DE102010014060A1 - Winding filter element for removing impurity from fluid stream e.g. gas flow, of internal combustion engine, has material arrangement including planar filter material, and multilayer filter material comprising membrane and carrier layers - Google Patents

Abstract

The element (1) has a filter body (2) manufactured by wrapping a filter material arrangement (3) and comprising an outlet-side sealed inlet port and an inlet-side sealed exhaust port. The filter material arrangement includes a planar filter material (5) and a wave-shaped or zigzag shaped filter material (6), which directly or indirectly corresponds with one another. One of the filter materials is formed as a multilayer filter material. The multilayer filter material comprises a membrane layer and a carrier layer. Layer thickness of the membrane layer is about 15 to 300 micrometer. The membrane layer is made of perforated or porous film e.g. plastic metal sheets. The carrier layer is made of fiber material, cellulose paper such as non-woven fabric i.e. plastic non-woven fabric. The fiber of the carrier layer is made of carbon fiber or glass fiber.

Description

The present invention relates to a wound filter element for removing contaminants from a fluid stream. The invention also relates to a use of a multilayer filter material for producing such a wound filter element.

A wound filter element is characterized by a filter body which is produced by winding a filter material arrangement and which has outlet channels closed on the outlet side and outlet channels closed on the inlet side, the filter material arrangement having at least one flat filter material and a wave-shaped or zigzag-shaped filter material, these filter materials resting on one another.

From the WO 2006/012495 A1 is a star filter element is known which has an annular filter body of a zig-zag folded filter material. The filter material used here is designed as a multilayer filter material and comprises a paper layer and a membrane laminated thereon, which represents a membrane layer.

From the JP 2007-075739 A a plate filter element is known whose flat or plate-shaped filter body is made of a zig-zag folded filter material. Again, the filter material used has a multilayer structure, which has a gas-permeable carrier layer, a filter layer and a membrane layer arranged between the carrier layer and the filter layer.

Other multilayer filter materials with a filter membrane are, for example, from WO 2008/153878 A2 and from the WO 2006/096180 A1 known.

The present invention addresses the problem of providing for a wound filter element an improved or at least another embodiment, which is characterized in particular by an improved filtering effect.

According to the invention, this problem is solved 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 within the filter material arrangement from which the wound filter body of the wound filter element is produced to design at least one filter material as a multilayer. Such a multilayer filter material can be used to improve the filter effect, since it is possible in particular to combine a stiffer carrier layer, which has a comparatively low filtration effect, with a less rigid layer, which realizes the actual filtration effect, especially for the smallest impurities.

Particularly advantageous here is the embodiment according to the invention, in which the multilayer filter material has at least one membrane layer and a carrier layer. The membrane layer is porous and contains, for example, micropores or micropores in order to achieve the desired filtration effect for small impurities or impurities with small grain size. In contrast, the carrier layer in principle does not have to show a significant filtration effect. Advantageously, however, the carrier layer has a certain filtration effect, for example, to filter out larger impurities, so impurities with a larger grain size from the respective fluid stream, before they hit the membrane layer.

The support layer itself may in turn be designed in multiple layers and, for example, have a special filter layer.

The carrier layer consists of a fiber-containing material. Preferably, the carrier layer may be made of a non-woven fabric, in particular a metal or synthetic fiber non-woven fabric, or of a cellulose paper. Furthermore, the carrier layer binder such. As resins. The nonwoven fabric can be made at least partially made of weldable plastic fibers in advantageous embodiments. In contrast, the cellulose paper may contain a proportion of plastic fibers. In particular, here weldable plastic fibers can be integrated into the cellulose paper. Appropriately, the proportion of weldable plastic fibers is then selected so high that the cellulose paper is weldable. For example, the proportion of plastic fibers may be in a range of about 20% to about 40%, which may mean vol .-% or wt .-%.

