EP1856375B1 - Oscillating piston engine - Google Patents

Abstract

An oscillating piston machine comprises a housing in which a first and at least a second piston are arranged, which pistons can rotate together in the housing about a rotational axis which is fixed to the housing and which pistons, as they rotate about the rotational axis, carry out reciprocating oscillating movements in opposite directions to one another about an oscillation axis which extends perpendicularly to the rotational axis and through the center of the housing, wherein the first piston has a first end face and the at least second piston has a second end face which faces the first end face, wherein the end faces bound a working chamber. The pistons are arranged in such a way that the rotational axis extends through the working chamber.

Description

The invention relates to a rotary piston machine, comprising a housing, in which a first and at least a second piston are arranged, which can rotate together in the housing about a housing-fixed axis of rotation, and when revolving about the axis of rotation about a perpendicular to the axis of rotation and through the housing center extending pivot axis to each other in opposite directions perform reciprocal pivotal movements, wherein the first piston has a first end surface and the at least second piston one of the first end surfaces facing the second end surface, wherein the end surfaces define a working chamber, wherein the pistons are arranged so that the axis of rotation the working chamber runs.

Such a reciprocating engine is from the document FR 2 322 282 A known.

Oscillating piston engines and in particular a rotary piston engine according to the present invention can be used as internal combustion engines (internal combustion engines), as pumps or as compressors. An oscillating piston engine according to the present invention is preferably used as an internal combustion engine and described as such in the present specification.

In the case of using an oscillating piston engine as an internal combustion engine, the individual working cycles of the intake, compression, ignition of the combustion mixture and the expansion and expulsion of the combusted combustion mixture are mediated by reciprocating pivotal movements of the individual pistons between two end positions.

At one from the document WO 03/067033 A1 the same applicant known oscillating piston engine and at one off US Pat. No. 3,075,506 known oscillating piston engine four pistons are arranged in the housing, which rotate around a housing-fixed housing fixed axis of rotation together and run around in the housing reciprocating pivotal movements about a pivot axis, wherein each two adjacent.Kolben pivot in opposite directions. In these known oscillating piston machines, two diametrically opposed pistons with respect to the center of the housing are rigidly connected together to form a double piston, and two such pairs of pistons are arranged crosswise in the center of the housing. Between each two facing end faces of the piston of the piston pairs, a working chamber is formed in each case, so that the known "oscillating piston engine" has two working chambers. Both working chambers, which are arranged diametrically opposite with respect to the housing center are, zoom in and out in the same direction in the reciprocating pivotal movement of the piston.

The pistons of these known reciprocating engines are arranged in the housing so that they are perpendicular to the axis of rotation in its TDC position in which the volumes of the two working chambers are minimal. In this position, the centrifugal forces acting on the piston are maximum when the piston is rotated about the axis of rotation. This leads to the fact that at high speeds, the expansion or the pivoting apart of the pistons must take place against the centrifugal forces, because the centrifugal forces counteract the auseinanderschwenkenden movement of the pistons. The working chambers are always outside and perpendicular to the axis of rotation in this oscillating piston engine.

The pistons of the known oscillating piston machines essentially have the shape of a ball wedge, and the geometry of the working chambers is correspondingly the same.

Although the out WO 03/067033 A1 known oscillating piston engine has very good operating characteristics, the present invention aims to provide a deviating from the above-described concept of the known oscillating piston engine new concept of a rotary piston engine.

From FR 2 322 282 A known oscillating piston machine has according to a first embodiment, two pivot pistons, which are arranged in a spherical housing. The two pistons rotate together around a housing-fixed axis of rotation. During the orbital movement of the two pistons about the axis of rotation, they perform pivoting movements about an axis perpendicular to the axis of rotation extending pivot axis. The two pistons are arranged in the housing so that the axis of rotation passes through the working chamber, which is formed by two mutually facing end surfaces of the two pistons. In a further embodiment, a total of four pistons are arranged in the housing.

The invention has for its object to provide a new concept for a rotary piston machine of the type mentioned.

According to the invention this object is achieved in terms of the aforementioned reciprocating piston engine in that the first and the at least second piston are slidably mounted in a piston cage which is arranged in the housing concentric to the axis of rotation about this, wherein the piston cage with respect to the first and at least second piston the rotational movement is rotationally fixed about the axis of rotation, and that the piston cage approximately perpendicular to the axis of rotation has a bore in which the first and at least second piston partially and slidably received therein, and which limits the working chamber in the circumferential direction.

The opposite of the WO 03/067033 A1 The new concept of the oscillating piston engine according to the invention therefore consists in arranging the at least two pistons so that the at least one working chamber is not perpendicular to the axis of rotation but rather to the axis of rotation or about the axis of rotation. The limit to the working chamber the centrifugal forces acting on the two pistons when revolving around the axis of rotation are less due to the smaller spacing of the pistons from the axis of rotation and also act in the direction of disengagement of the two pistons, ie the centrifugal forces support the working cycle of expansion. The centrifugal forces occurring perpendicular to the axis of rotation during rotation of the pistons about the axis of rotation thus support the expansion of the at least one working chamber.

The first and the at least second piston are slidably mounted in a piston cage, which is arranged in the housing concentric to the axis of rotation about this, wherein the piston cage with the first and at least second piston with respect to the rotational movement about the rotational axis is rotatably connected.

The piston cage and the first and at least second piston thus form the "inner machine" or the "inner engine" of the oscillating piston engine. The sliding bearing of the two pistons in the piston cage serves for the pivotal movement of the two pistons about the pivot axis, while the pistons, due to their rotation with respect to the rotational movement about the rotational axis, rotate together with the piston cage with the latter around the axis of rotation. The piston cage can now advantageously serve as a drive or driven member.

The piston cage has approximately perpendicular to the axis of rotation on a bore in which the first and at least second piston partially and slidably received therein, and which limits the working chamber in the circumferential direction.

The bore thus defines together with the two mutually facing end surfaces of the first and at least second piston, the at least one working chamber of the oscillating piston engine. Depending on the geometry of the end faces of the two pistons, the geometry of the bore of the piston cage is also selected, for example circular or, as likewise mentioned above, oval or of another shape corresponding to the shape of the end faces of the pistons. In a circular configuration of the end faces of the two pistons, in conjunction with the circular bore in the piston cage, a working chamber corresponding to a curved cylinder or a toroidal section is formed. The pistons are then preferably sealed against the wall of the bore of the piston cage by means of seals, which in the case of a circular bore and circular end surfaces are advantageously designed as adapted to the shape of the working chamber piston rings.

In a preferred embodiment, it is provided that the first and second end faces of the first and at least second pistons are circular.

In this embodiment, the first and at least second piston at least in the region which adjoins their end faces, cylindrical and thus very similar in this area classic piston reciprocating engines. An advantage that results from this is that as seals for the two pistons piston rings, if necessary with appropriate curvature, can be used, so that can be used here on long-standing experience in solving sealing problems in reciprocating engines. The through the two end surfaces The first and at least second piston limited working chamber has in this embodiment, the geometry of a bent about the pivot axis of the cylinder or Toroidabschnitts.

As an alternative to a circular configuration of the end faces of the first and at least second pistons, however, a deviating geometry, for example an oval shape, can be selected, which contributes to an enlargement of the at least one working chamber, in particular when the interior of the housing has ball symmetry.

In a further preferred embodiment, the first and the at least second piston are formed substantially arcuate.

It will be understood that the arcuate shape of the first and at least second pistons may be limited to the area adjacent their end surfaces, i. Facing away from the end faces outer sides of the piston can, as will be described hereinafter, are used as functional elements for the control of the piston for deriving the pivotal movement of the orbital motion of the piston and to have other shapes.

