DE19955809A1 - Piston of an internal combustion engine - Google Patents

Abstract

The present invention relates to a piston of an internal combustion engine. Such a piston has an upper part (1) and a jacket part (3) surrounding a piston pin, which are supported on at least one axial bearing surface (11, 12) of its joint surface, while they are joined together by at least one screw (2) through the bearing surface . The upper part of the piston also has an annular outer cooling gallery (9) and an inner cooling gallery (10) surrounded by this. In the piston according to the invention, at least one recess (19) is provided in its outer cooling gallery, which is located further down than the rest of the bottom (18) of the cooling gallery. The depression brings about a tangential movement in the cooling oil of the piston during a movement of the piston, which thus improves the cooling of the piston.

Description

The present invention relates to a piston of a Ver Internal combustion engine according to the preamble of claim 1.

Large pistons for diesel engines are usually multi-part, so called built pistons, which are typically connected to each other these days ne parts, an upper part and a lower part. These parts are through one Screw connection together with one screw or several screws quantity added. The upper part of the piston forms part of a combustion chamber and the upper part has ring grooves of the piston. The lower part of the piston is also called the piston skirt. The task of this jacket part is on the Top of the piston directed gas pressure forces by a piston pin to transmit a crank rod through which rod the power to a cure Belwelle flows. The jacket part of the piston is also arranged, side forces against a cylinder sleeve.

Because a piston is heated considerably by an engine in motion, piston parts must be cooled. The excess temperature conventionally derived from the piston with oil. The most advanced cooling The process for such large pistons for diesel engines is the so-called called shaker cooling. The upper part of the piston typically has two Cooling galleries, an inner cooling gallery and an outer one surrounding it Cooling gallery, in which galleries the cooling oil is directed. Such cooling galleries are conventionally symmetrical with the inner cooling gallery below in Direction of the piston pin is either open or partially closed. The outer cooling gallery is ring-shaped or cyclically symmetrical at the top.

However, for example in heavy oil diesel engines increasingly the problem that the in the cold rooms of the Kol bens acting cooling oil is unable to adequately heat derive the most heat-stressed components. To avoid them Water problems are the design of the cooling gallery, for example with drilling Hole-like recesses have been developed to prevent the penetration of cooling oil according to EP 0 464 626. The recesses can also be long be recesses created by machining, as in the script DE 41 18 400. Different designs of cooling galleries are also described in the documents DE 38 42 321 and DE 39 19 872.  

When examining the load on the piston, it is found that the structures of the piston in its operating conditions from deformation be influenced by temperature and gas pressure, what deformations in the screws that join the piston parts tiring voltage fluctuations to let. The size and number of voltage fluctuations affect the Life of the screws. With large voltage fluctuations the fatigue of the screw connection and thus the probability damage to the entire piston.

It can thus be established that the current piston Have defects that help cool them down and especially correct them Direction whose cooling is due.

The present invention has for its object the legs to reduce the disadvantages of the known prior art and to create a solution of a completely new type, by means of which the Ab Cooling of the piston intensified and better directed and the tension fluctuations in the screws in the screw connection of the piston can be reduced by.

This object is achieved in that the piston burns tion motor according to this invention, which are determined in the claims Have characteristics. More specifically, this arrangement is according to the invention mainly characterized by what is in the characterizing part of claim 1 is cited.

The inventive shaping of a cooling gallery makes egg ne more beneficial cooling effect than achieved by the conventional. If the Piston moves down depending on the slowed piston speed, An inertial force thus presses the cooling oil in the outer cooling gallery of the Piston into recesses according to the invention in the lower part of the cooling gallery. When the piston changes direction and the piston speed increases, the inertia continues to hold the oil in these wells presses. According to a preferred embodiment of the invention, the Un part of the cooling gallery in such a way that the oil is currently in the accumulates two depressions in the lower part of the cooling gallery. If the piston moving further upwards, the piston reaches its highest speed speed, after which the speed of the piston begins to slow down.  

Then the oil continues to move at an unchanged speed and gets rid of the lower part of the cooling gallery. After a certain amount of time the oil hits the top of the cooling gallery, with the oil still around direction of the piston is unevenly distributed. Because of the big loading acceleration of the piston, the free surface of the oil is currently in the Balanced top of the gallery. Because of its uneven distribution However, the oil can only escape thanks to a flow in the circumferential direction be compared. In this way, a tangential flow of the in the Wells accumulated oil causes while the oil gets into the top of the piston. Thanks to the solution according to the invention, the cooling oil flows in the cooling galleries of the piston not only during a pendulum motion tion of the piston in the direction of the piston longitudinal axis between the Top and bottom of the cooling gallery there and back, but thanks to the novel shape of the lower part of the outer cooling gallery can be an oil flow in the circumferential direction and a more efficient convection to be brought. In this way, with the help of the cooling oil, greater heat led away from the hot walls of the top of the piston become.

