DE274940C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

■ - M 274940 CLASS 46 «. GROUP

PETER from DITMAR in ST. PETERSBURG.

Explosive engine with rotating piston.

Patented in the German Empire on November 7, 1912.

In the usual four-stroke internal combustion engines As is well known, the only way to increase the performance at a given number of revolutions is to either increase the piston area 5 or the piston stroke increased. Both of these measures are with substantial increase related to the weight and dimensions of the engine, what for many purposes such as z. B. for flying machines and the like., Not permitted

ίο is.

The subject of the invention forms an internal combustion engine in which. while one revolution of the motor shaft not one, but two and more ignitions be, and this mode of action is achieved by appropriate Design and guidance of the piston in the cylinder spaces or chambers are formed, in which the known work processes of the four-stroke engines take place alternately. In this engine, the number of ignitions that take place during one revolution for the purpose of increasing or decreasing the performance at a given number of revolutions Can be increased or decreased as desired without affecting the weight or dimensions of the Motor increase significantly.

In the drawing, Fig. 1 schematically illustrates the machine forming the invention; Fig. 2 is a perspective view of the movable part and the stationary Parts of this machine; Fig. 3 shows the wave-shaped end face on the stationary part in plan; Figure 4 illustrates a modified embodiment of the machine.

As can be seen from Fig. 2, the piston body A , which has the shape of a hollow cylinder, is designed in a wave-like manner on its end faces, namely an elevation on the opposite side of the piston opposite a recess on one side of the piston and vice versa. The stationary end faces of the two cylinder ends B and C or the cylinder covers or bottoms, which, in contrast to the piston shafts, are symmetrical at both cylinder ends, also have the same wave-like shape.

There is thus a constant sliding of the piston shafts designated by 12, 13, 14, 15 in FIG. 2 on the shafts 4, 5, 6, 7 and 8, 9, 10, 11 of the fixed cylinder bases. This sliding movement of the individual waves against each other is caused by the explosions, which one after the other in the individual spaces formed between the shaft sides occur. The design of the wave surfaces is of course to be selected in such a way that the required movement can go on smoothly, and that in the most economical way Meaning the most beneficial effect is achieved.

The operation of this machine can be seen from the scheme in Fig. 1, which is a surface involute of the shafts 4, 5, 6, 7 or 8, 9, 10, 11 of the fixed parts and the shafts 12, 13, 14, 15 or Figure 12 ', 13', 14 ', 15' of the movable piston. The bevels. or the side surfaces of the projections and the depressions of the piston and cylinder shafts form chambers I, K, L,

M, N and O, P, Q, R, in which the various work processes of the four-stroke take place. If the piston moves z. B. such that the left side of the shaft 14 '(Fig. 1) of the piston moves along the right side of the stationary shaft 10 in the direction of the arrow 16, then by means of the expansion of the space R by means of corresponding, opening in time and closing valves or ducts, suction of the fuel-air mixture in these spaces R takes place. During the subsequent movement of the right side of the piston shaft 14 'along the left side of the stationary shaft 10 in the direction of the arrow 17, the mixture previously sucked into the same is compressed in the space Q. The explosion then takes place in this space, under the influence of which the left side of the piston shaft 14 'is repelled in the direction of the arrow 18. Finally, during the subsequent movement of the right-hand side of the shaft 14 'along the left-hand side of the stationary cylinder shaft 9, the burnt gases are expelled from the space P.

The processes in the individual forming and disappearing chamber spaces take place on the two piston sides in such an order that, for. B. during suction in a chamber space on one side, the compression or explosion takes place in the corresponding chamber space on the opposite side of the cylinder.
In such an engine, the cylinder volume of a conventional single-cylinder engine may correspond to the product of the height h of the shafts (Fig. 1) and the radial width (Fig. 3) of the end face with the shafts and the number of shafts on the periphery of the cylinder or of the piston, so that, for. B. with four shafts on each end face a total of eight times the working area compared to a conventional single-cylinder engine is achieved. The size of the piston stroke corresponds to the length of the shaft bevel, and the latter is selected accordingly in each individual case.

■ Since the piston describes a wave-shaped path in such a machine, it leads it simultaneously produces a rotating and an axial movement caused by the sliding of the Piston face is conditioned on the cylinder face.

The channels in the cylinder and piston body for the supply of the fuel-air mixture and for the exhaust can be arranged as desired.

Fig. 4 shows on the right side seen from the outside and on the left side partly (above and below) in section a modified embodiment of the engine, in which the working surfaces 20 of the cylinder N ' and 21 of the piston S are flat so that the Operations in the spaces R and R ' between the two piston sides and the cylinder base take place. The corresponding guidance of the piston is optionally achieved by a wave-shaped guide groove F on the cylinder body (or on the cylinder piston), in which z. B. the piston by means of appropriate projections possibly with the use of anti-friction balls or rollers Q slides in such a way that the piston is given several back and forth movements according to the shape of the guide groove by the explosion effect during one revolution of the motor shaft.

Claims (1)

Patent claim: Explosive engine with rotating piston, in which the piston end faces, which slide between appropriately designed stationary cylinder bases, are wave-shaped, and in which the work processes between the individual shaft parts take place, characterized in that the stationary Cylinder bottoms are provided with opposing, wave-shaped depressions and elevations, and the between rotatable piston has mutually offset wave-shaped elevations and depressions on its two end faces, so that between the elevations and depressions always closed, in a known manner with suitable inlet and exhaust pipes communicating spaces are created which vary depending on the position of the rotatable piston form and disappear again, and in which the four-stroke processes take place so that, for example, during the intake in a room on one side, the compression or explosion in the corresponding Space takes place on the opposite side of the cylinder. For this purpose ι sheet of drawings.