In a further preferred embodiment, the first piston and / or the at least second piston at least one running member, which is guided during rotation of the first and / or at least second piston along a correspondingly shaped cam, to the pivoting movements of the first and at least second piston generate, with the cam on Housing is arranged with respect to the axis of rotation at least approximately maximum distance.

In the known oscillating piston engine, a comparable control mechanism for the pivoting movements of the piston is provided, but there is the control cam with a smaller distance to the axis of rotation in the vicinity of the end faces of the housing. The advantage of the greater spacing of the cam from the axis of rotation is improved lever ratios to derive the pivotal movements of the at least two pistons from the orbital motion about the axis of rotation.

In this context, it is further preferred if the at least one running member is a ball which is rotatably mounted in a ball socket on a housing facing outside of the first and / or at least second piston, and if the control cam as a groove with a part-circular cross-section in the housing is formed, in which the ball partially engages.

Such a control mechanism, which uses a ball as the at least one running member, has the advantage of optimized friction reduction of the control mechanism, since the ball in the ball socket of the at least one piston is freely rotatable, as well as in the groove in the housing, so that the ball Camber may follow due to their all-round rotation with particularly low friction.

The ball socket may be formed to hold the ball captive, or the ball may be lubricated by a lubricating film. which is provided by an oil lubrication, be held by adhesive forces in the ball socket.

Preferably, both the first and the at least second piston on a running member in the form of a ball, which run in the same groove-shaped cam in the housing at a distance from each other.

As an alternative to the design of the at least one running element in the form of a ball, this may be a roller, the running surface of which is formed part-circular transverse to the circumferential direction of the roller, wherein the roller is mounted on a shaft which is connected at the end to the first or second piston. The cam is again preferably formed as a groove with a part-circular cross-section in the housing into which the roller partially engages.

The advantage of the design of the at least one running element as a roller or guide roller with shaft connection of the roller to the piston eliminates the oil adhesion of the ball to the piston necessary in the above-mentioned freely rotatable ball in all directions. Nevertheless, the entire width of the piston guide surfaces is used. The bearing of the at least one roller on the shaft is preferably carried out via precision needle roller bearings, and the roller is in particular preferably releasably connected to the piston.

Preferably, the piston cage is connected to at least one drive and / or output shaft, which runs parallel to the axis of rotation.

This can preferably be realized in such a way that the at least one drive and / or output shaft is arranged concentrically with respect to the axis of rotation and is connected in a rotationally fixed manner to the piston cage.

This refinement has the advantage that the oscillating-piston engine can be designed to be of compact overall construction, since there is no offset between the axis of rotation and the drive and / or output shaft. Furthermore, no transmission for transmitting the rotational movement of the piston cage to the drive and / or output shaft or vice versa is required.

Alternatively, however, it is also preferred if the at least one drive and / or output shaft is arranged at a lateral distance from the axis of rotation and with the piston cage via at least one gear assembly, for example. A sprocket or belt drive assembly is connected.

The advantage of this measure is that the at least one drive and / or output shaft with lateral offset to at least one working chamber, which is yes on the axis of rotation, is arranged. This in turn means that for the at least one working chamber in the case of using the oscillating piston engine as an internal combustion engine to be provided ignition or glow plug with the drive and / or output shaft does not collide. In the aforementioned measure, it may be necessary to decouple the ignition or glow plug from the rotational movement of the piston cage and the associated drive and / or output shaft, or to let the candle itself rotate, but this is an electrical contact Candle over sliding contacts required.

In the above-mentioned measure, in addition, the fuel injection nozzle and optionally inlet and outlet nozzles can also be arranged on the front side of the housing. In this case, combined spark plug injector arrangements can be provided.

In a further preferred embodiment, a channel passes through the piston cage, which opens on the one hand in the bore and on the other hand leads to the housing to communicate depending on the rotational position with an inlet or with an outlet opening in the housing.

The advantage of this measure is that the piston cage acts by means of the aforementioned channel or opening as a kind of valve for the inlet and outlet openings in the housing. It is therefore not necessary to provide the inlet and outlet openings in the housing with separate valves, nor to provide for the time of opening or closing a complex control of the valve, as is the case with classical reciprocating engines. Enabling the inlet and outlet ports to admit combustion air and / or fuel and vent burnt combustion mixture takes place in the correct cycle automatically by the orbital movement of the piston cage around the axis of rotation.

In a further preferred embodiment, the piston cage has at least one channel for a medium, in particular cooling / lubricating medium, which extends at least partially around and through the interior of the piston cage.

It is advantageous that the piston cage advantageously performs another function, namely the supply of all moving parts within the housing with a cooling and / or lubricating medium. The supply of a cooling / lubricating medium can take place via connections arranged on the housing, in which case the at least one channel preferably extends on the outside of the piston cage as an annular channel, so that the at least one channel always communicates with the supply connections.

In a further preferred embodiment, a bore passes through the piston cage at the level of the pivot axis in its direction, which bore preferably widens toward its ends.

This hole is advantageously used as a further coolant / lubricant channel, which contributes to a particularly intensive circulation of such a cooling / lubricating medium, since this bore extends perpendicular to the axis of rotation and thus the cooling / lubricating medium currently located therein when the piston cage rotates about the axis of rotation Centrifugal forces are applied to move the cooling / lubricating medium towards the flared ends of the bore. This advantageously occurs a ventilation effect on the circulation of the cooling / lubricating medium.

In a further preferred embodiment, a third and fourth piston are arranged in the housing, which are pivotable about the same pivot axis or a different pivot axis and can rotate with the first and second pistons about the axis of rotation and define a second working chamber.

In this refinement, a system which is advantageously symmetrical and thus mass-balanced with respect to the axis of rotation is also created in the case of the oscillating-piston engine according to the invention.

It is preferred if the four pistons are arranged so that the first and second working chamber when rotating the piston about the axis of rotation in the same direction zoom in and out.

This design contributes to the fact that the four pistons represent a mass-balanced system in each circulating and pivoting position.

In one embodiment of the oscillating piston engine with a total of four pistons, it is preferably provided in a first embodiment that the first and second pistons and the third and fourth pistons are arranged with respect to the axis of rotation so that the pivotal movements of all pistons take place in the same plane.

In this embodiment, the two working chambers are in a section along the axis of rotation and perpendicular to the pivot axis always in one and the same plane.

It is even more preferable if the first and second pistons and the third and fourth pistons are arranged with respect to the axis of rotation such that the pivoting movements of the first and second pistons in a first plane and the pivotal movements of the third and fourth pistons in a second plane, wherein the first and the second plane are rotated relative to each other by an angle other than 0 ° with respect to the axis of rotation.

In this embodiment, accordingly, the two working chambers formed by the four pistons are not in a common plane as in the aforementioned embodiment, but are offset from each other by an angle other than 0 ° with respect to the axis of rotation. This has the advantage over the aforementioned embodiment that the above-mentioned control curve or in the case of four pistons two cams and guided therein running organs, which are preferably designed as balls, must not have their end point in or before the orthogonal to the axis of rotation but can extend beyond the orthogonal, since due to the offset of the two pairs of pistons to each other, the running members in the UT position, ie at maximum open working chambers, can not collide with each other, since the pairs of pistons are mutually rotated by an angle not equal to 0 °. In this way, compared to the aforementioned embodiment, the maximum volume of the two working chambers (UT position of the piston) can be increased due to a larger opening angle of the two piston pairs. As with any of the above embodiments, it is preferred when the two working chambers zoom in and out in the same direction in this variant, which is achieved by a corresponding shaping of the cams.

It is particularly preferred in the context of the aforementioned embodiment, when the angle is at least approximately 90 °.

