DE102016005659A1 - Filter element for liquid filtration - Google Patents

Abstract

A filter element for liquid filtration has an annular filter medium body, in the interior of which a hollow body protrudes, wherein the interior of the hollow body communicates via a fresh air opening with the environment.

Description

Technical area

The invention relates to a filter element for liquid filtration according to the preamble of claim 1.

State of the art

Are known urea filters, which are used to filter an aqueous solution with a urea content. The aqueous solution is injected into the exhaust stream of diesel internal combustion engines to reduce nitrogen oxides. The urea filter for purifying the urea solution has a hollow cylindrical filter element, which is flowed through radially from the outside to the inside of the fluid, wherein the cleaned fluid is discharged axially from the inside clean room.

Under frost conditions there is a risk that the urea solution in the filter freezes and the filter element is damaged by the freezing process. To prevent freezing, urea filters can be equipped with a heating device.

Disclosure of the invention

The invention is based on the object with simple constructive measures a filter element for liquid filtration in such a way that use under freezing conditions does not lead to damage.

This object is achieved with the features of claim 1. The dependent claims indicate expedient developments.

The filter element according to the invention is used for liquid filtration, in particular for the filtration of liquids whose freezing point is at or near the water freezing point. For example, the filter element can be used for a urea filter, with which an aqueous solution with a urea content, which is for example one third of the liquid volume, can be cleaned.

Such urea solutions are injected into the exhaust stream from diesel engines to reduce nitrogen oxides to nitrogen and water.

The filter element has an annular, preferably hollow cylindrical filter medium body, which is flowed through radially by the fluid. Typically, the flow direction is radially from outside to inside, so that the outer circumferential surface of the filter medium body forms the raw side and the interior in the filter medium body the clean side. The interior is advantageously cylindrical.

The filter medium body may be formed fold-shaped and made of a nonwoven or paper material. At the end faces, the filter medium body advantageously has end disks which close the filter medium body in an axially fluid-tight manner.

In the interior of the filter medium body protrudes a hollow body, the wall of which is formed flow-tight. The interior of the hollow body is connected via a fresh air opening with the environment. This embodiment has the advantage that the interior of the hollow body assumes the ambient temperature, since an air exchange between the environment and the interior of the hollow body takes place via the fresh air opening. The hollow body therefore assumes the ambient temperature, which under freezing conditions causes the fluid is cooled by the hollow body and freezes in the interior. At the same time, the freezing process also begins on the radially outer side of the filter medium body, so that the freezing process takes place at least approximately simultaneously over the entire radial extent of the filter medium body.

The increase in volume associated with freezing in aqueous fluids does not lead to destruction of the filter medium body due to the simultaneity of freezing at the radially inner and radially outer location. Therefore, the filter element with the filter medium body can survive a freezing process undamaged and exert its thawing again its filtration function.

The accelerated freezing in the interior is supported by the volume displacement through the hollow body. The volume available in the interior for the fluid is reduced by the volume of the hollow body, so that, in combination with the faster cooling of the hollow body due to the air exchange via the fresh air opening, the freezing process in the interior is accelerated.

The hollow body is advantageously adapted to the cross-sectional geometry of the interior and has the same basic cross-section. Preferably, interior and hollow body are cylindrical, in principle, deviating cross-sectional geometries come into consideration, for example, an oval cross-sectional geometry.

The wall of the hollow body is formed flow-tight to an undesirable Exclude fluid from the interior into the interior of the hollow body. The fresh air opening is formed for example by the free, located outside of the interior end face of the hollow body. However, also come in embodiments in which the fresh air opening is introduced into the outer wall of the hollow body.

The fresh air opening is expediently located axially outside the interior in the filter medium body. However, it is also possible embodiments in which the fresh air opening is within the interior, but communicates with the environment, for example via an outwardly leading hose or pipe connection.

