DE102021129158A1 - Filter element and filter system - Google Patents

Abstract

The present invention relates to a filter element (1) comprising a plurality of filter medium bodies (11, 12) fitting into a predefined filter housing (3). Each filter media body (11, 12) further comprises a filter media element (111, 112) surrounded by a peripheral edge (C1, C2), each peripheral edge (C1, C2) having a plurality of side bands (21a-21e, 22a- 22e). The multiple filter medium bodies (11, 12) are connected to one another in a sealed manner via at least one of the side bands (21a, 22a) via a defined overlap (6) at an overlapping section (6a), the multiple filter medium bodies (11, 12) being arranged axially offset from one another and form a stair-like or step-like structure. To conform the filter element to the predefined housing, the plurality of filter media bodies (11, 12) are discretely shaped, with one of them having a non-rectangular shape.

Description

Technical field of the invention

The present invention relates to a filter element, in particular for air filtration, and to a filter system.

State of the art

In the field of air filtration, for example in motor vehicles or in building air conditioning systems, it is known to use filter elements which are arranged in corresponding filter housings in an air duct. Such filter elements usually have at least one filter medium body, which consists of a zigzag-pleated filter material, such as paper or non-woven fabric.

Typically, the primary objective of the filter element is to filter as much air as possible for a given filter housing and media. H. to cause the lowest possible pressure drop while maintaining good filtration efficiency.

Furthermore, when designing filter elements, it can be a challenge to adapt the shape of the filter element to the geometry of a corresponding cavity of a filter housing, since the cavity can have a complex shape, e.g. B. curved, curved, stepped, may be provided with obstacles or the like. A filter element can be conformed to the internal shape of the housing by changing the arrangements of a plurality of filter media bodies so that the filter element can fit within the housing.

EP1447250 A2 , describes a prefabricated filter housing that is divided into two chambers that are offset in height from one another. Each chamber receives a body of filter media to form a filter element. The filter media bodies are provided with a plurality of sealing flaps on their sides which ensure that the filter media bodies are inserted into the respective chambers which are sealed against the predefined filter housing. Since the chambers are offset in height from one another, the filter medium bodies are also offset in height from one another. The filter elements are not connected to each other, so that two individual filter elements have to be replaced separately during operation, which is time-consuming and costly, since two (different) parts have to be supplied.

Technical problem

In order to overcome the above problems, it is therefore an object of the invention to provide a filter element which is adapted to housings which require axially offset bodies of filter media, but which allow for easier maintenance and lower costs.

This object is achieved by a filter element according to claim 1.

Another object of the invention is to provide a corresponding filter system. This object is achieved by a filter system according to claim 11.

Description of the invention

The filter element of the present invention comprises: a plurality of filter media bodies each having a filter media element, each filter media body having a peripheral edge provided with a plurality of side bands along its edges.

Said filter medium bodies are tightly connected to one another to form the filter element, so that the filter medium bodies are axially spaced from one another, the filter medium bodies being able to separate an upstream raw side from a downstream clean side. The filter element thus formed is suitable for adapting to a predefined filter housing.

According to a preferred embodiment, the filter medium bodies are connected to one another via the side bands of the peripheral edges by a sealing means, so that they are joined together to form a filter element.

Since the filter element consists of a plurality of filter media bodies which are axially offset and fastened closely together, only the axially spaced filter element can be replaced during maintenance. This allows it to be easily replaced during maintenance, and completely eliminates the maintenance effort of replacing two or more filter media bodies. In addition, quick maintenance of the filter element is made possible, which in turn reduces the costs for replacing the filter element.

According to the preferred embodiment, at least one of the side straps of one filter medium body is sealingly attached to at least one of the side straps of the other filter medium body.

Another object of the invention is that the filter medium bodies are connected to one another in a sealed manner, forming a defined overlap of their side bands, one of the side bands of one filter medium body being overlapped with at least one of the side bands of the other filter medium body.

In an advantageous embodiment, at least one of the side bands consists preferably of a fleece material, in particular a fleece band. The sealing connection formed in this way by the fleece strips is used to attach the filter element to the predefined housing.

The axial distance between the filter medium bodies thus forms a stepped structure of the filter element, as a result of which, in contrast to the prior art, more filter media can be accommodated.

Also, the filter element formed in this way does not tear apart due to the overlapping of the filter medium bodies at the predetermined overlap by the non-woven tape during heavy engine operation and thus gives the filter system stability.

Severe stresses can include abnormal acceleration of the engine, driving on hilly terrain, unrepaired road structures, etc.

In a preferred embodiment, at least one of the filter media elements is pleated or zigzag or corrugated to accommodate more filter media within the predefined housing, the pleated filter media having a front and a back surface.

