EP0759519B1 - Piston ring for internal combustion engine - Google Patents

Description

The present invention relates to a piston for Internal combustion engines.

In the head of pistons for internal combustion engines are in Piston ring grooves usually used piston rings, which the task between the piston head and cylinder wall to seal the existing gap from the combustion chamber. at the piston ring slides as the piston moves up and down on the one hand with its outer peripheral surface in constant resilient system against the cylinder wall, on the other hand slides the piston ring oscillates in its piston ring groove by the tilting movements of the piston, its flanks, i.e. the top and bottom of the piston ring, alternately the upper or lower flank of the piston ring groove issue.

Depending on the material properties of each opposing sliding partner occurs with one or the other the other the more or less the sliding partner Wear on the so-called during a dry run Eating, scoring and ultimately one Engine destruction (see also Nüral Piston Manual Alcan Aluminumwerk Nürnberg GmbH, 1983, pages 146 to 151).

To the sliding behavior against the cylinder wall too improve, which usually consists of gray cast iron, are in State of the art numerous surface coatings for the circumferential surface of the piston rings has been developed. So is in DE-AS 17 51 573 a chrome-coated piston ring described, the additional part of its peripheral surface is coated with molybdenum. In the piston ring manual of Goetzewerke Friedrich Goetze AG, 3rd edition 1977, page 28 ff. are also wear-reducing layers as Tread reinforcements made of chrome, molybdenum, Ceramic, from bronze inlays or also from composite Layers of different materials can exist.

From DE-OS 21 56 127 is also an electrolytic Application of sliding layers on a piston ring and one Known cylinder wall, these sliding layers, e.g. Nickel, due to hard suspended particles in their Abrasion resistance can be increased. The particulate Inclusions can be made of silicon carbide or diamond consist.

In US 4,974,498 is a piston with a piston ring disclosed to be coated with synthetic diamond can.

Recent developments in piston rings make use of the possibility of depositing thin layers of plasma (plasma PVD or CVD processes) (cf. JP-A-62 58050). This publication describes the application of superhard coatings made of CBN, TiC, SiC, Al ₂ O ₃ or diamond to the outer circumference of piston rings. The thickness of these super hard layers is relatively large and is 15 µm. In addition, an outer layer of TiN with a smaller thickness of 3 µm is applied to the super hard material coating as the top coating.

DE 36 23 360 A2 is a combination of a piston with discloses a piston ring with molecular Carbon ions can be plated. In the textbook "Plasma Coating Process und Hartstoffschichten "by Dr. B. Rother and Dr. J. Vetter, German publisher for Grundstoffindustrie, Leipzig, 1992, are applicable here Plasma coating process described. JP 4000064 describes the coating of a piston ring by a Mixture of chrome, carbon and nitrogen using a Plasma coating process. Finally a piston is out a heat-resistant aluminum alloy with one in one unreinforced ring groove inserted piston ring from the DE 43 26 978 A1 known.

Although multiple efforts in the field of piston rings were made to wear the groove flanks Reducing the use of aluminum pistons could do this not achieved by the developments described above become. On the contrary, it turned out that just so-called super hard layers before the piston ring itself protect wear that such Wear protection layers, however, due to their hardness Aluminum alloys as a sliding partner a stronger one Cause wear. In particular, that has been widely used TiN insufficient dry running properties, so that such coatings in the event of a lack of lubricating oil produce considerable tread damage in the shortest possible time.

Due to the problems described above, the prior art Technology, especially for highly stressed diesel pistons the grooves closest to the combustion chamber, which consequently the highest thermal and mechanical stresses exposed by a cast piston ring carrier armored, which usually consists of austenitic gray cast iron (see also Nüral Piston Handbook, edition 1983, pages 128 to 131, especially Fig. 166).

Such ring carriers solve the problem of Groove wear in a satisfactory manner and therefore also applied on a large scale. However, with such Ring bearers also have a significant disadvantage because of the piston weight is increased and both when casting the Piston as well as in its mechanical processing elaborate manufacturing technology is what overall caused considerable additional costs. Piston ring carrier also occupy a space in the piston head that the Arrangement of cooling channels restricted and not there allows where they would be most wanted, namely in as close as possible to the top ring groove. From the state of the Technology also known alternatives to Ring carrier castings are, for example, reinforcements of the top ring groove by cladding or welding alloys of the groove flanks as well as Flame sprayed applied surface layers. however These processes also prepare large-scale manufacturing Problems and very high costs so that none provide a satisfactory solution.