Advantageously, the hollow body extends axially over a majority of the length of the interior in the filter medium body, for example over at least 80% or at least 90% of the interior length. Optionally, the protruding into the interior, closed executed end face of the hollow body is at a distance from the interior end face; but the front side can also conclude with the front side of the interior or protrude beyond the interior end face.

The wall of the hollow body may have a different thickness at different axial positions. Conveniently, the hollow body in the axially projecting into the interior portion has a smaller wall thickness than outside the interior.

It may also be expedient that the outer diameter of the hollow body is at least half of the inner diameter of the inner space in the filter medium body. Optionally, larger outer diameter come into consideration, for example, at least 60%, 70% or 80% of the inner diameter of the interior. However, hollow bodies are also possible whose outer diameter is less than 50% of the inner diameter of the inner space. However, larger outer diameters have the advantage that a larger volume displacement takes place in the interior and accordingly less fluid can accumulate in the interior, so that the cooling and possibly the freezing of the fluid in the interior takes place faster.

The hollow body may consist of an elastically yielding material, such as EPDM or a rubber material such. B. HNBR (hydrogenated acrylonitrile-butadiene rubber).

The filter element for liquid filtration forms a filter cartridge which can be advantageously used in a filter device such as a urea filter. The filter device comprises, in addition to the filter element, a filter housing into which the filter element is inserted. The hollow body can, according to an advantageous embodiment, be connected to a cover of the filter housing which closes the receiving opening into which the filter element is inserted. The hollow body is preferably fixedly connected to the lid of the filter housing, in particular made in one piece with the lid. It is expedient that the fresh air opening is adjacent to the outside of the lid, wherein advantageously the open end side of the hollow body forms the fresh air opening.

Brief description of the drawings

Further advantages and expedient embodiments can be taken from the further claims, the description of the figures and the drawings. Show it:

1 a section through a filter device which can be used as a urea filter, with a hollow cylindrical filter element inserted into a filter housing, in the interior of which a hollow body protrudes,

2 the filter element with einragendem hollow body in a detail view.

In the figures, the same components are provided with the same reference numerals.

Embodiment (s) of the invention

In the figures is a filter device 1 with a filter element 3 represented, which is used for the filtration of an aqueous solution with a urea content. The filter device 1 has a filter housing 2 and one in the filter housing 2 inserted filter element 3 on which a hollow cylindrical filter medium body 4 comprising, at both axial end faces of a respective end plate 5 respectively. 6 is enclosed. The filter element 3 with the filter media body 4 is traversed radially from outside to inside of the fluid to be cleaned, so that the outside of the filter medium body forms the crude side and a cylindrical interior 7 in the filter medium body 4 the clean side, from which the purified fluid is discharged axially.

The receiving filter housing 2 consists of a cup-shaped housing basic body 2a and one with the housing base 2a screw-on lid 2 B , The cup-shaped housing basic body 2a has a receiving space in which the filter element 3 is used axially. The lid 2 B is provided with an external thread and can in an associated internal thread on the housing body 2a be screwed.

The filter media body 4 is designed for example as a pleated filter and can be made of a paper or nonwoven material.

In the cylindrical interior 7 in the filter medium body 4 a hollow body protrudes 8th one, the one-piece with the lid 2 B of the filter housing is executed. The hollow body 8th on the one hand has the function of a displacement body, since the volume freely available for the fluid in the interior 7 by the insertion of the hollow body 8th is reduced accordingly. On the other hand has the hollow body 8th a temperature-conducting function by the interior 9 of the hollow body 8th over a fresh air opening 10 communicates with the environment and cold air in the interior at freezing temperatures 9 flows in, so that the hollow body walls cool accordingly and the fluid in the interior 7 also cooled accordingly. The hollow body 8th is cylindrical and has a rounded tip, which in the interior 7 protrudes. The fresh air opening 10 is located on the rounded tip axially opposite side and forms the open end side of the hollow body 8th on the outside of the lid 2 B , the conclusion of the filter device 1 forms to the outside, leaving the fresh air opening 10 connected to the environment and the interior 9 and the wall of the hollow body 8th can accept the ambient temperature.

