DE2610130A1 - Rotary piston IC engine - has rotating cylinder block and rotating guide ring eccentric to each other - Google Patents

Abstract

The engine has a circular cylinder block (1) which rotates on an axis (3) and has three radial cylinders (8, 9, 10). Each cylinder contains a reciprocating piston (5, 6, 7) the outer end of which is linked to an outer guide ring (2). The guide ring rotates about an axis (4) which is offset from the axis (3) of the cylinder block. As the cylinder block and guide ring rotate the spaces (41) formed between them and closed by the pistons vary in volume to form the working spaces. There is an inlet valve (23) into each cylinder and a non return valve (26) from each cylinder into the working space (41). Exhaust is through ports (27) in the outer guide ring (2) which are uncovered by a cylindrical sleeve (28).

Description

Internal combustion engine with rotary piston-like rotating pistons

The invention relates to an internal combustion engine with rotary piston-type Rotary piston.

Internal combustion engines with rotary piston-like rotating pistons are available in different Designs known or have been proposed. In such internal combustion engines This often results in a housing that has several sub-chambers inside over the circumference exists that merge into one another. The rotary piston itself has one of design deviating from the circular shape.

Since the rotary piston is generally around on a circular path the housing axis revolves, it is necessary to interpose gear parts, around the rotational energy of the driven rotary piston on a stationary shaft transferred genes to be able to. Such an internal combustion engine with a rotary piston is u in terms of the number of gear parts.

Like. Relatively expensive.

The object of the invention is to provide an internal combustion engine with a rotary piston type To create a rotary piston that is simple in structure and mode of operation. the Internal combustion engine with rotary piston-like rotating pistons is distinguished according to the invention characterized in that the machine has a disc rotatable about a fixed axis, one for Axis of rotation of the disc eccentrically mounted circumferential ring, radial in the disc running cylinders with pistons displaceable therein, articulated connection parts between the outer ends of the pistons and the circumferential ring and inlet channels for the Combustion gas mixture in the disc and outlet channels for the exhaust gases in or on the circumferential Has ring.

Such a structure of the internal combustion engine with rotary piston-like Rotary piston is achieved a machine structure that consists of relatively simple Sharing consists.

The kinematic conditions of the rotary piston internal combustion engine are clear and easy to master.

Intermediate gear parts or gears or the like. are not required. Depending on the size of the machine, there will be several sliding pistons in the rotatable Provide for a mounted disc. It is advantageous to use at least two or three sliding pistons to increase the uniformity of the drive pulse. In principle you get by with a sliding piston. The internal combustion engine according to Invention is very powerful.

Advantageously, the pistons are by means of a joint, e.g.

a cross pin or the like., stored in the circumferential ring. Here can the cross pin or the like. in an arcuate guide of the circumferential ring slide. In this way, a constraint-free displacement of the piston in the associated cylinders during the relative movement between the rotatable disc and the rotating one Ring guaranteed.

One at the connection point between the pistons is sufficient for sealing and ring arranged cover slide, which with the sliding of the hinge or cross pin is moved along in the arched guide.

According to a further feature of the invention are to the closed At the end of the cylinder spaces, the inlet lines for the fuel gas-LuSt mixture are provided. An overflow channel can run from the closed end of the cylinder spaces to the associated one be arranged between the disc and ring forming space so that the through the Pistons compressed gases into the associated combustion chamber between the disk and the ring can be transferred. Here, valves can be in the line and in the channel be arranged, each of the passage for the inflowing gases and the compressed Allow gases. Check valves which can be set to a predetermined pressure level can be used as valves are provided.

But you can also have a direct valve control or

Use slide control where the control is through the sliding Piston or the like. he follows.

According to a further feature of the invention is the circumferential Ring perforated in the radial direction to prevent the exhaust gases from flowing out to enable. Here, the circumferential ring is advantageously supported by a further, the outlet area limiting ring or the like. surround. This can be adjustable to regulate the beginning of the outflow of the exhaust gases to be able to. The outlet area of the latter ring extends over the remainder Rotation range of the piston to which the fuel gases act. To this Way, a complete venting of the forming, to the front of the Gaps between the rotatably mounted disc and the piston circumferential ring guaranteed.

Over the outlet area extends in an annular course Outlet duct from which the exhaust gases are discharged.

