The invention relates to a combustion engine piston and to a method for the production of a piston.
DE 10 2013 002 895 A1 discloses a piston of a combustion engine, which has an upper part with a ring zone, wherein a piston skirt adjoins the upper part and at least one space, in this case elongate holes, is formed in the piston, into which at least one space a coolant, in this case an alkali metal, is introduced. In this known piston, the spaces are filled directly with the coolant and are closed after filling. Here, closure is effected by means of a ball, which is pressed into the introduction opening. An alkali metal, in particular sodium, is used as a coolant.
This way of enabling piston regions which are subject to high stresses in terms of temperature to be cooled by means of the alkali metal has proven itself in principle. However, it has been found that a production method for introducing the coolant into the space provided for this purpose is problematic. In this respect, it is necessary to work very carefully to ensure that the coolant is introduced only into the space provided for it and that nothing can escape into the environment. It is therefore an expensive and problematic process to introduce the coolant directly into the space provided for it. This problem is exacerbated by the fact that not only a single space but, in DE 10 2013 002 895 A1, a plurality of skewed holes, into which the coolant has to be introduced, is provided.
It is therefore the underlying object of the invention to avoid the disadvantages described at the outset and to provide a piston and a method for the production of a piston of this kind by means of which the filling of the space with a cooling medium is simpler.
In respect of the piston, it is envisaged according to the invention that the coolant is introduced into a coolant container and the coolant container is inserted into the at least one space in the piston. This results in the advantage that first of all a coolant container is made available and filled with the suitable coolant. This takes place independently of the production of the piston per se. After the coolant container filled with the coolant and closed has been produced and made available, it can be inserted into the space provided for it in the piston. This simplifies the production of the piston per se quite considerably since it is no longer necessary to work with the coolant per se. This is made available after being enclosed gas tightly in the coolant container, which can be handled without any problems. This handling is manual but can also be automated.
After the coolant container has been inserted into the space provided for it in the piston, there are several possibilities as regards the configuration of the piston or as regards the next method step. On the one hand, it is envisaged according to the invention that the space is closed with a closure means after the insertion of the coolant container. This closure element can be the known ball, but any other separate closure means can be inserted and brought into operative connection with the introduction opening of the space in order to close said space with the coolant container situated therein. If a closure means is inserted, it is conceivable that the coolant container is arranged in a positively locked manner in the space and thus can no longer move relative to the piston. As an alternative, it is conceivable that the coolant container still has a certain play in the space after the closure of the space and hence that movement is possible. The fixed arrangement has the advantage that heat can thereby be more effectively transferred to the coolant and dissipated into regions that are subject to significantly lower stresses in terms of temperature. The movement of the coolant container in the space has the same advantage since the upward and downward movement of the piston during operation in the cylinder of the combustion engine means that it can likewise absorb heat in highly stressed regions and release said heat in less highly stressed regions if it moves in the space.
As an alternative, it is envisaged, as a development of the invention, that, after insertion into the space, the coolant container is fixed in its position there. This can be accomplished by press-fitting, adhesive bonding or other suitable measures, for example, which ensure that the coolant container is permanently fixed in its position after insertion into the associated space in the piston. On the one hand, this has the advantage that, as already described above, good heat transfer and hence heat dissipation from regions which are highly stressed in terms of temperature into regions which are less highly stressed in terms of temperature are likewise ensured. Moreover, closure of the insertion opening of the space can be omitted, thereby simplifying the production of the piston even further.
If the space is closed with a closure means after the insertion of the coolant container or the insertion opening remains open, this insertion opening is preferably provided in the inner region of the piston, which is not subject to further machining If the insertion opening is situated in the outer region of the piston, e.g. in the region above, below or within the ring zone or the skirt zone, it is possible to work with a separate closure means which is reworked after insertion and closure. Both in the case of closure of the insertion opening in the inner region or in the outer region of the piston, consideration can be given to welding, brazing or bonding the insertion opening shut or the like, instead of a separate closure element. Here too, the closed insertion opening can be reworked after the closure process.