In this embodiment, the highest possible symmetry of the mass distribution of the pistons in the housing is again achieved.

In a further preferred embodiment, the piston cage extends on both sides of the pivot axis or pivot axes and also receives the third and fourth piston.

Overall, a particularly simple and little parts requiring structure is thus created in which the piston cage receives all four pistons. For the third and fourth pistons, the piston cage, if this is provided for the first and second pistons as described above, for the third and fourth piston also has a bore in which the third and fourth pistons slidably mounted and with respect to the rotational axis with the piston cage are connected, said bore then limits together with the end surfaces of the third and fourth piston, the second working chamber.

In a further preferred embodiment, a housing inner wall of the housing is substantially spherical.

With this embodiment, advantageously a rotary piston machine is provided with ball symmetry, which has already proven itself in the known oscillating piston engine.

Alternatively, however, it can also be provided that a housing inner wall of the housing is oblong in the direction of the axis of rotation along a plane which includes the axis of rotation.

"Oblong" here means that the housing of the oscillating piston engine consists of two halves of the ball between which an elongated in the direction of the axis of rotation section is interposed. The oblong shape of the housing inner wall of the housing advantageously opens up the possibility of providing the following preferred embodiments.

Thus, it is preferred if in the housing a pivotable about the pivot axis hollow pin is arranged, which has in its wall an opening which communicates depending on the rotational position of the hollow pin with the first working chamber or optionally with the second working chamber.

This hollow pin can be advantageously used to supply fresh air, in particular pressurized fresh air, via the provided in the hollow pin circumferentially limited opening in the working chamber, or if two working chambers are provided, alternately in the two working chambers. As a result, combustion air can be passed under a form in the working chambers, whereby a higher compression of the fuel-air mixture in the working chambers can be achieved. In this way, the oscillating piston engine is particularly suitable as a diesel engine.

It is preferred if the hollow pin is connected to a gear which, when the pistons rotate about the axis of rotation, sets the hollow pin in rotation about the pivot axis.

In this way, the rotational movement of the hollow pin to communicate with the opening of one or the other working chamber, derived in an advantageously simple manner directly from the orbital motion of the piston about the axis of rotation, without an external control mechanism is required. With a suitable choice of the transmission ratio of the transmission synchronization of the rotational speed of the hollow pin is achieved with the speed of the oscillating piston engine in a simple manner.

It is further preferred if the transmission has a worm gear connected to the hollow pin, which meshes with at least one toothing arranged on the housing, which extends around the axis of rotation.

Such a transmission is structurally particularly simple, can be accommodated without increased space in the housing and with appropriate design of the worm teeth, the rotational speed of the hollow pin can then be adjusted depending on the speed of rotation of the piston about the axis of rotation.

Further advantages and features will become apparent from the following description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained not only in the respectively specified Combination, but also in other combinations or alone, without departing from the scope of the present invention.

Fig. 1

eine perspektivische Gesamtansicht einer Schwenkkolbenmaschine, gemäß einem ersten Ausführungsbeispiel;

Fig. 2

eine Ansicht der Schwenkkolbenmaschine in Fig. 1 in Richtung der Pfeile II in Fig. 1;

Fig. 3

einen Längsschnitt durch die Schwenkkolbenmaschine entlang einer Ebene parallel zur Drehachse und senkrecht zur Schwenkachse, wobei die Kolben der Schwenkkolbenmaschine in einer ersten Betriebsstellung dargestellt sind;

Fig. 4

eine Darstellung der Schwenkkolbenmaschine in derselben Betriebsstellung der Kolben wie in Fig. 3, leicht perspektivisch und die Kolben nicht im Schnitt;

Fig. 5

eine mit Fig. 4 vergleichbare Darstellung der Schwenkkolbenmaschine, wobei die Kolben in einer zweiten Betriebsstellung dargestellt sind;

Fig. 7

eine Darstellung der Schwenkkolbenmaschine in derselben Betriebsstellung der Kolben wie in Fig. 6, leicht perspektivisch und die Kolben nicht im Schnitt;

Fig. 8

einen Schnitt durch die Schwenkkolbenmaschine entlang der Linie VIII-VIII in Fig. 3;

Fig. 9

einen Schnitt durch die Schwenkkolbenmaschine entlang der Linie IX-IX in Fig. 3;

Fig. 10

einen Längsschnitt entlang der Linie X-X in Fig. 3 durch die Schwenkkolbenmaschine gemäß den Fig. 1 bis 9;

Fig. 10A

eine mit Fig. 10 vergleichbare Darstellung eines abgewandelten Ausführungsbeispiels der Schwenkkolbenmaschine;

Fig. 11

einen Längsschnitt durch die Schwenkkolbenmaschine vergleichbar mit Fig. 3 oder 4, wobei jedoch der Kolbenkäfig und die Kolben nicht im Schnitt dargestellt sind;

Fig. 12

eine Ansicht der Schwenkkolbenmaschine, bei der eine Gehäusehälfte abgenommen ist;

Fig. 13

eine perspektivische Darstellung der Anordnung aus Kolbenkäfig und Kolben in Alleinstellung und perspektivisch;

Fig. 13

eine perspektivische Darstellung der Anordnung aus Kolbenkäfig und Kolben in Alleinstellung und perspektivisch;

Fig. 14

eine perspektivische Ansicht einer Innenseite einer Gehäusehälfte der Schwenkkolbenmaschine in Alleinstellung;

Fig. 15a) bis d)

verschiedene perspektivische Ansichten bzw. Schnitte eines Kolbens der Schwenkkolbenmaschine einschließlich Lauforgan in Alleinstellung;

Fig. 16

einen Längsschnitt durch eine Schwenkkolbenmaschine gemäß einem weiteren Ausführungsbeispiel;

Fig. 17

einen Längsschnitt durch die Schwenkkolbenmaschine in Fig. 17 in einem Schnitt entlang einer Ebene, die bezüglich der Schnittebene in Fig. 16 um 90° gedreht ist;

Fig. 18

eine perspektivische Gesamtansicht einer Schwenkkolbenmaschine gemäß einem weiteren Ausführungsbeispiel;

Fig. 19

einen Längsschnitt durch die Schwenkkolbenmaschine in Fig. 18 entlang einer Ebene parallel zur Drehachse und senkrecht zur Schwenkachse;

Fig. 20

eine perspektivische Darstellung einer Hälfte der Schwenkkolbenmaschine in Fig. 18;

Fig. 21

eine perspektivische Darstellung der Anordnung aus Kolbenkäfig und Kolben der Schwenkkolbenmaschine in Fig. 18 in Alleinstellung und perspektivisch;

Fig. 22

ein Diagramm, das die einzelnen Arbeitstakte der Schwenkkolbenmaschine in Fig. 18 veranschaulicht;

Fig. 23

eine perspektivische Gesamtansicht einer Schwenkkolbenmaschine gemäß einem weiteren Ausführungsbeispiel;

Fig. 24

einen Schnitt durch die Schwenkkolbenmaschine in Fig. 23 entlang der Linie XXIV-XXIV in Fig. 23;

Fig. 25

einen Längsschnitt durch die Schwenkkolbenmaschine in Fig. 23, wobei die Schnittebene in Fig. 25 senkrecht zur Schnittebene in Fig. 24 verläuft;

Fig. 26

eine mit Fig. 25 vergleichbare Schnittdarstellung des Gehäuses gemäß einem gegenüber Fig. 25 abgewandelten Ausführungsbeispiel;

Fig. 27

eine Fig. 26 entsprechende Darstellung der Schwenkkolbenmaschine gemäß Figur 26, wobei in Fig. 27 zusätzlich der Kolbenkäfig mit den darin aufgenommenen Kolben im Längsschnitt dargestellt ist; und

Fig. 28

eine Darstellung ähnlich zu Fig. 24, wobei jedoch der Kolbenkäfig in einer um 90° versetzten Drehstellung in Bezug auf Fig. 24 im Längsschnitt dargestellt ist.

