DE323012C - Three-stroke explosion engine - Google Patents

Description

Three-stroke explosion engine. There are already four-stroke engines with rotary pistons known in which at the fourth Umdrehuirg of the piston in a part of the housing the exhaust takes place, while in the other part new fuel-air mixture sucked in - is. Such a machine only apparently works in three cycles.

In contrast, the subject matter of the invention is a three-stroke explosion engine with rotatable piston, with which the exhaust is the suction at the same time take place so that every third cycle forms a working stroke.

Operation of the engine subject of the invention is the following: the intake and exhaust occur during the first rotation of the piston, followed by the compression of the sucked in during the second rotation Fuel-air mixture and at the same time sucking in the outside air for the purpose of cooling and finally, on the third turn, the expansion and working of the inflamed ones Gases and at the same time the expulsion of the cooling air.

In the drawing is an example embodiment of the subject of the invention forming engine shown schematically.

The piston, which has an oval cross-section, rotates in the housing c b, which is mounted on the main shaft a so that it rotates with the same.

The housing c is provided with the usual exhaust valve k and the suction valve 1, furthermore with an ignition device g and with two rotatable vanes e and f which occupy the entire width of the housing and which can lay cavities provided in the cylinder wall so that they can Do not prevent piston b from rotating. The length of these wings is chosen so that they extend in every position of the piston up to its surface, this length being only slightly greater than the greatest distance between the inner wall of the housing and the wall of the piston for the purpose of falling back To prevent wings.

The piston b brushes with its appropriately blunt tip inner wall of the case, and its oval shape serves to make the wings e and f can slide on the piston surface without obstruction.

Furthermore, the wings are on the piston for the purpose of unhindered sliding the ends of the wings are suitably rounded and there are the lower surfaces of the same ground in an arc of a circle similar to the inner surface of the housing.

The way the motor works is as follows: A complete working cycle occurs during three revolutions of the piston. During the first rotation (starting from the piston position drawn with a full line in the drawing), the piston pushes the expanded gases in the cylinder with its front surface in the direction of the arrow in front of it, and pushes them out of the housing through the exhaust valve k and at the same time with its rear surface sucks fresh mixture through the valve 1 into the continuously increasing space of the cylinder between wing f and piston b. The wing f is constantly pressed against the piston during this entire revolution by an externally controlled resilient or similar device r (closed position of the wing f 1). At the same time, the wing e is held by a similarly acting device p in the open, i.e. in the cavity of the housing wall, until the piston, beginning the second rotation, has passed it, whereupon the wing e by the device p against the The piston is pressed and held in this position (position e2). As the piston continues to rotate, negative pressure is created behind the latter, in the space enclosed by the vanes e and f, which occupy the positions e2 and f 1. has exceeded, suck in air behind you or in the space between the wing e and the piston. At the same time, the piston will compress the fuel-air mixture in space n and temporarily push the mixture expelled from space n back into space n on wing f, where, due to the closed position of the wing, there is a fine negative pressure and where the ignition device g is located. The outside air directed behind the wing acts as an effective coolant.

These first two rotations are made directly by the one on the shaft a arranged flywheel brought forth. The tip of the piston b is now under the igniter g passed and the wing.? turned to rest position, so the ignition and explosion of the compressed mixture in the space behind causes the piston.

To the mixture compressed by the piston in the space -ii behind To be able to direct the piston, one or more pipes are in the cylinder wall i arranged which with their ends in front of the ignition device g and with their ends j open into the cylinder behind the ignition device.

As a result of this device, when the piston b passes in front of the orifices h of the lines i , the mixture flows through the orifices j into the pipelines i and out of these through openings h back into the channel behind the piston when the piston has the: -Ignition h has exposed again.

As the piston continues to rotate, the wing is lifted e, whereupon the fuel-air mixture is ignited.

The third or working revolution of the piston is caused by this explosion causes the cooling air to be driven out of the housing through the exhaust valve k will.

The device p causing the rotation of the wing e and the detonator g can be controlled by the shaft a in the desired manner.

The wing e is plosion from the moment of the explosion, i.e. during the third revolution (working stroke) and the next following first revolution (exhaust and suction) in the rest position, d. i. it is in the cavity of the housing wall c is held and only closes in it or falls on the surface of the piston, when the piston has just passed him. After lifting the wing f in the rest position, the second (compression) rotation begins, etc.

In the wing f a valve s is conveniently arranged to the excessive compression of the compressed mixture between the piston and the concave surface of this wing or the forcible lifting of the wing f by to prevent the mixture and consequently a crack of the piston.

The mode of operation of the machine is therefore briefly as follows: During the first rotation of the piston, during which the wing e, as shown, is in the rest position, ie in the cavity of the housing wall, the fuel-air mixture is passed through valve l into the between wing f and Piston b is sucked into the enlarging space, while the burned expanded gases are expelled through opening k in front of the piston. Here, the wing e remains in the rest position shown. At the beginning of the second rotation, during which wing e is initially still in the rest position, a negative pressure arises in the space between piston b and wing f. If piston b has now passed wing e , wing e will open Place the piston b and cooling air is sucked in through the connector k1 into the space between piston b and wing e . On the other hand, in the space n in front of the piston b, the mixture is compressed by lifting the vane f and finally pushed out of the space n through the channels j, - i, h into the space formed between the piston b j and the descending vane f, where it is ignited. Now the wing c is brought into the drawn rest position and the ignited gases expand during the third rotation into the space between piston b and the wing f in its working position Nozzle h driven out. In order to increase the power, several engines of this type can be arranged side by side and their pistons mounted side by side on the same shaft. In such an engine, the detonators are set to operate at different times.

Claims (1)

PATENT APPLICATION: Three-stroke explosion engine in which the suction and the exhaust take place at the same "time, with one attached to the main shaft and rotating pistons of oval shape extending across the width of the housing Cross section, characterized by two of the width of the housing formed accordingly and rotatably mounted in the wall of the latter, advantageously from the main shaft controlled blades, furthermore through channels expediently installed in the housing wall, which serve to keep the fuel-air mixture compressed in front of the piston behind to direct the same.