This application claims priority to German Patent Application No. 10 2013 009 164.0, filed May 31, 2013, and International Patent Application No. PCT/DE2014/000263, filed May 28, 2014, both of which are hereby incorporated by reference in their entirety.
The present invention relates to a piston for an internal combustion engine, having a piston head and a piston skirt, the piston head having a piston crown, a circumferential fire land, a circumferential ring belt with ring grooves and, in the region of the ring belt, a circumferential cooling duct which is open toward the bottom and is closed by way of a closure element, the cooling duct having a cooling duct bottom and a cooling duct ceiling, and the piston skirt having two piston bosses which are connected to one another via two running faces.
In modern internal combustion engines, the pistons are subjected to ever higher mechanical and thermal loads in the region of the piston crown and the combustion bowl. In addition to optimization of the piston cooling, it is therefore necessary to provide the piston firstly with the necessary stability, in order to withstand the mechanical loads which occur, and secondly to design the piston to be so flexible that damage, in particular cracks, are avoided which might be caused by way of said mechanical loads.
It is the object of the present invention to develop a piston of the generic type in such a way that an optimized balance between stability and flexibility is achieved and at the same time the cooling is improved.
The object is achieved by virtue of the fact that the inner face of exclusively one running face of the piston is connected via a connecting land to the underside of the piston head.
The piston according to the invention is therefore of asymmetrical construction. One of its running faces is attached to the two piston bosses. The other running face is additionally attached to the underside of the piston head. This construction ensures both satisfactory stability (additional attachment of one running face to the underside of the piston head), but secondly also a certain flexibility (attachment of one running face merely to the piston bosses). It is unimportant here whether the additional attachment of one running face to the underside of the piston head is provided on the pressure side or on the counter pressure side of the piston. Furthermore, the connecting land which connects one of the running faces to the underside of the piston head can be used to direct an oil jet onto the surface of the connecting land in a targeted manner during engine operation, in such a way that the underside of the piston head is cooled in a targeted manner. In this way, the cooling of the piston according to the invention is also improved.
Advantageous developments result from the subclaims.
The compression height can be, for example, between 38% and 45% of the nominal diameter of the piston head.
One advantageous development provides that the closure element is arranged in the piston head in such a way that a circumferential annular gap is configured in the piston crown. This dispenses with the necessity of providing oil outlet openings.
If the piston skirt is decoupled, the closure element can be configured as a separate component which is fastened to the piston.
The piston according to the invention can be configured as a single-piece piston. The cooling duct is then made in a cast or forged blank in a manner known per se by way of machining. It is preferred, however, that the piston is assembled from at least two components which are connected non-releasably to one another. In particular, the piston according to the invention can have a main piston body and a piston ring element. In this case, the closure element can be configured both as a separate component which is fastened to the piston and as a component which is connected in one piece to the piston. In the latter case, the closure element can be connected in one piece either to the main piston body or to the piston ring element.
The cooling duct can extend in the axial direction as a rule as far as the height of the lowermost ring groove and below, in order to achieve sufficient cooling, in particular of steel pistons, during engine operation with the aid of a cooling duct which is as large as possible. However, on account of the cocktail shaker effect, the cooling oil moves to and fro between the cooling duct ceiling, that is to say a very hot region, and the cooling duct bottom, that is to say a comparatively cool region. On account of the considerably lower temperatures in the region of the cooling duct bottom, in practice heat absorption from the piston head into the cooling oil no longer takes place there.
Particularly effective cooling is therefore preferably achieved by virtue of the fact that the cooling duct is shortened in the axial direction. As a consequence, the cooling oil moves, in particular in the region of the cooling duct bottom, in closer proximity to the highly thermally loaded cooling duct bottom and therefore overall in hotter regions than in a cooling duct which extends as far as the lowermost ring groove or below. Heat absorption from the hot regions of the piston head into the cooling oil therefore takes place in every phase of the piston movement. Particularly effective cooling of the piston head results, in particular, if the cooling oil quantity which is known from the prior art is retained and the cooling oil supply is set up in such a way that the cooling oil is exchanged rapidly during engine operation.
The cooling duct bottom is preferably arranged at the level of the second ring groove, particularly preferably between the first ring groove and the second ring groove, in order to further increase the cooling performance by the cooling oil moving in even greater proximity to the hot piston crown during engine operation.
A further preferred development provides that the height of the fire land is at most 9% of the nominal diameter of the piston head. In this way, positioning of the cooling duct in relation to the piston crown and the ring belt which is particularly advantageous for the dissipation of heat is brought about.
In this case, the spacing between the piston crown and the cooling duct bottom can be between 11% and 17% of the nominal diameter of the piston head. In addition or instead, the height of the cooling duct can be from 0.8 times to 1.7 times its width. Furthermore, as an alternative or in addition to this, the spacing between the piston crown and the cooling duct ceiling can be between 3% and 7% of the nominal diameter of the piston head. These dimension rules permit an optimized design and positioning of the cooling duct for all piston sizes.
A further particularly preferred embodiment consists in that a combustion bowl is configured in the piston head, and that the smallest wall thickness in the radial direction between the combustion bowl and the cooling duct is between 2.5% and 4.5% of the nominal diameter of the piston head. An improved thermal transfer between the combustion bowl and the cooling duct is achieved in this way.
The combustion bowl can be provided, for example, with an undercut, in order to define the wall thickness between the combustion bowl and the cooling duct.
The present invention is suitable both for pistons made from at least one steel material and for pistons made from at least one light metal alloy.
