FILTER DEVICE FOR FLUIDS

Abstract

The invention relates to a filter device for fluids, in particular in the form of a tank-installation return filter, comprising at least one filter element (27), which can be accommodated in a housing (3), which has a fluid inlet (17) for supplying unfiltered fluid to an inner cavity (31) of the respective filter element (27), which inner cavity is surrounded by a filter medium (29) through which unfiltered fluid can flow. The filter device is characterized in that a flow-conducting apparatus (13, 49, 77) that orients the flow of the unfiltered fluid reaching the filter medium (29) is provided between the fluid inlet (17) and the inner cavity (31) of the respective filter element (27).

Description

The invention relates to a filter device for fluids, in particular in the form of a tank-installation return filter, having at least one filter element, which can be accommodated in a housing, which has a fluid inlet for supplying unfiltered fluid to an inner cavity of the respective filter element, which inner cavity is surrounded by a filter medium through which unfiltered fluid can flow.

Such filter devices are available on the market in many prior art designs and embodiments. Among other things, they are used to filter out impurities in fluids such as hydraulic fluid. Hydraulic fluid becomes contaminated with impurities during the installation and start-up of the respective hydraulic system, and in addition to this initial contamination, contamination can also occur during operation, for example by impurities infiltrating the hydraulic tank due to inadequate tank ventilation, pipe openings, piston rod seals, and the like. In particular in hydraulic systems of work machines such as earth movers, excavators, and the like, it can be useful to filter returning fluids immediately in the area of the hydraulic tank, for example by installing the filter device directly in the tank as a return filter. Document DE 10 2004 014 149 B4 discloses an example of such a tank-installation filter.

On the basis of this prior art, the problem addressed by the invention is that of providing a filter device of the aforementioned type, which is distinguished by particularly favorable operating performance.

According to the invention, this problem is solved by a filter device having the features of claim 1 in its entirety.

Accordingly, an essential special feature of the invention lies in that a flow-conducting apparatus, which orients the flow of the unfiltered fluid reaching the filter medium, is provided between the fluid inlet via which the unfiltered fluid flows into the filter device and the inner cavity of the respective filter element. A more uniform pressure and flow distribution inside the filter element is achievable by influencing the flow direction in a targeted manner. It is furthermore possible to achieve a maximum retention time of the fluid inside the cavity of the filter element and along any additional elements that may be situated in the filter cavity, for example along a magnetic core or sensors. The filter folds in a folded filter medium are virtually stressed on one side only when the fluid is oriented in this manner, which can improve the performance of the filter element.

In exemplary embodiments in which the filter medium of the respective filter element delimits a cylindrical cavity, the flow-conducting apparatus has, in a particularly advantageous fashion, guide means for generating a swirl flow, which rotates in the cavity about the cylinder axis. A particularly long retention time along magnetic cores and thus an efficient separation of ferromagnetic particles from the fluid is thus achievable.

In particularly advantageous exemplary embodiments, the flow conducting apparatus has an inflow chamber upstream of the swirl-generating guide means, into which chamber the unfiltered fluid enters with an inflow direction predetermined by a connector apparatus and from which chamber the unfiltered fluid reaches the swirl-generating guide means with a flow direction that is altered relative to the inflow direction. The deflection of the inflowing fluid stream taking place in the inflow chamber leads to a flow abatement before the unfiltered fluid reaches the swirl-generating guide means.

In particularly advantageous fashion, the swirl-generating guide means can have one functional level in the form of a guide body situated in the inflow chamber that forms the flow path from the latter to an opening of the associated end cap of the filter element in question, into which guide body the unfiltered fluid can flow from the inflow chamber via an opening facing away from the connector apparatus and having inner conducting surfaces that run in a spiral around the axis in order to generate a swirl. A swirl flow rotating about the axis is thus generated within the area of the inflow chamber and before the fluid reaches the filter cavity of the filter element via the end cap thereof.

In order to achieve a particularly effective rotation, in particularly advantageous fashion it can be arranged such that the swirl-generating guide means have another functional level in the form of guide vane-like swirl elements, which are situated at the opening of the end cap leading to the filter cavity. The rotation of the flow is thus further strengthened directly at the element inlet.