It is the problem (object) on which the invention is based, to create a piston that is inexpensive to manufacture can be and has a piston ring that itself is wear-resistant and especially in the top groove of a highly loaded light metal piston can without the flanks of the groove a special reinforcement require.

This problem is solved by a piston, which Features of claim 1.

The piston according to the invention is made of a heat-resistant Made of aluminum alloy and has at least one Ring groove with at least one piston ring. According to the invention the piston ring is at least perpendicular to it Flanks of the main axis with a plasma CVD method applied hard carbon layer coated. The ring groove in which the piston ring is inserted is unbewehrt.

The hard carbon layer provided according to the invention serves primarily as a running layer opposite the groove flanks the piston ring grooves and not necessarily as Running layer compared to that usually made of gray cast iron existing cylinder liner. It can Hard carbon layer also on the outer peripheral surface of the Piston ring are applied, since it does not interfere there, however, there are none in gray cast iron liners significant additional benefits. On the other hand, the reinforcement of the piston ring according to the invention on its Top and its bottom, i.e. on the surfaces with fully touch the flanks of the piston ring groove significant benefits.

The hard carbon layer protects namely in the pairing of Piston ring and piston ring groove both the piston ring flanks as the flanks of the grooves in the piston material are also too high Wear, even when used in highly loaded diesel engines. Here it is with the Piston rings produced according to the invention possible on a Reinforcement of the piston ring grooves, what the Manufacturing costs of the pistons significantly reduced. On a ring carrier insert for the top piston ring groove are therefore waived, which makes it possible for the first time the cooling channel in the piston head in the under thermal Considered proximity to the top ring groove bring. As a result, the operating temperature in the range top ring groove lowered, and thus also effective for Operational safety of the top ring groove contributed. Finally, the one provided according to the invention Hard carbon layer also extremely good Dry-running properties.

The coating of the piston ring in the plasma CVD process takes place with a doped hard carbon layer, which has the formula a-C: H, where a is an amorphous material designated and C and H carbon and hydrogen as Identify material components.

Such a doped, super hard carbon layer is also under the trade name Dynamant (registered trademark) offered and is from the contribution of Dr. Knut Enke "With modified super hard carbon against wear, Corrosion and Friction "known in the yearbook Oberflächentechnik Band 45, 1989, from the metal publishing house has appeared. Ion bombardment creates one Carbon modification that is neither pure graphite nor pure Diamond is, but rather between these two Materials. The general formula a-C: H means that it is an amorphous ("a") non-crystalline Material is essentially made of carbon there is a proportion of unspecified Contains hydrogen.

The piston according to the invention is made of a heat-resistant Aluminum alloy is produced, which in claim 1 has specified composition. Such an alloy is known from DE 43 26 978 A1. However, has found that a piston from such Aluminum alloy, which according to the invention with a Combined hard carbon layer coated piston ring will bring decisive advantages. The invention proposed, heat-resistant aluminum alloy for the Piston material is not only in terms of Frictional wear advantageous, but especially in With regard to the striking stress of the Ring groove flanks under the influence of the in the groove oscillating with the motor piston movement in the Ring groove up and down moving piston ring. Other preferred, heat-resistant aluminum alloys are Al-Si-Mg alloys with relatively high levels of heavy metals such as Ni, Cu, Mn and Fe. With such piston alloys can the use according to the invention of the coated Piston rings even the top ring groove directly into the Piston material can be incorporated. Thus, the Combination of the hard carbon coated according to the invention Piston ring with a piston made of a heat-resistant Aluminum alloy, which has an unreinforced ring groove, a simple, inexpensive and in every way advantageous solution to the problem mentioned at the beginning.

Advantageous embodiments of the piston according to the invention are characterized by the subclaims.

According to an advantageous embodiment, the Pistons according to the invention are modified so that the Coating the outer peripheral surface with a special Running layer is omitted, but the piston ring on all sides is coated with the hard carbon layer.

Such an embodiment is particularly suitable for Pairing with a light metal cylinder liner, i.e. at Cylinder running surfaces made of aluminum alloys, for example. While the usual gray cast iron cylinder liners Piston rings coated with a front running layer should be, the pairing leads one way hard carbon coated piston ring, no other Coating of running layer on the outer peripheral surface also with a light alloy cylinder liner the face of the ring to a satisfactory Glide. Here, nitrided steel rings can be used without any previous end face allocation can be provided. In In individual cases, an additional galvanic Chrome coating of the end face can be provided.

Preferably takes place before coating with the Hard carbon layer a fine machining, through which the Piston ring is provided with a roughness of ≤ 1 µm. In the piston ring is advantageously in this state ready for installation.

