WO2015128197A1 - Method and device for producing a support basket - Google Patents

Abstract

The invention relates to a method for producing a support basket (2) for an annular filter element (3), wherein: an inner structure (27) made of at least one wire (17) is placed on a matrix (4) of a welding device (1); an outer structure (28) made of at least one wire (12) is placed on the inner structure (27); the outer structure (28) and the inner structure (27) are welded together at contact points (16), where the outer structure (28) touches the inner structure (27), by means of a welding tool (6) of the welding device (1), and the inner structure (27) is wound onto the matrix (4) and/or the outer structure (28) is wound onto the inner structure (27).

Description

 Method and device for producing a support basket

The present invention relates to a method and an apparatus for producing a support basket for a filter element. The invention also relates to such a support basket and equipped with such a support basket filter element.

In filter elements that are operated at relatively high differential pressures between the raw side and the clean side, it is customary to support the filter material on a support structure, which is permeable to the medium to be filtered on the one hand and on the other hand has a higher stiffness than the filter material. Such a support structure may also be referred to as a support frame or support basket.

In the case of annular filter elements, which are flowed through radially by the medium to be filtered, such a support structure, which is then also configured annularly, depending on the direction of flow of the filter element, be arranged radially inward or radially outward, so that the filter medium can be supported in the flow direction. In principle, designs are also conceivable in which an annular filter element is equipped both radially inwardly and radially outwardly with such an annular support structure.

From EP 0 682 967 A1, such an annular support structure is known, which is designed as a one-piece injection molded body and is made of plastic.

From DE 39 21 369 A1 discloses a further annular support structure is known, which is assembled in the axial direction of a plurality of individual support bodies. The individual support bodies are again injection molded from plastic. Another, tubular or annular support structure, which is made in one piece from plastic, shows the DE 196 52 603 A1.

From DE 33 1 1 324 A1 a support basket is now known, which consists of a wire mesh structure. The preparation of this known support basket is carried out so that from a transverse to the production axis wire mesh roll on a rotating cylinder in the production axis spirally a wire mesh web is mounted, wherein abutting edges of the individual spiral windings are formed by adjacent wires and fixed by a pressed flat steel strip together. Alternatively, the abutting edges can also be welded together.

In the support structures integrally formed by injection molding and supporting structures, which are assembled from several sections integrally formed by injection molding, different injection molding or injection molds must be provided and kept available for variants of the filter element. For small batches this means a considerable cost disadvantage. In the case of support baskets produced by means of a wound wire mesh track, only cylindrical shapes for the support cage can be realized. Cone-shaped or frustoconical support baskets can not be realized in this way, so that here too restrictions are imposed on the variety of types.

The present invention addresses the problem of providing a way for an annular support basket suitable for use in an annular filter element which simplifies the production of different variants. In particular, the present invention thus addresses the problem of providing an improved embodiment for a method and / or a device for producing such a support basket, which is characterized in particular by a simplified variant formation for the support basket.

This problem is solved according to the invention by the subject matters of the independent claims. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea to produce the support basket with an inner structure of wire and a wire outer structure, such that form between the inner structure and the outer structure a plurality of contact points in which touch the wires of the inner structure and the outer structure. In this case, the outer structure and the inner structure are attached to each other by being welded together at least in some of the aforementioned contact points. Furthermore, at least one of the structures is wound with respect to a longitudinal central axis of the support basket, that is to say formed from at least one helically extending wire.

Both the inner structure and the outer structure can be geometrically produced in virtually any shape, in particular cylindrical and conical, with different axial lengths, different radii and different cone angles can be realized. It is always possible to produce a stable support basket by welding the inner structure to the outer structure. By using wires or wire for producing the inner structure or the outer structure, the stiffness of the support basket can also be adjusted as desired via the spacing of adjacent wires or wire sections.

For the method is proposed in detail to apply an inner structure of at least one wire on a die of a welding device and an outer structure of at least one wire on the inner structure or to apply to the die. Furthermore, the outer structure is welded to the inner structure at contact points in which the outer structure contacts the inner structure by means of a welding tool of the welding device. The application of the inner structure to the die and / or the application of the outer structure to the inner structure can be carried out by winding the respective wire. This means that at least one wire is wound onto the die to produce the inner structure, ie can be arranged helically on the die. Additionally or alternatively, the outer structure can be produced by winding at least one wire helically on the inner structure or on the die.

