EP2140126A1 - Load-optimized interior of a piston - Google Patents

Abstract

The present invention relates to a piston (1) of an internal combustion engine having a piston crown (2) provided with a ring zone (8) and adjoining a piston skirt (3) encompassing a piston interior (16), the skirt having two load-bearing skirt wall segments (11) and two pin bosses (12). Each pin boss (12) encompassing a boss hole (13) is connected to a boss base body 15) by a boss support (14), the base body having ribs (17) to increase stiffness, which are aligned to the extent possible in the direction of the boss holes (13) continuously connecting the pin bosses (12). The curved or arched ribs (17) thereby cover a pivoting range of a connecting rod.

Description

 DESCRIPTION

Load-optimized interior of a piston

The invention relates to a piston of an internal combustion engine having a piston ring comprising a ring field, to which a piston shaft connects, which forms two diametrically opposed supporting shaft wall sections and two staggered pin bosses which together enclose a piston interior. Each pin hub includes a hub bore for receiving a piston pin and is connected via hub supports with a hub base body, which ribs for reinforcement, according to the features of the preamble of claim 1.

Higher loaded internal combustion engines with increased specific power and reduced fuel consumption require low oscillating masses and thus weight-optimized pistons, without limiting the service life. To achieve a sufficient fatigue strength, it is known to provide such piston with stiffening ribs. Preferably, the stiffening ribs intended to achieve an increased component strength of the piston are designed uniformly dimensioned. The known ribs are spaced in the piston interior to the peripheral surface of the piston shaft and thus arranged rotationally symmetrical to a vertical axis of the piston. It has been shown that such positioned stiffening ribs with an approximately constant wall thickness or thickness for higher loaded piston do not cause sufficient component rigidity.

The invention is therefore based on the object to improve the dimensional stability of the piston with targeted inexpensive representable measures. This object is solved by the features of patent claim 1.

According to the invention, it is provided that the piston interior includes, as far as possible, ribs aligned in the direction of the hub bores, which ribs are connected in one piece with the hub base body or the piston crown and which produce a continuous connection between the pin bosses. The an effective stiffening of the piston forming ribs are curved away from a pin axis or designed as a bridge shape. The dimensioning, the height, the rib thickness and the course of the ribbing according to the invention is such that they have a connecting rod release and thus take into account a pivoting range of a connecting rod.

The ribs according to the invention, which connect the pin bosses, optimize the force introduction or force deflection within the piston from the piston head into the pin bosses. The constructive concept according to the invention is easy to implement and inexpensive to represent and forms by means of a local, relatively small stiffness section between the pin bosses an advantageously load-optimized piston interior, which also leads to improved dimensional stability of the piston. These measures are particularly suitable for a weight optimized designed piston to achieve improved component strength. Advantageously, with the ribbing according to the invention, the service life of the piston can be increased and at the same time the number of damage cases can be reduced. The stiffening measures can be applied both to steel forged or welded pistons and to cast pistons. The trained according to the invention piston is preferably suitable for use in performance-enhanced, mechanically highly loaded internal combustion engines, especially diesel internal combustion engines.

Further advantageous embodiments of the invention are the subject of the dependent claims 2 to 15. A preferred design form according to the invention for a welded cooling channel piston provides for a positional correspondence between the ribs and a wall of the piston head which separates cooling channels and which is supported via a joining web on a joining web of the hub body. This results in an advantageous improved initiation of the force from the piston head starting on the joining webs and the ribs in the pin bosses.

Furthermore, it is provided according to the invention to make the ribs on the side facing away from the piston crown side arcuate. In this case, starting from the pin hubs, a height of the ribs sets in, which continuously decreases to a crest line of the ribs. This also a bridge shape forming contour can be advantageously adapted to a voltage curve, which adjusts due to the force introduced into the piston. Additionally or alternatively, the invention also provides that the ribs starting from the apex line, each reinforce or thicken in the direction of the pin boss.

Another concept of the invention comprises an approximately oval-shaped zone or recess in the region of the piston crown, wherein, to illustrate this solution, the ribs according to the invention arcuately connect the pin bosses and thus delimit the recess. The course and the height of the ribs takes into account the swivel range of the connecting rod.

The invention includes a diverse geometric design of the ribs, which can be selected exclusively under the aspect of optimum strength of the piston inner mold. For this purpose, offers a ribbing with a rounded, in particular semicircular cross-sectional profile. Furthermore, the ribbing may have differently extending outer contours. In particular, a convex or concave outer contour of the ribbing is suitable. Likewise, a rectilinear outer contour can be provided. Preferably, the outer contour is different from the inner contour of the ribbing, for example due to different radii of curvature or a largely straight or concave outer contour, which is associated with a rounded course of the inner contour.

To achieve approximately tension-free transitions between the ribs and the pin bosses or the hub supports rounded transition zones or rounded transitions are provided according to the invention. The thereby adjusting radii between the outer contour and the inner contour on the one hand and the pin hub on the other hand are the same, designed differently from each other or run in opposite directions.