In the use as a tank installation filter, the inflow chamber can advantageously be disposed on the top of a fluid tank forming the downstream (clean) side in the filtering process, and can have a floor formed by a tank wall section, in which an installation opening for the filter housing projecting into the tank is present, as well as a detachable housing lid facing the installation opening. The housing lid thus not only closes the inflow chamber but also serves as a maintenance and service opening for the installation and removal of the filter element when changing the latter.

The guide body having the spiral conducting surfaces, which forms the first functional level of the swirl-generating means, can extend in an advantageous fashion from the bottom of the housing lid until it contacts the end cap of the filter element in the operational position. The guide body thus not only forms the fluid guide, but can also serve as a retaining element that holds the filter element in the operational position in the filter housing.

In an advantageous fashion, the guide body can be attached to the housing lid and have a coaxial passage through which a magnetic core carrier fixed on the housing lid extends into the inner cavity of the filter element in question. By removing the lid along with the attached guide body when changing the element, not only does the filter element become freely accessible, but the magnetic core and any sensors disposed thereon will be taken out as well, thus making these components available for evaluation.

In an advantageous fashion, the filter housing can be fixed by means of a fastening flange to the installation opening formed in the floor of the inflow chamber, thus forming a seal which separates the upstream inflow chamber from the downstream tank. The filter housing can thus have a wall section extending from its fastening flange through the inflow chamber to the housing lid, which forms an impact wall that is arranged facing the connector apparatus for the unfiltered fluid situated on the chamber wall. The impact wall formed by the wall section of the filter housing projecting into the inflow chamber thus forms a flow deflection apparatus, which is provided in the inflow chamber for flow abatement.

According to claim 11, the subject matter of the invention is also a filter element that is provided for use with a filter device according to one of claims 1 through 10.

In the following, the invention is explained in detail with reference to an exemplary embodiment illustrated in the drawings. Shown are:

FIG. 1 a longitudinal section of an exemplary embodiment of the filter device according to the invention, installed in a fluid tank shown in a cutaway view;

FIG. 2 a partial longitudinal section in which the top portion of FIG. 1 is illustrated in larger scale;

FIG. 3 a perspective diagonal view of the housing lid of the exemplary embodiment, with a guide body of the flow-conducting apparatus and a magnetic core situated thereon;

FIG. 4 a perspective diagonal view of the guide body drawn on a larger scale relative to FIGS. 2 and 3, and

FIG. 5 a perspective diagonal view that just shows an end cap as well as components allocated to said end cap of a filter element provided for use in the filter device of the invention.

FIG. 1 shows a tank 1 storing a fluid such as hydraulic fluid, with an exemplary embodiment of the filter device according to the invention in the form of a tank-installation return filter installed therein. The filter device has a hollow cylinder-type filter housing 3, the bottom end 5 of which is open to the tank contents. This open end 5 forms the outlet on the downstream (clean) side, through which the cleaned fluid exits the filter housing 3 and reaches the tank contents. On its top end, the filter housing 3 has a fastening flange 7, with which it is fastened onto an installation opening 9 by screwing. The installation opening 9 is situated in an upper tank wall section in the form of a level floor 11 of an inflow chamber 13, which is disposed slightly recessed in the top of the tank 1. The inflow chamber 13 has the shape of a rectangular box. On a narrow side 15 of the box there is a connector apparatus 17 via which unfiltered fluid can flow into the chamber 13 with an inflow direction running parallel to the floor 11 and to the long sides of the chamber 13. To this end, provision is made in the connector apparatus 17 for a plurality of inflow channels running parallel to one another, of which the foremost channel opening in the viewing direction of FIG. 1 is shown in section. On the top, the inflow chamber 13 can be closed with a detachable housing lid 19, which is coaxial to the longitudinal axis of the filter housing 3 and which closes a housing opening 21 greater in diameter than the installation opening 9 in the floor 11.