The wires for producing the inner structure and / or the outer structure may be made of an electrically conductive material, for example of a metal or a metal alloy. It is also possible to produce the wires of plastic, as well as plastics are welded together.

In this case, an embodiment in which the welding of the outer structure to the inner structure takes place immediately upon winding up of the outer structure onto the inner structure is particularly advantageous. As a result, the effort for holding and positioning the outer structure on the inner structure can be reduced.

In the event that metallic wires are used, according to an advantageous embodiment, the die may be designed to be electrically conductive at least in the region of the respective wire of the inner structure. The welding of the inner structure with the outer structure is then carried out electrically appropriately, ie by means of an electric welding technique. Preferably, resistance welding or arc welding may be performed. The die or the electrically conductive regions of the die can serve as a ground connection during the electric welding, whereby the welding process is simplified. In another embodiment, the inner structure may be formed by a plurality of, in particular straight, pieces of wire which are distributed in the circumferential direction and spaced from each other on the die in the circumferential direction. This gives the internal structure a particularly simple geometry.

According to an advantageous development, the die for each piece of wire may have an electrically conductive wire piece receiving, in which the respective wire piece is axially and / or radially insertable. With the help of such wire piece recordings, the arrangement of the wire pieces on the die simplifies. In ferromagnetic wires, the generation of a magnetic holding force is conceivable in order to fix the pieces of wire to the die. For example, the die for this purpose contain at least one electromagnet or permanent magnet.

Alternatively, it is also conceivable to wind the inner structure onto the die and to wind the outer structure onto the inner structure. In other words, the at least one wire used to make the inner structure is wound on the die while the at least one wire used to make the outer structure is wound on the inner structure. In particular, a wound structure makes it possible to use only a single wire for the inner structure as well as for the outer structure, which simplifies the production of the respective structure. It is also conceivable to use a single common wire to form the inner structure and the outer structure.

According to an advantageous development, an inner winding forming the inner structure can have a different pitch than the outer structure forming outer winding. By this measure, contact points or contact points between inner structure and outer structure can be created even with co-directional winding.

Additionally or alternatively, it may be provided that an inner winding forming the inner structure and an outer winding forming the outer structure are wound in opposite directions of rotation. In this case, the inner winding and the outer winding may have the same or different slopes. Due to the opposite direction of rotation during winding, contact points inevitably occur between the inner structure and the outer structure.

According to another advantageous development, the respective winding can end closed at least at one axial end of the support basket. At a closed end of the winding, the last turn of the winding has no slope, resulting in a closed ring. As a result, the respective axial end of the support basket is stabilized.

A welding device according to the invention is characterized in detail by a die, a wire feed and a welding head. The die is arranged rotatably about a rotation axis on a console of the welding device. The wire feed is linearly adjustable parallel to the axis of rotation relative to the die. Further, the wire feeder allows the feeding of a wire for winding onto the die. The welding head is adjustable relative to the die. Furthermore, the welding head, the contact points in which wires or

Touch wire sections, weld together. The welding head of the welding device accordingly forms a welding tool, with which the outer structure can be welded to the inner structure in said contact points. According to an advantageous development, the welding head can be designed to be linearly adjustable relative to the die parallel to the axis of rotation. This results in a particularly simple construction for the welding device. Alternatively, it is also conceivable to arrange the welding head on a robot arm, so that the welding head is virtually arbitrarily three-dimensionally adjustable.

In another embodiment of the welding device, the die may be designed to be electrically conductive at least in the region of the respective wire of the inner structure. The welding head is expediently designed to carry out an electrical welding technique.

Furthermore, it can be provided that the die for several, preferably straight, wire pieces each having an electrically conductive wire piece receiving, in which the respective wire piece is axially and / or radially insertable. This measure also leads to a simpler handling of the welding device.

The insertion of the wire pieces in the wire piece receiving can be done manually. It is also conceivable that the welding device can be designed with a corresponding manipulation device, for example with a robot arm.

An inventive annular support basket, which is suitable for use in an annular filter element, has an annular inner structure of at least one wire and an annular outer structure of at least one wire which is helically wound on the inner structure. Furthermore, the outer structure is welded to the inner structure in contact points in which the outer structure contacts the inner structure. In this case, the outer structure does not have to be welded to the inner structure in all contact points between outer structure and inner structure. For a sufficient stability it is enough out when such a welded joint is produced at several contact points.