In the solution according to the invention, screws are one of them Upper part and shell part of a piston joining screw connection with an internal, axial bearing surface of the piston in one to one Piston pin arranged substantially vertical position, and the depressions The outer cooling gallery are located in one of the piston pins Location arranged. So the bottom of the cooling gallery is on the screws highest, with less cooling surface in the area of the screw connection is provided. This can cause thermal stress Temperature difference between the screws and part of the piston volume of the screw connection made as small as possible and one on the Voltage fluctuations that direct the screw can be reduced. This will significantly improved fatigue strength of the screws. How be the stretchable part of the screw connection is the screw. With the A screw force is generated under the influence of which parts to be joined together are pressed together. That this Volume exposed to screw force is called a press piece. If between between the screw and the surrounding press piece a large, especially  riizing temperature difference arises, the screws become significant Exposed to voltage fluctuations.

There is a tendency in the material of the screw connection of a built piston and in the material that surrounds the screws considerable temperature difference arises because of the threaded part of the screw ben, from which heat is transferred to the screws, close to you Combustion chamber. Otherwise the screw is surrounded by a free hole, with air around the screw that provides good thermal insulation det. The screw is heated to a high temperature. Of The material surrounding the screw transfers the heat elsewhere into the Construction derived what heat dissipation is strong when the distance to the cooling gallery is short.

These voltage fluctuations have a remarkable on effect on the life of the screws during the fluctuations and actions to be supplied thereon, however, according to the inventive solution solution must be reduced significantly.

In a solution with the screws of the top and the man part of the piston joining screw connection in the area egg ner inner, axial piston contact surface in a lower to the piston pin arranged on the right, the jacket part of the piston can be shaped so who that the force flow of the gas pressure force as little as possible through the press piece of the screw connection flows. Then the jacket part can be arched be designed while the pressing piece mainly from the screw ben surrounding so-called screw bags. Thanks to a sol structure causes a varying load generated by gas pressure the smallest possible voltage fluctuations in the screws.

The following is the invention with reference to the attached Drawing explained and a longitudinal section of the piston of a combustion motors shown, showing only the parts that are understandable speed of the invention are essential by the cut partially parallel to the Longitudinal axis of the piston pin and partly perpendicular to the longitudinal axis of the Piston pin runs.

The figure shows a preferred embodiment of the solution according to the Invention. The piston has an upper part 1 and a lower part 3 of the piston, which is preferably connected with screws 2 . The upper part of the piston has a plate 4 and a substantially cylindrical wall 5 , which is provided with at least one annular groove 6 for a piston ring. The plate receives a gas pressure force directed at the piston. The surface of the plate is designed such that it forms a combustion chamber trough 7 , and the lower surface 8 of the plate forms the upper part of an annular, outer cooling gallery 9 and the upper part of an inner cooling gallery 10 in the middle of the piston. This inner cooling gallery is connected to the outer cooling gallery of the piston via oil line channels.

The parts of the piston according to the invention are joined together on a joint surface which has at least one bearing surface, the embodiment of the figure showing a solution with two bearing surfaces, namely with an inner axial bearing surface 11 and an outer axial bearing surface 12 . The annular inner axial support surface is located between the cooling galleries 9 and 10 . The outer axial bearing surface is arranged with a substantially cylindrical wall 5 . Between the bearing surfaces on the upper part of the piston, the upper part of the outer cooling gallery of the piston is attached.

The lower part 3 of the piston, ie the jacket part, also has the inner and outer axial bearing surfaces 11 and 12 which receive the upper part of the piston and together delimit the lower part of the outer cooling gallery of the piston between them. The jacket part further has sliding surfaces 13 against a cylinder sleeve surrounding the piston and a hub 14 of the piston bolt with bearing bores.

The upper part 1 and the jacket part 3 of the piston are thus arranged to be supported on the annular, axial bearing surfaces 11 and 12 of one or more joint surface (s). The inner axial bearing surface 11 of the casing part forms part of an annular projection 16 which is substantially parallel to an assumed central axis 15 of the piston and which is arranged to receive the screws 2 which join the piston parts. The ring projection together with the lower surface 8 of the plate of the piston upper part of the inner cooling gallery 10 of the piston, while the outer cooling gallery 9 is arranged to surround the ring projection from the outside. In the area of the ring projection, below the inner axial bearing surface, the inner shape of the jacket part is designed like a vault. Screw bags 17 are then arranged to extend downward from the vault, which screw bags make up a significant part of a press piece surrounding the screw connection.

The two cooling galleries 9 and 10 of the piston are supplied with cooling oil, which is used for shaker cooling. The cooling oil is led via at least one supply channel into one cooling gallery, from which the oil gets into the other cooling gallery via oil line channels.