Suitably, the carrier layer has a layer thickness in the range of about 0.1 mm to about 2.0 mm, but preferably the layer thickness is in a range of 0.15 mm to about 0.8 mm, in particular, the layer thickness in the range of 0, 15 mm to 0.35 mm. However, the thickness of the carrier layer is preferably about 0.25 mm. With thicker backing layers, larger waves or wrinkles can be reliably supported, but no narrow waves or wrinkles can be produced. With thinner carrier layers, in particular smaller than 0.35 mm smaller waves or wrinkles can be represented with sufficient support. The fibers of the Nonwoven fabric or cellulose paper expediently have an average diameter which is greater than 10 .mu.m, in particular greater than 25 microns. Appropriately, the fibers of the carrier layer, so the fibers of the nonwoven fabric or the cellulose paper weldable fibers such. As metal fibers or plastic fibers from z. Example of polyethylene (PE) or polyester or polypropylene (PP) or polyamide (PA) or polytetrafluoroethylene (PTFE) or Polyfluorethylenpropylen (PFEP). Furthermore, the carrier layer and other fibers such. As carbon fibers or glass fibers. Likewise, at least two different fibers may be mixed together to form the nonwoven fabric or to reinforce the cellulose paper, or the material properties such. As the weldability or the media resistance to influence.

According to an advantageous embodiment, the membrane layer consists of a perforated or porous film, which z. B. may be formed of metal or plastic. Such films can be comparatively easily realized in different film thicknesses or film thicknesses and different porosities, ie with different pore sizes and / or pore density (number of pores per unit area).

For example, such a membrane layer may be made of polyfluoroethylene propylene (PFEP) or polytetrafluoroethylene (PTFE) or polyethylene (PE) or polypropylene (PP) or high density polyethylene (PE-HD) or polyester or polyamide (PA). A suitable layer thickness for the membrane layer may be in a range of 10 μm to 300 μm. Preferably, the layer thickness is in a range of 25 microns to 80 microns. For example, the membrane layer may have a thickness of about 50 microns, which is sufficiently flexible to be corrugated or folded on the carrier layer. In addition, this layer thickness provides the particles contained in the fluid flow sufficient resistance.

The membrane layer is characterized by a particularly effective filtration effect with regard to particularly small or fine impurities with small grain size. This is of particular interest in view of the so-called "particulate matter problem". In particular, so-called HEPA filters can be realized with the aid of such a membrane layer, with HEPA standing for High Efficiency Particulate Absorbing or Arrestance. In particular, the winding filter element presented here can thus be configured as a HEPA winding filter element. For this purpose, the membrane layer may have a pore size of 1 to 80 microns. Preferably, the pore size is between 3 microns and 50 microns. Preferably, pore sizes of about 4 to 40 microns, in particular about 10 microns or about 20 microns, provided. Here, the pore size, in particular the "mean flow pore size" (MFP), with a porometer z. B. the brands "Coulter" or "PMI" are determined. The largest pores define the maximum permeability of the membrane for particle size. By correspondingly small pores even the finest impurities of z. B. the intake air flow of an internal combustion engine and so the engine are protected.

The membrane layer is expediently laminated to the carrier layer. Additionally or alternatively, the membrane layer can be glued or welded to the carrier layer. Here, the plastic of the membrane layer connects to the fibers of the carrier layer. Alternatively, the weldable fibers, in particular plastic fibers, of the carrier layer can be melted and bonded to the membrane layer. Furthermore, both the fibers of the carrier layer, as well as the membrane layer can be melted and connected to the other joining partner.

According to an advantageous embodiment, the carrier layer may be configured as a filter layer. In this case, the carrier layer is preferably configured as a depth filter. In this way, the carrier layer can be assigned a filtration effect, in the sense of a prefiltration, in order to reduce a load of the membrane layer with larger or coarser impurities. For this purpose, the membrane layer is expediently arranged with respect to the fluid flow downstream of the carrier layer.

The membrane layer may be arranged between two carrier layers in a specific embodiment. Here, the upstream-side carrier layer serves as a pre-filter or as protection for the membrane layer and the downstream-side carrier layer forms an additional support or protective layer. The carrier layers can be designed differently in this embodiment. According to another embodiment, the filter medium is formed symmetrically. Here, the membrane layer is surrounded by identical carrier layers. By this configuration, the filter element formed can be installed in any direction. The carrier layers can fulfill different functions with respect to the membrane layer, in particular pre-separation, protection or support. Alternatively, it is also possible to arrange the carrier layer between two membrane layers. The two variants can also be realized cumulatively if the multilayer filter material has four or more layers. With more than one membrane layer, the membrane layers can have different filtration effects, ie have different pore sizes and / or pore densities, for example, to realize a fine main filtration and upstream thereof a less fine prefiltration.