According to an advantageous development, the inner structure may be formed by a plurality of, preferably rectilinear, pieces of wire which are distributed in the circumferential direction and spaced apart in the circumferential direction. In this case, the outer structure is helically wound on the inner structure.

In another embodiment it can be provided that both the inner structure and the outer structure are wound. In this case, an inner winding forming the inner structure may have a different pitch than an outer winding forming the outer structure. Additionally or alternatively, an inner winding forming the inner structure and an outer winding forming the outer structure may be wound in opposite directions of rotation. If the inner structure is wound, it may conveniently be made of a single, continuous wire. If the outer structure is wound, it can be made of a single, continuous wire. If the inner structure and the outer structure are wound, two separate wires can be used for winding the inner structure and for winding the outer structure, which can in particular also differ from each other by different diameters. It is also possible to use a single, continuous wire to wind the inner structure and to wind the outer structure.

The inner winding or the outer winding can end closed at least at one axial end of the support basket, ie in a closed circumferential ring. An inventive annular filter element has an annular filter body of a filter material, and has at least one support basket of the aforementioned type, on which the filter body is radially supported. Depending on the direction of flow of the filter element during operation of the support basket can be arranged radially inside or radially outside of the filter body. However, an embodiment is also conceivable in which a support basket is arranged on the filter body both radially inward and radially outwardly.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

Show, in each case schematically,

1 is a greatly simplified side view of a welding device,

2 is a greatly simplified axial view of the welding device according to a viewing direction II in Fig. 1, Fig. 3 simplified plan view of such a welding device

Fig. 4 is a side view of a support basket

Fig. 5 is a highly simplified cross section of a filter element which is equipped with such a support basket.

According to FIGS. 1 to 3, a welding device 1, with the aid of which a support basket 2 shown in FIGS. 4 and 5 can be produced for a filter element 3 shown in FIG. 5, a die 4, a wire feed 5 and a welding head 6. The die 4 is configured conical or frustoconical in the examples shown here. In principle, the die 4 can also be configured cylindrically. The die 4 is rotatably arranged about a rotation axis 7 on a bracket 8 of the welding device 1. For rotating driving of the die 4, a drive motor 9 may be provided. The wire feed 5 is parallel to the axis of rotation 7 relative to the die 4 linearly adjustable. For this purpose, the welding device 1 may have a linear unit 10, on which the wire feed 5 is arranged to be adjustable. The linear adjustability of the wire feed 5 along the linear unit 10 is indicated in Fig. 1 by a double arrow 1 1. The linear unit 10 may consist of a simple rectilinear rod or tube. The linear unit 10 may in particular comprise a spindle drive for linear adjustment of the wire feed 5.

The wire feeder 5 is also configured to feed a wire 12 to the die 4. In detail, the wire feed 5 for this purpose comprises a recognizable in Fig. 2 straightening unit 13, which is also combined with a cutting unit 14. Furthermore, the wire feed 5 according to FIG. 2 can comprise a guide unit 15. By a suitable rotational speed of the die 4 and a suitable linear propulsion of the wire feed 5, the wire 12 can be helically wound on the die 4.

The welding head 6 is also adjustable relative to the die 4. Furthermore, the welding head 6 is designed for producing welded joints in contact points 16, in which two wires 12, 17 or two wire sections of the wires 12, 17 touch. In Fig. 2, an arc 18 is indicated to symbolize the welding process. The welding head 6 is expediently also adjustable parallel to the axis of rotation 7 relative to the die 4. In particular, the same linear unit 10 can be used for this purpose. Suitably, the wire feed 5 and the welding head 6 form an assembly which is linearly adjustable along the linear unit 10 in a uniform manner. It is also conceivable to arrange the welding head 6 with respect to the axis of rotation 7 radially adjustable on the linear unit 10 in order to change the distance between the welding head 6 and the die 4 or to be able to track the conical contour of the die 4. A corresponding radial adjustability is indicated in Fig. 2 by a double arrow 19.

