The invention relates to a casting tool for producing a piston. The invention furthermore relates to a corresponding method for producing a piston of this kind.
Fluid energy machines in which pistons in cylinders perform a periodic translational motion, which is transmitted via connecting rods, are known in mechanical engineering as piston engines. Probably the most widespread type of piston engine is the reciprocating-piston engine, which converts the change in the volume of a gas into the described linear motion of the piston and, via a connecting rod and a crank, furthermore converts the latter into a rotary motion. In what is probably the most common variant of the piston engine, the internal combustion engine, the piston has a combustion recess for this purpose.
According to the prior art, suitable pistons are normally produced by means of a forming process, in particular by means of specialized casting techniques. Permanent mold casting, which is known from metal processing, in which a melt is cast via a gate at the top into a metal permanent mold known as a die and the cavity of which fills essentially by gravity alone or by virtue of external pressure application, has proven particularly suitable.
Compensating the extremely high thermal load which occurs during the operation of the engine in the edge region of the combustion recess, which can lead in unfavorable circumstances to the formation of cracks in the piston, has proven problematic here. In respect of this problem scenario, the use of cooled ring supports is known from the prior art, for example. The edge of the recess is increasingly also being reinforced by embedding ceramic fibers. The squeeze casting method or a robot-aided medium-pressure diecasting method (RMD) is now being used as a permanent mold casting method for this purpose in order to ensure complete infiltration of the ceramic fibers by the molten aluminum and thus to promote the incorporation of the ceramic fibers into the metal structure.
A corresponding method is known from DE 10 2004 052 231 A1 and the corresponding disclosure in EP 1804 985 B1. Both documents relate to a method for the series production of a piston, wherein a casting melt is introduced via a feed region into a multi-part casting mold having a casting head and at least one feeder, wherein it is envisaged that, after the casting of the piston blank, the opening of the upwardly open end of the feeder sleeve is subjected to a gas pressure acting on the casting melt. The leaktightness of the feeder is ensured by using a “collar feeder”. One embodiment of this method is characterized in that, after the filling of the piston casting tool, the formation of an edge shell formed by solidified casting melt is awaited. A special embodiment of the casting head and feeder sleeve leads to the formation of a collar around the feeder in this solidification phase, giving rise to a sealing surface between the mouthpiece of the feeder and the collar, which holds the feeder contents in position.
One critical factor here is found to be leaktight pressurization of the feeder materials, which are generally composed of thermally insulating and mechanically weak materials, such as ceramics. The formation of an edge shell in the feeder takes place functionally with a delay relative to the casting tool.
It is therefore the underlying object of the invention to provide an improved casting tool in such a way that high-quality pistons can be produced in a robust casting process for pistons.
According to the invention, this problem is solved by the subject matter of the independent claim(s). Advantageous embodiments form the subject matter of the dependent claim(s).
Accordingly, the invention is based on the fundamental concept of adding to a casting head used in the context of the casting method, a preferably ring-shaped groove running around the feeder or a preferably ring-shaped collar running around the feeder, the groove or collar furthermore being arranged at a radial distance from the feeder. The casting melt fed into the casting mold via the feeder or an inlet can solidify in this groove, for example, to form a circumferential sealing rib, the inner flank of which rests with a sealing effect against a corresponding inner flank of the groove. During solidification, the casting shrinks onto the groove flank, especially in the case of different thermal expansion coefficients, such as those between an aluminum melt and a steel die. In the case of a head mold which is typically formed from steel, the high thermal conductivity of the steel brings about rapid cooling and solidification of the melt at the contact points, and this can lead to directional solidification with the formation of a fine microstructure solidified in the form of columnar grains. The still molten part of the casting melt is held in position and prevented from emerging prematurely from the head die by the surface contact between the two flanks, even in the preferred but not essential case of pressurization of the melt via the feeder. The groove surface furthermore acts as a pressure tight surface during pressurization via the feeder. This is advantageous particularly if the melt in the feeder has not yet formed a stable edge shell, owing to the good thermal insulation of the feeder material, and hence the molten melt can infiltrate porous inserts, e.g. for recess edge reinforcement, by virtue of the pressurization via the feeder. While pressurization of the melt, particularly during infiltration of porous inserts, has proven advantageous and is preferred, the formation of a combustion chamber recess in a shrunk-on workpiece can also take place without pressurization and, according to the invention, can bring about directional solidification by rapid cooling.
Of particular advantage in the casting tool according to the invention is the fact that the circumferential groove or the circumferential collar is at a radial distance from the feeder and arranged separately from the latter, with the result that the feeder per se is not stressed by the shrinking on of the casting melt during the solidification of the casting melt, as is the case, for example, with the feeder in DE 10 2004 052 231 A1.
