DE102012022285A1 - Filter element for filtration of process fluids, hydraulic fluids and liquid fuels and lubricants, has multi-layer structure of filter medium with filter folds, where all filter folds terminate along imaginary circular cylinder - Google Patents

Abstract

The filter element (1) has a multi-layer structure of a filter medium (3), which comprises filter folds (5,7) in pleated form with different fold heights. The filter element has a flow direction for cleaning fluid from a dirty side (S) to the clean side (R). All the filter folds, which are adjacent to the clean side, terminate along an imaginary circular cylinder which passes through the filter medium coaxially to its longitudinal axis.

Description

The invention relates to a filter element with a preferably multilayer structure of a filter medium having pleated filter pleats with different pleat height, with filter pleats having a first filter pleat height and with filter pleats having a lower second pleat height, wherein the filter element is a flow direction for abrein to the fluid from a dirty side to a clean side.

Filter elements of this type are commercially available. In connection with fluid systems of various kinds such filter elements are widely used for the filtration of process fluids, hydraulic fluids, such as hydraulic oils, as well as liquid fuels and lubricants for the treatment of liquid media and the like. In many cases, in fluid systems in which the filter elements are used, only a limited usable space for the installation or removal of the system parts are available that contain the relevant filter cartridge-like filter elements. On the other hand, in order to be able to filter correspondingly large filter flows, a sufficient size of the filter surface provided by the filter element is required.

In order to provide a sufficiently large filter surface, the known filter elements, as are freely available on the market, comprise a zig-zag folded or pleated filter medium typically composed of several layers of different filter materials. During manufacture, the filter medium is passed through a cutting device, in which the filter medium is cut to size on the edge before it is moved on to a folding machine, in which the zigzag shape or the pleat is formed. In the further course of production, the cut filter medium is then separated into sections, which are formed into a tubular body and thus form the filter element.

On this basis, the invention has the object to show an improved filter element, which has a high filter performance at a low flow rate even after prolonged service life.

This object is achieved by a filter element having the features of claim 1. Advantageous embodiments and further developments of the filter element will become apparent from the dependent claims.

According to the invention, the transitions of all filter folds, which are arranged adjacent to the clean side, terminate toward the clean side along a notional circular cylinder, which passes through the filter medium coaxially to its longitudinal axis.

The inventive arrangement of filter pleats of the first pleat height and the second pleat height stabilizes, wherein the filter pleats of the second pleat height support the filter pleats of the first pleat height. Consequently, a pressure-stable construction for the filter element over the filter folds of different heights is achieved. Furthermore, the filter folds of the first fold height are kept in their original arrangement during operation of the filter element and have a particularly large surface facing the dirty side. The dirty surface facing the open surface is therefore larger than conventional filter elements with a uniform fold height over the entire circumference. This makes it easier for the fluid to penetrate the filter medium, and thus leads to a filter element with improved over the lifetime filter performance and a longer life.

In standard filter element solutions all filter pleats regularly have the same operating height, which depending on the flow conditions can cause several adjacently arranged filter pleats immediately come into contact with each other along their effective filter surface, resulting in a kind of "blocking" of the element material in this contiguous area leads, as the medium to be filtered can no longer undisturbed reach all the filter folds of the element composite. By the introduced filter pleats with the second lower pleat height, the first filter pleats, regardless of the Durchströmungssituation, securely held in position and can thus effectively ensure the filtration of particulate contaminants from the fluid over the entire service life of the filter element. This is not possible with conventional elements.

Advantageously, the filter folds with the first fold height and the filter folds with the second fold height are arranged predominantly alternately to one another. The alternating or varying arrangement causes a particularly effective stabilization of the pleat geometry of the filter pleats of the first pleat height. Also, when the arrangement is alternating, more filter pleats of the first pleat height can project freely beyond filter pleats of the second pleat height, so that the surface of the filter pleats of the first pleat height exposed to the dirty side is maximized.

The filter folds with the second filter fold height can stabilize the alignment and / or arrangement of the filter folds with the first fold height. The filter folds of the second fold height therefore serve as support folds. This stabilization has an advantageous effect over the life of the Filter element, since the filtration performance is significantly improved over time by stabilizing the shape of the filter folds.

It is particularly advantageous for the filter folds with the second fold height to prevent contacting or sticking together of the filter folds of the first fold height, provided that the filter folds project with the first fold height beyond the second fold height toward the dirty side. The contacting of filter pleats always leads to an undesirable reduction of the effective filter area. This is effectively prevented by the arrangement according to the invention, since the filter pleats of the first pleat height are spaced from each other.

Conveniently, the effective filter surface of the filter medium is compared to a filter medium with uniformly high filter folds, comparable to the first fold height, despite reducing the filter surface equal, preferably increased. Consequently, with the same effective filter area, the amount of filter medium can be reduced or, despite the reduction in the surface area of the filter medium, the effective filter area can be obtained. Both approaches lead to a much improved filter element in which the utilization of the filter medium is optimal.

Advantageously, the clean side is arranged on the inside of the filter element, which is covered by the formation of the notional circular cylinder of the filter medium. In this way, the filter medium is advantageously flowed through during the filtration from outside to inside.