In an advantageous embodiment, at least one of the side strips of one filter medium body is attached to the end face of the other filter medium body with the folded filter medium.

According to a preferred embodiment of the invention, the filter element is designed to fit into a predefined filter housing in an installed or assembled condition, the filter element being defined as having a plurality of directions.

By defining directions for the filter element, the orientation of the filter element in relation to the predefined housing of the filter system can be easily understood.

In an advantageous embodiment, when installed, an axial direction and a lateral direction are defined for the filter element, which are perpendicular to one another.

In an advantageous embodiment, the direction in which the folds are formed in the filter media element is defined as the fold direction.

In a further advantageous embodiment, the fold direction of the filter element in the installed state is perpendicular to its axial direction and parallel to its lateral direction.

In a further advantageous embodiment, the fold direction of the filter element in the installed state is parallel to its axial direction and perpendicular to its lateral direction.

In another advantageous embodiment, each filter media body has an upstream dirty air side and a downstream clean side, with the unfiltered dirty air flowing from the upstream dirty air side of the filter element to the downstream clean side to provide clean air.

In a further advantageous embodiment, the air flow from the upstream dirty side to the downstream clean side is defined as a flow direction that runs perpendicular to the axial and lateral direction of the filter element. The axial and lateral directions of the filter element serve to define and understand the pleat direction and the flow direction of the dirty raw air from the upstream raw side to the downstream clean side.

In an advantageous embodiment, at least one of the filter media bodies is chosen to be non-rectangular to fit within the predefined housing of complex shape. Conveniently, the filter element according to the invention can be retrofitted into the existing, predefined housing.

Accordingly, in an advantageous embodiment, at least one of the filter media bodies is non-rectangular, particularly trapezoidal, to fit within the given filter housing, while the other filter media body is rectangular or square in shape.

Accordingly, in an advantageous embodiment, the filter media bodies are superimposed such that the filter media bodies are axially spaced from one another, with the non-rectangular filter media body being axially spaced from the rectangular filter media body.

In a further advantageous embodiment, the axially staggered, spaced-apart filter media bodies form a stair or step structure wherein the raw upstream side of the non-rectangular filter media body is axially spaced from the raw upstream side of the rectangular filter media body, and vice versa.

In a further advantageous embodiment, the step structure can be an ascending step structure or a descending step structure.

Since the filter element adopts a stepped or stepped structure, most of the available space in the predefined housing is used, which, as already mentioned, creates more filter surface for the dirty raw air on the inlet side. In addition, the filter medium bodies can be used interchangeably. In practice, the rectangular and non-rectangular bodies of filter media can be interchanged, being joined by the non-woven tape at the predefined overlap to conform the filter element to the predefined filter housing. Another object of the invention relates to a filter system with a predefined housing and a filter element according to the invention. The predefined housing comprises: an accommodation space for accommodating the filter element, an insertion opening through which the filter element is inserted into the accommodation space, and a plurality of fixing pins which are arranged on a housing wall opposite the insertion opening.

In an advantageous embodiment, the locating pins are arranged diagonally opposite one another on the housing wall, with at least one of the several locating pins extending over the upstream unfiltered side of the at least one filter medium body and at least one of the several locating pins over the downstream clean side of the at least one filter medium body when installed.

In an advantageous embodiment of the invention, the direction in which the filter element is inserted into the predefined filter housing is defined as the insertion direction, with the insertion direction running perpendicular to its lateral direction and parallel to its axial direction. And it is also parallel to the pleat direction of the filter element. In a further advantageous embodiment, the insertion direction is perpendicular to the fold direction of the filter element.

In a further advantageous embodiment, the fleece strip of the at least one side strip is aligned parallel or perpendicular to the insertion direction of the filter element.

character list

• 1 shows the installation status of a filter element in a predefined housing;
• 2 shows the filter element in the non-installed state;
• 3 shows an exploded view of the filter element;
• 4 shows the insertion of the filter element into the predefined housing and
• 5 shows the predefined chassis in an uninstalled state.

Detailed description of the drawings

As in 1 shown, the present invention describes a filter element 1 that can be inserted into a predefined filter housing 3 and thus forms a filter system 10 .

As in 2 and 3 shown, the filter element 1 comprises a plurality of filter media bodies, namely a first filter media body and a second filter media body, represented by 11 and 12, respectively. The first filter media body comprises a first filter media member 111 having a first peripheral edge C1, and the second filter media body comprises a second filter media member 112 with a second peripheral edge C2.