In this case, the casting tool according to the invention for a piston comprises the casting mold mentioned for forming the piston from the casting melt, the casting head with the centrally arranged feeder for feeding the casting melt into the casting mold, and a pressurized gas line opening into the feeder for the purpose of compressing the casting melt within the casting mold. The preferably ring-shaped, in particular circular ring-shaped, groove running around the feeder and at a radial distance therefrom, and/or the preferably ring-shaped, in particular circular ring-shaped, collar running around the feeder and at a radial distance therefrom, is/are optionally provided here in the casting head. The groove has an inner groove flank for forming the casting melt into a ring-shaped sealing rib in such a way that an inner rib flank of the sealing rib rests with a sealing effect against the inner groove flank when the casting melt solidifies in the groove, whereas the collar has an outer collar flank for forming the casting melt into a ring-shaped sealing groove in such a way that an outer groove flank of the sealing groove rests with a sealing effect against the outer collar flank when the casting melt solidifies. Common to those complementary embodiments is the fact that there is no load on the feeder, in particular the feeder collar as known from DE 10 2004 052 231 A1, during solidification of the casting melt, and there is no premature solidification in the feeder.
To achieve an advantageous lightweight design of the piston, the use of a suitable aluminum alloy may be considered as a casting melt, for instance. Through the selection of specific alloying elements, which are introduced into the aluminum liquefied by melting, it is possible to selectively influence properties such as hardness, vibration absorption, toughness and the machinability of the piston blank for mechanical processing.
Because of its low viscosity, low shrinkage and other positive casting properties, an aluminum-silicon alloy, for example, has proven suitable as a light-metal casting melt, having its eutectic composition at a silicon content of approximately 12% by weight. Either a hypoeutectic or a slightly hypereutectic mixing ratio is recommended here for the method proposed, giving the resulting aluminum alloy a solidification region in which, in addition to the casting melt, there is already a small proportion of solid phases as well. In this way, the sealing effect according to the invention of the solidifying rib is achieved at an early stage. Adding up to 6% by weight of copper, up to 3% by weight of nickel and up to 1% by weight of magnesium may also be regarded as expedient for additionally increasing the strength of the piston blank. In all cases, the proportions of alloy are given in percent by weight.
The invention is furthermore based on the general concept, in the case of a method for producing a piston by means of a multi-part casting tool, of introducing a casting melt via a separate inlet of the casting tool, wherein the casting melt is subjected to pressure within the casting head by means of a pressurized gas line opening into the feeder. In this case, the missing volume due to the shrinkage of the solidifying melt and the infiltration of any porous inserts that are present is supplied to the casting mold from the feeder. During this process, the casting melt solidifies into a ring-shaped sealing rib in a groove running around the feeder in the casting head and at a radial distance therefrom, such that an inner rib flank of the sealing rib rests with a sealing effect against an inner groove flank of the groove of the piston casting tool. As an alternative, it is also possible to provide a collar on the casting head instead of the groove or in addition to the latter, with the result that the casting melt solidifies at this circumferential collar at a radial distance from the feeder to give a ring-shaped sealing groove, such that an outer groove flank of the sealing groove rests with a sealing effect against an outer collar flank of the collar of the piston casting tool. Common to both embodiments is the fact that no mechanical load is imposed on the feeder by a shrinking-on process during solidification of the casting melt; instead, the shrunk-on casting is supported directly on the casting head by a pressure force exerted via the sealing surface and, at the same time, brings about sealing along the sealing surface.
A particularly advantageous embodiment is obtained if the collar of the head mold is already as close as possible in its contours to the shape of the subsequent combustion recess, in particular of the recess edge and neck. By introducing cooling passages in the casting head close to the groove or the collar and by appropriate cooling in conjunction with the surface contact at the sealing surface under the shrinkage pressure, the removal of heat from the melt can be accelerated. In the surroundings of the contact surface, this leads to an improved character of the microstructure and, as a result, to higher quality of the casting by virtue of the accelerated solidification. Moreover, the more rapid solidification allows earlier pressurization for better infiltration of porous inserts.
In a preferred embodiment, the proposed production method is carried out as a gravity diecasting or low-pressure casting method under a pressure of between 0.3 bar and 20 bar. With a reduced space requirement compared with sand casting methods for a similar purpose, substantially full mechanization by means of suitable robots is made possible in this way, allowing a considerable increase in casting output.
Further important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated description of the figures with reference to the drawings.
It goes without saying that the features mentioned above and those which remain to be explained below can be used not only in the respectively indicated combination but also in other combinations or in isolation without exceeding the scope of the present invention.
Preferred illustrative embodiments of the invention are shown in the drawings and are explained in greater detail in the following description, wherein identical reference signs refer to identical or similar or functionally identical components.