Embodiments of the invention are illustrated in the drawings and will be described in more detail with reference to this. Show it:

Fig. 1

an overall perspective view of a rotary piston machine, according to a first embodiment;

Fig. 2

a view of the oscillating piston engine in Fig. 1 in the direction of the arrows II in Fig. 1 ;

Fig. 3

a longitudinal section through the oscillating piston engine along a plane parallel to the axis of rotation and perpendicular to the pivot axis, wherein the pistons of the oscillating piston engine are shown in a first operating position;

Fig. 4

a representation of the oscillating piston engine in the same operating position of the piston as in Fig. 3 , slightly perspective and the pistons not in section;

Fig. 5

one with Fig. 4 comparable representation of the oscillating piston engine, wherein the pistons are shown in a second operating position;

Fig. 7

a representation of the oscillating piston engine in the same operating position of the piston as in Fig. 6 , slightly perspective and the pistons not in section;

Fig. 8

a section through the oscillating piston engine along the line VIII-VIII in Fig. 3 ;

Fig. 9

a section through the oscillating piston engine along the line IX-IX in Fig. 3 ;

Fig. 10

a longitudinal section along the line XX in Fig. 3 by the oscillating piston engine according to the Fig. 1 to 9 ;

Fig. 10A

one with Fig. 10 comparable representation of a modified embodiment of the oscillating piston engine;

Fig. 11

a longitudinal section through the oscillating piston engine comparable to Fig. 3 or 4 but with the piston cage and pistons not shown in section;

Fig. 12

a view of the oscillating piston engine, in which a housing half is removed;

Fig. 13

a perspective view of the arrangement of piston cage and piston in isolation and in perspective;

Fig. 13

a perspective view of the arrangement of piston cage and piston in isolation and in perspective;

Fig. 14

a perspective view of an inner side of a housing half of the oscillating piston engine in isolation;

Fig. 15a) to d)

various perspective views or sections of a piston of the oscillating piston engine including running member in isolation;

Fig. 16

a longitudinal section through a rotary piston machine according to another embodiment;

Fig. 17

a longitudinal section through the oscillating piston engine in Fig. 17 in a section along a plane that is in relation to the cutting plane in Fig. 16 rotated by 90 °;

Fig. 18

an overall perspective view of a rotary piston machine according to another embodiment;

Fig. 19

a longitudinal section through the oscillating piston engine in Fig. 18 along a plane parallel to the axis of rotation and perpendicular to the pivot axis;

Fig. 20

a perspective view of a half of the oscillating piston engine in Fig. 18 ;

Fig. 21

a perspective view of the arrangement of piston cage and piston of the oscillating piston engine in Fig. 18 in isolation and in perspective;

Fig. 22

a diagram showing the individual working cycles of the oscillating piston engine in Fig. 18 illustrated;

Fig. 23

an overall perspective view of a rotary piston machine according to another embodiment;

Fig. 24

a section through the oscillating piston engine in Fig. 23 along the line XXIV-XXIV in Fig. 23 ;

Fig. 25

a longitudinal section through the oscillating piston engine in Fig. 23 , where the cutting plane in Fig. 25 perpendicular to the cutting plane in Fig. 24 runs;

Fig. 26

one with Fig. 25 Comparable sectional view of the housing according to one opposite Fig. 25 modified embodiment;

Fig. 27

a Fig. 26 corresponding representation of the oscillating piston engine according to FIG. 26 , where in Fig. 27 in addition, the piston cage with the piston received therein is shown in longitudinal section; and

Fig. 28

a representation similar to Fig. 24 However, wherein the piston cage in a 90 ° offset rotational position with respect to Fig. 24 is shown in longitudinal section.

In Fig. 1 to 10 such as Fig. 11 and 12 is a provided with the general reference numeral 10 oscillating piston engine shown in various views. Further details of the oscillating piston engine 10 are in Fig. 13 to 15 shown.

The oscillating piston engine 10 is designed as an internal combustion engine in the present embodiment.

The oscillating piston engine 10 has a housing 12, which is composed of two housing halves 14 and 16. The housing halves 14 and 16 each have a flange 18a and 18b, via which the housing halves 14 and 16 are detachably connected to each other.

On the housing 12 diametrically opposite inlet ports 20 and 24 are arranged for fresh air / fuel with respect to the center of the housing, the openings of which pass through the housing (see. Fig. 9 ). Likewise, outlet 22 and 26 are provided. The inlet ports 20 and 24 serve to supply fresh air or combustion air, while the outlet ports 22 and 26 are used for ejecting combusted fuel-air mixture. The inlet ports 20 and 24 are each assigned a port for a fuel injection nozzle, as shown for the inlet port 24 with a port 25 (see also Fig. 9 ). In Fig. 2 a corresponding port 21 for the inlet port 20 is shown.

Furthermore, a plurality of terminals 28 to 38 for the supply and discharge or circulation of a cooling / lubricating medium through the interior of the oscillating-piston engine 10 are arranged on the housing.

In the embodiment of the oscillating piston engine 10, a housing inner wall 39 is substantially spherical or has ball symmetry, such as for example Fig. 3 evident.

In the interior of the housing 12, four pistons 40 to 46 are arranged, which together in the housing 12 about an axis of rotation 48 according to an arrow 49 (FIG. Fig. 3 ) can run around. During this orbital movement, the pistons 40 to 46 perform a pivoting movement superimposed on the revolving movement about a pivot axis 50 which is common to all four pistons 40 to 46 between two end positions, the one end position in FIG Fig. 3 (so-called UT position), and the other end position in Fig. 6 (so-called TDC position) is shown.

Both the axis of rotation 48 and the pivot axis 50, which are to be understood as geometric axes, pass through the center of the housing 12 of the spherical housing. Furthermore, the pivot axis 50 is always perpendicular to the axis of rotation 48, but runs around the latter, however, according to the orbital motion of the pistons 40 to 46 about the axis of rotation 48.

Of the pistons 40 to 46 are each two pistons with respect to the pivot axis 50 diametrically opposite, in each pivotal position of the pistons 40 to 46, which are the pistons 40 and 44 on the one hand and the pistons 42 and 46 on the other. However, the pistons 40 to 46 are individually supported in the housing 12, i. not rigidly connected in pairs.

Each of the pistons 40 to 46 has an end surface, that is, the piston has an end surface 52, the piston 42 has an end surface 54, the piston 44 has an end surface 56 and the piston 46 has an end surface 58.

Each facing end surfaces, which in the present case, the end surfaces 54 and 56 of the pistons 42 and 44 and the end surfaces 52 and 58 of the pistons 40 and 46, each defining a working chamber 60 and 62, which serve as combustion chambers. The axis of rotation 48 passes through both working chambers 60, 62, preferably centrally in each position of the pistons.

Since in each case adjacent pistons 40 to 46 execute opposing pivoting movements relative to each other during rotation about the axis of rotation 48, the working chambers 60 and 62 always increase and decrease in the same direction as one another.

For example, from the in Fig. 3 As shown in the state of maximum volume of the working chambers 60 and 62, the pistons 40 and 46 pivot towards each other (FIG. Fig. 5 ), as well as the pistons 42 and 44. In this case, reduce the volumes of the working chambers 60 and 62, up to the in Fig. 6 illustrated final state in which the working chambers 60 and 62 occupy their minimum volume.