The pistons in the rotatable disc can be shaped with a circular Be provided cross-section. The pistons preferably have one more or less flat, e.g. rectangular cross-section. The height of the rectangular cross-section aligns depending on the height of the rotatable disc or the rotating ring.

The invention is based on an embodiment shown in the drawing explained below.

Fig. 1 shows an embodiment of the internal combustion engine with rotary piston-type Rotary piston according to the invention in view and in the scheme.

Fig. 2 to 4 represent different phases of the internal combustion engine Fig. 1 shows a schematic representation of a full revolution of 60 °.

Fig. 5 illustrates a vertical section through the internal combustion engine according to the invention in the scheme.

Fig. 6 and 7 show in detail and in the scheme of the education a slide valve for transferring the compressed gases to the combustion chamber.

The internal combustion engine in the rotation system essentially settles composed of a rotatably mounted disc 1 and a circumferential ring 2, whose Central axes are arranged offset from one another. The disk 1 is around the axis 3 mounted, while the circumferential ring 2 is mounted about the axis 4. These axes 5 and 4 lie on a radial line, so that disk 1 and circumferential ring 2 are aligned touch in one place. In the disc 1 there are slidable pistons, e.g. three Pistons 5, 6 and 7, arranged in corresponding recesses 8, 9 and 10 of the Disc 1 can slide back and forth. Each piston 5, 6, 7 is by means of a joint with the surrounding ring 2 in connection. The piston can be used for this purpose by means of a transverse pin 11, 12, 13 in an arcuate guide 14, 15, 16 of the circumferential ring and slide forward to avoid constraints or

Clamps when moving the piston in the recesses during to avoid dealing. The arched guides can be used to increase the Be tightly closed grooves. The pistons 5,6,7 each engage in corresponding ones Recesses 17, 18, 19 of the circumferential ring 2. To seal the pistons against the recesses 17, 18, 19 cover slides 20, 21, 22 can be provided which go with the piston accordingly and lie in corresponding grooves that are are located on the inner surface of the circumferential ring 2.

For each cylinder space 8, 9, 10 an inlet line 23 is in the rotatable Disc 1 is provided, which via a valve 24 to the closed end of the cylinder 8 leads.

An overflow channel 25 is provided on the opposite side, to which a valve 26 is assigned. These valves are advantageously check valves and are in a suitable manner under spring pressure, the spring strength accordingly is predetermined. For a better overview, the channels are only with the valves drawn in at the piston 5. These are the same for the other pistons arranged in the rotatable disk 1.

The circumferential ring 2 has openings over the entire circumference 27 provided, which extend in the radial direction. These breakthroughs are used to Outflow of the exhaust gases.

The outlet area for the exhaust gases is surrounded by a Ring surrounding further ring 28 is determined. This is on a predetermined part the circumference is also perforated or has a slot 29.

The further ring 28 can pass directly through the housing 28a of the internal combustion engine are formed. An exhaust duct 50 may extend over the peripheral portion of the outlet area 29 of the ring 28 or of the housing 28a extend. The use of a ring 28 has the advantage that it can be adjusted in relation to the circumferential ring, so that the outlet area 29 with respect to the gases flowing out in certain respects can be regulated.

The rotatable disc 1 is provided with an output shaft 31 which is mounted at 32 of the housing 28a. On the opposite side of the rotatable Disc 1, a nozzle 33 is arranged, to which the inlet line 34 for the fuel gas-air mixture leads. In addition, the electrical ignition line 35 for the spark plugs are guided, which the fuel gas-air mixture in the appropriate time cause inflammation. The circumferential ring 2 is by means of the collar 56 in the Housing 28a or the bearing flange 37 mounted.

Figs. 6 and 7 show an embodiment for the control of the Overflow line 25 through a slide 38, which under the action of a spring 59 stands, the slide) 8 being provided with a throughflow opening 40. In the appropriate Moment, i.e. in the position of the highest compression, the slide 38 shifted against the action of the spring 39, so that the opening 40 the way of the compression chamber of the piston 5 to the overflow channel 25 releases. After going back of the piston 5, the slide 8 closes the access to the overflow channel 25 below the action of the spring 39.

