US20160051910A1

US20160051910A1 - Filter element

Info

Publication number: US20160051910A1
Application number: US14/779,583
Authority: US
Inventors: Andreas Schunk; Dominic Schneider
Original assignee: Hydac Filter Systems GmbH
Current assignee: Hydac Filter Systems GmbH
Priority date: 2013-05-03
Filing date: 2014-04-05
Publication date: 2016-02-25
Also published as: EP2991748A1; CN205412513U; EP2991748B1; WO2014177246A1; US20190232203A1; DE102013007605A1; US10653981B2

Abstract

The invention concerns a filter element for fluids, in particular for hydraulic fluid, consisting of at least one foldable filter casing (10) with at least one filter layer (18, 20, 22, 24), which extends between two end caps (26, 32), characterized in that, in order to vary in regions the thickness of the filter casing (10), the height (h₁) of each filter fold (12, 44) increases from one end cap (26) to the other end cap (32) or, with the filter fold height (h₁) being maintained, the outer diameter (40) of the filter casing (10) varies in the direction of one of the end caps (26, 32).

Description

The invention concerns a filter element for fluids, in particular for hydraulic fluids, consisting of at least one foldable filter liner having at least one filter layer, where said filter liner extends between two end caps.
Filter elements of this kind are customary. Such filter elements are widely used in conjunction with fluid systems of all kinds for filtering processing fluids, compression fluids such as hydraulic oils, liquid fuels and lubricants, as well as for the treatment of liquid media and such like. Fluid systems, in which the filter elements are used, provide in many instances only a limited amount of space for the installation or removal of those system components that contain the respective filter candle-like filter elements. Nevertheless, in order to be able to filter correspondingly large fluid flows, a sufficiently large filter surface is required from the filter element.
To provide a sufficiently large filter surface, the known, commercially freely available filter elements consist typically of multiple layers of different filter materials of a zig-zag-like folded or pleated filter medium. During production the filter medium is passed through a cutting facility in which the filter material is trimmed to size along the edges before it is fed to a folding machine where the zig-zag-shape or pleating is formed. In the next stage of production the trimmed filter medium is cut into sections that are formed into a tubular body, which forms the filter element.
Based on this, it is the object of the invention to provide an improved filter element, which is characterized by a high filtering capacity even after a long service life.
This object is met by a filter element having the features of claim 1. Advantageous embodiments and further developments of the filter element are disclosed in the dependent claims.
According to the invention, provision is made in which, for a zonal variation of the thickness of the filter liner, the height of the respective filter pleats increases, starting from one end cap to the other end cap, or in which the outer diameter of the filter liner increases in the direction of one end cap whilst the height of the filter pleats is maintained.
The shape of the filter liner that is provided according to the invention, which may, for example, be designed such that the outer and/or inner liner surface of the filter liner extends conically, opens up the opportunity to adapt the filter liner, or more accurately, the structure of the filter layers that form the filter liner, optimally to the varying pressure and flow conditions that occur in the different regions between the end caps. For example, the fact that a higher or lower static pressure exists close to one of the end caps, can be accommodated through a greater height of the folds and the resultant thickening of the filter liner. In this respect it is also possible to make the outer diameter of the filter liner at one or the other end cap greater than in the vicinity of the other end cap. This can achieve a more even flow through the filter, which results in a low pressure loss at reduced turbulence, resulting, in turn, in a high filtering capacity and a long service life.
In particularly advantageous exemplary embodiments, in which the filter liner surrounds a hollow space, the arrangement may be advantageously designed such that the one end cap is provided with a passage to supply unfiltrate, which flows through the filter liner from the hollow space outwards in filtration direction, and in which the other end cap is closed to said flow.
Such an inflow of the unfiltrate from the direction of one of the end caps provides the particular advantage that the height of the filter pleats changes in that it increases in the direction towards the closed end cap. As a result of the thus caused increased thickness of the filter liner in the vicinity of said end cap, the increased dynamic pressure level is taken into account, which is present in the vicinity of the closed end cap when unfiltrate is fed in from the other end cap.
The change in the height of the filter pleats can be constant to achieve a conical shape of the outer and/or inner side of the filter liner.
In particularly advantageous exemplary embodiments, the increase in the height of the pleats creates a zonal increase of the outer diameter of the filter liner. The filter element thus has the shape of an externally conical filter candle, in which the conicity may be relatively small, for example in the range of 1 to 2 angular degrees.
Alternatively, the arrangement may be such that the increase in the height of the pleats causes not only a zonal increase in the outer diameter of the filter liner but also a zonal decrease of the internal diameter of the hollow space of the filter liner. Thus, the conical shape of the outside results also in an inner cone shape in the internal hollow space of the filter liner.
The outer diameter of the filter liner preferably increases from the open end cap towards the closed end cap. When feeding unfiltrate from the upper end cap, the cone shape that tapers from bottom to top is advantageous for the flow of the filter medium.
When forming the pleated filter liner by folding the filter layers, the process followed may be such that, to pleats of a first kind which, due to their height, make up the majority of the thickness of the filter element, pleats of a second kind are added, preferably alternating, that have pleats that are lower in height than those of the first kind. This type of folding pattern, also called M-pleat or W-pleat, has advantages with respect to the configuration of the filter liner according to the invention, such as lower pressure losses, increased capacity to absorb contaminants and an increased security against a kind of “blockage”, such as can occur in conventional filter elements through immediate contact between effective pleat surfaces, depending on the flow conditions.
As an alternative to changing the thickness of the filter liner through a change in filter pleat heights, which is caused by a corresponding kind of folding pattern, the zonal variation of the thickness of the filter liner can also be achieved through local application of additional, in particular strip-like, filter layers while maintaining the same pleat height. It is possible, for example, to provide a varying number of filter layers from one edge of the filter layer mat, which forms the filter liner, to the other edge of the filter mat.