At freezing temperatures, accordingly, the aqueous solution in the interior 7 of the filter medium body 4 freeze. At the same time, the freezing process also begins on the radially outer side of the filter element 3 so that the freezing process takes place uniformly and simultaneously in the radial direction. This has the advantage that the filter medium body 4 not deformed and accordingly the filter element with the filter medium body is not destroyed by the freezing process. Accordingly, the filter device retains 1 their ability to function, so that after thawing the fluid in the filter device 1 can be cleaned.

The hollow body 8th is advantageously due to the one-piece design with the lid 2 B from the same material as the lid, in particular from a plastic material. The wall of the hollow body 8th is fluid-tight, to prevent ingress of fluid into the interior 9 of the hollow body 8th to prevent. The thickness of the wall of the hollow body 8th is formed at different axial positions of different sizes; the larger axial part of the interior 7 projecting portion of the hollow body 8th has a smaller wall thickness than that outside the interior 7 located section. This ensures that when cold air enters the interior 9 the wall inside the interior 7 cools quickly and therefore quickly a freezing process is initiated.

The hollow body 8th has a relatively large outer diameter, whereby a relatively large volume in the interior 7 through the hollow body 8th is displaced. Accordingly, the remaining volume in which purified fluid is contained reduces, thereby allowing faster cooling and faster freezing of the remaining volume in the interior 7 is guaranteed. The outer diameter of the hollow body 8th points in the interior 7 protruding section about 70% of the inner diameter of the interior 7 on. In the area of the larger outside diameter in the section outside the interior 7 is the outer diameter of the hollow body 8th about 80% of the inside diameter of the interior 7 , In the axial direction, the hollow body extends 8th over approximately the entire axial length of the filter media body 4 , only the rounded end face of the hollow body 8th is located at a small axial distance to the front side of the interior 7 ; Overall, the hollow body extends 8th at least 90% over the axial length of the filter media body 4 ,

Claims (11)

Filter element for liquid filtration, in particular for a urea filter, with an annular filter medium body ( 4 ) housed in a filter housing ( 2 ), characterized in that in the interior ( 7 ) of the filter medium body ( 4 ) a hollow body ( 8th ) whose wall is formed flow-tight, wherein the interior ( 9 ) of the hollow body ( 8th ) via a fresh air opening ( 10 ) communicates with the environment. Filter element according to claim 1, characterized in that the hollow body ( 8th ) is formed as a hollow cylinder. Filter element according to claim 1 or 2, characterized in that the fresh air opening ( 10 ) in the wall of the hollow body ( 8th ) and outside the interior ( 7 ) of the filter medium body ( 4 ) lies. Filter element according to one of claims 1 to 3, characterized in that the hollow body ( 8th ) consists of an elastically yielding material, such as EPDM or a rubber material such. B. HNBR. Filter element according to one of claims 1 to 4, characterized in that the outer diameter of the hollow body ( 8th ) at least 50% of the inside diameter of the interior ( 7 ) of the filter medium body ( 4 ) is. Filter element according to one of claims 1 to 5, characterized in that the wall of the hollow body ( 8th ) has a different wall thickness axially sections. Filter element according to one of claims 1 to 6, characterized in that the hollow body ( 8th ) axially over at least 80% of the axial length of the interior space ( 7 ) of the filter medium body ( 4 ). Filter element according to one of claims 1 to 7, characterized in that the filter medium body ( 4 ) is formed fold-shaped. Filter device, preferably urea filter, with a filter element ( 3 ) according to one of claims 1 to 8 and with a filter housing ( 2 ) for receiving the filter element ( 3 ). Filter device according to claim 9, characterized in that the hollow body ( 8th ) with a lid ( 2 B ) of the filter housing ( 2 ) connected is. Filter device according to claim 9 or 10, characterized in that the hollow body ( 8th ) through the lid ( 2 B ) of the filter housing ( 2 ) and the fresh air opening ( 10 ) adjacent to the outside of the lid ( 2 B ) lies.

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