WO2007014602A2

WO2007014602A2 - Filter element and a device

Info

Publication number: WO2007014602A2
Application number: PCT/EP2006/006172
Authority: WO
Inventors: Peter Pfeuffer; Klaus Veeser
Original assignee: Carl Freudenberg Kg
Priority date: 2005-08-04
Filing date: 2006-06-27
Publication date: 2007-02-08
Also published as: DE102005037313A1; WO2007014602A3

Abstract

The filter element comprises a non-woven body (1) comrising first fibres (2), wherein said non-woven body (1) is associated with stabilisation means (3). The aim of said invention is to develop a long service life filtering system for efficiently filtering fine particles. For this purpose, the inventive filter element is characterised in that the non-woven body (1) is associated with second fibres (4) whose equivalent diameter is smaller than the diameter of the first fibres (2). A system provided with said filter element is also disclosed.

Description

Filter element and arrangement

description

Technical area

The invention relates to a filter element comprising a nonwoven fabric body, which comprises first fibers, wherein the nonwoven fabric body stabilizing agents are assigned. The invention further relates to an arrangement of such filter elements.

State of the art

Filter elements of the type mentioned are already known from the prior art. In particular, from DE 100 16 182 A1 and DE 196 30 522 A1 processes for producing plissierfähiger filter materials made of nonwoven fabric known. Stabilizing agents in the form of a grout are assigned to a nonwoven fabric in these processes. This gives the filter element a high stability and rigidity.

However, the known filter element is not satisfactorily equipped with regard to its separation performance against fine dusts or particles which have a very small extent. Furthermore, the generic filter elements are insufficiently designed with regard to their regenerability. It is particularly problematic that a filter element, which is a long time in use, contamination which make a regenerability of the nonwoven material impossible. The consequences of this are a shortening of the life of the filter elements and a greatly reduced filter performance.

Presentation of the invention

The invention is therefore based on the object of specifying a filter system which ensures effective filtering of fine particles with a long service life.

The present invention solves the aforementioned object by the features of claim 1. Thereafter, a filter element of the type mentioned is characterized in that the nonwoven fabric body second fibers are associated, which have smaller equivalent diameter than the first fibers.

According to the invention, it has been recognized in a first step that a fiber fraction of first fibers, which act as matrix fibers, can easily be provided with a stabilizing agent in order to impart a particular rigidity to a filter element. As a result, the operability of the filter element is realized. The stiffness of the filter element ensures that it is not subjected to severe deformation during inflow operations by fluids to be filtered, whereby its service life is greatly increased. According to the invention has further been recognized that the assignment of second fibers, which are smaller

Have equivalent diameter than the first fibers, increase the ability of the filter element to filter finer particles. Finally, it has been recognized that the provision of a second fiber fraction increases the scope of the generic filter elements. In that regard, a combinatorial effect is realized by the inventive design, namely an increased filter performance against fine particles while increasing the life of the filter element. Consequently, the object mentioned above is achieved.

In a structurally particularly advantageous embodiment, second fibers could be applied to the nonwoven fabric body at least in regions as a coating. This specific embodiment is advantageous for use of the filter element in surface filtration because a fluid to be filtered can first be filtered by the matrix fibers, namely the first fibers, and then the fine particles remaining in the fluid are deposited on the surface of the filter element by the second fibers can be.

The coating could act as a membrane. It is conceivable that the membrane is associated upstream of the nonwoven fabric body. As a result, the finest particles are immediately separated from a fluid to be filtered. In this specific embodiment, the matrix fibers could include activated carbon fibers, so that after deposition of fines, unpleasant odors can be additionally absorbed from a fluid.

The second fibers could be incorporated within the nonwoven body. With this configuration, a homogeneous distribution of the second fibers within the matrix fibers is possible. It is conceivable that the concentration of the second fibers and the concentration of the first fibers within the nonwoven fabric body is constant in all spatial directions. This concrete design allows a trouble-free production of

Nonwoven fabric body and a uniform elasticity and stability. In the deformation of the nonwoven fabric body damage in the extent due to material weaknesses are almost impossible.