The fastening flange 7 of the filter housing 3 forms a seating surface 23 on its inside for the sealed contact of the associated end cap 25 of a filter element 27, wherein the end cap 25 in typical fashion forms a rim for the facing end of a hollow cylinder-shaped filter medium 29, which surrounds an inner filter cavity 31 that forms the upstream side of the filtering process. Accordingly, the space 33 between the outer side of the filter medium 29 and the inner wall of the filter housing 3 forms the downstream side, from which the filtered fluid exits the filter housing 3 via the open bottom end 5 and reaches the tank contents. Likewise in typical fashion, the upstream cavity 31 of the filter element 27 is safeguarded against excessive pressure build-up by means of a bypass valve 35 (FIG. 1), which is situated on the bottom end cap 37 of the filter element 27, wherein a debris catching basket 39 projecting into the filter cavity 1 is provided at this opening.

As an essential component of the flow-conducting apparatus provided according to the invention, the inflow chamber 13 forms a space that abates and orients the flow of unfiltered fluid incoming via the connector apparatus 17, the inflow direction of which is indicated with flow arrows 41. For this purpose, the inflow chamber 13 has a conducting element in the form of a wall section 43, which extends in the form of a circular section from the fastening flange 7 of the filter housing 3 through the inflow chamber 13 to an annular body 45 situated on the inside of the housing lid 19. The wall section 43 forming an impact wall extends over an arc length such that the fluid can flow around it laterally, along the long sides of the inflow chamber 13. The flow path of the unfiltered fluid thus continues with an altered flow direction indicated by arrows 47 on the way toward the inner cavity 31 of the filter element 27. The filter device of the invention has swirl-generating guide means in two functional levels on this other fluid path. The first functional level is formed by a guide body 49, which is shown separately in FIG. 4. As can be clearly discerned from this Figure, the guide body 49 has conducting surfaces 51 inside a hollow cylinder, which have a spiral course relative to the longitudinal axis such that a swirl is generated in an axial flow in such a way that the flow rotates about the longitudinal axis. Entry windows 53 running obliquely to the axis are formed in the wall of the guide body 49 for admitting the fluid to the conducting surfaces 51. The conducting surfaces 51 are delimited in a radially inward manner by axially extending wall portions 55, which abut at the top and bottom ends against inner rings 57 and 59, respectively, and which delimit a central passage through the guide body 49. The guide body 49 is attached to the bottom of the housing lid 19 with the edge 61 (the edge on the top in the figures).

Furthermore, an end of the carrier 65 of a magnetic core is mounted in a central through-bore 63 of the housing lid 19, which carrier has, in a fashion typical of magnetic cores, a group of permanent magnets 67 and which, with the housing lid 19 attached, extends into the filter cavity 31 as far as the debris-catching basket 39. The carrier 65 thus passes through the inner passage of the guide body 49 and the opening 75 of the end cap 25. A sensor 69 on the bottom end of the magnetic core enables a monitoring of the quality of the hydraulic fluid. The amount of ferritic particles collected by the magnets 67 can be indicated by means of a sensor 71. Furthermore, on the inside of the end cap 37 provision can be made for a RFID sensor 73 for detecting the filter element 27.

As a second level of the swirl-generating guide means, at the opening 75 of the end cap 25 leading to the filter cavity 31 provision is made of another swirl-generating apparatus, which has guide vanes 77 arranged in a ring channel in the nature of turbine blades. The channel 79 is delimited on the inside by a connection piece 81 of the end cap 25, which the carrier 65 of the magnetic core passes through, in the operational position. A connection plate 82 (FIG. 5) surrounding the channel 79 is situated on the top of the end cap 25, which plate has a projecting ring 83 surrounding the channel 79. In the operational position, the end section 85 of the guide body 49 contacts the inside of the projecting ring 83 such that the flow path continues from the guide body 49 to the filter cavity 31 via the channel 79 with the guide vanes 77. The swirl imparted to the flow by the spiral conducting surfaces 51 of the guide body 49 is further strengthened at the inlet of the filter cavity 31 by the guide vanes 77 such that a powerful rotation about the longitudinal axis takes place inside the filter cavity 31. For this purpose there are, in particular, more guide vanes (6) on the end cap 25 of the filter element than there are (4) on the guide body 49. By suitably positioning and selecting the curvature for each stationary disposed guide vane, the swirl flow can be adjusted for the fluid in an evident manner. As FIG. 5 shows, a retaining bracket 87 that forms a handle for changing the filter element is mounted in a hinged manner on the top of the end cap 25.

