DE1292940B - Pistons for internal combustion engines - Google Patents

Description

The invention relates to a piston made of an aluminum alloy for Internal combustion engines, on the face of which a protective plate made of heat-resistant metal is attached by means of steel fasteners, which in the protective plate have countersunk heads and shafts received in bores in the piston end wall.

A known piston made of an aluminum alloy has steel elements for attaching a protective plate made of heat-resistant metal on its face. The fastening elements are formed with countersunk heads Screws, the shafts of which engage in bores in the piston end wall (German patent specification 421004).

Because the protective plate and the piston are made of different materials with mutually different coefficients of thermal expansion, represents the known connection of the protective plate with the piston face by means of screws, which do not have any special protection against rotation, an imperfect solution The screws will loosen over time. Loosening the screws has serious consequences, which are that the protective plate on the Piston front wall loosens. This ensures that the piston works properly questioned in the long run.

The object of the present invention is the known piston to avoid inherent disadvantages and in particular to create an attachment, with which a thin protective plate is as simple as possible and thus securely attached to the Piston end wall can be attached to prevent accidental loosening during the Operation is avoided.

The object of the invention is achieved in that the fastening elements Are pins whose shafts sit with a press fit in the holes in the piston end wall, and that the press pairing to maintain a press fit in the during the Operating temperature range to be expected at room temperature a different Has thermal expansions of aluminum alloy and steel corresponding oversize.

The advantage of the present invention over the prior art is that the attachment of the protective plate to the piston end wall by means of Press pins require considerably less work than fastening by means of screws. In the case of fastening according to the invention by means of compression pins, there is a surprising result Way the further advantage that the press pins have a much greater security offer against unintentional loosening of the protective plate during piston operation than the known screws. Even with significantly different thermal expansions between the protective plate and the piston are seated so tightly that the protective plate is can't loosen up.

In an advantageous further development of the invention, the pins are as grooved pins known per se with grooved ones lying in the bores of the piston end wall or knurled surface sections formed.

The formation of the pins as grooved pins offers the advantage of a best possible locking of the pins in the holes in the piston front wall and thus the safest possible connection between the protective plate and the piston face.

The drawing represents preferred embodiments of the invention It shows FIG. 1 shows a plan view of the piston, FIG. 2 shows a section along the line 2-2 according to FIG. 1, Fig. 3 shows a modified form of a pen, F i G. 4 one along the line 4-4 according to FIG. 3 drawn in an enlarged view Section and F i g. 5 shows a detail of part of the pin according to FIG.

The piston 10 (FIGS. 1 and 2) consists of an aluminum-silicon alloy that expands slowly and has a coefficient of thermal expansion of approximately Has. The piston has in its end wall an "enclosed" annular combustion chamber 11 which is shaped like, for. B. British Patent 715,524 describes. The combustion chamber 11 has an opening 12 which opens towards the piston end face and has a smaller diameter than the outer walls of the annular combustion chamber 11 .

In the present arrangement, the aperture in a thin protective plate 13 is formed of refractory metal, which is fixed by a number of pins 14 which hineinerstrecken through holes in the protective plate 13 into bores 10a in the end wall of the piston 10 on the piston 10 .

The protective plate 13 and the pins 14 are made of a silicon chrome steel with a coefficient of thermal expansion of approximately Stainless steel can also be used for these parts.

The end wall of the piston 10 is provided with a flat recess 10 b which extends radially outward from the circumference of the annular combustion chamber II. The protective plate 13 is let into the shallow recess 10 b.

The holes in the protective plate 13 through which the pins 14 extend are countersunk. The pins 14 are provided with correspondingly shaped heads 14a with which they fit flush into the countersunk holes. This arrangement has the advantage that heavy shear loads on the pins which occur due to different thermal expansion are avoided.

The bores 10 a extend in the longitudinal direction in the end wall of the piston 10 and can be precisely manufactured using conventional and inexpensive machines. The diameter of the bores 10 a is smaller than the diameter of the pins 14, so that the pins are firmly seated in the bores and hold the protective plate 13 firmly in position under all operating conditions. The relative dimensions of the bores 10a and pins 14 are selected taking into account the physical properties, including the coefficients of thermal expansion of the materials used and the temperature fluctuations likely to occur during use, so that the protective plate 13 does not loosen. Of course, the excess used must not be so great that the piston 10 is overstretched. The pins 14 have tapered parts 14b at their ends with a taper of, for example, 15`- ', which not only facilitate entry into the bores 10a, but also produce a polishing effect when the pins are inserted into the bores 10a so to ensure a good fit.

If desired, the parts 14 b can be caulked after the pins 14 have been hammered in, in order to create a second head.

The F i g. 3 to 5 show particular embodiments of pins 14 by means of which an improved locking is achieved. The pins 14 have the already described countersunk heads 14a and the tapered ends 14b. Their middle parts have a shape shown at 14 c (F i g. 3). As in known grooved pins, grooved or knurled surface sections 14 d and 14 f are formed around the shaft between longitudinal elevations 14 e (FIGS. 4 and 5). The angles of the bevel of the surface sections 14f are, for example, 30 ° in order to prevent the piston metal from shearing when the pins 14 are struck.

The pins 1.4 are not only advantageous over screws in production because thread cutting is superfluous, but also allow. Reducing the weight of the piston 10 and thus the inertia of the same, since the heat-resistant protective plate 1.3 can be made much thinner than would be the case if, for. B. the heat-resistant surface would be formed by a screwed insert. The pins 14 are also self-locking, in contrast to countersunk screws, which are difficult to lock in place.

Likewise, by interposing a thin layer of heat insulating material between the protective plate 13 and the piston 10, as already discussed, better combustion efficiency can be achieved if desired.

If the opening 12 is to be offset from the center line of the piston 10 or the annular combustion chamber 11, the pins 14 and the bores 10a are preferably arranged non-uniformly so that the plate 13 always rests correctly on the end wall of the piston during installation and is not incorrectly stored can.

Claims (2)

Claims: 1. Pistons made of an aluminum alloy for internal combustion engines, on its face a protective plate made of heat-resistant metal by means of steel Fastening elements is attached, which heads countersunk in the protective plate and have shafts received in bores in the piston end wall, characterized in that that the fastening elements are pins (14), the shafts of which are press fit into the Bores (10a) sit in the piston end wall, and that the press pairing to maintain a press fit in the temperature range to be expected during operation Room temperature in the different thermal expansions of aluminum alloy and Steel has corresponding oversize. 2. Piston according to claim 1, characterized in that the pins (14) are designed as grooved pins known per se with grooved or knurled surface sections (14d, 14f) lying in the bores (10a).