However, it is also conceivable that the nonwoven fabric body exhibits a progressive structure, namely that the concentration of the second fibers within the nonwoven fabric body can be described by a gradient. In particular, it is conceivable that the concentration of the second fibers continuously increases or decreases in at least one spatial direction. These embodiments of the filter element are advantageous for use in depth or storage filtration. In these filtration processes, it is important that a fluid to be filtered flows through the filter element and is evenly filtered in all areas within the nonwoven fabric body as far as possible. In a progressive structure, defined areas are defined in which the fluid to be filtered is filtered particularly effectively depending on the particle sizes to be separated.

The second fibers could have equivalent diameters of at most one micron. Although both the matrix fibers, namely the first fibers and the second fibers, are subject to a distribution, the first fibers have equivalent diameters between 5 and 50 microns and the second fibers equivalent diameters which are at most 1 micron or significantly less. In that regard, the equivalent diameters between the first and second fibers differ significantly. This ensures that the first fibers perform a completely different filtering function than the second fibers. By dimensioning the second fibers, even the finest particles, which are significantly smaller than 1 μm, can be successfully deposited. The second fibers could be made against this background by electrospinning or melt-blown processes. By electrospinning even fibers can be made in the nanometer range, so that particles with this dimensioning can be effectively deposited.

The nonwoven body could be associated with a coating of polytetrafluoroethylene. The provision of such a coating gives the filter element an anti-adhesive property, which facilitates the regeneration of the filter element and thus effectively prevents an impairment of its filter performance. Usually, such a coating is produced by stretching a polytetrafluoroethylene film, which is guided according to a defined Stretching process is connected to the filter element. The stretching process involves stretching the film so that cracking centers are formed on the film in which the material structure of the film is selectively weakened.

The first and second fibers could comprise synthetic fibers, respectively, and the first and second fibers could be configured as synthetic fibers. This specific embodiment allows a chemically resistant design of the nonwoven fabric body. With such a nonwoven fabric body, aggressive solvents or aggressive gases can be filtered without problem over a long period of time.

Wear is significantly less pronounced in a nonwoven fabric body of synthetic fibers than in a nonwoven fabric comprising natural fibers. Furthermore, synthetic fibers are more readily chemically modifiable than natural fibers. In particular, it is conceivable against this background that the synthetic fibers can be provided with a coating.

The first and / or the second fibers could comprise fibers of a thermoplastic material. It is conceivable that the fibers are made of polypropylene or polyester. The use of thermoplastics is advantageous, since the material properties of these substances are well known and insofar an almost error-free production is possible.

The second fibers could consist of polymers that are particularly suitable for an electrostatic spinning process or a melt-blown process. The polymers could include polyamide or polycarbonate.

The stabilizing agents could comprise at least one stabilizing structure. A stabilizing structure is advantageous because it may be directly associated with the nonwoven body. It is to be understood in this respect as an intrinsic and integral formation of a stabilizing agent, which can not be separated from the nonwoven body. This makes it possible to one Nonwoven fabric body to give a special rigidity, which prevents deformation of the nonwoven fabric body during Anströmprozessen. By preventing deformation processes, it is ensured that the entire filter surface is available for the filtration process and not parts of the surface become ineffective due to their mutual contact.

The stabilizing structure could be formed as a grove with mountains and valleys. Such a stabilizing structure can be applied by two counter-rotating rollers, which have elevations and depressions which correspond to one another. Grooving with mountains and valleys also increases the effective filter area of a filter element.

The stabilizing structure could be formed as an embossing. By embossing is meant the application of a structure to the nonwoven body. It is conceivable that punctual impressions, linear impressions,

Lettering or symbols or geometric shapes are imprinted. The embossing can be done during a calendering process or by thermal processes. Any embossing gives the nonwoven body a flexural rigidity, thereby increasing its life.

Against this background, the stabilizing structure could also be designed as a curvature. It is conceivable that the nonwoven body as a whole has a twist or twist, which gives it a special flexural rigidity. An already pre-curved element is particularly resistant to bending or deformation, contrary to its curvature.