The invention is now explained in greater detail based upon exemplary embodiments depicted in the drawing. Shown are in:

FIG. 1 the upper part of the filter element according to the prior art in partial section and schematically simplified;

FIG. 2 a perspective view of an exemplary embodiment of the filter element according to the invention;

FIG. 3 a perspective view of the exemplary embodiment of FIG. 2 shown in longitudinal section;

FIG. 4 a schematically very simplified functional sketch to show the configuration of only the filter liner for one exemplary embodiment of the filter element according to the invention, in which the representation depicts an exaggeratedly large cone angle that is not to scale;

FIGS. 5 and 6 are functional sketches, similar to FIG. 4, of the filter liner of further exemplary embodiments;

FIG. 7 a schematically simplified, perspective view of a filter liner for one exemplary embodiment of the invention, shown in expanded view;

FIG. 8 a schematically simplified top view of the filter liner of a further exemplary embodiment;

FIG. 9 an enlarged depiction of the section marked with IX in FIG. 8, and

FIG. 10 a longitudinal section in perspective view of the filter element according to a further exemplary embodiment of the invention.

The filter element that is partially illustrated in FIG. 1, which constitutes the prior art, has a filter liner 10 as the filter material with a predefinable surface area and predefinable filter characteristics. The filter liner 10 is pleated, as illustrated in FIG. 1, with individual filter pleats 12, which extend in a tight package sequence between an inner fluid-permeable support tube 14 and an outer cylindrical casing 16, which is likewise fluid-permeable. The casing 16 may consist of a mesh structure made from plastic or stainless steel or similar. For the sake of a clearer depiction, the individual filter pleats 12 are depicted slightly pulled apart in the left, upper part of FIG. 1, and the individual layer structure of the pleated filter liner 10 is revealed from the partial depiction facing the observer.
In the case of filter elements of this kind, the filter liner 10 typically comprises a first support layer 18, a second layer 20 as protective nonwoven, a third layer 22 as the main nonwoven or filter layer, optionally a further, likewise adjoining, not depicted, layer of a protective nonwoven and, if applicable, a fourth layer in form of another support layer 24, which extends along the inner circumference. Said support layers 18, 24 may consist of a wire fabric, a plastic grid or a plastic fabric. One of these support layers 18, 24 serves as a drainage layer in addition to its supporting function. The protective nonwovens 20 are normally composed of a plastic nonwoven, and the main nonwoven layer, or filter layer 22, is composed of materials such as glass fiber paper, synthetic filter material (melt-blown fibers), cellulose paper, or the like. The layers referred to above can also be made from so-called composite materials of the same type, or of a different type. Depending on the layer structure and on the respective filter materials used, the filter liner 10 has predefinable filter characteristics, in accordance with the filtration task, wherein, on principle, a high pressure differential stability is desired, as well as a high R-stability across a wide pressure differential range, as well as predefinable filter fineness, wherein sufficient flow channels should be available on the filter element for decreasing the pressure differential, while a good resilience against changing pressure loads should be ensured at the same time.
With respect to FIG. 1, fluid flows through the filter liner 10 in the known filter element from the exterior to the interior, and the filter element rests, at its relevant folds on its internal circumference, against the external circumference of the support tube 14, on the annular outlets thereof. Each of the filter element ends is accommodated in an end cap, wherein only the upper end cap 26 is depicted in FIG. 1, which also comprises a spring-loaded bypass valve 28 that enables the passage of fluid for safety reasons, even if the filter element 10 is blocked through contaminants.