A convex, outwardly rounded contour of the ribbing according to the invention preferably extends between the pin bosses in a radius "R" which corresponds to> 50% of a radius "h" of the piston. The associated inner contour of the ribbing advantageously runs in a radius "r" which corresponds to ≥ 20% of the piston radius The ribbing is also designed so that a distance dimension "c" between the axis "xx" and the apex line of the inner contour, which is differs from the radius "r", preferably the dimension "c" exceeds the radius "r". The further design of the ribbing also provides that the radius "R" defining the outer radius differs from the dimension "d" which is established between the axis "x-x" and the apex line of the apex line of the outer contour.

For a friction-welded piston, the ribbing according to the invention can be arranged so that there is a positional coincidence between the ribbing and a joining web connected by friction welding, via which a piston upper part and a piston lower part or a hub base body are supported. Thus, the ribbing at least partially a thickening of the friction welding can be used to an advantageous thickening of Reibschweißbereichs.

To clarify the invention embodiments are explained below. Show it:

1 shows a piston in longitudinal section with a ribbing according to the invention between the pin bosses,

2 shows a comparison with the figure 1 rotated by 90 ° piston in longitudinal section,

3 shows the piston according to Figures 1 and 2 in a view of the piston head,

FIG. 4 shows a half-illustrated piston in a view of the piston crown, wherein the ribbing has a convex outer contour, and

FIG. 5 shows a piston view comparable to FIG. 4, in which the ribbing has a rectilinear outer contour.

The illustrated in Figure 1 piston 1 is designed as a cooling channel piston, which comprises a piston crown 2 as a piston upper part and a piston skirt 3 as piston lower part, said components are supported via joining shafts 4a, 4b. In order to create a structural unit, at least the joining webs 4a, 4b are friction-welded and thus joined together in a material-locking manner, forming on both sides of the joining webs 4a, 4b welding beads 5a, 5b. The piston head 2 has the front side of a combustion chamber 6 and on the outside a land land 7, which is followed by a ring field 8 for receiving piston rings, not shown. Spaced to the ring field 8, a first radially encircling cooling channel 9 and a central cooling channel 10 are integrated in the piston 1, which are acted upon in the operating state together by a coolant. The immediately following to the ring field 4 piston skirt 3 includes two diametrically opposite shaft wall sections 11 and offset it two pin bosses 12 with integrated hub bores 13. The hub bores 13 are intended to receive a piston pin not shown in Figure 1, with the a connecting rod is articulated on the piston 1. Coincidentally, the pin bosses 12 are connected via hub supports 14 directly to a hub body 15, which forms an intermediate plane to the piston head 2. As additional, the component strength of the piston 1 improving measure the pin bosses 12 are connected via two arcuate, the hub body 15 associated ribs 17. These ribs 17 positioned in the piston interior 16 effect an improved introduction of force from the piston head 2 via the joining webs 4a, 4b, the hub body 15, the ribs 17 and the pin bosses 12 into the piston pin and from there into the connecting rod. At the same time, this measure improves the component strength of the piston 1, since the ribs 17 produce an effective connection between the pin bosses 12 which has a positive effect on the structural stresses. The rounded course of the ribbing 17 extends from a central apex line 18 starting, arcuate on both sides to the pin bosses 12. This sets a distance "a" between a pin axis 19 of the hub bore 13 and the ribbing 17 in the region of the apex line 18 a Measure "b" between the pin axis 19 and the transitions of the ribbing 17 in the pin bosses 12 exceeds.

FIG. 2 shows the piston 1 according to FIG. 1 in a sectional view rotated by 90 °, in which the two ribs 17 arranged opposite one another are shown. The ribs 17 assigned directly to the hub base body 15 have a flattened, approximately half-round shaped cross-sectional profile, whereby rounded transitions to the hub base body 15 are established. In this case, there is a far-reaching positional coincidence between the ribs 17 and the connecting webs 4a, 4b formed by annular walls of the piston crown 2 and the hub body 15. This forms a local stiffening of the piston 1 in a zone between the pin bosses 12. All further details and components of the piston 1 correspond to the piston 1 illustrated in FIG. 1 and explained above. In Figure 3, the piston 1 is shown in a view of the piston interior 16. This illustration illustrates the extension of the ribs 17 on the hub body 15 in another view. Thereafter, the ribs 17 on a radially outwardly directed convex curvature. Each rib 17 extends limited from the apex line 18, starting in the direction of the pin bosses 12. Correspondingly, the radii "r, R" for an inner contour 20 and an outer contour 21 of the ribs 17 are assigned to different centers on an axis "yy". The position of the ribs 17 is defined by distance dimensions "c" and "d", which adjust from the axis "xx" to the apex line 18 of the inner contour 20 and the outer contour 21 and which correspond to a partial dimension of the piston radius "s". The radius "r" determining the inner contour (20) of the ribbing (17) corresponds to> 20% and the radius "R" determining the outer contour (21) corresponds to ≥ 50% of the piston radius (s). The design also provides that both the distance dimension "c" from the radius "r" and the distance dimension "d" from the radius "R" is different. Furthermore, the ribbing 17 forms rounded, the course of the curved outer contour 21 oppositely curved transition zones 22, which allow an optimal connection and thus ideal transition of the ribbing 17 to the pin bosses 12.