The nonwoven body could have a thickness between 0.2 and 5 mm. The choice of this thickness range advantageously allows a sufficient deformability of the filter element with satisfactory filter performance. The stabilizing means could comprise at least one connecting element. Against this background, it is conceivable that the nonwoven body is associated with separate elements such as strips, wires or cords, which are mechanically, chemically or thermally bonded to the nonwoven body in any way. It is conceivable against this background that the

Connection elements are welded or glued to the nonwoven fabric body. Due to their inherent rigidity or in interaction with the nonwoven fabric body, the connection elements can give the filter element overall a high flexural rigidity.

At least one connection means could be designed as a strand. The strand could extend over the filter surface of the nonwoven body. The provision of a strand allows stabilization of the entire filter surface. Concretely, it is conceivable that a folded nonwoven fabric body is provided with one or more strands, which extend over the

Wrinkles and fold valleys extend. This concrete configuration not only allows a stabilization of a folded structure but also a secure spacing of the individual pleat tips or pleated skirts. This ensures that a high effective filter surface is ensured even with strong incoming flows and differential pressures. Against this background, it is conceivable that a strand is arranged both on the inflow and outflow side or both raw and clean gas side on the nonwoven fabric body. This embodiment realizes a particularly high stability of the nonwoven fabric body. It is conceivable that two strands are arranged opposite one another on both sides of the nonwoven fabric body. It is advantageous that the strands can penetrate the material of the nonwoven fabric body and form a composite with each other.

The strand or strands could be made of a thermoplastic adhesive. The use of a thermoplastic adhesive allows easy processing. In particular, it is conceivable that the adhesive is applied continuously by spraying onto the nonwoven fabric body. In front In this background, it is also conceivable that the adhesive after hardening has an elasticity which allows the nonwoven body to be deformed without the strand being damaged, in particular having crack sites.

The nonwoven body could be folded. A pleat structure increases the effective filter area of a filter element. A folded nonwoven body can be provided with connecting elements on both the pleat back and on the pleated end faces in order to increase its bending stiffness and to keep the pleat spacing constant. As a result, a gluing of the wrinkles and thus a reduction of the effective filter surface is prevented.

The filter element could be designed as a flat filter. Flat filters are used in particular as air filters. Flat filters are characterized by a low elevation but strong areal expansion, so that large areas can be effectively equipped with a filter medium.

The nonwoven body of the flat filter could have first folds and second folds, the second folds having larger flanks than the first folds. Flanks are the areas forming the second folds. This embodiment realizes a double-folded filter element with maximized filter area.

The filter element could be designed as a star filter. Star filters find particular use as air or oil filters. The design as an oil filter allows the realization of a particularly large effective filter area in a confined space.

The object mentioned at the outset is furthermore achieved by an arrangement having the features of patent claim 20. Thereafter, filter elements are operatively connected to one another with angle formation. To avoid repetition in relation to the inventive step, reference is made to the comments on the filter element as such.

The filter elements could be W-shaped. In this case, it is particularly conceivable that a plurality of filter elements are connected to one another at their edges in a material, positive or non-positive manner. The connection can be made by a thermal process or an adhesive process. In particular, a plurality of flat filters could be positioned in a zigzag arrangement with their filter surfaces forming angles to one another. This concrete embodiment realizes a maximum effective filter area in a confined space, namely by positioning already folded filter elements again in a fold-forming arrangement.

There are now various possibilities for designing and developing the teaching of the present invention in an advantageous manner. For this purpose, on the one hand to the subordinate claims, on the other hand, to refer to the following explanation of preferred embodiments of the filter elements according to the invention with reference to the drawings. In conjunction with the explanation of the preferred embodiments with reference to the drawings, generally preferred embodiments and developments of the teaching are explained.

Brief description of the drawing

In the drawing show

Fig. 1 shows a flat filter with a fold structure, which two

Includes fiber fractions and the strands are assigned as stabilizer, and

2 shows a W-shaped arrangement of flat filters according to FIG. 1. Embodiment of the invention

Fig. 1 shows a filter element comprising a nonwoven fabric body 1 with first fibers 2 having an equivalent diameter of 5 to 50 microns. Stabilizing agent 3 is assigned to nonwoven fabric body 1 for stabilization.

The nonwoven fabric body 1 further comprises second fibers 4 having smaller equivalent diameters than the first fibers 2. The equivalent diameters of the fibers 4 are at most 1 micron or are significantly smaller than 1 micron. Equivalent diameter means the diameter that a fiber of any cross-sectional shape would have if its cross-sectional shape were circular for the same area.