The FIG. 2, in contrast, depicts an exemplary embodiment of the filter element according to the invention in form of a type of filter candle in which, during the filtering process, the medium flows through the filter liner 10 from the inside to the outside. Correspondingly, the end cap 26 shown in FIG. 2 at the top is provided with a central passage 30 for the supply of unfiltrate, whilst the lower end cap 32 is closed. In FIG. 2 as well as in FIG. 3, which show the exemplary embodiment in longitudinal section, the outer casing, which is designated with 16 in FIG. 1, has been omitted in each. A handle 34, which is molded on the open end cap 26, facilitates handling when installing or removing the filter element, which may be accommodated in a filter housing or a tank (neither of which are shown). The outside of the filter element shown in FIG. 2 and FIG. 3 tapers slightly conically from the closed, lower end cap 32 to the upper, open end cap 26, in which the taper is hardly visible in the depiction in FIGS. 2 and 3 since the angle of the conical taper in the example shown is only one angular degree.
The FIGS. 4 to 6 depict, through highly simplified and not-to-scale sketches that show the cone angles exaggeratedly large to facilitate understanding, a number of possibilities to shape the filter liner 10 in such a way that the thickness of the filter liner 10 varies from one end cap to the other end cap. To increase of the thickness of the filter liner 10 from top to bottom, that is, from the upper, open end cap 26 to the lower, closed end cap 32, a variation of the height h₁(see FIG. 9) of the filter pleats 12, 44 is provided in each of the examples from FIGS. 4 to 6. The variation of the filter pleat height shown in each of the examples of FIGS. 4 to 6 is constant, resulting in a cone shape of the filter liner 10. In this respect the FIG. 4 depicts a configuration in which the inner hollow space 36 with its inner surface 38, which is surrounded by the filter liner 10, defines a hollow cylinder, whereas the outer surface 40 is enlarged from top to bottom. In contrast, the example shown in FIG. 5 differs in that the height h₁of the filter pleats 12, 44 decreases from bottom to top, which not only gives the inner hollow space 36 a conical shape in which the inner surface 38 diverges from top to bottom and thus reduces the inner diameter of the hollow space 36, but at the same time the outer surface 40 forms a cone that tapers towards the top, which is also the case in FIG. 4. In contrast, the example depicted in FIG. 6 shows that the outer surface 40 is cylindrical, whereas the inner hollow space 36 is conically tapered from top to bottom since the internal diameter of the inner surface 38 of the hollow space 36 decreases towards the bottom when measured.
The exemplary embodiment in FIG. 7 in turn differs in that, at a constant pleat height h₁, the filter liner 10 is pulled apart slightly in the lower section so as to create an outer diameter that decreases towards the top.
The FIGS. 8 and 9 depict a special, advantageous type of pleating for filter liner 10 in form of a so-called M-pleat; compare in FIG. 8 the pleated section that is hatched and referenced with M. Alternating to pleats 44 of a first kind, which through their pleat height h₁determine the thickness and thus the outer diameter of the formed filter liner 10, this type of pleating provides filter pleats 42 of a second kind that have a lower pleat height h₂. To be able to provide this type of pleating, the so-called M-pleating, with a desired conical shape, a corresponding variation of the pleat height h₁for the pleats 44 of the first kind across the height of the filter liner 10 is provided.
As already mentioned, the variation in the height of the filter pleats does not have to be constant. Instead of providing a regular conical shape on the outer surface 40 or the inner surface 38 of the filter liner 10, it is possible to form a ball-shaped or an irregular contour along the filter liner 10 through increasing and decreasing pleat heights.
The depiction of FIG. 10, which is similar to that of FIG. 3, shows a further exemplary embodiment in which, with the filter pleat height of the filter liner 10 remaining unchanged, a desired zonal variation of the thickness of the filter liner 10 is achieved in that additional filter layers 48, 50, 52, 54 and 56 are provided on the filter liner 10 in form of strips of different widths. As shown in FIG. 10, the vertical extension of the additional layers is such that the increased thickness, caused by the layers, increases from top to bottom because all additional layers overlap in the bottom section, whereas in the upper section the widest additional layer 48 is exposed, and no additional layer is present in the end section adjacent to the upper end cap 36. This results in the desired shape of the outer diameter being tapered towards the top. The additional layers 48, 50, 52, 54, 65 may be made from different materials, for example, additional filter layers and/or support layers and/or drainage layers.

