The present invention relates to a cooling channel cover for a piston of an internal combustion engine, said cover having mutually opposite end faces, with a supply element for cooling oil having an inlet region and an outlet region, wherein the supply element is received in an opening provided in the cooling channel cover and held on the cooling channel cover by a clipped-in latching connection. The present invention further relates to a piston provided with such a cooling channel cover.
A cooling channel cover of the generic type is known from EP 1 238 191 B1. This known cooling channel cover has an intrinsically elastic supply element which is received in an opening provided in the cooling channel cover and fastened thereto by means of a latching connection or by clipping in. For mounting purposes, the known supply element is deformed elastically inward in order to be able to guide it through the opening in the cooling channel cover. This requires that the known supply element is provided only with very small solid latching noses and bearing surfaces which have only very little contact with the cooling channel cover. Reliable operation of a piston provided with such a cooling channel cover is not reliably ensured on account of the forces occurring on the latching noses and bearing surfaces during engine operation and on account of the thus occurring wear in the region of the latching noses and bearing surfaces.
The object of the present invention therefore consists in developing a cooling channel cover of the generic type in such a way that reliable operation of a piston provided therewith is ensured without excessively increasing the mass of the supply element and thus the inertia forces acting during engine operation.
The solution consists in the fact that the supply element has, at the inlet region, at least one spring tab which extends radially outward in the circumferential direction of the cooling channel cover and, at the outlet region, at least one latching element which is radially elastic in the circumferential direction of the cooling channel cover, wherein the at least one spring tab bears against one end face and the at least one latching element bears against the opposite end face of the cooling channel cover.
The present invention further relates to a piston for an internal combustion engine having such a cooling channel cover.
The spring tongues and latching elements provided according to the invention have the advantage that, combined with a low mass, they allow a larger surface contact between the supply element and the cooling channel cover than is the case in the prior art. The wear during engine operation is thus considerably reduced in this region by comparison with the prior art. Furthermore, it is no longer necessary to design the entire supply element to be intrinsically elastic, which substantially increases the strength of the latching connection according to the invention.
Advantageous developments can be found in the subclaims.
In each case two spring tabs and latching elements which are radially opposite one another in the circumferential direction of the cooling channel cover are preferably provided. The strength of the latching connection according to the invention is thus further increased.
Furthermore, the forces which act during engine operation act symmetrically on the supply element, with the result that wear is further reduced.
A preferred development consists in the fact that the at least one latching element bears by way of a bearing surface and the at least one spring tab bears by way of a bearing surface against the end faces of the cooling channel cover, and that the size of the bearing surface of the at least one latching element is from 30% to 60% of the size of the bearing surface of the at least one spring tab. This preferred development takes account of the circumstance that the acceleration of the piston according to the invention is different at the top and bottom dead center during engine operation, since the maximum acceleration at the top dead center is approximately twice as high as the maximum acceleration at the bottom dead center. The different size of the bearing surfaces of latching element and spring tab thus means that the wear behavior is optimized in this region.
The inlet region of the supply element is expediently designed to be widened in a funnel shape in order to optimize the entry of cooling oil injected by means of a cooling oil nozzle. The outlet region is preferably designed as a standpipe, with the result that the cooling oil issuing into the cooling channel is optimally distributed.
The supply element can have a passage opening with a round cross section. However, the cross section of the passage opening can also be designed to be larger in the circumferential direction of the cooling channel cover than in the radial direction of the cooling channel cover in order to increase the receiving capacity of the supply element for cooling oil.
The supply element can consist of a plastic and/or a metallic material, with only the at least one spring tab or the at least one latching element having to be designed to be elastic.
The cooling channel cover can be designed as a component which is separate from the piston, for example as a two-part elastic component, which can be produced in particular from a spring sheet. However, the cooling channel cover can also be formed integrally on the piston.
Exemplary embodiments of the present invention are described in more detail hereinbelow with reference to the appended drawings, in which, in a schematic illustration which is not true to scale:
A piston 10 is illustrated by way of example in
In a further embodiment, it is also conceivable that the opening receiving the supply element 50 can also be formed by at least one joint opening 37, 38.
Two mutually opposite spring tabs 54, 55 are arranged at the inlet region 51 in the vicinity of the outlet region 52, said spring tabs being designed to be elastic in the direction of the arrows A and extending radially outward and, in the mounted state, in the circumferential direction of the cooling channel cover 30 (see
In the exemplary embodiment described, for mounting purposes the cooling channel cover 30 is first connected to the piston 10 in a manner known per se in order to close the cooling channel 16. The openings 41 and 42 of the part-covers 31, 32 for receiving the supply elements 50 are generally arranged very close to the outer wall of the piston bosses 18. This means that, in a view from below, the spring tabs 54, 55 project beyond the outer wall of the piston bosses 18. For mounting purposes, the supply element 50 is first moved past the outer wall of the piston bosses 18 axially in the direction of the piston crown 12. As soon as the spring tabs 54, 55 come to lie on the side of and above the outer wall of the piston bosses 18, there occurs a relative movement in a plane parallel to the piston crown 12 until the supply element 50 is aligned with the opening 41 or 42 in the cooling channel cover 30 and the spring tabs 54, 55 are oriented in the circumferential direction of the cooling channel cover 30. In each case a spring tab 54 can optionally cover a joint opening 37 or 38. The outlet region 52 of the supply element 50 is then guided through the opening 41 or 42 while compressing the latching elements 56, 57 in the piston axial direction until the spring tabs 54, 55 bear against the end faces 34, 36 of the part-covers 31, 32 of the cooling channel cover 30. As soon as the latching elements 56, 57 have passed completely through the opening 41, 42, they snap back into their original position. The cooling channel cover 30 is now arranged between the bearing surfaces 58 of the spring tabs 54, 55 and the bearing surfaces 59 of the latching elements 56, 57. The supply element 50 is held firmly on the cooling channel cover 30 and is supported by way of its bearing surfaces 58, 59 on the cooling channel cover 30 (see
Number | Date | Country | Kind |
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10 2014 015 946.9 | Oct 2014 | DE | national |
This application claims priority to German Application No. 10 2014 015 946.9, filed on Oct. 30, 2014, and International Patent Application No. PCT/EP2015/074782, filed on Oct. 27, 2015, the contents of which are hereby incorporated by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/074782 | 10/27/2015 | WO | 00 |