The second fibers 4 are applied to the nonwoven fabric body 1 as a coating. The stabilizing agents 3 comprise a stabilizing structure. The stabilizing structure is designed as a grooving with mountains 5 and valleys 6. The nonwoven fabric body 1 is folded and formed as a flat filter.

The flat filter further comprises stabilizing means 9, which are formed as strands of a thermoplastic adhesive. Schematically, it is shown in FIG. 1 that two strands 9 of a thermoplastic adhesive extend along the nonwoven fabric body over the fold peaks 10 and fold valleys 11.

According to a further embodiment, the strands 9 can be located downstream from further strands. The strands 9 can be connected through the nonwoven fabric body with further strands by deliquescence or flow into each other.

The first fibers 2 and the second fibers 4 are configured as synthetic fibers. Fig. 2 shows an arrangement of filter elements, which are designed as flat filters. The filter elements are arranged in a W-shape. The filter elements are connected to each other at their edges 7, wherein their filter surfaces 8 form angles to each other. The filter surfaces 8 form the

Flanks of a second fold structure, namely the W-shape. Each filter surface 8 consists of a nonwoven fabric body having a first pleat structure.

FIG. 2 shows an arrangement of filter elements according to FIG. 1. All filter elements of the arrangement from FIG. 2 can have strands 9 extending as a stabilizing agent, which extend along the nonwoven fabric body 1. With regard to further advantageous embodiments and developments of the teaching of the invention reference is made on the one hand to the general part of the description and on the other hand to the appended claims.

Finally, it should be particularly emphasized that the previously purely arbitrarily chosen embodiments are only for the purpose of discussion of the teaching of the invention, but do not limit these to these embodiments.

Claims

claims

A filter element comprising a nonwoven fabric body (1), which first

Fibers (2), wherein the nonwoven fabric body (1) stabilizing means (3) are associated, characterized in that the nonwoven fabric body (1) second fibers (4) are assigned, which have smaller equivalent diameters than the first fibers (2).

2. Filter element according to claim 1, characterized in that second fibers (4) on the nonwoven fabric body (1) are applied at least partially as a coating.

3. Filter element according to claim 2, characterized in that the coating acts as a membrane.

4. Filter element according to one of claims 1 to 3, characterized in that second fibers (4) are incorporated within the nonwoven fabric body (1).

5. Filter element according to one of claims 1 to 4, characterized in that the nonwoven fabric body (1) has a progressive structure.

6. Filter element according to one of claims 1 to 5, characterized in that the equivalent diameter of the second fibers (4) amount to at most 1 micrometer.

7. Filter element according to one of claims 1 to 6, characterized in that the nonwoven fabric body (1) has a coating

Polytetrafluoroethylene is assigned.

8. Filter element according to one of claims 1 to 7, characterized in that the first (2) and / or the second fibers (4) comprise fibers of a synthetic material.

9. Filter element according to one of claims 1 to 8, characterized in that the stabilizing means (3) comprise a stabilizing structure.

10. Filter element according to claim 9, characterized in that the stabilizing structure as a grooving with mountains (5) and valleys (6) is formed.

11. Filter element according to claim 9, characterized in that the stabilizing structure is formed as an embossment.

12. Filter element according to claim 9, characterized in that the stabilizing structure is formed as a curvature.

13. Filter element according to one of claims 1 to 12, characterized in that the stabilizing means (3) at least one

Include connecting element.

14. Filter element according to claim 13, characterized in that the connecting element is designed as a strand.

15. Filter element according to claim 14, characterized in that the strand consists of a thermoplastic adhesive.

16. Filter element according to one of claims 1 to 15, characterized in that the nonwoven fabric body (1) is folded.

17. Filter element according to one of claims 1 to 16, characterized by a configuration as a flat filter.

18. Filter element according to claim 17, characterized in that the nonwoven fabric body (1) has first folds and second folds, wherein the second folds have larger flanks than the first folds.

19. Filter element according to one of claims 1 to 16, characterized by a configuration as a star filter.

20. Arrangement comprising filter elements according to one of claims 1 to 17, wherein the filter elements are operatively connected to each other at an angle.