Of the figures, which are each schematic:
As shown in
According to
In this case, the groove flank 9 or the collar flank 13 can have a slope angle α of between 3° and 20°, preferably from 10° to 15°, relative to a perpendicular 16 to a surface of the casting head 5. On the one hand, the slope angle α selected should be small enough, with regard to the friction coefficients, to ensure reliable retention of the shrunk-on casting on the sealing surface. On the other hand, the slope angle α should still be sufficiently large to allow easy removal of the fully cast piston 2. This geometrical configuration furthermore ensures that, for its part, the sealing rib 10 or sealing groove 14 formed after the hardening of the casting melt 4 defines an inner rib flank 11 or outer groove flank 15 which rests flat against said inner groove flank 9 or outer collar flank 13 and thus seals off the casting head 5 or head die against premature and unwanted escape of the casting pressure and hence allows correct infiltration of the porous inserts.
By means of the casting tool 1, a piston 2 can be produced as follows: first of all, the casting melt 4 is fed via the inlet 21 into the casting head 5 and, via the latter, into the casting mold 3 of the casting tool 1, wherein the casting melt 4 is subjected to pressure within the casting head 5 by means of the pressurized gas line 7 opening into the feeder 6 in order to avoid the formation of shrinkage cavities and in order to infiltrate porous cast-in parts. As the casting melt 4 is poured into the casting mold 3, it also enters the groove 8 running in a ring shape around the feeder 6 in the casting head 5 and at a radial distance therefrom and solidifies to form a ring-shaped sealing rib 10, wherein the respective inner rib flank 11 of the sealing rib 10 rests leaktightly against the inner groove flank 9 of the groove 8 (cf.
In this case, the casting melt 4 should be subjected to pressure after the filling of the casting mold 3 and before the complete solidification of the casting melt, at the earliest after the filling of the casting mold 3 and after the partial solidification of an edge shell of the piston and partial areas of the inlet 21. In order to be able to reinforce regions subject to particularly high loads, e.g. a recess edge 17 or a ring support region of the piston, provision can be made to insert a porous insert 18 at that point (cf.
The insert 18, in particular a ring support or a recess edge protector, can, for example, be porous and infiltrated by means of pressure exerted on the casting melt 4. At the same time, infiltration can be assisted by the production of a vacuum by means of suction lines 20. A near-eutectic aluminum alloy containing 10% to 14% by weight of silicon and/or furthermore up to 6% by weight of copper, up to 3% by weight of nickel and/or up to 1% by weight of magnesium is particularly suitable for the casting melt 4. Moreover, it is possible, for the purpose of increasing hot strength, to add further elements, e.g. V and Zr (in each case <0.2%), and, for grain refinement, Ti (<0.2%) and P (<0.01%), for example. A near-eutectic or even hypoeutectic configuration of the AlSi alloys has proven advantageous in terms of suitability for infiltrating porous inserts. Moreover, there is a preference for a casting melt which is largely free from impurities due to low-melting elements with a melting point <490° C., e.g. Pb, Bi, Sn, Zn, wherein the concentrations of these elements individually are each below 0.01%.
Casting of the pistons 2 is performed by the gravity diecasting or low-pressure casting method, and solidification of the casting melt in the casting mold takes place, in particular, under a pressure of between 0.3 bar and 20 bar.
In a manner known per se, the casting melt 4 described is introduced into the casting tool 1 via the inlet 21, with the result that the free regions of the casting mold 3 around a core 19, which subsequently forms the small end bearing eye of the piston 2, fill up all around with casting melt 4. The specific embodiment of the casting head 5 and the feeder 6 allows the formation of the sealing rib 10 or sealing groove 14 holding the feeder contents in position when, to achieve short cycle times, the casting tool is opened in accordance with the method at a time at which the contents of the feeder 6 may still be partially liquid internally. In this case, the stabilizing effect of the sealing rib 10 or sealing groove 14 is assisted by the groove 8 essential to the invention surrounding the feeder 6 in the casting head 5 or, in the complementary embodiment, by the annular collar 12, within which the casting melt 4 solidifies to form the ring-shaped sealing rib 10 or sealing groove 14.
For this purpose, the casting melt 4 can rise to a desired extent within the feeder 6, giving rise to a free space within the feeder 6 above the introduced casting melt 4 after feeding of casting melt 4 has ended, via which free space the casting melt 4 can be subjected to a gas pressure of between 0.3 bar and 20 bar. It has proven advantageous to configure the casting head 5 of the piston casting tool 1 in such a way that the feeder 6 is guided at the outside diameter in the casting head 5 by a sleeve 22, to which the pressure line 7 is flanged in a pressure tight manner. The gas for pressurization is fed to the feeder 6 via the pressurized gas line 7, which is open to the environment during the process of introducing the casting melt 4, thus allowing pressure equalization to take place (cf.
Number | Date | Country | Kind |
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10 2014 216 517.2 | Aug 2014 | DE | national |
This application claims priority to German Patent Application No. 10 2014 216 517.2, filed on Aug. 20, 2014, and International Patent Application No. PCT/EP2015/066598, filed on Jul. 21, 2015, the contents of which are hereby incorporated by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/066598 | 7/21/2015 | WO | 00 |