DE1179762B - Multi-cylinder piston machine - Google Patents

Description

Multi-cylinder piston engine The invention is directed to a multi-cylinder piston machine, their reciprocating piston movement as a result is converted into a rotary motion that moved together with the piston rods reciprocating rollers in one arranged on the outer circumference of a rotating body Engage curve and that the rollers in reciprocating with the piston rods and mounted sliding blocks guided parallel to the axis of rotation of the rotating body are, with two sliding blocks arranged symmetrically to the center plane of the machine are.

Such a piston machine can either be used as a prime mover, e.g. B. as an internal combustion engine, or as a work machine, e.g. B. as a compressor, Find use.

The principle, a reciprocating piston movement via cam guides to convert it into a rotary motion is already known.

In such a case, all roles are on the same level and the considerable forces acting perpendicular to the rollers tend to the body of revolution having the curve guide in the opposite sense twist. The problem of an absolutely necessary force balance is thereby paid no attention. ..

Another previously known arrangement also has this deficiency which also subjected the roller guided in the curve to considerable shear is.

Also another internal combustion engine with several through a central one Gear meshing rigidly connected and working together on a shaft Rotation bodies neglects the problem of force balance, and the roles work completely separately from each other.

Finally, there is an internal combustion engine with a thrust cam gear to the state of the art, in which the rollers engaging in the curves - the piston in reciprocating with these, arranged symmetrically to the center plane of the machine Sliding blocks are stored.

A multi-cylinder piston machine with a cam groove transmission is also known with a rotary body which can be pushed axially against spring pressure and has a cam guide, wherein a stop limiting the axial movement is present.

However, the application of this known principle in practice requires a balance of the effective forces, and at the same time the requirement arises an arrangement that is as space-saving as possible. With the solution to this problem deals The invention. For this purpose it provides that with a multi-cylinder. Piston engine of the type indicated, in a known four-cylinder piston engine Way symmetrically to the center plane of the machine at least two over a toothing intermeshing bodies of revolution are present and that the two. Sliding blocks symmetrical to a plane imagined by the axis of rotation of both bodies of revolution, are arranged.

This arrangement results in a practically perfect balance of forces brought about, which ensures an extremely quiet run of the machine. On the other hand, with this arrangement there are a number of devices in the prior art required guide elements in discontinuation.

It is within the scope of the invention that the piston rods in pairs arranged sliding block approaches are attached to the sliding blocks.

According to another characteristic, they are only together in a known manner with the shaft carrying the associated gearwheel rotatable body of revolution in likewise known: way arranged axially slidable by itself under the action of a spring. This measure makes it possible to keep the compression pressure constant and through the spring to bring about a compensation, whereby an axial movement of the rotating body limiting stop is present. Other features, details and advantages of the invention will appear from the following description of some preferred ones Embodiments as well as on the basis of the drawing. Here, FIG. 1 a partial sectional side view of the piston machine according to the invention, FIG. 2 is a plan view according to line II-II in F i g. 1, Fig. 3 the development of the curve of a solid of revolution, F i g. 4 is a theoretical diagram for explaining the function of an internal combustion engine and F i g. 5 shows an axial section through a further embodiment of the invention.

Like F i g. 1 and 2 show, there are two cylindrical shafts 1 on the two shafts Rotary body 2 arranged, which are provided with curves 3, the side surfaces 4 run diagonally. The rotating bodies 2 are each connected to a gear 5, and these gears 5 mesh with each other. The arrangement of the bodies of revolution is symmetrical to the center plane of the machine. One of the two shafts 1 can optionally act as a simple bearing, while the other shaft 1 to transmit the movement serves.

Four frustoconical rollers 6 cooperate with the cams 3, the axes 7 of which are seated in bearings 8 , which in turn are arranged in pairs on the sliding blocks 9. Each sliding block 9 is provided with four lobe-shaped projections 10 , which connect the sliding blocks 9 to two piston rods 11 each with the aid of axes (not shown), each of which is connected to a piston 12 moving in the associated cylinder 13. The sliding blocks 9 are guided parallel to the axis of the cylinder 1.3 by means not shown. The four cylinders 13 and the elements used to convert movement are arranged in a known manner in a block, not shown, which also carries the devices for lubrication, cushioning, etc.

