EP0154939B1 - Oil-cooled, two-piece linked piston - Google Patents

Description

Today, high engine outputs can be operated with oil cooling in internal combustion engines, whose pistons and combustion processes are designed so that only little heat flows from the combustion chamber to the cylinder wall. In connection with the possibilities of oil cooling, the design of the internal oil spray cooling is becoming increasingly important, especially since it can replace the external circulation cooling up to the level of the ring carrier of the piston upper part (cf. DE-OS 33 14 543).

The proposal has already been made to equip the lower part of the piston with oil guide surfaces in a two-part piston (cf. DE-OS 25 434 78). The heat can be dissipated from the cylinder via the lower piston part and the oil spray cooling to the inside of the oil, and heat can also be transferred from the upper cylinder part to the lower cylinder part, which brings about a standardization of the cylinder temperature (cf. DE-ES 33 14 543) .

However, according to the prior art, the power cooling of this oil cooling system is limited by the fact that the bolt can be well lubricated using the previously known oil guide surfaces (baffle surfaces), but the heat removal from the cylinder in the area of the lower piston part occurs intensively only along these oil guide surfaces, but across the piston pin bearing the cooling of the cylinder still needs to be increased.

This disadvantage is particularly noticeable in engine practice in the case of cast cylinders, where the disadvantages of less cooling in the direction of the crankshaft due to the cast cylinders and the lack of external cooling with the disadvantages of less internal oil cooling transversely to the piston pin direction in the area of the lower piston part due to the last paragraph described shortcomings meet.

Thus, the state of the art with regard to the internal oil spray cooling and the lower piston part of a two-part piston has the result that, although the cylinder temperature is standardized in the longitudinal direction of the cylinder, a uniform temperature level is not achieved in the cylinder circumference. However, it is precisely the internal oil spray cooling which is to be able to be aligned uniformly or comparatively to the temperature of the entire inner surface of the cylinder. Because only the thermal roundness of the cylinder enables the installation of completely round pistons and thus the sealing play between piston and cylinder is reduced to a minimum. It is shown and described in the above-mentioned DE-OS 25 43 478 an oil-cooled, two-part articulated piston, the piston crown of which is cooled from below by an oil injection, there also guide surfaces (21) for supplying the cooling oil to the piston boss and guide surfaces (27) for Drain the cooling oil to the crankcase. However, the cooling oil can only be injected there on one side of the piston pin, and the cooling oil flowing back hits the cylinder wall predominantly in one plane, which runs transversely to the piston pin.

It is the task of the present application to make the temperature distribution of the inner surface of the cylinder evenly uniform. This is guaranteed with the measures of the 1st claim. Refinements can be found in the further claims.

The newly developed proposal is to improve the internal oil cooling of the cylinder by staggering the backflow of the sprayed cooling oil in the lower part of the piston by 90 °. The lower piston part should have several guide surfaces, with at least one inner guide surface (along the pin) aligning the cooling oil to the pin and past it towards the upper piston part in a known manner, while at least one outer guide surface ensures the return flow of the oil, specifically across the pin axis, so that the cooling oil (in the previously not cooled area) is drained off on the cylinder wall. The oil spraying up from below cools indirectly via the inner oil guide surface (s) the cylinder areas, which are in the longitudinal position of the pin, while the returning oil, which is not steered on the upper part of the piston, cools the cylinder areas diagonally to the position of the pin.

The oil flowing back over the outer guide surface (s) is then retained by a sealing edge at the lower end of the lower piston part, which bears against the cylinder, or discharged downward through a slot or a bore.

The advantages of such cooling lead to the elimination of the previous shortcomings. The thermal roundness of the cylinder enables the piston to be made gas-tight. It can be placed close to the cylinders above the piston rings. All previous types of cooling are defective in this point because the pistons cannot be adapted to the thermal runout of the cylinder. However, pollutants (e.g. CH) are generated in the sealing gaps, and such freedom of movement for the piston increases noise.

Furthermore, the thermal out-of-roundness of cast-in cylinder bushes can be compensated for by the proposed internal cooling and the piston lower part; stronger cooling across the pin axis results in an even tempering of the cylinder as a whole.

