DE1152720B - Manufacture of piston rings by powder metallurgy - Google Patents

Description

Production of piston rings by powder metallurgy The use the powder metallurgical manufacturing process is particularly economical then interesting when it comes to the production of large series of parts of the same type Dimension is, in addition, according to the previous manufacturing process, one more require considerable machining. These requirements are in particular given in the manufacture of piston rings for internal combustion engines.

Such piston rings are predominantly made using a special casting process Cast from pearlitic gray cast iron and then machined, with a multiple of the spreading weight must be machined. In the past, the piston rings were considered closed, circular rings turned, slotted and then thermally tensioned. Today has on the other hand, the production of mechanically tensioned rings largely prevailed. Included the rings are turned on non-circular lathes in a precisely calculated, non-circular shape, cut out a section so that the ring is circular in shape when pressed together accepts. The ring produced in this way has significant advantages. The radial tension of the mechanically tensioned ring occurs almost evenly on the entire circumference of the ring on what could not be achieved with a thermally stressed ring. It also holds the mechanically tensioned ring retains its tension even at significantly higher temperatures. The low output factor, the extensive and also the non-round ring Even complicated machining can now be done by the Koibenring production seem predestined for the powder metallurgical manufacturing process. It it is therefore not surprising that many attempts have been made to make piston rings in this way. First they tried in England to solve the problem the composition of a material corresponding to the cast iron used on a metal-ceramic Ways to solve. Electrolyte or sponge iron powder was used 15 to 25% white Cast iron powder and a corresponding amount of the finest graphite powder. The heating processes the briquetted parts were guided so that the carbon is not completely in Solution went. Nevertheless, quite remarkable technological properties of the parts were achieved the process could not continue to prevail because the product obtained in the long run it did not meet the requirements.

It has now been further proposed, e.g. B. by adding chromium alloy Cast iron to improve the technological properties. About greater success but nothing has become known in this way either. It was also suggested that more ferritic-pearlitic in the case of a relatively easy-to-manufacture sintered iron Structure the necessary spring properties through a partial internal hardening of the To create rings. Undoubtedly, this method is using modern hardening processes feasible with circular, i.e. thermally tensioned rings, but not straight cheap. However, it cannot be used for rings that are not round. Since you are now today can no longer do without the advantages of the mechanically tensioned ring and So the application of partial internal hardening comes as a general solution the production problem of piston rings by powder metallurgy does not in question.

According to the invention, a method is now proposed according to which in Piston rings that are flawless in every respect, made by powder metallurgy, are used the known double press sintering process can be produced, wherein it is only a question of the shape of the pressing tool used, whether the rings round or out of round. The basis of the invention is an alloy that In addition to a very high OE, other properties are also guaranteed that those far exceed the best pearlitic cast iron. This is especially true for tear, Wear and heat resistance as well as corrosion resistance and sliding properties to.

For this purpose, an alloy is proposed that consists of 4 to 8% copper, 0.3 to 0.8% silicon, 0.4 up to 0.6 "/ o manganese, 0.4 to 1.2% tin, Zinc or aluminum, 0.8 to 1.2% carbon, the remainder being Fe. The maximum grain size should be of all single powder types used do not exceed 0.15 mm.

In the production and processing of this alloy you can now In principle, two routes can be taken, the second route being somewhat higher in cost caused, but also the achievement of top quality in terms of technological properties of the material.