According to FIG. 1, the welding device 1 can also be equipped with a further wire feed 20, which feeds the aforementioned wire 17 to the die 4. This additional wire feed 20 allows a linear feeding of the wire 17. This further wire feed 20 may also be equipped with a straightening unit 21 and a cutting unit 22. The further wire feed 20 is also arranged parallel to the axis of rotation 7 relative to the die 4 according to a double arrow 23 adjustable. By means of this further wire feed 20, the wire 17 can be fed in such a way that straight-line wire pieces are produced, which are also referred to below as 17. The straight wire pieces 17 are placed in a straight line on the die 4, so that they lie in a plane in which the axis of rotation 7 is located. In the case of conical die 4, an angle results between the wire pieces 17 and the axis of rotation 7. 4 has a plurality of wire piece receivers 25 arranged distributed in the circumferential direction 24 indicated by a double arrow, which are designed such that in each case such a piece of wire 17 can be inserted therein. The insertion can be done axially as indicated in Fig. 1. In principle, however, a radial insertion or insertion of the wire pieces 17 in the wire piece receptacles 25 is possible.

In order to be able to realize an electrical welding method, the die 4 is designed to be electrically conductive at least in the region of the wire pieces 17. In the example of Figures 1 and 2, this is achieved in that the wire piece receivers 25 are made of an electrically conductive material. According to FIG. 1, a ground connection 26 of the welding device 1 can be electrically conductively connected to the wire piece receptacles 25. It can be provided that the ground terminal 26 is arranged eccentrically with respect to the axis of rotation 7 on the console 8, such that the ground terminal 26 is electrically connected only to that piece of wire receiving 25 whose wire piece 17 is to be welded to the wound wire 12.

4, the support basket 2 has an inner structure 27, which consists of at least one wire 17. Furthermore, the support basket 2 has an outer structure 28, which also consists of at least one wire 12. The outer structure 28 contacts the inner structure 27 in the aforementioned contact points 16. At least in some of these contact points 16 or in all contact points 16, the outer structure 28 is welded to the inner structure 27. In the preferred example shown, the inner structure 27 is formed of a plurality of straight wire pieces 17, which are distributed in the circumferential direction 24 and spaced apart in the circumferential direction 24. In contrast, the outer structure 28 is formed by winding the wire 12 onto the inner structure 27, thereby having an outer winding 29. The outer winding 29 points to the axial ends 30, 31 of the support basket 2 each have a closed winding end, which is formed in each case by a ring in the circumference 24 closed ring 32 and 33 respectively. The respective ring 32, 33 lies in a direction perpendicular to the longitudinal central axis 34 of the support basket 2 extending plane. In the example, the inner structure 27 is formed of four straight wire pieces 17, while the outer structure 28 is formed of a single wire 12 which extends helically over the entire axial length of the support basket 2. In another embodiment, the inner structure 27 may be formed by such a wire winding, which then expediently has a different pitch than the outer winding 29. Additionally or alternatively, the inner winding and the outer winding 29 may be wound in opposite directions of rotation.

5, the annular filter element 3 comprises an annular filter body 35 made of a filter material and an annular support basket 2. In the example of FIG. 5, the filter element 3 can be flowed through radially from outside to inside, which is indicated by flow arrows 36. In this case, a crude side 37 is located outside the filter body 35 during operation of the filter element 3, while a clean side 38 is then located inside the filter body 35. During operation of the filter element 3, there is a strong pressure gradient between the raw side 37 and clean side 38, whereby the filter body 35 is pressed radially inward. In this constellation, the support basket 2 is expediently arranged radially on the inside of the filter body 35 so that the filter body 35 can be supported radially on the support basket 2. In the reverse flow direction, the support basket 2 is then expediently arranged radially on the outside of the filter body 35. Basically, an embodiment is conceivable in which both radially outwardly and radially inwardly such a support basket 2 can be arranged on the filter body 35. The production of such a support basket 2 is carried out according to the figures 1 to 3 preferably such that initially the inner structure 27 is applied from at least one wire 17 to the die 4. In the example shown here, four wire pieces 17 are thus distributed evenly distributed in the circumferential direction 24 on the die 4 so as to form the inner structure 27. The feeding of the wire pieces 17 takes place, for example, by means of the further wire feed 20. Subsequently, the outer structure 28 is applied from the wire 12 to the inner structure 27. For this purpose, the wire 12 is wound helically on the die 4 and thus also on the inner structure 27. The helical winding takes place by a corresponding coordination between the rotation of the die 4 and the linear adjustment of the wire feed 5.

By winding the outer structure 28 onto the inner structure 27, the contact points 16 are formed. With the aid of the welding head 6, the outer structure 28 can now be welded to the inner structure 27 in the region of these contact points 16. This can be done expediently already during the winding of the outer structure 28 on the inner structure 27, whereby costly holding means for positioning the outer structure 28 on the inner structure 27 accounts.

