DE321094C - Explosive engine with rotating pistons - Google Patents

Description

Explosive engine with rotating pistons. Subject of the invention is an explosion engine with rotating pistons, in which abutment slide step into the path of the pistons and thus form the explosion chambers. Engines of this Art are already known in several versions. That differs from them Invention both through the innovation of the abutment slide, as well as through a device to shut down the inlet valve.

The subject matter of the invention is shown in the drawings.

The motor consists of a rotating disk a, on the edge of which the four pistons b1, b, b3 and b4 are fixed at equal intervals. The pistons move in an annular space which is surrounded by a water-cooled cylinder c. The cylinder is provided with a slot d to accommodate the edge of the disk (see FIGS. 2 and 3.) The annular space in the cylinder c is divided into three equal sections by abutment slide e, which form the explosion spaces An inlet pipe f, which contains the valve x , and an exhaust pipe g open into each of these sections in the vicinity of the opposite piston open into bores f '. The walls of the slot d contain cutouts k- at regular intervals (see FIGS. 2 and 3) which are at the same height as the bores f' d he disc a stand. Parts L ', to which the tubes 1 connect, extend into these cutouts. These tubes are connected to the cylinders -in (see FIG. 2).

Figs. 2 to 5 illustrate individual parts of the engine, Fig. 2 represents a section in the direction of the line A-B of Fig. I. In Fig. 2 are the channel e 'and the holes f' shown in section. The slider e is from one Surrounding jacket p, on both sides of which the cylinder m are located. In these Cylinders with holes q in the upper part move pistons ya (see Fig. i), which are connected to the slides e by a linkage o, and which are pressed down by the springs F. Missing on the cooled cylinder c ' the cooling jacket between the exhaust pipe g and the slides e, since these parts are not come into contact with the hot gases. The walls of the cylinder c are elongated with Cutouts g 'provided through which the excess, used gases into Free kick. In addition, the pistons sweeping past become at the cutouts g1 cooled by the outside air. The cooling jacket only begins behind the slides (in Fig. 2 indicated by dotted lines). In the lower part is the slide e with a semicircular Section of the size of the clear width of the annular space in cylinder c provided.

In FIG. 3, the sealing of the walls of the slot d against the disk a is illustrated on an enlarged scale. The seal consists of two rings s1 and sa, which are ground into the walls of the slot and are pressed against the disc by the springs t, which are at regular intervals (see FIG. I). The ring. surrounds the cutouts h of the slit walls (see Fig. d.) Which are connected to the end pieces 1, the tubes l.

Fig. 5 shows the sealing of the slide e against the disk a. It consists of a box r, inside of which there is a metal block r, which is pressed by the springs s against the circumference of the disk a. When withdrawing of the slide e, the box r with the associated parts lies in a recess c, in the cylinder wall (see Fig. i).

The operation of the machine is as follows: The disc a is located turning. The piston b moves away from the slide e and through the inlet pipe f pressurized mixture enters. After behind the piston b, a sufficient amount of fuel-air mixture has accumulated, takes place through the at the point h attached candle takes the ignition, the valve x closes as a result of the inner Explosion pressure, and the piston b is driven over the exhaust pipe g, where the used gases escape. When the piston b, the position of the piston b. has taken, the slide e located in front of the piston is lifted. After your Passing the piston, the slide lowers again, which is followed by the next Section repeats the same game: Find a during one revolution of the disc behind each piston there were three, a total of 12 explosions.

The movement of the slide e happens as follows: In the channels e, and f, there is always the same pressure as in the cylinder space behind the piston b. If one of the channels f now meets an extension piece 1 of the tubes l, and this happens when the explosion takes place in a room, for example in front of the piston b, the high pressure that prevails in channel e is built up, through the tube l into the cylinder, continues, acts on the piston fn and loves the slide e until the piston ra has passed the holes q , where the gases escape into the open. When the piston za has exceeded these holes, the slide, due to its rigid connection by linkage o, with the piston st also has the passage for the piston b. completely exposed (see Fig. a). The piston located in front of the slide can now b. move under the retracted slider. The purpose of the semicircular bevel of the lower edge of the slide is. to fill the gap in the cylinder wall surrounding the annular work area, which is created by the rising slide, as otherwise the piston rings could get stuck in these gaps. In addition, the slides are set at an angle to prevent the piston rings from suddenly hitting the slot. If the mixture supply is shut off and, as a result, no more explosion takes place, a locking member automatically enters the path of the slide e when the valve closes, preventing the slide from sliding back into its final position.

The valve x closes and opens, depending on the inner or external pressure is greater. But now the valve would open after they were used up Gases have escaped through the exhaust pipe and the slide e has lifted, causing the fresh mixture would reach one of the pistons b and would thus fizzle out uselessly. To prevent this, a spring b ,. attached, which is so burdened, that valve x cannot be opened by the pressurized mixture. Only when the slide has lowered again and the piston has crossed the inlet pipe valve x can open. For this purpose the valve a; (see Fig. i) connected to a rod z that goes through the pipe wall and at the free end one Plate ai bears. Under this plate is the spring b ″ which is the valve cone pushes up. At the upper end of the slide e there is a one-armed rod on the rod o Hebei d, rotatably mounted, which is pressed down by the spring e, '. so is the spring e, weaker than the pressure of the ignited gases, but stronger than the spring b "which in turn is stronger than the pressure of the fresh mixture.

When the slide e is in the final position, the one-armed lever d rests on the disk a, and: when the spring b is compressed, the valve x opens. If the mixture ignites, the spring also gives way, the lever d is pushed up and the valve x closes. After the gases have escaped through the exhaust pipe, the slide e also loves each other, and thus also the one-armed lever dl, so that the valve x remains closed.

Claims (1)

PATENT CLAIMS; i. Explosive juice machine finite orbiting piston and several abutment sliders which step into the path of the pistons, characterized in that, that the slide (e) through the rod (o) rigidly with the piston (n) of the cylinder (m) connected by the pressure of the exploded Gases that act on the pistons (yz), lift them .. a. Explosive engine according to Claim 1, characterized in that the closing of the valve (x) by the Explosion pressure takes place, the opening, however, by a lever on the slide (e) is fixed and that the valve can only open when the slide is open is in the final position.