FIGS. 4 and 5 show ribs designed as an alternative to FIG. 3. According to FIG. 4, the ribbing 23 includes a concave outer contour 24 which is associated with an inner contour 20 which is comparable to the other exemplary embodiments. As a result, a stronger constriction of the ribbing in the region of the apex line 18 sets. A further variant designed according to the invention is shown in FIG. 5, according to which the ribbing 25 has a rectilinear outer contour 26 in conjunction with an inner contour 20 according to FIG. 1. LIST OF REFERENCE NUMBERS

piston

piston crown

Piston shaft a Joint b Joint bridge a Weld bead b Weld bead

Combustion bowl

top land

ring box

Cooling channel 0 Cooling channel 1 Shaft wall section 2 Pin hub 3 Hub bore 4 Hub support 5 Hub body 6 Piston interior 7 Ribbing 8 Crest line 9 Pin axis 0 Inner contour 1 Outer contour 2 Transition zone 3 Ribbing 4 Outer contour 5 Ribbing 6 Outer contour

Distance between the pin axis (19) and the crest line (18) the ribbing (17), according to Figure 1; b Distance between the pin axis (19) and the connection

Ribbing (17) on the pin boss (12), according to Figure 1; c distance between the axis "x-x" and the crest line (18) of

Inner contour (20) of the ribbing (17), according to Figure 3; d distance between the axis "x-x" and the crest line (18) of

Outer contour (21) of the ribbing (17), according to Figure 3; r radius of the inner contour (20) of the ribbing (17), according to Figure 3;

R radius of the outer contour (21) of the ribbing (17), according to Figure 3;

S radius of the piston (1), according to Figure 3

Claims

1.

Piston of an internal combustion engine with a ring field (8) having a piston head (2) to which a piston interior (16) enclosing piston skirt (3) with two supporting shaft wall sections (11) and two pin bosses (12) connects, each pin boss (12 ) comprises a hub bore (13) and is connected via a hub support (14) to a hub body (15) which includes at least one ribbing (17, 23, 25) for reinforcement, characterized in that the hub body (15) extends as far as possible in the direction the hub bores (13) aligned, the pin bosses (12) consistently connecting ribs (17, 23, 25) facing away from a pin axis (19) curved or arched designed and thereby take into account a pivoting range of a connecting rod.

Second

Piston of an internal combustion engine according to claim 1, characterized in that the position of the ribbing (17, 23, 25) coincides with joining webs (4a, 4b), via which an annular wall of the piston head (2) on the hub body (15) is supported ,

Third

Piston of an internal combustion engine according to claim 1, characterized in that the ribbing (17, 23, 25) starting from a pin axis (19) has an arcuate outward course.

4th

Piston of an internal combustion engine according to claim 1, characterized in that the ribs (17, 23, 25) of a apex line (18) starting in each case in the direction of the pin boss (12) increase or expand.

5th

Piston of an internal combustion engine according to claim 1, characterized in that the ribs (17, 23, 25) between the pin bosses (12) define an approximately oval-shaped recess or zone for the connecting rod eye on the hub body (15).

6th

Piston of an internal combustion engine according to claim 1, characterized in that an outer contour (21, 24) of the ribbing (17, 23) is convex or concave.

7th

Piston of an internal combustion engine according to claim 1, characterized in that the outer contours (26) of the spaced-apart ribs (25) are aligned straight and approximately parallel to each other.

8th.

Piston of an internal combustion engine according to claim 1, characterized in that the stiffening rib (17) has a largely semicircular cross-sectional profile.

9th

Piston of an internal combustion engine according to claim 1, characterized in that the outer contour (21) of the ribbing (17) to form rounded

Transition transition zones (22) in the hub support (14) or the pin bosses (12).

10th

Piston of an internal combustion engine according to claim 1, characterized in that the inner contour (20) of the ribbing (17, 23, 25) rounded into the pin boss (12) or the hub support (14) passes.

11th

Piston of an internal combustion engine according to claim 1, characterized in that an inner contour (20) of the ribbing (17) in a radius "r" of> 20% of a piston radius (s) and an outer contour (21) of the ribbing (17) in a radius "R" of> 50% of the piston radius (s) runs.

12th

Piston of an internal combustion engine according to claim 11, characterized in that the position of the inner contour (20) of a distance "c" between an axis "xx" and a crest line (18) of the inner contour (20) is determined, the radius "r" surpasses.

13th

Piston of an internal combustion engine according to claim 11, characterized in that the position of the outer contour (21) of a distance dimension "d" between an axis "xx" and a crest line (18) of the outer contour (21) is determined, wherein the radius "R" exceeds the measure "d".

14th

Piston of an internal combustion engine according to claim 1, characterized in that at least partially a positional match between the ribbing (17, 23, 25) and the joining webs (4a, 4b), which are connected by means of a friction welding.

15th

Piston of an internal combustion engine according to claim 14, characterized in that the Vemppung (17, 23, 25) at least partially leads to a thickening of the friction welding.