As explained above, the filter body of the wound filter element is produced by winding a filter material arrangement which has a flat filter material and a wave-shaped or zig-zag-shaped filter material. With the aid of the multi-layered filter material, which in particular contains the membrane layer, the wave-shaped or zig-zag-shaped filter material can now preferably be formed. It is also possible to form the flat filter material through the multilayer filter material. Furthermore, an embodiment is possible in which both the wave-shaped or zig-zag-shaped filter material and the flat filter material are formed by the multilayer filter material.

The invention presented here is also characterized by the use of a multilayer filter material comprising at least one membrane layer and a carrier layer for producing such a wound filter element.

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.

It show, each schematically

1 a greatly simplified, principal cross-section of a wound filter element,

2 a greatly simplified longitudinal section of the wound filter element,

3 - 6 each a greatly simplified sectional view of a multilayer filter material, in different embodiments,

7 and 8th greatly simplified, enlarged cross-sections of the wound filter element in the region of a filter material arrangement, in various embodiments.

According to the 1 and 2 comprises a wound filter element 1 a filter body 2 consisting of a filter material arrangement 3 is made. The wound filter element 1 can be used to remove contaminants from a fluid stream. The fluid stream is preferably a gas stream. In principle, however, is also a use of the wound filter element 1 in a liquid flow, in particular in a fuel flow of internal combustion engines conceivable. Impurities, with the help of the Wickelfilterelements 1 can be filtered out of the respective fluid stream, are in any case solid or particles. If the fluid stream is a gas stream, it is also possible to use liquid or droplet-shaped contaminants with the aid of the wound filter element 1 Remove from the respective fluid stream.

The filter body 2 is made by winding the filter material assembly. A corresponding winding axis 4 around which the filter material arrangement 3 is wrapped around, stands in 1 perpendicular to the plane of the drawing and thus extends parallel to a longitudinal direction of the filter body 2 and thus the wound filter element 1 , The filter material arrangement 3 has at least one flat filter material 5 and at least one wavy or zig-zag shaped filter material 6 on. The at least two filter materials 5 . 6 correspond within the filter material arrangement 3 with each other, so are in contact or lie on each other, the filter materials 5 . 6 directly, z. B. by direct contact with each other, or indirectly, for. B. by an adhesive layer, are interconnected. In the example shown, the filter material arrangement 3 from exactly one level filter material 5 and exactly a wavy or zig-zag shaped filter material 6 educated.

According to 2 showing a simplified longitudinal section of the wound filter element 1 or of the filter body 2 shows are in the filter body 2 several in the longitudinal direction of the filter body 2 , ie parallel to the winding axis 4 running channels 7 . 8th educated. These are several inlet channels 7 through which the in 2 through arrows 9 indicated fluid flow into the filter body 2 can occur, as well as to outlet channels 8th through which the fluid flow 9 again from the filter body 2 can escape. The inlet channels 7 are on an outlet side 10 of the filter body 2 So closed on the outlet side, for example by means of plugs 11 , Gluing, welding or the like. In contrast, the outlet channels 8th on an inlet side 12 of the filter body 2 , ie closed on the inlet side, for example with plugs 13 , Gluing, welding or other material adding possibilities. Alternatively, the closure can also be formed by the filter material of the filter body itself. The fluid flow 9 must therefore flow through the filter body 2 walls 14 flow through which the inlet channels 7 from the outlet channels 8th Separate and filter through the materials 5 . 6 the filter material arrangement 3 are formed. This results in the desired filtration effect.