As a development of the invention, it is envisaged that the coolant container is of elongate and cylindrical design, being designed as a tube for example. This has the advantage that, by virtue of this elongate extent of the coolant container, one end is arranged in a region which is highly stressed in terms of temperature and the other end is arranged in a region which is less highly stressed in terms of temperature. Owing to the upward and downward movement of the piston in the cylinder of the combustion engine, suitable alignment of the coolant container ensures that the coolant in the coolant container absorbs the heat in the highly stressed regions and dissipates it in the direction of the less highly stressed regions. This heat transfer can take place continuously, especially if the coolant container is completely filled with the coolant. However, discontinuous heat transfer is also conceivable, especially if the coolant container is not completely filled with the coolant and said coolant can move backward and forward between the two ends of the coolant container.
Thus far, it has been assumed that the space for accommodating the coolant container is introduced into the piston during the production of the piston (e.g. by casting the piston with lost cores, which are flushed out and then form the space to accommodate the coolant container) or more space is introduced after the production of the piston, e.g. by drilling or the like. In an alternative embodiment of the invention, it is furthermore envisaged that the coolant container is cast into the piston. The coolant container which has been separately manufactured, filled with coolant and closed is made available in a suitable manner and inserted into a casting mold for the piston. This insertion resembles the insertion of a lost core for the production of cooling cavities, for example (e.g. annular cooling passages) into a casting mold for the piston. For example, the at least one coolant container can be secured on a mandrel of the casting mold. After the closure of the casting mold, it is filled with molten casting material, which surrounds the at least one coolant container (and any lost cores which may be present), with the result that, after the solidification of the molten casting material, the coolant container is arranged at the location envisaged for it within the piston and can perform its function.
The same above-described embodiments and the advantages resulting therefrom apply in the same way to the method according to the invention for the production of the piston.
One illustrative embodiment of a piston according to the invention, by means of which the production steps are also explained, is described below and shown in
Reference numeral 1 indicates, by way of example, a one-piece piston 1, which has an upper part 2. A piston skirt 3 adjoins the upper part 2, wherein, in this design of the piston, the two opposite sections of the piston skirt 3 are connected by connecting walls 4, in which a pin bore 5 is also arranged. The pin bores 5 to receive the ends of a piston pin can be present but do not have to be present. The ends of the piston pin can also be arranged in some other way on the lower side of the upper part 2. In a manner known per se, the upper part 2 has a ring zone 6, wherein a central region (
A combustion chamber recess 8 can be present in the upper part 2 of the piston 1, as can a cooling passage 9 running around in the form of a ring. The combustion chamber recess 8 and/or the cooling passage 9 can, but need not be, present, depending on the intended use of the piston 1.
A closure for openings 11 of spaces 12 situated within the piston 1 is indicated by 10 in
Considering
Irrespective of the direction from where the spaces 12 are accessible and where the openings 11 (insertion openings) thereof are located, the spaces 12 are thus introduced in the required numbers into the main body (solid material) of the piston after the production of the piston 1 (to be more precise of a piston blank) or during production itself. As already described, introduction can be accomplished by means of lost cores which are flushed out. Instead, the respective space 12 can be introduced by suitable methods, e.g. drilling, milling or the like, after the production of the piston blank. This can be seen, for example, from the piston shown in
After a piston as shown in
As can be seen in
To fill the coolant container 12 and for heat transfer, any suitable coolant may be considered. Alkali metals, e.g. sodium, are of particular advantage since they have very good heat transfer in the temperature working range of the piston 1.
Number | Date | Country | Kind |
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10 2015 217 468 | Sep 2015 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/071342 | 9/9/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/042356 | 3/16/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
6904876 | Hofbauer | Jun 2005 | B1 |
20150075455 | Bischofberger | Mar 2015 | A1 |
Number | Date | Country |
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726 685 | Sep 1939 | DE |
726 685 | Oct 1942 | DE |
100 15 709 | Dec 2001 | DE |
10 2011 111319 | Feb 2013 | DE |
2 333 962 | Jul 1977 | FR |
H04 265451 | Sep 1992 | JP |
Number | Date | Country | |
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20180252182 A1 | Sep 2018 | US |