As in the 2 - 3 shown further. 2-3, the first filter media element 111 and the second filter media element 112 comprise a filter medium 5, the filter medium 5 being folded or corrugated in a zigzag or continuous V-shaped manner, the filter medium 5 further comprising a first filter medium 51a which is the first filter media element 111, and a second filter medium 51b forming second filter media element 112, the first pleated filter medium 51a being defined as having two faces, namely front face 7a and back face 7b. Similarly, the second filter medium 51b has two surfaces, namely the front 8a and the back 8b. The direction in which the folds are formed in the filter medium is referred to as the fold direction P of the filter element 1 .

As in 3 As shown, the peripheral edges C1 and C2 of the first and second filter medium bodies 11, 12 each have a plurality of side bands. The first peripheral edge C1 of the first filter media body 11 includes a plurality of side bands 21a, 21b, 21c, 21d and optionally 21e. Similarly, the second peripheral edge C2 of the second filter media body 12 comprises a plural number of sidebands 22a, 22b, 22c, 22d and optionally 22e.

The first and second filter medium bodies 11 and 12 have a discrete shape, one of which has a square or rectangular shape while the other is non-rectangular, specifically trapezoidal.

As in 3 further shown, side straps 21a and 21c and side straps 21b and 21d are of equal length, and side straps 22a, 22b, 22c, 22d and 22e are of different lengths, side straps 21a and 22a being of equal length.

The first and second filter media bodies 11 and 12 are axially spaced from each other, with the filter media bodies 11, 12 extending one above the other in a predefined overlap 6 where the first filter media body 11 and the second filter media body 12 are superimposed.

The predefined overlapping 6 is defined as an overlapping area 6a, on which the first filter medium body 11 and the second filter medium body 12 are arranged one above the other in an axially offset manner.

In one embodiment, the side band 22a of the second filter media body 12 is attached to the front face 7a of the first pleated filter media 51a at the overlapping portion 6a.

The axially offset and spaced filter medium bodies 11 and 12 are sealed from one another by the equilateral side bands 21a and 22a.

The side bands 21b, 21c and 21d and the side bands 22b, 22c, 22d and 22e seal the axially offset arranged first and second filter medium bodies 11 and 12 against the predefined filter housing 3 .

The side bands 21a-21d and 22a-22e preferably consist of a non-woven material 52, in particular a non-woven band. However, other available forms of non-woven material can also be used.

The filter medium bodies 11 and 12, which are arranged axially offset and sealed against one another at the side bands 21a and 22a, form a filter element 1.

As in 1 shown, the filter element 1 has a plurality of directions in the installed or assembled state, namely the axial direction A and the lateral direction L, with the axial direction A running perpendicular to the lateral direction L and the previously defined folding direction P of the filter element perpendicular to the axial Direction A and parallel to the lateral direction L of the filter element 1 runs.

As in further illustrated, the fold direction P of the filter element in the installed state is parallel to its axial direction A and perpendicular to its lateral direction L.

As in 3 shown, the filter element 1 further comprises an upstream dirty side RS and a downstream clean side CS, the unfiltered dirty air flowing from the upstream dirty side RS through the filter element 1 to the downstream clean side CS to provide a clean and filtered air, and the direction in which the air flows from the upstream raw side RS to the downstream clean side CS is defined as the flow direction F.

In the installed or mounted state, the flow direction F of the filter element 1 is perpendicular to its axial direction A, the direction in which the predefined overlap 6 is formed being perpendicular to the axial direction A.

How further in 3 shows, the first filter media body 11 further comprises an upstream raw side RS1 and a downstream clean side CS1, and the second filter media body 12 further comprises an upstream raw side RS2 and a downstream clean side CS2, being in an installed or assembled state the upstream raw side RS1 and the upstream raw side RS2 are axially spaced from each other, and the downstream clean side CS1 and the downstream clean side CS2 are axially spaced from each other with respect to their respective upstream raw sides RS1 and RS2.

In the installed or assembled state, the filter element 1 assumes a step-like structure, in particular a stepped structure, with the axially offset arranged upstream blank sides RS1 and RS2 having an increasing stepped structure and the corresponding downstream clean sides CS1 and CS2 having a decreasing stepped structure with respect to the fold direction P of the Form filter element 1 and vice versa. According to one of the 4 and 5 Embodiments shown, a filter system 10 comprises the axially offset arranged rectangular and non-rectangular filter medium bodies 11 and 12, which fit into the predefined filter housing 3, wherein the predefined filter housing 3 also has a receiving space 31 for opening of the filter element 1, an insertion opening 32 through which the filter element 1 is inserted into the receiving space 32, and a housing wall 33 opposite the insertion opening 32. As in 1 shown, the filter system 10 further comprises a plurality of locating pins 41 and 42 which are arranged diagonally opposite one another on the housing wall 33, with the locating pin 41 extending over the upstream raw side RS1 of the first filter medium body 11 and the locating pin in an installed or assembled state 42 extends over the downstream clean side of the second filter medium body 12, the side bands 21a and 22a being arranged at a distance x and y, respectively, from the locating pins 41 and 42. However, the distance x is not shown in the figures.