In the first way, the powder mixture of pure iron, copper, Ferrosilicon and ferromanganese powder as well as tin, zinc or aluminum powder and Graphite made by intensive mixing. To facilitate pressing and Prevention of segregation phenomena, mainly during mechanical filling of the molds, about 0.5% zinc stearate and about 0.0511 / a are added to the mixture Oil too. The powder mixture is now at a specific pressure of about 6 t / cm2 briquetted and at a temperature below the melting point of copper, sintered at about 1020 to 1050 ° C, about 1 hour. This is the same as with all of the following Heat processes in a known manner to ensure that a decarburization of the parts is kept to a certain minimum. After the parts have been sintered for the first time redensification takes place, again with a specific pressure of about 6 t / cm2, and a further sintering at about 1200 ° C. From the cooling zone of the sintering furnace the parts are then removed at a temperature of about 950 ° C, quenched in oil, reheated to around 750 ° C under protective gas and slowly cooled, if possible in an oven. The second way is as follows: There is an iron alloy powder in the requested Grain size manufactured, the silicon, manganese and carbon already as alloy elements contains. This alloy powder is in a known manner and in the desired Completely chemically or galvanically coated with copper and carefully reduced. It is important to ensure that no decarburization takes place. The encased Powder is now mixed with tin, zinc or aluminum powder and oil in the aforementioned Amount mixed and pressed. The addition of zinc stearate is not necessary in this Cases. The further processing corresponds to that described above.

If you want very high strength in special cases; properties Achieve, it is possible without difficulty, the compaction in the second Pressing in a warm state, for example at a temperature between 850 and 950 ° C. One can then also use the specific; Pressing pressure at the first Select a lower briquetting rate. Depending on the special. Composition of the material strengths of up to 100 kg / cm2 and densities of 7.6 and higher can then be achieved.

It is still possible to initially use the alloy without carbon to process and subsequently only a carburization of the outer zone of the parts to undertake. Since the carbon in the present alloy is less used to increase strength but primarily a transformation of the ferritic iron into pearlite should allow, a restriction of the carbon content to the outer zones can be of the parts represented. It should also be mentioned that it is of course based on the ways proposed according to the invention is also possible to produce piston rings, to which very special requirements are placed. So be here for example stated that rings can be produced particularly cheaply because of their resistance to corrosion special requirements are made. Such rings have so far been preferred made of special bronze. You can according to the present invention by proportionate increase in the elements copper as well as tin, zinc or aluminum in the alloy beyond the originally intended level with the greatest success are fabricated. When composing the alloy, however, is then fundamental start from copper-coated iron alloy powder. The sheath thickness is set to at least 60 / a, while the rest of the copper is in powder form can be introduced.

According to the proposals according to the invention, practically any piston ring are made, provided that its dimensions and the need are fundamentally out economic considerations for a fabrication on powder metallurgy Appropriate ways.

Claims (6)

PATENT CLAIMS: 1. Manufacture of thermally or mechanically stressed Piston rings by powder metallurgy using the double press sintering process, characterized in that a powder mixture with a maximum grain size of "0.15 mm, consisting of 4 to 8% copper, 0.3 to 0.8% silicon, 0.4 to 0.6% manganese, 0.4 up to 1.2% tin, zinc or aluminum, 0.8 to 1.2% carbon, the remainder iron, each pressed with a specific pressure of about 6 t / cm2, avoiding stronger decarburization at a temperature below the melting point of copper sintered after the first pressing and at about 1200 ° C after the second pressing will. After the second sintering, the rings are removed from the cooling zone of the sintering furnace removed at about 950 ° C, quenched in oil, heated again to 750 ° C and slowly cooled before the completion of the piston rings takes place in the usual way. 2. Manufacture of piston rings according to claim 1, characterized in that silicon and manganese in the form of ferro-silicon and ferro-manganese powder of the appropriate grain size can be added to the powder mixture. 3. Production of piston rings according to claim 1 or 2, characterized in that silicon, manganese and carbon are already in the iron to be pulverized are contained as alloy components and that Copper completely or at least partially by sheathing on the iron alloy powder is applied. 4. Production of piston rings according to one of claims 1 to 3, characterized in that the second pressing takes place in the warm state, wherein the pressing pressure can be reduced during the first briquetting. 5. Amendment the method according to any one of claims 1 to 4, characterized in that the Powder mixture initially processed carbon-free will and after after the second sintering of the parts, partial carburization of the outer ring layers is carried out in a known manner to a depth of about 0.5 mm. 6. Production of piston rings of increased corrosion resistance according to one of claims 1 to 5, characterized in that the copper content of the alloy is increased in proportion to the content of tin, zinc or aluminum beyond 8%, but always a minimum of 6% copper chemical or electrolytic coating of the iron alloy powder is introduced into the mixture.