It is understood that the pistons 40 and 46 when pivoting about the pivot axis 50 always left of the line VIII-VIII in Fig. 3 remain, and the pistons 42 and 44 always to the right.

To derive the pivoting movements of the pistons 40 to 46 about the pivot axis 50 from the orbital motion of the pistons 40 to 46 about the axis of rotation 48, each piston 40 to 46 a running member 64 (piston 40), 66 (piston 42), 68 (piston 44) and 70 (piston 46) on. The running members 64 to 70 are balls, each in a ball socket 72, as in Fig. 15 is shown for the piston 40, are mounted, wherein the ball socket is arranged on an outer side of the respective piston 40 to 46, which faces the housing inner wall 39.

The balls 64 to 70 can, as in Fig. 3 is loosely supported in the ball pans 72 and held there by adhesion by means of a lubricating film, the ball pans 72 then not extending beyond the diameter of the balls 64 to 70, or the ball pans can, as in Fig. 15a ) and b), by means of an extension 74 extending beyond the ball diameter, the balls 64 to 70 hold in a form-fitting and thus captive manner.

In any case, the balls 64 to 70 are freely rotatable in the ball sockets 72 in all directions about their respective ball center.

The running members or balls 64 to 70 are assigned two control cams in which the balls 64 to 70 run. More specifically, the balls 64 and 70 of the pistons 40 and 46 associated with a first control cam 76 which is formed as a groove with a part-circular cross-section in the housing inner wall 39. A corresponding control cam 78 is assigned to the running members or balls 66 and 68 of the pistons 42 and 44.

The balls 64 and 70 thus run in the same control cam 76, and the balls 66 and 68 in the same control cam 78. The balls 64 and 70 on the one hand and the balls 66 and 68 on the other are each offset from each other with respect to the axis of rotation 48 by 180 °.

The cams 76 and 78 are arranged with respect to the axis of rotation 48 at least approximately the maximum distance, as from Fig. 3 shows that they are located almost at the height of the pivot axis 50. The cams 76 and 78 are generally substantially orthogonal to the axis of rotation 48th

In Fig. 14 showing the housing half 14 in isolation, the cams 76 and 78 are seen in perspective in detail.

The pistons 40 to 46 are mounted in the housing 12 in a piston cage 80 which revolves around the axis of rotation 48 together with the pistons 40 to 46, which is described in more detail below with further details of the pistons 40 to 46. In Fig. 11 to 13 the piston cage 80 is shown in non-sectional views.

The piston cage 80 is in the embodiment shown, and preferably a one-piece component, but instead of a one-piece design but also a multi-piece design is conceivable.

The piston cage 80 extends along the axis of rotation 48 over the entire length of the housing 12, wherein shaft extensions 86 and 88 of the piston cage 80 protrude from the housing.

The piston cage 80 in each case has a main bearing section 82 or 84 adjoining the shaft extensions 86 and 88 on, via which the piston cage 80 is rotatably mounted in the housing 12 about the axis of rotation 48. The bearing sections 82 and 84 are connected at the center of the housing via a middle section 90, which has a pin-like section 92 extending along the pivot axis 50, on which the pistons 40 to 46 are mounted toward the center of the housing or to the pivot axis 50.

According to Fig. 10 The piston cage 80 has two bores 94 and 96, in which the pistons 40 to 46 are slidably mounted. More specifically, in the bore 94, the pistons 40 and 46 and in the bore 96, the pistons 42 and 44 slidably mounted. The holes 94 and 96 are circular in shape, and accordingly, the end surfaces 52 to 58 of the pistons 40 to 46 are also formed circular. The pistons 40 to 46 are mounted in the bores 94 and 96 by means of piston rings for sealing the working chambers 60 and 62, as in Fig. 3 for the piston 40 with seals 98 (outside) and 100 (inside) is shown. The pistons 42 to 46 have according to Fig. 3 corresponding seals on its radial outer side and its radial inner side.

The bores 94 and 96 define, together with the end surfaces 52 to 58, the working chambers 60 and 62.

In the bores 94 and 96 of the piston cage 80, the pistons 40 to 46 rotatably connected to the piston cage 80, so that the pistons 40 to 46 rotate together with the piston cage 80 about the axis of rotation 48, while the pistons 40 to 46 according to their pivotal movements to the pivot axis 50 in the holes 94 and 96 are slidably movable to the individual Performing cycles of the inlet, compression, expansion and ejection.

The pistons 40 to 46 are substantially as in FIG Fig. 15 is shown arcuately formed, and also the working chambers 60 and 62 have approximately the shape of a curved or curved cylinder, wherein the curvature is concentric with the pivot axis 50.

The arrangement of piston cage 80, the piston 40 to 46 together with the running members 64 to 70 forms the "inner engine" of the oscillating piston engine 10, i. This arrangement includes all moving parts of the oscillating-piston engine 10.

In the bearing portions 82 and 84 of the piston cage 80, such as in Fig. 4 and 9 a plurality of channels 102 and 104, respectively, which extend circumferentially and through the interior of the bearing portions 82 and 84 of the piston cage 80 and which communicate with the already mentioned above terminals 28, 30 and 36, 38, so that through the channels 102, 104, a cooling / lubricating medium for cooling and lubricating the piston cage 80 can be passed. The channels 102 and 104 serve primarily for cooling the internal engine in the vicinity of the working chambers 60, 62.

According to Fig. 4 Cooling / lubricating medium channels 106 and 108 are also formed in the housing 12, wherein in the piston cage 80 in the direction of the pivot axis 50, a bore 110 passes through its central portion 90, which also serves as a cooling / lubricating medium channel. During rotation of the piston cage 80 about the axis of rotation 48 which is located in the bore 110 Cooling / lubricating medium due to centrifugal forces in the direction of the housing inner wall 39 thrown. In this way, a cooling or lubrication of the pistons 40 to 46 and the running members 64 to 70 is accomplished in the center of the inner motor. At the running members 64 to 70, the lubricating film thereby formed also serves to hold the running members 64 to 70 in the ball sockets 72 of the pistons 40 to 46 by adhesion, unless as shown in FIG Fig. 15 is shown, this is accomplished by a positive connection.

The bore 110 widens at its two ends like a trumpet, in order to improve the distribution of the cooling / lubricating medium in the center of the housing 12 yet.

According to Fig. 9 and 10 Are two further holes or channels 114 and 116 are provided in the piston cage 80, which open on the one hand in the bores 94 and 96, and on the other hand to the housing inner wall 39, at the level of the inlet and outlet ports 20 and 22 and 24 and 26 lead. The channels 114 and 116 serve to engage in a rotational position of the piston cage 80 about the axis of rotation 48 through the inlet port 20 and 24, a fuel-air mixture in the working chambers 60, 62, and in a different rotational position burned fuel-air mixture through the outlet 22 and 26 eject. In the other rotational positions of the piston cage 80 closes these nozzles. The piston cage 80 thus simultaneously assumes the function of a valve for releasing and closing the connecting pieces 20 to 26.

How to continue Fig. 10 is apparent, in the piston cage 80 for each working chamber 60 and 62 each have a spark plug 118 and 120 are provided, which are arranged on the rotation axis 48 and rotate together with the piston cage 80 about this. Electrical leads (not shown) are connected in accordance with example by slip rings with the spark plugs 118 and 120. In the case of using the oscillating piston engine 10 as a diesel engine, the candles 118 and 120 are accordingly glow plugs.

The offset by 180 ° with respect to the axis of rotation 48 arrangement of the connecting pieces 20 and 22 relative to the connecting pieces 24 and 26 serves that at least in one of the working chambers 60 and 62 when rotating the piston 40 to 46 about the axis of rotation 48 by 360 ° always an expansion process he follows. Thus, if a working cycle of expansion is taking place in the working chamber 60, a working cycle of the discharge of burned fuel-air mixture takes place in the working chamber 62, and vice versa.