Claims

1. A filter element for fluids, in particular for hydraulic fluid, consisting of at least one foldable filter liner (10) having at least one filter layer (18, 20, 22, 24), which extends between two end caps (26, 32), characterized in that, in order to achieve a zonal variation of the thickness of the filter liner (10), the height (h1) of each filter pleat (12, 44) increases from one end cap (26) to the other end cap (32), or that the outer diameter (40) of the filter liner (10) changes in the direction of one of the end caps (26, 32) whilst maintaining the filter pleat height (h1).

2. The filter element according to claim 1, characterized in that the filter liner (10) surrounds a hollow space (36), that the one end cap (26) is provided with a passage (30) for the supply of unfiltrate, which flows in filtration direction from the hollow space (36) towards the outside through the filter liner (10), and that the other end cap (32) is closed to said flow.

3. The filter element according to claim 1, characterized in that the height (h1) of the filter pleats (12, 44) changes in that it increases in the direction of the closed end cap (32).

4. The filter element according to claim 1, characterized in that the change in the height (h1) of the filter pleats (12, 44) is constant.

5. The filter element according to claim 1, characterized in that the increase in pleat heights (h1) causes a zonal increase in the outer diameter (4) of the filter liner (10).

6. The filter element according to claim 1, characterized in that the increase in pleat heights (h1) causes not only a zonal increase of the outer diameter (40) of the filter liner (10) but also a zonal decrease of the inner diameter (38) of the hollow space (36) of the filter liner (10).

7. The filter element according to claim 1, characterized in that the outer diameter (40) of the filter liner (10) increases from the open end cap (26) towards the closed end cap (32).

8. The filter element according to claim 1, characterized in that, in addition to pleats (12, 44) of a first kind, which determine the majority of the thickness of the filter liner (10) through their pleat height (h1), preferably alternating pleats (42) of a second kind, which have a smaller pleat height (h2) compared to the pleats of the first kind (12, 44), are provided.

9. The filter element according to claim 1, characterized in that the zonal variation of the thickness of the filter liner (10) is achieved through local application of additional, in particular strip-like, filter layers (48, 50, 52, 54, 56).