According to the 3 - 8th is now at least one of the filter materials 5 . 6 , for the manufacture or for the construction of the filter material arrangement 3 is used as a multilayer filter material, which hereinafter with 15 referred to as. According to 7 is preferably the wave-shaped or zigzag-shaped filter material 6 through the multilayer filter material 15 formed while the plane filter material 5 in this embodiment, a single-layered design. In contrast, shows 8th an embodiment in which both the wave-shaped or zig-zag-shaped filter material 6 as well as the flat filter material 5 are each configured multi-layered, so by the multilayer filter material 15 are formed.

According to the 3 - 8th includes the multilayer filter material 15 at least one membrane layer 16 and a carrier layer 17 , It shows 3 an embodiment in which the multilayer filter material 15 only one membrane layer 16 and only one carrier layer 17 having. It is expedient in this case, the membrane layer 16 with respect to the fluid flow 9 arranged downstream.

In contrast, the show 4 - 6 Embodiments in which the multilayer filter material 15 has more than two layers. In detail shows 4 an embodiment in which three layers are provided, namely the membrane layer 16 , the backing layer 17 as well as another layer 18 , The membrane layer 16 is here purely exemplary between the carrier layer 17 and the other layer 18 arranged. At the next shift 18 it may be, for example, a filter layer. Likewise it is possible the further layer 18 identical to the carrier layer 17 to design, so that then the membrane layer 16 between two carrier layers 17 is arranged.

5 on the other hand shows an embodiment in which two membrane layers 16 are provided, between which the carrier layer 17 is arranged.

Finally shows 6 again an embodiment with a membrane layer 16 , a carrier layer 17 and another layer 18 , In this case, the carrier layer 17 between the membrane layer 16 and the other layer 18 is arranged. The carrier layer 17 and the other layer 18 can also be used as a multilayer embodiment of a modified carrier layer 17 ' be understood. In this case, this carrier layer comprises 17 ' a carrier material layer ( 17 ) and a filter material layer ( 18 ). In principle, the carrier layer 17 ' also have more than two layers.

Furthermore, it is also possible within the multilayer filter material 15 to provide four or more layers, in particular may be provided that membrane layers 16 and carrier layers 17 alternate.

The membrane layer 16 is expedient on the carrier layer 17 laminated. Additionally or alternatively it can be provided, the membrane layer 16 with the carrier layer 17 to weld. For this, the membrane layer must 16 be made of a weldable plastic. Likewise, the backing layer needs 17 which is preferably made of a fibrous material containing weldable fibers. In other embodiments, the membrane layer is 16 by gluing or calendering with the carrier layer 17 connected. Here then no weldable materials are required. In principle, the membrane layer 16 under temperature and / or pressure with the carrier layer 17 get connected.

The carrier layer 17 , in particular the multilayer carrier layer 17 ' may preferably be designed as a filter layer, and in particular work as a depth filter. In such a depth filter, a comparatively high filtration effect is realized despite the comparatively large pore size, which is determined by the spacing of the fibers used, through the material thickness to be flowed through.

At the in 7 In the embodiment shown, the membrane layer 16 the corrugated or folded filter material 6 firmly with the adjacent planar or unwanted or unfolded filter material 5 connected, in particular welded, glued or calendered be. Additionally or alternatively, the carrier layer 17 the corrugated or folded filter material 6 with the adjacent planar filter material 5 firmly connected, in particular welded or glued or calendered be. It is clear that then also the flat filter material 5 from a corresponding material, such. B. plastic is made.

At the in 8th In the embodiment shown, the membrane layer 16 of the undulating or zig-zag shaped filter material 6 with the membrane layer 16 of the flat filter material 5 be firmly connected, in particular welded, glued or calendered be. Additionally or alternatively, it may be provided here, the carrier layer 17 of the undulating or zig-zag shaped filter material 6 with the carrier layer 17 of the flat filter material 5 firmly connect, in particular to weld or glue.