The operation of the oscillating-piston engine 10 will be described below.

Starting from the operating position of the piston 40 to 46 according to Fig. 3 and 4 there are the pistons 40 to 46 in their so-called. UT (bottom dead center) position. After a 45 ° rotation about the axis of rotation 48, the pistons 40 and 46 or 42 and 44 have moved by half to each other, as in Fig. 5 is shown. The working chambers 60 and 62 have been reduced by about half their volume. The pivoting movement of the pistons 40 to 46 was mediated by the leadership of the running members 64 to 70 in the cams 76 and 78.

After a further rotation by 45 ° about the axis of rotation 48 then take the piston 40 to 46 in Fig. 6 and 7 illustrated OT (top dead center) position in which the volumes of the working chambers 60 and 62 are minimal. After a further rotation by 45 ° about the axis of rotation 48 in the continued direction then take the piston 40 to 46 again in the position Fig. 5 and after a further rotation of 45 ° the position according to Fig. 3 one. After a rotation through 180 ° about the axis of rotation 48, the working chambers 60 and 62 are again maximum.

Thus, after a full 360 ° turn, each of the working chambers 60 and 62 has once had the four power strokes of intake, compression, expansion and ejection.

In Fig. 10A is a slightly modified embodiment of a rotary piston engine 10 'shown, which differs from the oscillating piston engine 10 only in that the holes 94' and 96 'in the piston cage 80' and correspondingly the end surfaces 52 'and 54' (the same applies to the end faces, not shown 56 'and 58') not circular, but as in Fig. 10A for example, are shown, oval or elliptical. As a result, the working chambers 60 'and 62' can be enlarged relative to the circular configuration.

In Fig. 16 and 17 Yet another embodiment of an oscillating piston engine 10 "is shown, which differs from the oscillating piston engine 10 or oscillating piston engine 10 'as follows.

While the housing 12 of the oscillating piston engine 10 and the oscillating piston engine 10 'has ball symmetry, the housing 12 "of the oscillating piston engine 10" is formed oblong. More specifically, the housing 12 "consists of two hemispheres 13" and 15 ", between which is interposed an elongate portion 17" extending in the direction of the axis of rotation 48. In this way, the housing 12 "is pivoted in the direction of the axis of rotation 48" Version of the housing 12 longer, which allows the following measures.

Thus, at the central portion 90 "of the piston cage 80", which is in accordance with Fig. 17 is also formed oblong in cross section, inside a hollow pin 122 is arranged, which has an opening 124 in its wall. The central portion 90 "has on the axis of rotation 48" two openings 126 and 128, with which communicates the opening 124 of the hollow pin 122 depending on its rotational position, wherein the opening 124 can communicate with only one of the openings 126 and 128. The hollow pin 124 is "rotatably mounted about the pivot axis 50" in the central portion 90. The rotational movement of the hollow pin 122 about the pivot axis 50 "is derived from the orbital motion of the piston cage 80" about the rotation axis 48 ".For this purpose, the central portion 90" at one end has a gear 130 which has a worm toothing 132 firmly connected to the hollow pin 122 , The worm gear or worm wheel 132 meshes with a toothing 134 arranged concentrically about the axis of rotation 48, so that when the center section 90 "including the hollow pin 122 rotates about the axis of rotation 48, the worm toothing 132 and thus the hollow pin 122 are set in rotation about the pivot axis 50" ,

In the housing, an inlet 136 is also provided for fresh air, which can be closed and opened by a conventional valve device 138, for example. Fresh air, in particular precompressed fresh air, can now be introduced into the interior of the hollow pin 122 through the inlet 136, and depending on the rotational position of the hollow pin 122 relative to the openings 126, 128, the fresh air is introduced into the working chambers 60 "or 62", and although in addition to the supply of fuel-air mixture through the connecting pieces 20 "and 24". In this way, the oscillating piston engine 10 "is a motor with so-called. Charging.

The worm toothing 132 and the toothing 134 are correspondingly designed so that the rotational movement of the hollow pin 122 about the pivot axis 50 "is synchronized with the piston positions of the pistons 40" to 46 "in a suitable manner Working chamber 60 "or in the working chamber 62" should preferably then take place or the opening 124 should communicate with the respective opening 126 and 128 when the ignition of the through the inlet nozzle 20 "and 24" embedded fuel-air mixture just before its ignition A 360 ° rotation of the hollow pin about the axis of rotation 48 "should cause a 360 ° rotation thereof about the pivot axis 50.

Incidentally, the oscillating piston engine 10 "corresponds to the embodiments of the oscillating piston engine 10 or 10 ', so that reference is made to the description there.

In FIGS. 18 to 21 a further embodiment of a rotary piston machine 210 and the details are shown. In the FIGS. 18 to 21 For example, parts that are the same or comparable to parts of the oscillating piston engine 10, 10 'and / or 10 "have been given the same reference numerals, but increased by 200. For example, the oscillating piston engine 210 includes a housing 212 describe such aspects of the oscillating piston engine 210, which differ from the previously described embodiments.

The oscillating piston engine 210 has four pistons 240 to 246 in the housing 212, wherein the pistons 240 and 246 are arranged as the first piston pair and the pistons 242 and 244 as the second piston pair with respect to the rotational axis 248 so that the pivoting movements of the pistons 240 and 246 in a first plane and the pivoting movements of the pistons 242 and 244 take place in a second plane, wherein the first and the second plane with respect to the rotation axis 248 relative to each other by an angle other than 0 °, and in the present embodiment by 90 ° to each other.

This means that the pivot axis of the pistons 240 and 246 is perpendicular to the pivot axis of the pistons 242 and 244. In Fig. 19 is a pivot axis 250 of the piston 242 and 244 located perpendicular to the plane of the Fig. 19 runs while a pivot axis 251 of the pistons 240 and 246 perpendicular to the pivot axis 250 and thus in the plane in Fig. 19 runs.

The offset by 90 ° with respect to the axis of rotation 248 arrangement of the piston pairs 240, 246 and 242, 244 is also off Fig. 21 clearly, in which a piston cage 280 of the oscillating piston engine 210th with the piston 240 to 246 and these associated running members 264, 266, 268, 270 are shown in the form of balls in isolation. In the Fig. 21 shown parts of the oscillating piston engine 210 together again form the inner motor of the oscillating piston engine 210th

The piston cage 280 differs correspondingly from the piston cage 80 of the oscillating piston engine 10 in that the bores 294 and 296 defining the working chambers 260 and 262 are orthogonal to one another.

Due to the mutually orthogonal arrangement of the working chambers 260 and 262 due to the mutually orthogonal arrangement of the pairs of pistons 240, 246 on the one hand and 242, 244 on the other hand, the maximum opening angle of the respective pairs of pistons 240, 246 and 242, 244 and thus the maximum volume of the working chambers 260, 262 relative to the oscillating piston engine 10 in Fig. 1 increased.

This results, for example, a comparison of Figures 19 and 3. Fig. 3 shows the pistons 40 to 46, as already described above, in their maximum opening angle or in their BDC position in which the working chambers 60 and 62 assume their maximum volume.

Fig. 19 shows correspondingly the pistons 240 to 246 in their maximum opening angle with respect to the pivot axes 250 and 251, ie also in its UT position.

