DE292374C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The invention relates to an explosion engine with an arm-shaped Piston rotating continuously and without changing direction. At the ring-shaped A number of explosion chambers are connected to the room, the mixture filling of which leads to an explosion is brought when the rotating piston has exposed the channel leading to the annular working space of each chamber.

ίο A ⁷ On known machines with multiple explosion chambers is different, the subject invention in that the mixture fills generate in the chambers is not an additional, but the overall performance of the explosion engine.

In addition, in the subject of the invention, the residues of the burned Gases are completely removed from the chambers before each new filling. Own the chambers during the work a constant volume, and the mixture filling is under constant pressure as the piston continues to move until ignition occurs.

The subject of the invention is shown in an exemplary embodiment in the drawing. It shows:

Fig. Ι a longitudinal section according to AB of Fig. 2,

FIG. 2 shows a section according to CD of FIG. 1, FIG. 3 shows a section according to EF of FIG. 1,

FIG. 4 shows a section according to G-Ji of FIG. 1.

5 and 7 show a view of the piston,

Fig. 6 shows an axial section of the piston and drive plate, and

Fig. 8 is a longitudinal section of the piston with a view of the nose.

The stationary housing 2 containing the annular working space (piston path) consists of two halves that meet in the middle and are connected by screws 3 connected and by sealing rings embedded in the housing halves on both sides 4 are secured in their position to each other. The main shaft 5 of the engine is in the middle of the housing 2 axially to the piston path stored and carries a protruding into the recess 7 between the housing halves Disk 6. The recess 7 is connected to the working space through an annular slot 8. In this A dovetail-shaped projection 9 of the piston 10 protrudes through the slot and engages

into a corresponding section of the disk 6 (FIG. 2), so that the disk 6 and the shaft 5 are carried along as the piston 10 rotates. The part of the slot 8 left free by the piston attachment 9 is filled by a ring 11 engaging with the disk 6 by tongue and groove 12 so that the explosive mixture or the burnt gases cannot penetrate into the recess 7. The shoulder of the piston 10 engaging in the disk 6 is designed so that the centrifugal forces occurring on the piston cannot be transmitted to the shaft and any irregularities in the shaft movement cannot be transmitted to the piston and the sealing rings.

The annular working space is through rotary valve 13, which it with exhaust ports 14 connect, divided. The movement of the slide from one end position to the other wherein the exhaust port 14 is opened, takes place through a piston attached and this leading nose 15. The slide will close as soon as the piston is connected moved them past, due to the pressure of the gases behind the piston has the effect that the half of the slide acting on the half of the slide opposite the exhaust opening Pressure predominates and therefore the scbieber rotates automatically and the exhaust port is released.

Close to the outer wall of the annular working space in close succession Explosion chambers 16, one after the other while displacing the burnt gases are filled with fresh gas-air mixture, which accordingly the movement of the piston is caused to ignite.

The filling of the explosion chambers with pressurized gas-air mixture takes place from the space 17 when the channel 10 ″ of the piston coincides with the lower opening 16 ^{a of} the explosion chambers 16 and the channel 17 ″ of the housing, through these channels. An encircling the shaft and the piston bell 18 located in the interior of the stationary housing 2, verschen with an opening i8 ^a connecting channel 17 ⁰ with the space 17 when the channel 17 ^s ίο with the piston passage "coincide. By The pressurized gas-air mixture now penetrates these channels into the lower part of the explosion chamber just opposite the piston opening and fills it, whereby the gases still in the chamber from the previous explosion through the upper opening 16 ^& through a lateral slot 19 (Fig 2 and 6) of the piston in front of this and out of the next exhaust opening.When the piston continues to move, the upper opening i6 ⁶ is now closed, while the lower opening i6 ™ is still connected to the space 17, so that a complete Filling of the explosion chamber can take place immediately before the piston with its further rotation the two the explosion chamber with the ring-shaped A. Working space connecting chamber openings 16 "and i & have completely free and the transition to the next following chambers tightly closed, as illustrated in Fig. 4, the gas-air mixture is ignited in the first chamber next to the rotary valve by means of a candle 20. As the piston 10 continues to rotate, the mixtures are then ignited in the following chambers. Λ

The compressed air required to produce the compression is supplied by several adjacent the motor housing paired double-acting pumps 22 generated by a crank 23 of the shaft 5 driven in pairs by means of links 24 and slide bearings 30 will. The compressed air is collected in the crankcase 25 (Fig. 1 and 3) and from here through a carburetor screen 26 (Fig. 1 and 4), which is connected to the through line 32 (Fig. 1) supplied fuel is sprayed, pressed into the gas space.

The approximately too much generated compressed air is through a check valve 27 (Fig. 1) in a container 28 is conveyed, from where they can be started through lines 29 which can be shut off of the engine can be guided into the piston path. The whole thing is from a coat 31 surrounded, in which cooling water circulates.

Claims (3)

Patent claims: 1. Explosive engine with rotating piston in an annular space, characterized in that the annular space (1) explosion chambers (16) are connected, the mixture fillings are successively exploded when the piston leads to the annular space channel (16 "and ΐ6 ^δ ) exposed each chamber. 2. Explosive engine with rotating piston in an annular space according to claim 1, characterized in that the entry of the gas-air mixture into the explosion chambers (16) through an opening arranged in the piston (io ^a ) and the outflow of the displaced by the entering air mixture from the explosion chambers Exhaust gases takes place through the slot (19) of the piston. 3. Explosive engine after claim i, characterized in that the slide (13) of semicircular cross-section by the pressure prevailing in the annular space from the piston path releasing position are automatically rotated so that the exhaust port is opened and the piston path completed is, while by one attached to the piston (10) and rushing ahead of it The nose (15) of the slide (13) is rotated so that the piston path is released and the exhaust duct is closed. 1 sheet of drawings.