In the piston according to the invention, the movement of the cooling oil in the outer cooling gallery 9 is intensified, preferably by milling a bottom 18 of the cooling gallery in order to provide the bottom with a varying depth. Thus, a recess 19 or more is arranged at the bottom of the cooling gallery, which are lower than the rest of the gallery floor. When the piston moves, the cooling oil in the cooling galleries is controlled to accumulate in the recess if it is in the lower part of the gallery. Because of the movement of the piston, the oil hits an upper part 20 of the plate of the cooling gallery before the top dead center of the movement. When the upper part of the gallery is hit, the oil is distributed unevenly in the circumferential direction because of the depressions in the lower part of the gallery. Under the action of an inertia force, the oil is pressed into the upper part of the cooling gallery and is currently compensated for by a tangential flow. In this way, an oil flow is created in the circumferential direction, which flow derives larger amounts of heat from the hot walls of the Kol benoberteil.

In a second embodiment of the invention, the screws 2 of the screw connection joining the upper part 1 and the jacket part 3 of the piston are attached to the inner axial bearing surface 11 of the piston in a position substantially perpendicular to the piston pin. The bottom 18 of the outer cooling gallery is located higher on the pressing piece than the surrounding bottom of the cooling gallery, while the bottom is deeper in the direction of the piston pin than in the direction perpendicular to the pin direction. Because the outer cooling gallery 9 on the screws is low and the radial cross-sectional area of the cooling gallery is also the smallest, the cooling effect generated with cooling oil in the area of the pressing piece of the screw connection is also smaller than in the other parts of the cooling gallery. In this way, a smaller temperature difference is created between the screws and the press pieces surrounding them.

With the vault-like shape of the annular projection 16 of the casing part 3 below the inner axial bearing surface 11 , the highest part of the arch of the vault 21 is substantially brought to the screws 2 . In that the screw bag 17 extending down from the vault forms a significant part of the pressing piece of the screw connection, the jacket part of the piston is provided with a structure in which the force flow of the gas pressure force flows through the pressing piece of the screw connection as little as possible. Such a structure reduces the stress fluctuations in the screws caused by the load on the gas pressure force of the piston.

It is to be understood that the above description and the ge listening figure are only intended to illustrate the present invention lichen. The invention is thus not limited to the above or to the limited embodiment in the claims, but Many different variations and modifications of the Invention to be evident, which is within the scope of the inventive idea of the attached th claims are possible.

Claims (6)

1. Piston of an internal combustion engine, which piston has an upper part ( 1 ) and a jacket part surrounding a piston pin ( 3 ), which are supported on at least one axial bearing surface ( 11 , 12 ) of its joint surface, while the upper part and the jacket part with at least two screws ( 2 ) are joined together by the bearing surface, the one ends of the screws being arranged in the vicinity of a combustion chamber adjacent to the upper part and thus being thermally loaded, and in that the piston has an outer cooling gallery ( 9 ) surrounding it in a ring shape and one of these surrounded in nere cooling gallery ( 10 ), the outer cooling gallery ( 9 ) in a bottom ( 18 ) formed on the surface of its jacket part ( 3 ) has depressions ( 19 ) which are located further down than the rest of the bottom of the cooling gallery, characterized in that there are at least two recesses ( 19 ) and that these are arranged substantially in line with the piston pin s Ind, wherein the cooling oil is arranged in the cooling galleries, mainly accumulate in the recesses ( 18 ) of the bottom when it is located in the lower part of the outer cooling gallery ( 9 ), the cooling oil distributed unevenly in the circumferential direction of the piston substantially at top dead center the piston movement is arranged to abut the top ( 20 ) of the piston, the abutment being arranged to cause a tangential flow of the cooling oil to balance the cooling oil in the top of the piston. 2. Piston according to claim 1, characterized in that the recess ( 19 ) is produced by milling. 3. Piston according to claim 1 or 2, characterized in that there are two recesses ( 19 ). 4. Piston according to one of the preceding claims, characterized in that the bottom ( 18 ) of the outer cooling gallery ( 9 ) is arranged on a press piece surrounding the screws ( 2 ), to be the highest in comparison to the rest of the bottom, while the ra diale cross-sectional area of the cooling gallery is smallest. 5. Piston according to claim 4, characterized in that the jacket part ( 3 ) of the piston is arranged to form the press piece surrounding the screw ( 2 ), while the press piece is arched on the screw near the bottom ( 18 ) of the outer Cooling gallery ( 9 ) extends and forms a screw bag ( 17 ) penetrating into the jacket part around the screw. 6. Piston according to one of the preceding claims, characterized in that the screw ( 2 ) on a benbolzen to Kol substantially vertical sectional plane or in connection with it is brought to.