If it is an internal combustion engine, then during the expansion process of the corresponding roller 6 by the piston 12, a downward movement according to FIG. 1 granted, and this movement is transmitted to the rotating body 2 via the inclined side surfaces of the curves 3. The two pistons 12 connected to the same sliding block 9 thus execute the expansion stroke at the same time, so that the force components acting perpendicular to the direction of movement on the wall 4 of the curves 3 cancel each other out.

This also applies to the other work cycles of the machine.

During the exhaust stroke, the wall 4 of the curves 3 acts on the rollers 6 and thus on the pistons 12, which is also the case during the intake process and the compression.

While two plungers 12 are in expansion cause the other two with the other sliding block 9 connected to the piston 12 of the intake stroke, thereby ensuring a perfect balancing of the engine.

The development of a curve 3 is shown in FIG. 3 shown schematically. In contrast to the representation according to FIG. 1 in this case the piston 12 performs different movements, depending on whether it is the intake and compression stroke or the expansion or exhaust stroke. In the drawing, the distance AB corresponds to the inlet, BC to the compression, CD to the expansion and DE to the outlet. The volume captured by the piston 12 is thus significantly greater during the expansion and the outlet CDE than during the preceding cycles ABC.

In Fig. Figure 4 is the diagram of the engine of Figure 4. 3 reproduced, where the pressures are plotted on the ordinate and the volumes or the stroke are plotted on the abscissa are. It can be seen from this that, as compared with an internal combustion engine, it is more common Type the hatched triangle B-D represents the profit. The expansion can namely take place much further, practically up to the outlet pressure, because of the special shape allows the curve to increase the expansion stroke.

It can also be seen from this graph that the inlet time is significant can be longer than the compression time because the distance A-B is much larger than the distance B-C, which has a very favorable effect on the efficiency. The parts Finally, the C-D and D-E of the curve may be shaped so that their development is linear is so that the piston can perform a smooth movement, which increases the efficiency particularly favorably influenced, while in the internal combustion engines of the usual type Movement is sinusoidal, d. H. accelerated during one half of the stroke and during the other half of the stroke is delayed.

It is actually possible to make the curves 3 so that in each Case achieved the optimal efficiency of the engine or the machine according to the invention will.

The F i g. 5 schematically shows two half-sections of a motor according to the invention, the pistons 12 of which are connected to the rollers 6 which move in the curves of the rotating bodies 2. These rotating bodies sit with the interposition of a spring 15 on the shafts 14 carrying the gearwheels 5. The rotating bodies 2 are entrained in rotation by the grooves 16 , the stops 17 limiting this axial movement. This arrangement keeps the compression pressure constant, which is in any case balanced by the spring 15. In the right half of FIG. 5, the rotary body 2 with the roller 6 and the piston 12 has been pressed upwards by the spring 15. This corresponds to the case in which the inlet quantity is minimal and the volume 18 reaches its zero value at the moment of compression at top dead center. The gears are supported on the housing 19 via bearings 20 of a known type.

Claims (4)

Claims: 1. Multi-cylinder piston machine, its reciprocating Piston movement is thereby converted into a rotary movement that together with the Piston rods moved reciprocating rollers in one on the outer circumference of a rotating body arranged curve engage and that the rollers back and forth in with the piston rods moving and parallel to the axis of rotation of the rotating body guided sliding blocks are mounted, with two sliding blocks arranged symmetrically to the center plane of the machine, characterized in that in a four-cylinder piston engine in a known manner symmetrical to the median plane of the machine at least two over one Toothing (5) intermeshing rotary body (2) and the two Sliding blocks (9) symmetrical to one through the axis of rotation of both rotating bodies (2) imaginary plane are arranged. 2. Piston machine according to claim 1, characterized characterized in that the piston rods (11) are arranged in pairs of sliding blocks (10) are attached to the sliding blocks (9). 3. Piston machine according to one of the claims 1 and 2, characterized in that in a known manner only together with the the associated gear-bearing shaft rotatable body of revolution (2) under the action of a spring are axially displaceable by themselves. 4. Piston machine according to claim 3, characterized characterized in that a stop limiting the axial movement of the rotating body (2) (17) is present. Publications considered: German patent specification No. 688,930; Austrian Patent No. 55 313; French patent specification No. 664,968; U.S. Patent Nos. 1,177,609, 2,439,867.