DE2113726A1 - Rotary piston machine - Google Patents

Description

Rotary piston machine.

The inventor named: Ing.Herbert Buhl, Wittlich.

The invention relates to a particularly simple principle for Rotary piston machines.

This is seen as a characteristic of a rotary piston machine Presence of one or more rotating pistons, through whose or whose movement the periodically changing workspaces are formed.

The invention consists in that a rectangular flat = piston, which is pivotably mounted on a crank pin, with the help of a control in Executes swiveling movements depending on the rotational movement of the shaft. The panning of the flat piston can be with a gear - transmission with control rod or a lead pin attached to the flat butt, which is tied in a curved path or lit any other control.

Qann understands a pivoting movement of the flat piston here as a Vibration of the flat piston, i.e. a back and forth movement from a maximum angular deflection to the opposite maximum angular deflection and to kick.

Depending on the number of oscillations of the flat piston per revolution The shaft creates certain limiting curves that are created by the two outer corners of the flat piston are described. With an integer number of oscillations The same limiting curve is always described for each revolution of the shaft.

After this resulting limiting curve, a cylindrical one becomes Liantel made, which is closed by side locks. Concentric The shaft is mounted in these side locks so that the rotating and controlled flat piston the working space changes periodically and through the Position of the flat piston during the work cycle creates a torque.

In the three figures there are three limiting curves for the cylindrical iiantel of the machine shown.

Figure 1 shows a limiting curve that occurs when there are two oscillations of the flat piston results in one revolution of the shaft.

Figure 2 shows a limiting curve for three pig breeds, and Figure 3 shows a limiting curve for four oscillations per revolution of the shaft.

The limiting curves can also be set for any Construct the number of vibrations per revolution of the shaft.

The shape of the limiting curve is primarily determined by the length of the flat piston and the maximum angular deflection of the oscillation.

The length of the flask, or more precisely, the distance between the two Lines of contact where the flat piston encounters the cylindrical limiting jacket is subject to certain laws. If the piston is in the Central position, i.e.

able to make the piston with the crank arm at an angle of 90 degrees, then in Figure 1 the angle legs close the shaft center - one line of contact and shaft center = point - other line of contact an angle of 90 degrees. In Figure 2 the angle is always 60 degrees, in Figure 3 the angle is 45 degrees. In general, the following applies to the determination of the angle in degrees: 360 divided by twice the number of oscillations per revolution.

For the construction of four-stroke rotary piston Brennkratt = machines only those limiting curves can be used for which an even number of oscillations per revolution, i.e. 2, 4, 6, 8 etc.

There are seals in the four side surfaces of the flat piston let in. The gas exchange is carried out through simple openings in the running surface Self-controlled flat piston. The resulting enlargement and reduction of the work area is used for suction, compression, work and pushing out of the burnt gases, These four-stroke rotary piston internal combustion engines do not need any valves. Due to the lack of narrowing gas cross-sections and of reciprocating masses are therefore much higher speeds compared to the Reciprocating engine possible.

In Figures 1 and 3, the four-stroke rotary = piston internal combustion engines come into question are shown: The shaft 1, the crank arm 2, the crank pin 3, the flat piston +, the intake port 5, the exhaust port 6 and the spark plug 7th

In Figure 1, you get one work cycle for a flat piston ae revolution, in Figure 3 you get two work cycles per revolution.

In the construction of prime movers, such as B. with a "steam = motor", Or, conversely, when building compressors, all limitation curves can of course be used to be used.

In Figure 2, which can be used as a prime mover, the following are shown: The cell 1, the crank arm 2, the crank = pin 3, the flat piston 4, the inlet port 5 and the outlet opening 6.

Of course, the constructions are not limited to a flat piston, Instead, you will install as many flasks as possible in order to run smoothly to achieve with many work cycles.

Claims (5)

P A T E N T A N S P R Ü C H E l.) Rotary piston machine characterized in that one or several rectangular flat pistons, which are swiveling = bar mounted on a crank arm each are vibrations, with the help of a controller depending on the rotary movement of the shaft Execute, and thereby in a cylindrical boundary jacket, which by side locks is completed, periodically changing workspaces are created. 2. Rotary piston machine according to claim 1, characterized in = denotes that the flat piston or pistons have an integer number of vibrations per revolution the shaft. 3. Rotary piston machine according to Claim 1 and 2, characterized in that that inlet and outlet openings are present at appropriate points and with what the gas exchange is controlled by the piston itself. 4. Rotary piston machine according to claim 1 to 3, characterized in that that sealing strips are embedded on the edges and surfaces to be sealed, 5. Rotary piston machine according to Claims 1 to 4, characterized in that in the central position of the flask, d. H. in the position of the flat bottom flask with the Crank = arm forms a right angle, the straight line passing through the center of the shaft and one point of contact of the flat bulb with the boundary jacket each go, the following Must form angles in degrees: 360 divided by twice the number of oscillations per revolution.