EP0592630A1

EP0592630A1 - Oil filter

Info

Publication number: EP0592630A1
Application number: EP93907747A
Authority: EP
Inventors: Beat Günter BERGER
Original assignee: HERDING AG
Current assignee: HERDING AG
Priority date: 1992-04-30
Filing date: 1993-04-20
Publication date: 1994-04-20
Also published as: WO1993022024A1

Abstract

Le filtre à mazout échangeable destiné à être monté dans un dispositif de filtrage placé dans la conduite d'arrivée de mazout d'un brûleur à mazout présente un élément de filtrage poreux cupuliforme constitué de particules de polyéthylène frittées ainsi que d'un élément de fixation en polypropylène de forme sensiblement annulaire et relié à l'élément de filtrage. L'élément de fixation annulaire est relié uniquement à l'extrémité de l'élément de filtrage cupuliforme, sans s'engager dans celui-ci, du fait qu'à la surface de jonction des deux parties, les matériaux de ces deux parties sont partiellement fondus entre eux et/ou que le matériau de l'élément de fixation pénètre en partie dans les pores de l'élément de filtrage poreux. Le filtre à mazout est réalisé en une seule opération par un chauffage commun des granulés en polyéthylène et en polypropylène dans un moule en céramique au moyen de micro-ondes.The exchangeable oil filter for mounting in a filter device placed in the oil supply line of an oil burner has a cup-shaped porous filter element made of sintered polyethylene particles and a fastening element polypropylene of substantially annular shape and connected to the filtering element. The annular fixing element is connected only to the end of the cup-shaped filtering element, without engaging in it, because at the joining surface of the two parts, the materials of these two parts are partially fused together and/or that the material of the fixing element partially penetrates into the pores of the porous filter element. The fuel oil filter is made in a single operation by jointly heating the polyethylene and polypropylene granules in a ceramic mold by means of microwaves.

Description

Olfi lter

Technical field

The present invention relates to an oil filter for interchangeable insertion in a filter device arranged in the oil supply line of heating oil burners, with a porous, cup-shaped filter body made of sintered polyethylene grains and with an essentially annular fastening part made of polypropylene connected to the filter body. The invention further relates to a manufacturing method for such an oil filter.

State of the art

It is common to provide a filter device in the heating oil supply line to a heating oil burner so that any contaminants present in the heating oil, for example rust particles from the heating oil tank, are retained and not in the heating oil burner. For example, by clogging the burner nozzle, can cause malfunctions. For such filter devices, there is quite often a type in which oil filters of the type mentioned at the outset are provided in a cup-shaped and usually also transparent housing in a base part (which is mounted in the heating oil line) which is detachably fastened. With their fastening part, the oil filters themselves are detachably fastened to the base part (usually by means of a bayonet rotary connection) and can be exchanged in the event of contamination after the cup-shaped housing has been removed beforehand. A dirty oil filter is usually not cleaned. Instead, a dirty oil filter is regularly replaced with a new one. It therefore goes without saying that the oil filter must be an element that is as cheap as possible and therefore also simple, inexpensive and that can be produced in large numbers.

So far, the filter body and the fastening part have been manufactured separately: the filter body by sintering for several hours in an oven, the fastening part by injection molding or extrusion. The parts manufactured in this way are then connected to one another. To produce a stable connection, in addition to gluing, a mutual mechanical engagement of the filter body and the fastening part is provided in the known oil filters. The fastening part usually engages in the cup-shaped filter body with engagement or holding means specially molded onto it. Although this results in a stable connection of the two parts, on the other hand there is a narrowing of the cross section of the opening of the cup-shaped filter body which is disadvantageous in terms of electrical engineering.

Oil filters with cup-shaped filter bodies are also known, the active filter surface of which is enlarged by a plurality of indentations or bulges of the side wall distributed over the circumference. In cross section, the filter body of this oil filter has a kind of rosette shape. With molded ribs the fastening part engages a little in the filter body and there between the bulges of the side wall. As a result, there is only a relatively non-central hole in the fastening part for the oil flow.

