DE479387C - Rotary piston internal combustion engine - Google Patents

Description

Rotary piston internal combustion engine The invention relates to a Internal combustion engine with a rotary piston and rotating compression cylinders. Of the Rotary piston is provided in a known manner with an eccentric piston projection; the ring-shaped working space is closed off by spring-loaded abutments.

Rotary piston machines have already become known in which the Mixture sucked in by pumps arranged in the rotor, compressed and fed into the annular space is pressed, but in which the air supply for the combustion mixture in the relatively high compression was insufficient. The invention therefore provides one Runner in front, which has rotating, eccentrically driven pistons, which is also in circumferential, reciprocating cylinders. The purpose of this arrangement is that the cylinders themselves also act as pistons in their housing, whereby on the one hand the first-mentioned pistons compress the gas, while the cylinders compress the Compress air, or vice versa. Both compressed gases are in a compression room out, which is connected by a control with the annular space of the rotor. The mixture receives its corresponding composition in this separate mixing space.

The invention is illustrated by way of example in the accompanying drawings.

Fig. I is a cross section through the machine.

Fig. 2 is a longitudinal section and Fig. 3 shows the control of the mixing room.

In a heat-insulated housing i is a rotor 2 with a piston projection 3 on a hollow shaft q. arranged and runs in the direction of the arrow. A spring-loaded abutment, which consists of the two levers 6 and 7 mounted on a bolt 5, grinds on the rotor 2. On the housing i, the exhaust 8 is arranged next to the abutment. Cylindrical bores io are screwed into the rotor, in which the cylinder ii can move back and forth. In the cylinders there are pistons i2, which with connecting rods i_3 on an eccentric ring i q. are attached. The eccentric ring 14 sits on the eccentric 26. Mixing spaces 16 for air and gas are arranged between the compressors and can be controlled in a controllable manner by slide or control devices 17 to close off the annular space 18. The rotary slide 17 have a lever i9 (Fig. 3) which runs with a rod 2o, on which a roller 2 i sits, over a cam 22, the rod 2o being spring-loaded in the direction of the arrow. The neck 22 is also seated on the hollow shaft 4, on the outside of the housing.

The cylinder space io is through a channel 23 with the interior of the hollow shaft q. connected so that the gas supplied to the hollow shaft through this channel into the Cylinder space io can flow in. Through the channel 24 and the opening 25 in the cylinder wall i i can bring air into the space between Cylinder i i and the piston 12 enter. These two compression spaces are in the same way with channels in connection that lead to the compression space 16. There are 2 in runner Spark plugs 27 are arranged, which are connected via the spaces 16 with the explosion spaces 28 stand. A spark plug 32a serves as a starting aid and can if necessary be used as a substitute.

The mode of operation of the machine is as follows: After the rotor has started is, the ignition by a spark plug 27 in one of the explosion chambers 28 is initiated, the piston projection 3 comes in the drawing on the left in front of the abutment 6 to lie. The pistons following the piston projection 3 in the direction of rotation 12 and cylinder, i i have then reached their end position in which, like -bei the top cylinder in Fig. i, no more space for compression gases is available. These are therefore all under the maximum pressure in the mixing space 16 compressed, and the controller 19-22 comes into operation, i. -H. the one on the Wave q. seated cam 22 has arrived in the position shown in Fig. 3, and the suspension 32 of the rod 2o acts in the direction of the arrow, so that the rod with the roller 2i along the shoulder of the cam 22 on the shaft q. slides down and thus the lever i9 pivots so far that the rotary valve 17 opens the opening to the Explosion space 28 releases. There is now again ignition by a spark plug 27, and the gas pressure expands as the piston projection 3. In is pushed forward the other three compression devices work in the same way during the cycle, and there are four explosive shocks on the piston during one revolution, so that an even rotation of the rotary piston is ensured.

In the horizontal position on the left, the cylinder i i is still in its End position, while the piston 12 is almost halfway through the eccentric 26 is shifted and thus through the channel opening 24 and the slot z5 air into the Has sucked in room 29. The cylinder i i has already reached the vertical position below covered about half of its way and thus has the slot 25 by sweeping over it of channel 2q. closed: the piston 12 has indeed receded according to the eccentric shape; but since the cylinder i i has covered a greater distance, has sucked in gas air compression has already taken place in room 29 in room i o. Up to the horizontal Position in the figure on the right, the cylinder i i now also compresses the gas in space i ö, until finally both parts are back in the vertical position above have arrived. Before that, a channel similar to channels 2 [, 25] became the mixture space 16 opened, in which the compressed gases are then pushed over in the strongest compression will. Shortly after this vertical position, the rotary valve is opened 17 the ignition in the explosion chamber 28.

-The cylinders i i are in. Different movement opposite the piston i2 is moved by the second eccentric 15 or by any other corresponding means Furnishings. The eccentrics 15 and 26 are arranged in a stationary manner. But they are adjustable so that the positions can be shifted by a few degrees. The compression is then lower and the explosive force is therefore lower. You can also access this Way to regulate the number of revolutions. The eccentrics are adjusted by worms 3o and 31, which can also be connected to corresponding control devices, which in turn depend on the number of revolutions or a centrifugal regulator. Separate Cylinders can be turned off to reduce efficiency, or it individual cylinders can compress air and the others gas.

The controllability of the mixing by the piston and by the cylinder allows yourself; can change the space ratio between gas and air. That can be driven so far that one compression space is equal to zero, i.e. H. either only gas or only air is drawn in. The control is accordingly regulated so that one or the other compression space either only air or only gas is supplied.

The individual parts are cooled by water, which is cooled by a special Systexn. Can be circulated within the rotor.

Claims (1)

PATENT CLAIMS: i. Internal combustion engine with rotary piston and rotating compression piston, characterized in da.ß in the rotor (2) the rotating compression piston (12) in piston cylinders (ii), both of which compress air and gas separately or together, and one of which each. Piston (12) draws in air and the other piston (i i) draws in gas, the space ratio of which is adjustable and variable. 5. Machine according to claim i and 2, characterized in that the two compression pistons (11, 12) are driven relative to one another by fixed but adjustable eccentrics (15; 26) or the like. 3. Machine according to claim i and 2, characterized in that the position of the pistons (II, 12) to one another and thus the mixing ratio of gas and air can be regulated by the eccentric position. q .. Machine according to claim i, characterized in that the gas and air supply is so controllably arranged that alternately only air is supplied to one piston set (11, 12) and only gas to the other (II, 12). 5. Machine according to .Anspruch i and 2, characterized in that the gas mixture is pressed into a controlled mixing space (1 6) which is to be connected by a control (17) with the explosion space (28) and the annular space (18).