In summary, it can be stated that the winding filter element presented here 1 Characterized in that for its production a multilayer filter material 15 is used, the at least one membrane layer 16 and at least one carrier layer 17 having.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2006/012495 A1 [0003]
• JP 2007-075739A [0004]
• WO 2008/153878 A2 [0005]
• WO 2006/096180 A1 [0005]

Claims (9)

Wickelfilterelement for removing impurities from a fluid stream ( 9 ), - with a filter body ( 2 ) produced by winding a filter material arrangement ( 3 ) and the outlet side closed inlet channels ( 7 ) and outlet channels closed on the inlet side ( 8th ), the filter material arrangement ( 3 ) at least one flat filter material ( 5 ) and a wave-shaped or zigzag-shaped filter material ( 6 ), which correspond to each other, in particular directly or indirectly, - wherein at least one of the in the filter material arrangement ( 3 ) used filter materials ( 5 . 6 ) as a multilayer filter material ( 15 ) - wherein the multilayer filter material ( 15 ) at least one membrane layer ( 16 ) and a carrier layer ( 17 ) having. Winding filter element according to claim 1, characterized in that - the membrane layer ( 16 ) consists of a perforated or porous film, in particular plastic or metal foil, and / or - that the carrier layer ( 17 ) consists of a material containing fibers, and / or - that the carrier layer ( 17 ) is multi-layered. Winding filter element according to claim 1 or 2, characterized in that - the membrane layer ( 16 ) is made of polyfluoroethylene propylene (PFEP) or polytetrafluoroethylene (PTFE) or polyethylene (PE) or polypropylene (PP) or high density polyethylene (PE-HD), or polyester or polyamide (PA), and / or - that the membrane layer ( 16 ) has a layer thickness in the range of 15 microns to 300 microns, and / or - that the membrane layer ( 16 ) has a pore size in the range of 1.0 microns to 80 microns. Winding filter element according to one of claims 1 to 3, characterized in that - the carrier layer ( 17 ) is made of a non-woven fabric, in particular a synthetic fiber non-woven fabric, or of a cellulose paper, and / or - that the non-woven fabric is at least partially made of weldable plastic fibers, and / or - that the cellulose paper contains a proportion of synthetic fibers, which is chosen so high that it can be welded, this proportion in particular being in the range from 20% to 40%, and / or - that the carrier layer ( 17 ) has a layer thickness in the range of 0.2 mm to 1.0 mm, and / or - that the fibers of the nonwoven or cellulose paper have a mean diameter greater than 10 .mu.m, in particular greater than 25 microns, and / or - Fibers of the carrier layer are made of plastic fibers, in particular polyethylene (PE) or polypropylene (PP) or polyamide (PA), or of polyester, or of carbon fibers or of glass fibers or of any combination thereof. Winding filter element according to one of claims 1 to 4, characterized in that - the membrane layer ( 16 ) on the carrier layer ( 17 ) is laminated, and / or - that the membrane layer ( 16 ) with the carrier layer ( 17 ) is welded, and / or - that the membrane layer ( 16 ) with the carrier layer ( 17 ) is glued. Winding filter element according to one of claims 1 to 5, characterized in that the carrier layer ( 17 ) is designed as a filter layer, in particular as a depth filter. Winding filter element according to one of claims 1 to 6, characterized in that - the membrane layer ( 16 ) between two carrier layers ( 17 ), and / or - that the carrier layer ( 17 ) between two membrane layers ( 16 ) is arranged. Winding filter element according to one of claims 1 to 7, characterized in that - only the wave-shaped or zig-zag-shaped filter material ( 6 ) through the multilayer filter material ( 15 ) is formed, wherein in particular it can be provided that the membrane layer ( 16 ) with the adjacent planar filter material ( 5 ), in particular welded, and / or the carrier layer ( 17 ) with the adjacent planar filter material ( 5 ), in particular welded, is, or - that both the wave-shaped or zigzag-shaped filter material ( 6 ) as well as the flat filter material ( 5 ) through the multilayer filter material ( 15 ), wherein in particular it can be provided that the membrane layer ( 16 ) of the undulating or zig-zag shaped filter material ( 6 ) with the membrane layer of the planar filter material ( 5 ), in particular welded, while the carrier layer ( 17 ) of the undulating or zig-zag shaped filter material ( 6 ) with the carrier layer ( 17 ) of the flat filter material ( 5 ), in particular welded, is. Use of a multilayer filter material ( 15 ), the at least one membrane layer ( 16 ) and a carrier layer ( 17 ), for producing a wound filter element ( 1 ) according to one of claims 1 to 8.

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