Claims

1. A filter device for fluids, in particular in the form of a tank-installation return filter, having at least one filter element (27) which can be accommodated in a housing (3), which has a fluid inlet (17) for supplying unfiltered fluid to an inner cavity (31) of the respective filter element (27), which inner cavity is surrounded by a filter medium (29) through which unfiltered fluid can flow, characterized in that a flow-conducting apparatus (13, 49, 77) that orients the flow of the unfiltered fluid reaching the filter medium (29) is provided between the fluid inlet (17) and the inner cavity (31) of the respective filter element (27).

2. The filter device according to claim 1, characterized in that the filter medium (29) of the respective filter element (27) delimits a cylindrical cavity (31) and that the flow-conducting apparatus has guide means (49, 77) for generating a swirl flow that rotates in the cavity (31) about the cylinder axis.

3. The filter device according to claim 1, characterized in that the flow-conducting apparatus has an inflow chamber (13) upstream of the swirl-generating guide means (49, 77), into which chamber the unfiltered fluid enters with an inflow direction (41) predetermined by a connector apparatus (17) and from which chamber the unfiltered fluid reaches the swirl-generating guide means (49, 77) with a flow direction (47) that is altered relative to the inflow direction.

4. The filter device according to claim 1, characterized in that the swirl-generating guide means have a functional level in the form of a guide body (49) situated in the inflow chamber (13) that forms the flow path from the latter to an opening (75) of the associated end cap (25) of the filter element (27) in question, into which guide body the unfiltered fluid can flow from the inflow chamber (13) via an opening facing away from the connector apparatus (17) and which has inner conducting surfaces (51) that run in a spiral to the axis for generating a swirl.

5. The filter device according to claim 1, characterized in that the swirl-generating guide means have another functional level in the form of guide vane-like swirl elements (77) that are situated at the opening (75) of the end cap (25) leading to the filter cavity (31).

6. The filter device according to claim 1, characterized in that the inflow chamber (13) is disposed on the top of a fluid tank forming the downstream side in the filter process, and has a floor (11) formed by a tank wall section in which there is an installation opening (9) for the filter housing (3) projecting into the tank (1), as well as a detachable housing lid (19) facing the installation opening (9).

7. The filter device according to claim 1, characterized in that the guide body (49) having the spiral conducting surfaces (51) extends from the bottom of the housing lid (19) until it contacts the end cap (25) of the filter element (27) in the operational position.

8. The filter device according to claim 1, characterized in that the guide body (49) is attached to the housing lid (19) and has a coaxial passage through which a magnetic core carrier (65) fixed to the housing lid (19) extends into the inner cavity (1) of the filter element (27) in question.

9. The filter device according to claim 1, characterized in that the filter housing (3) is fixed with a fastening flange (7) to the installation opening (9) formed in the floor (11) of the inflow chamber (13), forming a seal which separates the upstream inflow chamber (13) from the downstream tank (1).

10. The filter device according to claim 1, characterized in that the filter housing (3) has a wall section (43) extending from its fastening flange (7) through the inflow chamber (13) to the housing lid (19), which forms an impact wall that is arranged opposite the connector apparatus (17) for the unfiltered fluid situated on the chamber wall.

11. A filter element for use in a filter device as in claim 1, which has an end cap (25) with an opening (75) leading into the inner filter cavity (31) of the filter element (27), characterized in that at the opening (75), provision is made of a flow-conducting apparatus (77, 79, 81, 82) with guide vanes (77) onto which a fluid can flow and which induce a rotation of the flow.

12. The filter element according to claim 11, characterized in that the guide vanes (77) surround a central hollow cylinder (81) in the manner of a blade ring, which hollow cylinder forms a passage for the magnetic core carrier (65).