For the proportionally largest emission of an internal combustion engine, the C0 ₂ emission, it will be important in the future that a high thermal tightness of the combustion process is paired with an optimal gas tightness of the piston and cylinder: the more uniformly the cooling takes place over the entire cylinder circumference, the higher this can be Temperature level of the cylinder can be selected, which is an important requirement for the combustion of vegetable oils instead of petroleum products; With regard to the exhaust gases, vegetable oil gives a neutral CO _z balance.

A possible embodiment follows.

Image description

Fig. 1: In Fig. 1, the inner and outer oil flushing of the cylinder is shown, part (1) representing the motor housing with the oil channel (2). On the oil channel (2), which is fed with lubricating oil, one or more oil splashes (3) are arranged, which spray the interior of the cylinder (4) in the plane of motion of the connecting rod. The spray oil (5) is controlled by guide vanes (6) in the direction of the upper piston part (7) and from there is conveyed back from above (5a) to the lower piston part (8).

On the inside of the cylinder, better oil cooling is achieved over the entire circumference of the cylinder. For this purpose, the piston lower part (8) has on its inside next to the mentioned guide vanes (6), which run in the direction of the piston pin (20), on its outside, guide surfaces (31) (Fig. 2), which are transverse to the piston pin (20) stand. Oil cooling thus reaches the entire cylinder circumference and approximately 80% of the cylinder length of the inner cylinder surface up to the level of the upper piston part. The inner cooling oil does not reach the cylinder surface covered by the piston sealing jacket (22), which is why the sealing jacket is cooled on its inner surface with spray oil (5a). An annular channel (10) is inserted approximately as deep as the length of the sealing jacket, so that good oil cooling is guaranteed on both sides of this important upper cylinder part.

A combustion process is provided in the piston combustion chamber (27), in which the excess air (29) rotates around the hot combustion zone (28), which provides good protection against high temperatures in the upper piston part (7).

This type of low heating and cooling makes it possible for the usual gas seal between the cylinder head at the connection point (30) to be dispensed with.

Fig. 2: Fig. 2 shows a section of the lower piston part (8) in the direction of the piston pin with the outer guide surfaces (31) which catch the spray oil (5a) (Fig. 1) thrown back by the upper piston part (7) (Fig. 1) . The oil is held here briefly by the lower oil sealing edge (33) in order to achieve more intensive cooling of the cylinder wall in this plane. It then flows through the holes or a slot (34) into the lower part of the cylinder (4). The arrows (5a) show the oil (5) previously sprayed up on the guide surfaces (6), which is deflected back by the piston top and transversely to the injection plane (offset by 90 °) through the new guide surfaces (31) its outflow to the lower part of the cylinder ( 4) takes place.

Instead of the four guide surfaces described in the exemplary embodiment, more or fewer guide surfaces including those that are divided or at an angle to one another can be used for other application examples; as well as the shape of the inner or outer guide surfaces should not be determined by this example and also not the type of bore or the dissipating slot.

Claims (4)

1. An oil-cooled two-section articulated piston, the sections of which are jointed by means of a pin (20), whereby the upper section, facing the combustion chamber (7), receives gas forces and the lower section, facing the crankshaft (8) receives lateral forces, provided with a piston bottom cooling taking place by means of an injection oil cooling (5) from the crankcase, and with conducting surfaces which are fitted under the piston bottom, characterized in that the lower section of the piston (8) presents four conducting surfaces, the internal guiding blades (6) directing the oil splashed upwards into the space beween the piston's lower and upper sections (5a), from where it is redirected down to the cylinder surfaces transverse to the pin axis by means of the external guiding surfaces (31).

2. An articulated piston according to claim 1, characterized in that the cooling oil (5a) directed to the cylinder wall (4) is collected in an interspace between the side wall of the piston's lower section (8) and the cylinder wall (4) and is retained by an insulating rim (33) on the lower edge of the piston's lower section (8).

3. An articulated piston according to claim 2, characterized in that the cooling oil (5a) in the interspace flows to the crankcase through a slit or a bore (34).

4. An articulated piston according to one of the claims 1 to 3, characterized in that the cooling oil on both sides of the piston pink is splashed onto the appropriate guiding surfaces (6).

Images