While in the oscillating piston engine 10 all four pistons 40 to 46 are pivotable about the common pivot axis 50 or in other words, the pivotal movements of the pistons 40 to 46 extend in the same plane and thus the working chambers 60 and 62 are arranged in a same plane, this means that the running members 64 and 66 on the one hand and 68 and 70 on the other hand in this arrangement, approximately the orthogonal to the axis of rotation 48 come very close, whereby the associated control cams 76 and 78 must be designed so that in the UT position, the running members 64 and 66 on the one hand and 68 and 70 on the other hand do not collide with each other.

Due to the offset by 90 ° arrangement of the piston pairs 240, 246 on the one hand and 242, 244 on the other hand according to the oscillating piston engine 210, this problem does not exist because the running gears 264, 266 and 268, 270 offset by 90 ° to each other in their cams 276 and 278th to run. This allows the cams 276, 278 even closer to the orthogonal (line A in Fig. 19 ) or be extended beyond this, whereby the maximum opening angle of the piston pairs 240, 246 and 242, 244 relative to the oscillating piston engine 10 can be increased, in the embodiment shown by about 10 °. However, this also increases the maximum volume of the working chambers 260, 262 of the oscillating piston engine 210, as a result of which an even higher compression ratio in the case of the oscillating piston engine 210 relative to the oscillating piston engine 10 can be achieved.

As with the oscillating piston engine 10, the working chambers 260, 262 of the oscillating piston engine 210 increase and decrease in the same direction. For example. when the working chamber 260 expands in the course of a power stroke, the working chamber 262 expands to draw in new fresh gas. The two processes thus take place temporally simultaneously, but spatially offset by 90 ° to each other. It thus always and desirably opens and closes both working chambers 260, 262 at the same time.

According to Fig. 18 In addition, in the case of the oscillating piston engine 210, inlet ports 220 and 224 are not arranged diametrically opposite one another, as in the case of the oscillating piston engine 10, with respect to the axis of rotation 248, but offset by 90 ° relative to one another. The same applies to outlet pipe 222, of which in Fig. 18 only the outlet of the working chamber 260 associated 222 can be seen.

In Fig. 22 3 is a diagram illustrating the operation of the oscillating piston engine 210 with respect to the expansion, ejection, suction, and compression strokes in the two working chambers 260 and 262.

In the diagrams, the cams 276 and 278 are shown unwound, it follows from this illustration that the two cams 276 and 278 now serpentine parallel to each other, while the cams 76 and 78 of the oscillating piston engine 10 mirror symmetry with respect to a median plane through the housing center of the housing 12 are formed and arranged mirror-symmetrically perpendicular to the axis of rotation 48.

In Fig. 22 is also symbolically a rectangle for the respective piston pair 240, 246 (working chamber 260) and the associated running members 264, 270 shown in the form of a pitch circle, wherein the running members 264, 270 run along the control cam 276. The same is shown for the second piston pair 242, 244 and their running members 264, 270 with respect to the control cam 278 and the working chamber 262.

In the Fig. 23 to 28 another embodiment of a rotary piston machine 310 is shown. In Fig. 23 to 28 For example, those parts of the oscillating piston engine 310 which are comparable to the corresponding parts of the oscillating piston engine 10 or 210 have been given the same reference numerals, increased by 300. Only the differences of the oscillating piston engine 310 to the oscillating piston engine 10 will be described below. If some parts of the oscillating piston engine 310 are not described in detail below, the description of the oscillating piston engine 10 or the oscillating piston engine 10 ', 10 "and / or 210 applies to these parts.

In the case of the oscillating-piston engine 310, the output and / or drive shaft is not arranged concentrically on the axis of rotation 348, but at a lateral distance from it. The piston cage 380 is provided on the face side and concentrically with the axis of rotation 348 with a ring gear 440, which meshes with a gear ring 442 connected in a rotationally fixed manner to the drive and / or drive shaft 387. In addition to the sprocket 440, the piston cage may be provided on the end face opposite the sprocket 440 with a second sprocket 444. The drive and / or output shaft 387 is formed continuously between its shaft extensions 386 and 388, so that a drive connection with the piston cage 380 is required only via one of the sprockets 440 and 444, as in Fig. 25 is shown.

Fig. 26 in contrast represents a modified embodiment in which the drive and / or output shaft between the shaft extensions 386 'and 388' is not continuous, but the shaft extensions 386 'and 388' are both about sprockets 442 and 446 with the sprockets 440th and 444 in connection. This embodiment makes it possible, the wave extensions 386 'and 388' contrary to the representation in Fig. 26 also with an axis offset and / or with different gear ratios to each other to design. For example, one unit may be driven via one of the shaft extensions 386 'or 388', and the other is connected to the drive train of the vehicle.

Since in the oscillating piston engine 310, the drive and / or output shaft 387 is not on the axis of rotation 348 about which the piston cage 380 and the pistons 340 to 346 therein rotate, the spark plugs 418 and 420 at a respective end-side housing cover 448 and 450 , So be mounted on non-rotating parts, and in particular do not rotate with the piston cage 380. The housing covers 448 and 450 are part of the housing 312 removable.

Likewise, in the case of the oscillating-piston engine 310, as shown, injection nozzles 452 and 454 on the front-side housing covers 448 and 450 can serve the two working chambers 360 and 362 (cf. Fig. 24 ) are arranged.

Also, in this embodiment, inlet stubs 490, 492 for air and outlet stubs 494, 496 for burnt mixture can be provided on the front side of the housing cover 448 and 450.

Another difference between the oscillating piston engine 310 and the previously described oscillating piston engines 10, 10 ', 10 "and 210 is the design of the running members 364 to 370 associated with the pistons 340 to 346.

The running members 364 to 370 are each formed as a roller, as will be described hereinafter with reference to the running member 364 in the form of the roller 456. The roller 456 has a tread 458, which is part-circular transverse to the circumferential direction of the roller 456. The roller 456 is connected via a pin 460 to the piston 340, wherein the roller 456 is rotatable about the pin 460 relative to the piston 340. The shaft 460 extends parallel to the axis of rotation 348. The roller 456 is rotatably mounted on the pin 460 thereto, preferably via a needle bearing, in particular a precision needle bearing. The roller 456 is also releasably connected to the piston 340 via locking rings arranged at the end of the pin 460.

As in the previously described oscillating piston engines 10, 10 ', 10 "and 210, each running member 364 to 370 runs in the form of a respective roller 456 in a cam 376 and 378, respectively, which engage and partially engage the runners 364 and 370, respectively are guided.

The arrangement of the pistons 340 to 346 can be chosen contrary to the illustration also according to the arrangement of the pistons 240 to 246 of the oscillating piston engine 210, that is such that the pivot pistons 340 and 346 relative to the pistons 342 and 344 offset by 90 ° with respect to the axis of rotation 348 are arranged to each other. In this case, also the cams 376 and 378 as in the oscillating piston engine 210 with two wave crests and two troughs may be configured to achieve greater pivot strokes of the pistons 340-346, as already described with respect to the oscillating piston engine 210.

Furthermore, it is possible to use in all previously described oscillating piston machines the chambers facing away from the two working chambers between the piston as Vordruckräume, as in the oscillating piston engine according to WO 03/0670233 A1 described in that document.

