The invention concerns an air filter housing for at least one compact air filter element, comprising at least one filter chamber that is provided at its ends with at least one hose connector socket, respectively, wherein the compact air filter element is insertable between the hose connector sockets with sealing of the cross-section of the filter chamber.
Compact air filter elements are comprised of a corrugated filter paper and a smooth filter paper. The filter papers are glued together and then wound together to a filter element of the desired size. In this connection, gluing is done by bead-shaped application of the pasty adhesive in the edge areas such that the interstices between the corrugated layer and the smooth layer are alternatingly closed off at the two end faces so that no direct flow through the channels formed between the filter papers is possible. An air flow, when flowing from the unfiltered air side to the filtered air side, first reaches only a branch channel, then passes through the filter paper and flows out from a branch channel on the other side. In comparison to conventional folded filters, these compact air filters have the advantage that for the same size a larger filter surface area is provided or for the same filter surface area a smaller size is made possible so that accordingly also the air filter housing for the compact air filter element can have a smaller size. The advantage with regard to the size however entails the disadvantage that the acoustic damping is worsened as a result of the significantly reduced housing volume for compact air filter elements.
Object of the invention is therefore to provide an air filter housing for a compact air filter element with improved acoustic properties that is of a simple and inexpensive design. This object is solved by an air filter housing having the features of claim 1.
The air filter housing, known in general, is supplemented by an additional resonator chamber element that is connected to the actual filter space by at least one air-conducting channel or slot. In this way, an acoustic influence on pressure vibrations in the air flow according to the principle of a Helmholtz resonator is realized wherein by means of the size of the volume of the resonator chamber and by means of location and size of the connecting channels as parameters the acoustic properties can be affected. By means of integration into the air filter housing or the attachment to the exterior in accordance with the present invention, no additional space for a separate acoustic damping means is required.
The terms “channel” or “slot” are used in the following interchangeably for cutouts that are provided in a wall that separates the main chamber as a filter chamber from an auxiliary chamber serving as a resonance chamber and that have an acoustically effective opening width.
A first embodiment provides that on the outer circumference of the filter chamber one or several, preferably box-shaped, resonator chamber elements are to be arranged and to be connected by at least one air-conducting channel or slot to the inner filter chamber.
It is in particular advantageous to provide an annular chamber element in the area of the transition from the hose connector socket to the filter chamber. The transition from the smaller cross-section of the hose connector socket to the greater cross-section of the filter chamber is predetermined. An annular chamber element that is attached in this area thus utilizes the already present space inside or outside of the air filter housing without requiring an enlargement of the housing.
The annular chamber element can be divided into partial chambers by webs that extend in particular radially so that in particular also chambers of different sizes are formed and, accordingly, different sound frequencies can be affected. Each partial chamber is in communication with the interior of the air filter housing by at least one channel or slot.
An especially simple solution provides that the annular chamber element is formed of an annular cover section and an annular hoop section. The annular hoop section is directly welded to the large filter chamber and the annular cover section is welded to the hose connector socket. In this way, it is also possible to retrofit an already existing production air filter housing with integrated bypass resonator without this requiring an entirely new development of the air filter housing.
The connecting channels can extend either radially into the annular chamber element, in particular beginning at the narrow cross-section of the hose connector socket. Alternatively, connecting channels can be provided that extend approximately axially, i.e. parallel to the flow direction.
The annular chamber element can also be arranged in the interior of the filter chamber inasmuch as in the filter chamber a cavity is provided by the filter chamber not being completely filled by the compact air filter element.
Advantageously, the resonator chamber elements are filled with a damping material in order to provide additional absorption of sound energy. Lining the chambers and/or the filter housing with damping material can serve the same purpose.
Moreover, it can be provided that at the intake side in the air filter housing a so-called inlet tulip is formed, i.e., a channel that initially continuously tapers and then suddenly widens so that a pressure wave reflection occurs here.
These and further features of preferred embodiments of the invention can be taken from the claims as well as the description and the drawing wherein the individual features taken alone or combined in form of subcombinations can be realized for embodying the invention and also in other fields and can represent advantageous as well as individually protectable embodiments for which protection is sought here.
The invention will be explained in the following with reference to the drawing in more detail. The
The taken-in air passes the compact air filter element 20 and is then discharged through the connector socket 3.
About the connector socket 3 there is an annular chamber element 6 as a first resonator chamber element. It forms an annular cavity that in the illustrated embodiment on the one hand is connected by means of radial channels 9 to the interior of the hose connector socket 3 and on the other hand by means of approximately axial channels 8 with a cavity located adjacent to the compact air filter element 20 in the filter chamber 1.
The annular chamber element 6 is of a very simple configuration in that the air filter housing 10, generally known with respect to the elements 1, 2, and 3, is provided with channels 8, 9 and an annular hoop section 6.1, e.g. in the form of a pipe section, is attached externally on the air filter housing 10. For example, when the air filter housing is made of plastic material an appropriate plastic hoop can be welded thereto. The annular cover section 6.2 then separates between its outer edge at the annular hoop section 6.1 and its inner edge at the connector socket 3 an air volume that is connected to the interior of the air filter housing 10 only by means of the channels 8, 9. The thus produced cavity is acoustically effective and enables to affect acoustically detectable vibrations in the air column that is being passed through the air filter housing 10, i.e., to dampen them or to even eliminate them completely.
The frequency ranges that can be affected are directly correlated with the air chamber volume of the resonator chamber. In order to provide differently sized volumes for different frequency spectra, the embodiment according to
Number | Date | Country | Kind |
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10 2006 025 230.6 | May 2006 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/053754 | 4/18/2007 | WO | 00 | 7/31/2009 |