As in 4 1, the filter system 1 is further formed by inserting the filter element 1 into the accommodating space 31 through the insertion opening 32, with the direction in which the filter element 1 is inserted into the accommodating space 31 being defined as the insertion direction I, which is parallel to the axial direction A is the normal to the lateral direction L of the filter element and parallel to the pleat direction P of the filter element. As in shown further, the fold direction P runs perpendicular to the insertion direction I.

In a further advantageous embodiment, the plurality of filter medium bodies can be two or more than two, e.g. B. act three filter media bodies, the respective side bands fit into the given filter housing.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was 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.

Patent Literature Cited

• EP 1447250 A2 [0005]

Claims (14)

Filter element (1) with a filter medium body (11, 12) which has a peripheral edge (2) which can cooperate in a sealing manner with a predefined filter housing (3), the filter medium body (11, 12) being suitable for an upstream unfiltered side ( RS) from a downstream clean side (CS), wherein the filter medium body (11, 12) comprises at least two filter medium elements (111, 112) with a filter medium (5), characterized in that the at least two filter medium bodies (11, 12) axially offset sealing attached to each other. Filter element (1) after claim 1 , characterized in that at least one of the filter media elements (111, 112) comprises a pleated filter media (51a, 51b). Filter element (1) after claim 1 or 2 , characterized in that the peripheral edge (2) has at least one side band (21a, 22a) which is sealingly attached to at least one filter media element (111, 112), wherein preferably the at least one side band (21 a) on one of the end faces ( 7a, 7b) of the pleated filter medium (51a, 51b), the side band preferably having a fleece material (52). Filter element (1) after claim 2 , characterized in that the at least one filter medium body (11, 12) has a plurality of side bands (21a-21e, 22a-22e), wherein the at least one side band (21a) the at least one filter medium body (11) and the at least other filter medium body ( 12) sealingly connects. Filter element (1) after claim 1 or 2 , characterized in that the at least two filter medium bodies (11, 12) have at least one side band (21a-21e), the at least two filter medium bodies (11, 12) being connected directly or indirectly via said side bands. Filter element (1) after claim 1 or 2 , characterized in that the at least two filter medium bodies (11, 12) are arranged perpendicular to their axial direction (A) with a predetermined overlap with one another. Filter element (1) after claim 1 or 4 , characterized in that at least two filter medium bodies (11, 12) are attached to one another in a sealing manner, at least one of the filter medium bodies (11, 12) having a non-rectangular shape, in particular a trapezoidal shape. Filter element (1) according to one of claims 3 until 6 , characterized in that the upstream raw side (RS) of the non-rectangular filter medium body (11, 12) is sealingly attached to the axially offset downstream clean side (CS) of the other filter medium body on its side bands (21a, 22a) perpendicular to the axis direction (A) of the filter medium body is. Filter element (1) according to one of the preceding claims, characterized in that the upstream raw side (RS2) of the non-rectangular filter medium body is arranged axially offset to the upstream raw side (RS1) of the other filter medium body and vice versa. Filter element (1) after claim 8 , characterized in that the upstream raw sides (RS1, RS2) of the at least two filter medium bodies (11, 12) are aligned axially offset from one another and form a rising or falling staircase structure on the upstream raw side and vice versa. A filter system (10) comprising: a predefined housing (3) having a receiving space (31) for receiving a filter element (1), the housing (3) having an inlet on the raw flow side (RS) of the filter element (1) and an outlet the clean flow side (CS) of the filter element (1), characterized in that the filter element (1) is a filter element according to one of the preceding Claims 1 - 10 is. Filter system (10) after claim 11 , wherein the housing (3) has an insertion opening (32) for the filter element (1), which opens into the receiving space (31); wherein the housing (3) has at least one fixing pin (41, 42) which is arranged on a housing wall (33) opposite the insertion opening (32), and wherein the at least one fixing pin (41, 42) is in an installed state of the filter element (1) extends over one of the filter media bodies (11, 12) of the filter element (1). Filter system (10) after claim 12 , comprising a plurality of locating pins (41, 42), wherein in an installed state of the filter element (1) at least one of the plurality of locating pins (41, 42) extends over the upstream raw side (RS) of the at least one filter medium body (111, 112 ) and at least one of the plurality of locating pins (41, 42) extends over the downstream situated clean side (CS) of the at least one filter medium body (111, 112). Filter system (10) according to one of the preceding claims, characterized in that the folds of the pleated filter medium (51a, 51b) are aligned perpendicularly or parallel to the insertion direction (I) of the filter element (1) through the insertion opening (32).

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