Alternatively it can be provided that the clean side is arranged on an outer side of the filter medium, which faces the fictitious circular cylinder. Consequently, the filter medium is flowed through from the inside to the outside. This arrangement has the advantage that the density of the filter medium can be substantially increased.

Advantageously, the respective filter fold of two adjacent flat filter surfaces is formed, which form the pleated filter medium coherently and have the same bending radius in the region of the transition to the respectively adjacent filter pleat. The arched transitions protect the filter medium during pleating. Furthermore, it is ensured that the flat filter surfaces are spaced from each other. In this way, the effective filter area is also advantageously increased.

Conveniently, the filter pleats are supported on one side by a support tube through which the fictitious circular cylinder is formed. The support tube offers a contact surface for the filter folds. Therefore, they are additionally stabilized in shape, which is particularly advantageous for highly fluctuating or pulsating fluid flows.

Furthermore, the filter folds with the second fold height can occupy 1/4 to 3/4, preferably approximately 2/3, of the height of the filter folds with the first fold height. In experiments for this area an optimal stabilization and support effect of the filter folds with simultaneous optimization of the effective filter surface could be determined.

Particularly advantageous in axial plan view of the filter medium and seen from the clean side of the filter fold of the second filter pleat height, which is bounded by a respective adjacent filter pleat with the first pleat height, formed a kind of M-fold arrangement.

Advantageously, in order to obtain columnar fine filtration regions on the base of the filter medium which is arranged on the clean side, the individual filter folds of different fold height spread with a conical profile to form the M fold arrangement.

Conveniently, due to the M-fold arrangement between two adjacently arranged filter pleats of the first pleat height, which delimit a filter pleat of the second pleat height, a free waiting space for fluid on the dirty side in the form of a fictitious cylinder segment is formed, which during operation of the filter element to a homogenization, as well preferably to a reduction, the flow rate for the fluid through the filter element leads. In the free waiting room thus fluid can be cached or dammed, in order to then flow through evenly through the filter medium. In this way, the filtration performance is improved and it is avoided excessive charging of the fluid due to a high flow rate.

It is particularly preferred due to the M-fold arrangement during operation of the filter element, in which this normally flows through a fluid with particle contamination, which leads to an electrostatic charge of the filter element, this charge reduced by the reduction of the fluid flow rate due to the respective waiting room.

The invention is explained in more detail with reference to an embodiment shown in the figures. Show it:

1 a perspective view of the filter medium;

2 a plan view of the filter medium of 1 ; and

3 an enlarged section of the representation of 2 ,

In the 1 to 3 is a filter element according to the invention 1 with a multilayer structure of a filter medium 3 shown. The filter medium 3 has filter pleats in pleated form 5 . 7 with different fold height h1, h2. filter pleats 7 a first fold height h1 are different from filter folds 5 with a contrast lower second fold height h2. The filter folds 5 with the second pleat height h2 take about 2/3 of the height of the filter pleats 7 with the first fold height h1. The filter element 1 has a flow direction for a fluid to be cleaned from an outer dirty side 5 to an inner clean side R on. Close to the clean side R, all filter folds 5 . 7 along a fictional circular cylinder 9 off, the filter medium 3 passes through coaxial with its longitudinal axis LA.

The filter folds 7 with the first pleat height h1 and the filter pleats 5 with the second fold height h2 are arranged alternately to one another and indeed the way that the filter folds 5 with the second fold height h2 the orientation and arrangement of the filter folds 7 Stabilize with the first fold height h1.

Through the filter folds 5 with the second fold height h2, a contacting or sticking together of the filter folds 7 prevents the first fold height h1, because the filter folds 7 with the first pleat height h1 across the filter pleats 5 project with the second fold height h2 to the dirty side and are spaced from each other.

It is particularly advantageous that the effective filter surface of the filter medium 3 compared to a filter medium with uniformly high filter folds, comparable to the first fold height h1, is equal to or even increased despite reducing the filter surface. The respective filter fold 5 . 7 is indeed made of two adjacent flat filter surfaces 11 . 13 formed contiguous the pleated filter medium 3 form. The flat filter surfaces 11 . 13 point in the area of the transition 15 to the respectively adjacent filter fold 7 . 5 the same bending radius BR on.

On the clean side R are the filter folds 5 . 7 through a support tube 9 supported, by which the notional circular cylinder is formed. The support tube 9 is made of metal and has distributed on its peripheral surface, circular holes for the passage of fluid.

In axial plan view of the filter medium 3 and seen from the clean side R forms the filter fold 5 with the second pleat height h2, each of which is adjacent to a filter pleat 7 is limited to the first fold height h1, a kind of M-fold assembly M from. For obtaining column-shaped fine filtration areas 16 on the purely arranged reason 17 of the filter medium 3 spread the individual filter folds 5 . 7 different fold height h1, h2 in a conical shape to form the M-fold assembly M on.