Starting with the position of the parts of FIG. 1 it follows that the Piston 5 has reached its compression position. That in the compression space 8a Compressed fuel gas-LuSt mixture is, as soon as the desired pressure is reached, passes through the overflow channel 25 with the valve open into the combustion chamber 41, in which the ignition can be effected. Here the inlet valve 24 is closed and the valve 25 is immediately brought into the closed position after the pressure in the combustion chamber 41 has increased compared to the pressure of the compressed gas. The gases in the combustion chamber 41 now act on the flank 6a of the preceding one Piston 6 and exert an angular momentum on disk 1. With the rotation of the disk 1 there is also a rotation of the circumferential ring 2 via the articulated connection one of the pistons. As the system continues to rotate, the piston is removed from the cylinder space 8 returned leads. The piston 5 has now started the intake stroke.

The resulting negative pressure causes the fuel gas-air mixture to flow through the inlet line 25 sucked. Since with further emergence of the piston 5 from the rotatable disc 1 a constantly growing flank surface 5a is created after a predetermined angular rotation reached a position in which the exhaust gases through the Openings 27 and the outlet area 29 of the further ring 28 in the exhaust duct 30 can flow (Fig. 2). After reaching an angle of rotation of 1800 the piston has 5 reached its highest extended position. From there he moves back to Center of the system, so that the sucked fuel gas-air mixture in the cylinder space 8 is compressed. The valve 24 is closed, with the valve 26 in FIG the overflow channel 25 to the highest compression of the fuel gas-air mixture in the cylinder 8 remains closed. Those in the other rooms 42 and 43 between Residual gases in the piston can be released during the further rotation of the system flow through the outlet area 29 unhindered. As soon as the combustion chamber 41 is in the making is understood, the compressed gas can overflow at the appropriate time, namely as soon as the pressure of the compressed gas is higher than the counter holding force of the valve 26th

The same processes take place with the other pistons 6 and 7, whereby the angular momentum of the ignited fuel gases follow one another. When several units are lined up and act on the same output shaft 51, the result is a continuous drive of the output shaft. The combustion chambers are completely vented and vented in the remaining time of the circulation of the system held.

Claims (9)

Claims 9 racing engine with rotary piston-like rotary pistons, characterized in that the machine is mounted rotatably about a fixed axis (3) Disc (1), one mounted off-center (4) to the axis of rotation (3) of the disc (1) circumferential ring (2), at least one in the disc (1) radially extending cylinder (8,9,10) with piston (5,6,7) sliding in it, articulated connection parts (11,14) between the outer ends of the pistons (5,6,7) and the circumferential ring (2) as well Inlet channels (23) for the fuel gas-air mixture in the disc (1) and outlet channels (27) for the exhaust gases in or on the circumferential ring (2). 2. Internal combustion engine according to claim 1, characterized in that the pistons (5,6,7) by means of a joint, e.g. transverse pin (11,12,15) or the like, in the circumferential ring (2) are mounted and the transverse pin (11, 12, 15) in one arcuate guide (14,15,16) of the circumferential ring (2) is slidable. 3. Internal combustion engine according to claim 1 or 2, characterized in that that at the junction between the piston and the circumferential ring a the piston associated cover slide (20,21,22) is provided. 4 internal combustion engine according to one of claims 1 to 3, characterized in that that to the closed end of the cylinder spaces (8,9,10) the inlet line (23) for the fuel gas / fuel mixture and from this cylinder chamber end to the combustion chamber (41) between the disk (1) and the ring (2) is an overflow channel (c) are provided for the compressed gases, and da3 in the inlet line (2D) and the overflow channel (2g entile (24, 26) are arranged. 5. Internal combustion engine according to one of claims 1 to 4, characterized in that that the valves are check valves which can be adjusted to a predetermined pressure level. 6. Internal combustion engine according to one of claims 1 to 4, characterized in that that the valves of the piston are controllable slide valves (58). 7. Internal combustion engine according to one of claims 1 to 6, characterized in that that the circumferential ring (2) is provided with openings (27) in the radial direction and of a further ring or the like that delimits the outlet area (29). (28) surrounded is. . Internal combustion engine according to one of Claims 1 to 7, characterized in that daA the further ring (2ç) is part of the housing (20a) of the machine. 9. Internal combustion engine according to one of claims 1 to 5, characterized in that da3 the pistons (, õ, 7) have a flat, e.g. rectangular, cross-section.