In the following text, exemplary embodiments of the present invention will be explained in greater detail using the appended drawings, in which, in a diagrammatic illustration which is not true to scale:
The piston 10 has a piston head 11 with a piston crown 12 which has a combustion bowl 13, a circumferential fire land 14 and a circumferential ring belt 15 with ring grooves 16, 17, 18 for receiving piston rings (not shown). A circumferential cooling duct 19 is provided at the level of the ring belt 15.
Furthermore, the piston 10 has a piston skirt 21 which is decoupled thermally from the piston head 11 with piston bosses 22 and boss bores 23 for receiving a gudgeon pin (not shown). The piston bosses 22 are connected via boss attachments 24 to the underside 11a of the piston head 11. The piston bosses 22 are connected to one another via running faces 25a, 25b.
The cooling duct 19 is configured such that it is open at the bottom and is closed by way of a separate closure element 35, a closure plate in the exemplary embodiment. The closure element 35 is fastened to the piston head 11 in a manner known per se below the ring belt 15 and extends in the direction of the combustion bowl 13 in such a way that the annular free end of the closure element 35 forms a circumferential annular gap 36 together with the outer wall of the combustion bowl 13.
According to the invention, the inner face 37 of exclusively one running face, namely the running face 25a of the piston 10, is connected via a connecting land 38 to the underside 11a of the piston head 11.
During engine operation, a cooling oil jet can be directed along the inner face 37 of the running face 25a in the direction of the surface of the connecting land 38, in order to improve the cooling of the underside 11a of the piston head 11, as indicated by the arrow P.
For further improvement of the cooling of the piston 10, the closure element 35 is curved in the direction of the piston crown 12 in such a way that a cooling duct bottom 26 is formed which lies approximately at the level of the second ring groove 17 in the exemplary embodiment. The cooling duct bottom 26 can also be arranged between the first ring groove 16 and the second ring groove 17.
Furthermore, the cooling duct 19 has a cooling duct ceiling 27.
In the exemplary embodiment, the compression height KH is between 38% and 45% of the nominal diameter DN of the piston head 11.
The essential difference between the piston 110 according to
The essential differences consist firstly in the design of the main piston body 231 and the piston ring element 232 and secondly in the fact that the piston 210 has a closure element 235 of different design in comparison with the piston 10 according to
The piston 210 has a closure element 235 in the form of a circumferential flange which is connected in one piece to the main piston body 231. The closure element 235 extends in the direction of the ring belt 15 in such a way that its free end forms a circumferential annular gap 236 together with the inner wall of the ring belt 15. The closure element 235 forms the cooling duct bottom 226. In the exemplary embodiment, the cooling duct bottom 226 lies approximately between the first ring groove 16 and the second ring groove 17. Furthermore, the cooling duct 219 has a cooling duct ceiling 227.
In the exemplary embodiment, the piston ring element 232 of the piston 210 comprises a part of the piston crown 12, the fire land 14 and the ring belt 15. The piston ring element 232 can be connected to the main piston body 231, in particular, by way of a welding method, for example electron beam welding or laser welding, the welded seam 233 being arranged in the piston crown.
The essential difference between the piston 310 according to
The combustion bowl 13 is provided with an undercut 429, in order to determine the wall thickness between the combustion bowl 13 and the cooling duct 419 (see below in this regard).
The following details apply to pistons 10, 210, 410 according to
It is preferred that the height h of the fire land 14 is at most 9% of the nominal diameter DN of the piston head 11 (see
On the basis of this dimension rule for the fire land 14, it is preferred that the spacing a between the piston crown 12 and the cooling duct bottom 426 is between 11% and 17% of the nominal diameter DN of the piston head 11 (see
Moreover, it is preferred that the height c of the cooling duct 419 is from 0.8 times to 1.7 times its width d. Said dimension rule brings about an optimum volume of the cooling duct 419 and an optimum orientation relative to the hot combustion bowl 13, in particular to the bowl edge, and to the hot piston crown 12 and to the cooler ring grooves 16, 17, 18.
Finally, it is preferred that the spacing b between the piston crown 12 and the cooling duct ceiling 427 is between 3% and 7% of the nominal diameter DN of the piston head 11 (cf.
Ultimately, it is preferred that the lowest wall thickness w in the radial direction between the combustion bowl 13 and the cooling duct 419 is between 2.5% and 4.5% of the nominal diameter DN of the piston head 11. An improved thermal transfer between the combustion bowl 13 and the cooling duct 419 is achieved in this way.
In
According to
According to
As a consequence, further improved cooling of the piston head results in the case of pistons with an axially shortened cooling duct.
Number | Date | Country | Kind |
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10 2013 009 164 | May 2013 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/DE2014/000263 | 5/28/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/190962 | 12/4/2014 | WO | A |
Number | Name | Date | Kind |
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5000078 | Gabele | Mar 1991 | A |
6892689 | Bischofberger et al. | May 2005 | B2 |
20090071001 | Kondoh et al. | Mar 2009 | A1 |
Number | Date | Country |
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3713242 | Oct 1988 | DE |
10040486 | Mar 2002 | DE |
10063568 | Jul 2002 | DE |
10132446 | Jan 2003 | DE |
102004003980 | Aug 2005 | DE |
102008046115 | Mar 2009 | DE |
09317554 | Dec 1997 | JP |
2005-069219 | Mar 2005 | JP |
WO-2012083929 | Jun 2012 | WO |
Entry |
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English abstract for JP-09317554. |
English abstract for DE-102004003980. |
English abstract for DE-10132446. |
English abstract for DE-10047258. |
English abstract for DE-10040486. |
German Search Report for DE-102013009164.0, dated Jul. 10, 2013. |
English abstract for JP2005-69219. |
Number | Date | Country | |
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20160115900 A1 | Apr 2016 | US |