For the layer thickness of the coating of the piston ring with the hard carbon layer has a thickness of at least 2.5 µm, and preferably 3 ± 0.5 µm, as particularly favorable proved.

For the material of the piston ring according to the invention Gray cast iron is preferred, especially in tests with steel good results have been achieved.

The surface of the piston ring is also preferably below the coating is nitrided. The coating of the outer Circumferential surface of the piston ring can preferably be known Way with chrome, molybdenum, nickel, diamond or similar Materials are made to wear the peripheral tread of the piston ring.

The piston according to the invention is preferably also nearby its uppermost ring groove with a cooling channel in the piston head Mistake. For this cooling channel it is preferred that the narrowest Distance between the cooling channel and the bottom of the groove top ring groove is not more than 3 mm. With a such configuration of the piston according to the invention particularly good properties could be achieved.

The following is the production of the invention Pistons purely by way of example based on an advantageous Embodiment described.

To manufacture the piston ring, first a Piston ring blank according to known steel processes manufactured and nitrided in its surface.

In a subsequent step, the outer peripheral surface of the piston ring with a running layer opposite the Cylinder liner provided, for example, from galvanic applied chrome exists. Then the so obtained Piston ring ready for installation to a roughness of Rz ≤ 1 µm superfinished.

To the piston ring thus obtained with the invention The coating is applied on all sides using the plasma CVD process with a doped hard carbon layer coated, which has a thickness of 3 ± 0.5 microns. This Hard carbon layer, sold under the trade name Dynamant is known and defined by the general formula a-C: H, makes the surfaces of the piston ring in a special way slidable against the groove flanks of the respective Piston ring groove with which the ring is engaged. hereby both the piston ring flanks and the groove flanks protected against excessive wear.

The piston provided according to the invention is made from a cast heat-resistant aluminum alloy as claimed in claim 9 claimed and described in DE 43 26 978 A1. With regard to the alloy composition, this is Publication also on the subject of the disclosure of this Registration made. After casting the piston will be in the train the usual mechanical processing the piston ring grooves pierced directly into the material of the piston without a special flank reinforcement is provided. The Piston rings according to the invention are made in a conventional manner inserted in the piston ring grooves of the piston.

Those made in accordance with the present invention Piston rings have been used for pairing above unreinforced grooves in an aluminum piston alloy described, and the claims relate to this Combination of features. However, it should be mentioned that the Piston rings in an advantageous manner for pairings in grooves in Iron materials can be used, e.g. with built pistons with a light metal base and a steel top or cast iron. Those produced according to the invention can also be used Piston rings in pairs with grooves in the known Ring carriers are used. You can also go here Extreme loads Extends the service life of the sliding surfaces cause.

Claims (10)

1. Piston, in particular for diesel engines,

   consisting of a heat-resistant aluminium alloy and

   having at least one non-reinforced annular groove and

   at least one piston ring, which is inserted in the annular groove, and is coated with a doped hard-carbon layer applied by a plasma-CVD process at least on its flanks lying vertically to its main axis.

   characterised in that the doped hard-carbon layer has the following composition: a-C H, wherein

   a:

   amorphous material,

   C:

   carbon and

   H:

   hydrogen,

   and in that the aluminium alloy has the following composition:

   2 - 6 % copper, 2 - 6 % nickel, 11 - 16 % silicon, 0.5 to 2.0 % magnesium, up to 0.7 % iron, up to 0.5 % manganese, remainder aluminium.
2. Piston according to claim 1, characterised in that the piston ring is coated on all sides with the hard-carbon layer.
3. Piston according to one of the above claims, characterised in that the piston ring is microfinished before coating with the hard-carbon layer, preferably to a roughness ≤ 1 µm.
4. Piston according to one of the above claims, characterised in that the layer thickness of the coating of the piston ring is at least 2.5 µm, preferably 3 ± 0.5 µm.
5. Piston according to one of the above claims, characterised in that the piston ring consists of steel.
6. Piston according to at least one of claims 1-4, characterised in that the piston ring consists of cast iron.
7. Piston according to one of the above claims, characterised in that the surface of the piston ring is nitrided under the coating.
8. Piston according to one of the above claims, characterised in that the outer peripheral surface of the piston ring is coated with one .or more of the following materials: chromium, molybdenum, ceramic, bronze, nickel, SiC, TiC, Al₂O₃, or diamond.
9. Piston according to one of the above claims, characterised in that the latter has a cooling channel in the piston head in the vicinity of its uppermost annular groove.
10. Piston according to claim 9, characterised in that the shortest distance between cooling channel wall and the groove base of the uppermost annular groove is no more than 3 mm.