Claims (23)

1. An oscillating piston machine, comprising a housing (12; 212; 312) in which a first and at least a second piston (40, 46; 240, 246; 340, 346) are arranged, which pistons (40, 46; 240, 246; 340, 346) can rotate together in the housing (12; 212; 312) about a rotational axis (48; 248; 348) which is fixed to the housing and which pistons, as they rotate about the rotational axis (48; 248; 348), carry out reciprocating oscillating movements in opposite directions to one another about an oscillation axis (50; 251; 350) which extends perpendicularly to the rotational axis (48; 248; 348) and through the centre of the housing, wherein the first piston (40; 240; 340) has a first end face (52; 252; 352) and the at least second piston (46; 246; 346) has a second end face (58; 258; 358) which faces the first end face (52; 252; 352), wherein the end faces (52, 58; 252, 258; 352, 358) bound a working chamber (60; 260; 360), wherein the pistons (40, 46; 240, 246; 340, 346) are arranged in such a way that the rotational axis (48; 248; 348) extends through the working chamber (60; 260; 360), characterized in that the first and the at least second piston (40, 46; 240, 246; 340, 346) are mounted in a sliding fashion in a piston cage (80; 280; 380) which is arranged in the housing (12; 212; 312) concentrically with respect to the rotational axis (48; 248; 348) so as to be rotatable about said rotational axis (48; 248; 348), wherein the piston cage (80; 280; 380) is connected in a rotationally fixed fashion to the first and at least second piston (40, 46; 240, 246; 340, 346) with respect to the rotating movement about the rotational axis (48; 248; 348), and that the piston cage (80; 280) has, approximately perpendicularly with respect to the rotational axis (48; 248), a bore (94; 294) in which the first and at least second pistons (40, 46; 240, 246) are received partially and so as to slide therein and which bounds the working chamber (60; 260) in the circumferential direction.
2. The oscillating piston machine of Claim 1, characterized in that the first and the second end faces (52, 58; 252, 258; 352, 358) are of circular design.
3. The oscillating piston machine of Claim 1 or 2, characterized in that the first and the at least second piston (40, 46; 240, 246; 346) are of essentially arcuate design.
4. The oscillating piston machine of anyone of Claims 1 through 3, characterized in that the first piston (40; 240; 340) and/or the at least second piston (46; 246; 346) have at least one running member (64, 70; 264, 270; 364, 370) which, as the first and/or at least second piston (40, 46; 240, 246; 340, 346) rotates, is guided along a correspondingly designed control cam (76; 276; 376) in order to generate the oscillating movements of the first and at least second piston (40, 46; 240, 246; 340, 346), wherein the control cam (76; 276; 376) is arranged on the housing (12; 212; 312) at an at least approximately maximum distance from the rotational axis (48; 248; 348).
5. The oscillating piston machine of Claim 4, characterized in that the at least one running member (64, 70; 264, 270) is a ball which is rotatably mounted in a ball socket (72; 272) on an outer side, facing the housing (12; 212), of the first or at least second piston (40, 46; 240, 246), and in that the control cam (76; 276) is embodied as a groove with a pitch-circle-shaped cross section in the housing (12; 212), into which groove the ball partially engages.
6. The oscillating piston machine of Claim 4, characterized in that the at least one running member (364, 370) is a roller (456) whose running face (458) is constructed in the form of a pitch circle transversely with respect to the circumferential direction of the roller (456), wherein the roller (456) is mounted on a shaft (460) which is connected at the end side to the first or second piston (340, 346), and in that the control cam (376) is embodied as a groove with a cross section in the form of part of a circle in the housing, into which groove the roller (456) partially engages.
7. The oscillating piston machine of any one of Claims 1 through 6, characterized in that the piston cage (80; 280; 380) is connected to at least one drive shaft and/or output shaft which extends parallel to the rotational axis (48; 248; 348).
8. The oscillating piston machine of Claim 7, characterized in that the at least one drive shaft and/or output shaft is arranged concentrically with respect to the rotational axis (48; 248) and is connected in a rotationally fixed fashion to the piston cage (80; 280).
9. The oscillating piston machine of Claim 7, characterized in that the at least one drive shaft and/or output shaft is arranged at a lateral distance from the rotational axis (348) and is connected to the piston cage (380) by means of at least one transmission mechanism arrangement.
10. The oscillating piston machine of anyone of Claims 1 through 9, characterized in that a duct (114; 314) passes through the piston cage (80; 280), said duct (114; 314) opening at one end into the bore (94; 294) and at the other end opening into the housing (12; 212) in order to communicate with an inlet opening or with an outlet opening in the housing (12; 212) depending on the rotational position of the piston cage (80; 280).
11. The oscillating piston machine of anyone of Claims 1 through 10, characterized in that the piston cage (80; 280) has at least one duct (102; 302) for a medium, in particular cooling medium/lubricating medium which extends at least partially over the circumference and through the interior of the piston cage (80; 280).
12. The oscillating piston machine of anyone of Claims 1 through 11, characterized in that a bore (110) which is preferably widened in the direction of its ends passes through the piston cage (80) at the level of the oscillation axis (50), in the direction of said oscillation axis (50).
13. The oscillating piston machine of anyone of Claims 1 through 12, characterized in that a third and fourth piston (42, 44; 242, 244; 342, 344) are arranged in the housing (12; 212; 312), which pistons (42, 44; 242, 244; 342, 344) can oscillate about the same oscillation axis (50; 251; 350) or an oscillation axis (250) which is different therefrom, and can rotate with the first and second pistons (40, 46; 240, 246; 340, 346) about the rotational axis (48; 248; 348) and define a second working chamber (62; 262; 352).
14. The oscillating piston machine of Claim 13, characterized in that the four pistons (40-46; 240-246; 340-346) are arranged in such a way that as the pistons (40-46; 240-246; 340-346) rotate about the rotational axis (48; 248; 348), the first and second working chambers (60, 62; 260, 262; 360, 362) increase and decrease in size in the same direction.
15. The oscillating piston machine of Claim 13 or 14, characterized in that the first and second pistons (40, 46; 340, 346) and the third and fourth pistons (42, 44; 342, 344) are arranged with respect to the rotational axis (48; 348) in such a way that the oscillating movements of all the pistons (40-46; 340-346) occur in the same plane.
16. The oscillating piston machine of Claim 13 or 14, characterized in that the first and second pistons (240, 246) and the third and fourth pistons (242, 244) are arranged with respect to the rotational axis (248) in such a way that the oscillating movements of the first and second pistons (240, 246) occur in a first plane, and the oscillating movements of the third and fourth pistons (242, 244) occur in a second plane, wherein the first and second planes are rotated relative to one another by an angle which is unequal to 0° with respect to the rotational axis (248).
17. The oscillating piston machine of Claim 16, characterized in that the angle is at least approximately 90°.
18. The oscillating piston machine of anyone of Claims 13 through 17, characterized in that the piston cage (80; 280; 380) extends on either side of the oscillation axis (50; 350) or oscillation axes (250, 251) and also accommodates the third and fourth pistons (42, 44; 242, 244; 342, 344).
19. The oscillating piston machine of anyone of Claims 1 through 18, characterized in that a housing inner wall (39; 239) of the housing is essentially spherical.
20. The oscillating piston machine of anyone of Claims 1 through 19, characterized in that a housing inner wall (39") of the housing (12") is oblong in section in the direction of the rotational axis (48") along a plane which includes the rotational axis (48").
21. The oscillating piston machine of Claim 20, characterized in that a hollow pin (122), which can rotate about the oscillation axis (50") and which has, in its wall, an opening (124) which communicates with the first working chamber (60") or, if appropriate, with the second working chamber (62") as a function of the rotary position of the hollow pin (122), is arranged in the housing (12").
22. The oscillating piston machine of Claim 21, characterized in that the hollow pin (122) is connected to a transmission mechanism (130) which, when the pistons (40"-46") rotate about the rotational axis (48"), causes the hollow pin (122) to rotate about the oscillation axis (50").
23. The oscillating piston machine of Claim 22, characterized in that the transmission mechanism (130) has a worm toothing or worm gear (132) which is connected to the hollow pin (122) and meshes with at least one toothing (134) which is arranged on the housing (12") and extends about the rotational axis (48").

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