Due to the M-fold arrangement M between two adjacently arranged filter folds 7 the first fold height h1, which is a filter fold 5 Limit with the second fold height h2 is a free waiting room 19 for fluid on the dirty side S formed in the manner of a fictitious cylinder segment. During operation of the filter element 1 it comes because of the free waiting room 19 to even out and to reduce the flow rate of the fluid through the filter element 1 ,

Furthermore, due to the M-fold arrangement M during operation of the filter element 1 in which this is normally traversed by a fluid with particle contamination, resulting in an electrostatic charge of the filter element 1 leads, this charge by reducing the fluid flow due to the respective waiting room 19 reduced. It has been shown that the charge increases with increasing flow velocity and accordingly decreases with decreasing flow velocity. The aim is therefore to reduce the flow rate so far that any remaining charge can be derived by grounding the fluid in downstream components of a hydraulic circuit.

Thus, the filter element according to the invention has 1 even after a longer life a high filter performance at a low flow rate. The filter element 1 is therefore less expensive and safer in operation due to the reduced charge of the fluid flowing through, which can lead to unwanted discharges with the consequence of the destruction of the element material, the rising oil aging and increased fire risk.

Claims (14)

Filter element with a preferably multilayer structure of a filter medium ( 3 ), which in pleated form filter folds ( 5 . 7 ) with different fold height (h1, h2), with filter folds ( 7 ) with a first pleat height (h1) and with filter pleats ( 5 With a contrast lower second pleat height (h2), wherein the filter element is a flow direction for abgereininendes fluid from a Dirt side (S) to a clean side (R), characterized in that all filter folds ( 5 . 7 ), which are arranged adjacent to the clean side (R), along a notional circular cylinder ( 9 ) containing the filter medium ( 3 ) passes through coaxially to its longitudinal axis (LA). Filter element according to claim 1, characterized in that the filter folds ( 7 ) with the first pleat height (h1) and the filter pleats ( 5 ) are arranged with the second fold height (h2) predominantly alternating with each other. Filter element according to one of the preceding claims, characterized in that through the filter folds ( 5 ) with the second pleat height (h2) the orientation and / or arrangement of the filter pleats ( 7 ) is stabilized at the first fold height (h1). Filter element according to claim 3, characterized in that through the filter folds ( 5 ) with the second fold height (h2) contacting or sticking together the filter folds ( 7 ) is prevented with the first fold height (h1), provided that the filter folds ( 7 ) with the first pleat height (h1) over the filter pleats ( 5 ) with the second fold height (h2) projecting toward the dirty side (S). Filter element according to one of the preceding claims, characterized in that the effective filter surface of the filter medium ( 3 ) compared to a filter medium with uniformly high filter folds, comparable to the first fold height (h1), despite reducing the filter surface is the same, but preferably increased. Filter element according to one of the preceding claims, characterized in that the clean side (R) is arranged on the inside of the filter element, which forms the fictitious circular cylinder ( 9 ) of the filter medium ( 3 ) is included. Filter element according to one of the preceding claims, characterized in that the clean side (R) on an outer side of the filter medium ( 3 ) is arranged, which the fictitious circular cylinder ( 9 ) is facing. Filter element according to one of the preceding claims, characterized in that the respective filter fold ( 5 . 7 ) of two adjacent flat filter surfaces ( 11 . 13 ) contiguous to the pleated filter medium ( 3 ) and in the area of transition ( 15 ) to the respectively adjacent filter fold ( 7 . 5 ) have the same bending radius (BR). Filter element according to one of the preceding claims, characterized in that the filter folds ( 5 . 7 ) to the clean side (R) through a support tube ( 9 ), by which the fictitious circular cylinder ( 9 ) is trained. Filter element according to one of the preceding claims, characterized in that the filter folds ( 5 ) with the second fold height (h2) about 1/4 to 3/4, preferably about 2/3, the height of the filter folds ( 7 ) with the first fold height (h1). Filter element according to one of the preceding claims, characterized in that in axial plan view of the filter medium ( 3 ) and from the clean side (R) of the filter fold ( 5 ) with the second pleat height (h2), each of which is arranged adjacent to a filter pleat ( 7 ) is limited to the first fold height (h1) forms a kind of M-fold arrangement (M). Filter element according to claim 11, characterized in that for obtaining column-shaped fine filtration areas ( 16 ) on the cleanly arranged ground ( 17 ) of the filter medium ( 3 ) the individual filter folds ( 5 . 7 ) of different fold height (h1, h2) with a conical profile to form the M-fold arrangement (M). Filter element according to claim 11 or 12, characterized in that due to the M-fold arrangement (M) between two adjacently arranged filter pleats ( 7 ) with the first fold height (h1), which has a filter fold ( 5 ) with the second fold height (h2), a free waiting room ( 19 ) is formed for fluid on the dirty side (S) in the manner of a fictitious cylinder segment, which leads in the operation of the filter element to a homogenization, and preferably to a reduction, the flow rate of the fluid through the filter element. Filter element according to one of claims 11 to 13, characterized in that due to the M-fold arrangement (M) during operation of the filter element, in which this is normally traversed by a fluid with particle contamination, resulting in an electrostatic charge of the filter element, this charge by the reduction of the fluid flow rate due to the respective waiting room ( 19 ) is reduced.

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