tube for the ends of the wire winding. These stops 9 can consist of inserted bogenför shaped strips or rings, but they can also be formed by circumferential impressions in the metal sheet tube body 5 .

Since the well filter tubes 1 regularly have a greater length, for example of 6000 mm, it is possible, but not recommended, to form the wire winding tube body 6 by means of a single wire winding of corresponding length. Rather, the wire winding jacket 6 should be formed by a plurality of wire coils of limited axial length, which are inserted one behind the other into the sheet metal tubular body 5 , both ends of the wire forming them being supported or fixed on spacer rings between them as stops 9 .

The individual wire coils can have a length of 500 mm, for example, so that twelve individual wire coils can be inserted one after the other into the metal sheet-tube body 5 for a well filter tube 1 of 6000 mm in length to form the wire-winding jacket 6 .

It is advisable to firmly weld or solder the individual turns 7 of the or each wire winding to the sheet metal tubular body in at least two diametrically opposite circumferential areas. It is advisable to provide the welds lying on at least two axially parallel lines and preferably to provide each one of them at the edge of a wall opening 4 .

On the other hand, these welds can also be formed as two continuous, axially parallel resistance welded seams, which should then preferably run along a wall section of the sheet metal tubular body free of openings 4 .

Although it is sufficient in most cases that the ends of the wire windings 7 of the or all of the wire windings are supported against the stops 9 , it is recommended in some cases, however, that these ends of the wire windings 7 are also firmly attached to the wall of the sheet metal tubular body 5 weld.

In order to obtain the largest possible proportion of perforated area in the sheet metal tubular body 5, in the exemplary embodiment according to FIGS. 1 to 3 it is provided that this has only round holes as wall openings 4 .

Instead of the round holes, slot holes can also be made in Form of elongated holes can be provided.  

In any case, that is, both when providing round holes and slot holes, these are arranged on the sheet metal tubular body 5 so that they lie in both the longitudinal direction and in the circumferential direction in rows, which is such that between the individual rows of holes also in the longitudinal direction and in the circumferential direction continuous wall areas remain.

In Fig. 3 of the drawing, the procedure for setting forth the well filter tubes 1 , namely the installation of the wire-wound tubular body 6 in the sheet metal tubular body 5 is shown. Here, the wire-wound tubular body 6 is first placed radially and axially inward under elastic tension such that its outer diameter 10 is at least smaller than the inner diameter 11 of the metal sheet tubular body 5 . Then the wire winding tube body 6 , which is held under tension, is axially inserted into the sheet metal tube body 5 in the direction of arrow 12 . As soon as he has reached the intended axial end position within the sheet metal tubular body, the wire-wound tubular body 6 is released radially and axially, so that, on the one hand, he supports the entire inner circumference of the sheet metal tubular body 5 in a supportive manner while he and others on the other hand, with the two ends of its windings 7, there is an axial abutment at the stops 9 and, between its individual windings 7, the relatively narrow gap openings 8 are formed, which extend helically in the longitudinal direction of the wire winding tubular body 6 .

The wire for the formation of the wire winding tube body 6 should have a minimum diameter of 3 mm and the wire winding should be dimensioned in its length so that between its individual turns 7 in the installed state, column 8 adjust, the clear width accordingly between different needs between 0.5 mm and 4 mm.

Of course, there is also the possibility of forming a double-walled well filter tube of the type described above using sheet metal tubular bodies 5 which have 4 slot bridge openings or blind openings as wall openings. It is only important that the wire-wound tubular body 6 is inserted into the interior of the sheet metal tubular body 5 and there supports itself against the total circumference of the sheet metal tubular body 5 under radial and axial elastic pre.

Claims (12)

1. Well filter tube with double jacket filter, consisting of a ver on its circumference and at least over most of its length with wall perforations seen sheet metal tubular body and a concentrically arranged tubular body made of helically wrapped wire with a gap between the adjacent turns, characterized in that the wire-wound tubular body ( 6 ) is inserted radially and axially under elastic prestress into the sheet metal tubular body ( 5 ) and spread against its inner circumference, and that at least the two ends of each wire coil are fixed against stops ( 9 ) on the sheet metal tubular body are. 2. Well filter tube according to claim 1, characterized in that the stops ( 9 ) extend at least over limited order sections of the sheet metal tubular body ( 5 ) and each facing the inner tube support surfaces for the ends of the wire-wound tubular body ( 6 ). 3. Well filter tube according to one of claims 1 and 2, characterized in that the stops ( 9 ) consist of inserted, arcuate strips or rings. 4. Well filter tube according to one of claims 1 and 2, characterized in that the stops ( 9 ) of circumferential impressions of the Me tallblech-tubular body ( 5 ) are formed. 5. Well filter tube according to one of claims 1 to 4, characterized in that several wire coils of limited axial length are inserted one behind the other in the sheet metal tubular body and their ends are each supported or fixed at intermediate stops ( 9 ) or spacer rings. 6. Well filter tube according to one of claims 1 to 5, characterized in that the individual windings ( 7 ) of the or the wire winding ( 6 ) with the sheet metal tube body ( 5 ) in at least two diametrically opposite circumferential areas are firmly welded or soldered. 7. Well filter tube according to one of claims 1 to 6, characterized in that the welds lie on two axially parallel lines and each individual one of them is preferably provided each time on the edge of a wall opening ( 4 ). 8. Well filter tube according to one of claims 1 to 6, characterized in that the welds are formed by two continuous, axially parallel resistance welds, which preferably run along a wall section of the sheet metal tube body free of openings ( 4 ). 9. Well filter tube according to one of claims 1 to 8, characterized in that each end of the or all of the wire coils ( 6 ) is firmly welded to the wall of the sheet metal tube body ( 5 ). 10. Well filter tube according to one of claims 1 to 9, characterized in that the sheet metal tube body as wall openings ( 4 ) has only round or slot perforations. 11. Well filter tube according to one of claims 1 to 10, characterized in that the round or slot perforations ( 4 ) lie both in the longitudinal direction and in the circumferential direction in rows and row on the sheet metal tubular body between these holes in the longitudinal direction and in the circumferential direction by going Wall areas are formed. 12. A method for producing well filter tubes with double jacket filter according to one of claims 1 to 11, in which a tubular body made of helically wound wire with a gap distance between the adjacent turns is connected to a metal sheet tubular body having circumferences and at least over most of its length is characterized in that the wire winding ( 6 ) is initially placed radially and axially inwards under elastic prestress, then axially inserted into the sheet metal tubular body ( 5 ) and finally released radially and axially in its inserted end position.