From EP-Bl 0231 588 a method for producing a porous sintered body is known, in which a granulate of a plastic material is filled into a ceramic mold and the ceramic mold is subsequently heated by microwave radiation. The heat required to sinter the plastic granulate is transferred from the ceramic mold to it. The known method is characterized above all by a very short process duration of at most a few minutes. EP-Bl 0231 588 mentions that it is possible to fill the ceramic mold in layers with different plastic granules, which have different sintering properties, in order to obtain a sintered body with different properties in sections.

Presentation of the invention

It is an object of the present invention to provide an oil filter which is simple and inexpensive to manufacture and in which the above-mentioned disadvantages of the known oil filter are avoided. This object is achieved according to the invention by an oil filter of the type mentioned at the outset, in which the ring-shaped fastening part, without engagement in the cup-shaped filter body, is connected exclusively to its edge, namely by partially fusing the material of the two parts to one another at the connecting surface of the two parts and / or the material of the fastening part has partially penetrated into pores of the porous filter body.

Such an oil filter according to the invention can be produced by using the microwave sintering process already mentioned above. The present invention is based on the surprising finding that despite the very different melting and sintering conditions for polypropylene on the one hand and polyethylene on the other hand, it is possible to briefly heat a ceramic mold by means of microwaves in such a way that a polypropylene granulate contained therein is completely melted and liquefied In contrast, polyethylene granules in the same form are only partially melted and sintered together. A powder could also be used instead of granules.

According to the invention, polypropylene granules or for the fastening part and polyethylene granules for the filter body are therefore filled together into the same ceramic mold, which is subsequently heated in a microwave oven. Of course, when heating the ceramic mold containing the two different plastic materials in the microwave oven, care must be taken that it is only heated to such an extent that it is heated so quickly that the heat that it transfers to the two different materials only melts at least approximately completely and Liquefaction of the polypropylene granules is not sufficient to completely liquefy the polyethylene granules. On the other hand, the heat introduced into the polyethylene granulate or powder must also be sufficient to melt it and sinter it together, at least superficially. The polyethylene granulate or powder can also be melted completely, as long as it does not get past a viscous or pasty state during the heating period in comparison with the polypropylene. Possibly. Controlled cooling immediately after the heating phase prevents the polyethylene from becoming too liquefied.

The different behavior of the two plastic materials during the heating phase can also be explained, for example, by influence the choice of the grain size of the granules and by choosing a favorable melt index for both materials. In any case, the polyethylene should react more slowly to the heat than the polypropylene and should also remain in a viscous, rather doughy state with a high viscosity. It is convenient to use high density polyethylene and ultra high density polypropylene.

As soon as the polypropylene is liquid, it can penetrate into the spaces between the grains at the interface with the still granular, possibly only surface-melted polyethylene. Furthermore, it will fuse with polyethylene already melted onto the surface of polyethylene grains. After cooling and re-solidification of both plastic materials, there is a firm and very stable connection between them.

The connection is also stable enough that an additional engagement of the fastening part in the filter body, which narrows the cross section for the oil flow, can be dispensed with in the oil filter according to the invention. The process described above allows the filter body and the fastening part to be produced in a fixed mutual connection in a single operation. In particular, the fastening part can be made flush on the inside with the inner wall of the cup-shaped filter body. Even if the cross-section of the filter body, which is preferred, is rosette-like, the fastening element can easily be flush with the side wall of the filter body, as a result of which the fastening part does not result in any narrowing of the flow cross-section for the oil in this case either.

By means of a suitable design of the ceramic shape, on the outside, as in the known oil filters, grooves, ribs, undercuts or the like can be provided on the fastening part for entering into a bayonet rotary connection with a suitable counterpart. Brief description of the drawings

An embodiment of the invention is explained below with reference to the accompanying drawings. The drawing shows:

1 is an oil filter according to the invention in side view,

2 shows the oil filter of FIG. 1 in section,

Fig. 3 is a plan view of the oil filter of Fig. 1, and

Fig. 4 under a) and b) schematically the type of connection of the filter body ^* and fastener in the oil filter.