At the axial ends 30, 31 of the support basket 2, a closed ring 32 or 33 can be generated at the beginning and at the end of the winding process of the outer structure 28 to produce a closed axial end 30, 31 of the support basket 2.

Claims

claims 1 . Method for producing a support basket (2) for an annular filter element (3),  in which an inner structure (27) of at least one wire (17) is applied to a die (4) of a welding device (1),  in which an outer structure (28) of at least one wire (12) is applied to the inner structure (27),  in which the outer structure (28) is welded to the inner structure (27) at contact points (16) in which the outer structure (28) contacts the inner structure (27) by means of a welding tool (6) of the welding device (1), - Wherein the inner structure (27) is wound onto the die (4) and / or the outer structure (28) is wound onto the inner structure (27). 2. The method according to claim 1, characterized, in that the welding of the outer structure (28) to the inner structure (27) takes place during the winding of the outer structure (28) onto the inner structure (27). 3. The method according to claim 1 or 2, characterized, - That the die (4) at least in the region of the respective wire (17) of the inner structure (27) is electrically conductive, - That the welding of the inner structure (27) and the outer structure (28) takes place electrically. 4. The method according to any one of claims 1 to 3, characterized, in that the inner structure (27) is formed by a plurality of wire pieces (17) distributed in the circumferential direction (24) on the die (4). 5. The method according to claim 4, characterized, that the die (4) for each piece of wire (17) is an electrically conductive Wire piece receptacle (25) into which the respective piece of wire (17) is inserted. 6. The method according to any one of claims 1 to 3, characterized, that the inner structure (27) is wound on the die (4), wherein the outer structure (28) is wound onto the inner structure (27). 7. The method according to claim 6, characterized,  - That an inner structure (27) forming inner winding has a different pitch than an outer structure (28) forming outer winding (29), and / or - That an inner structure (27) forming inner winding and the outer structure (28) forming the outer winding (29) are wound in opposite directions of rotation. 8. The method according to any one of claims 1 to 7, characterized, the respective winding (29) ends closed at least at one axial end (30, 31) of the support basket (2). 9. Welding device for producing a support basket (2) for an annular filter element (3),  - With a die (4) which is arranged about a rotation axis (7) rotatably on a bracket (8) of the welding device (1),  - With a wire feed (5) which is parallel to the axis of rotation (7) relative to the die (4) linearly adjustable and with which a wire (12) for winding on the die (4) can be fed,  - With a welding head (6) which is adjustable relative to the die (4), and with the contact points (16) in which wires (12, 17) or wire portions of the wires (12, 17) contact, are welded. 10. Welding device according to claim 9, characterized, that the welding head (6) is linearly adjustable parallel to the axis of rotation (7) relative to the die (4). 1 1. Welding device according to claim 9 or 10, characterized, in that the die (2) is electrically conductive at least in the region of the respective wire (17) of the internal structure (27). 12. Welding device according to one of claims 9 to 1 1, characterized, in that the die (4) has for each piece of wire (17) of the inner structure (27) an electrically conductive piece of wire piece (25) into which the respective piece of wire (17) can be inserted. 13. Support basket for an annular filter element (3),  with an inner structure (27) of at least one wire (17),  with an outer structure (28) made of at least one wire (12),  - Wherein the outer structure (28) is helically wound on the inner structure (27),  - Wherein the outer structure (28) in contact points (16), in which the outer structure (28) contacts the inner structure (27), with the inner structure (27) is welded. 14. Support basket according to claim 13, characterized, in that the inner structure (27) is formed by a plurality of wire pieces (17) distributed in the circumferential direction (24). 15. Support basket according to claim 13, characterized, that the inner structure (27) is wound helically. 16. Support basket according to claim 15, characterized, - That an inner structure (27) forming inner winding has a different pitch than an outer structure (28) forming outer winding (29), and / or - That an inner structure (27) forming inner winding and the outer structure (28) forming the outer winding (29) are wound in opposite directions of rotation. 17. Support basket according to one of claims 13 to 16, characterized, the respective winding (29) ends closed at least at one axial end (30, 31) of the support basket (2). 18. Filter element with an annular filter body (35) and with at least one support basket (2) according to any one of claims 13 to 17, on which the filter body (35) is radially supported.