Weσe implementation of the invention

The oil filter shown in Figures 1 to 3 has a porous filter body 1 made of sintered polyethylene grains and a fastening part 2 connected to it made of essentially solid, i.e. non-porous polypropylene. The filter body 1 is essentially cup-shaped with a base part 3 and a side wall 4. The side wall 4 is provided with a total of eight indentations or bulges to enlarge its surface over its circumference, so that the filter body 1 has a rosette-shaped cross section.

The fastening part 2 is essentially ring-shaped. On the inside, it is flush with the inside of the side wall 4 of the filter body 1. The course of the side wall 4 is indicated in Fig. 3 by a dashed line.

Outside are on the fastening part 2 over its circumference several webs 5 are formed to form a bayonet rotary fastening on a suitably designed counterpart, not shown here (on the base part of an oil filter device mentioned at the beginning). In Fig. 3, the mentioned webs also illustrated by dashed lines.

In the oil filter shown in the figures, the oil enters the porous filter body 1 from the outside (arrow P1 in FIG. 2) and leaves it again (arrow P2 in FIG. 2) through the central opening 6 in the fastening part 2 Fastening part 2 ends flush on the inside with the side wall 4 of the filter body 1, there is no cross-sectional constriction by the fastening part 2 that inhibits the oil flow.

4 schematically shows the conditions in the transition area between the filter body 1 and the fastening part 2, namely under a) before the heat treatment by means of the microwaves and under b) after this treatment. Before the heat treatment, the materials, polyethylene (PE) for the filter body and polypropylene (PP) for the fastening part, are each in the form of loose, unrelated granules, the granules adjoining one another. After the heat treatment, the polypropylene essentially forms a compact, homogeneous mass (except perhaps for individual grains, which are indicated by dashed lines in FIG. 4b), while the polyethylene granules have fused together superficially, but have been retained as grains with gaps. By penetrating part of the polypropylene between the polyethylene grains, the compact fastening part made of polypropylene and the porous filter body made of polyethylene are firmly connected to one another.

In conclusion, it should also be mentioned that the method described could possibly also be used to produce other useful elements in addition to oil filters of the type described here at low cost. For example, filters for other uses, screens, inserts for silencers or Air dispensers and the like. "Corks" or "cones" for closing bottles could also be produced in the manner described. In this respect, the present invention should not be regarded as being restricted to oil filters. The same naturally also applies to other plastic materials, provided that they exhibit the same or a similar behavior as the polypropylene mentioned on the one hand and polyethylene on the other hand in a comparable heat treatment by means of microwaves in a ceramic mold.

Claims

1. Oil filter for interchangeable insertion into a filter device arranged in the oil supply line of heating oil burners with a porous, cup-shaped filter body (1) made of sintered polyethylene grains and with an essentially annular fastening part (2) made of polypropylene connected to the filter body, characterized in that ring-shaped fastening part (2) without engagement in the cup-shaped filter body (1) is connected exclusively to the edge thereof, namely in that the material of both parts partially fused together at the connecting surface of the two parts and / or the material of the fastening part partly in pores of the porous Filter body (1) has penetrated.

2. Oil filter according to claim 1, characterized in that the fastening part is flush on the inside with the inner wall of the cup-shaped filter body.

3. Oil filter according to one of claims 1 or 2, characterized in that the side wall of the cup-shaped filter body is provided over its circumference with a plurality, preferably eight, indentations and bulges to enlarge its surface.

4. Oil filter according to one of claims 1 to 4, characterized in that the annular fastening part is provided on the outside with grooves, ribs, undercuts or the like for entering a bayonet rotary lock with a suitable counterpart.

5. A method for producing an oil filter according to one of claims 1 to 4, characterized in that both the polyethylene for the filter body and the polypropylene for the fastening part are each in granules. or powder form are filled together into a ceramic mold and that the ceramic mold is subsequently heated in a microwave oven for just so long and so strongly and, if necessary, cooled after it has been heated that the heat transferred from the ceramic mold to the two different materials melts at least approximately completely and Liquefaction of the polypropylene granules or powder, on the other hand only sufficient to sinter the polyethylene granules or powder.