EP0756068A2 - Rotary internal combustion engine - Google Patents

Abstract

The engine housing contains a cylinder chamber with an even number of pistons and a ring groove (46). The sealing ring (47) set in the ring groove of the housing or one of the piston supports is biased by a force acting from the groove and adjoins a counter face of the relevant piston support. A spring (50) can be mounted between the base of the ring groove and the sealing ring. A pin (52) set between a blind hole (48) in the base of the ring groove and a recess of the sealing ring secures the latter against turning. The sealing ring has on its radially outer face a circumferential groove (58) containing a spring ring (60).

Description

The invention relates to a rotary piston internal combustion engine according to the preamble of the main claim.

Such rotary piston internal combustion engines are provided with a control device which controls the rotary movement of the two piston carriers in such a way that working spaces formed between two different piston carriers belonging to adjacent pistons within the cylinder space are alternately enlarged and reduced during the rotational movement of the pistons and that during the non-uniform rotary movement of the Piston carrier performs a uniform rotary movement. The angular position of the enlarging and reducing spaces relative to the cylinder space is fixed. The cylinder space is provided with at least one inlet opening in the area of an enlarging space and at least one outlet opening in the area of a shrinking space, between which an ignition area is formed in the cylinder space, within which the working spaces circulating between the pistons assume a minimum volume and in them contained ignitable mixture ignites.

Such a rotary piston internal combustion engine is known from US Pat. No. 3,890,939. In this known internal combustion engine, the seal between the housing and the piston carriers is provided by sealing rings, which are each arranged in opposing annular grooves formed in the housing and the adjacent piston carrier or the two piston carriers, and depending on the radial pressure difference on the radially outer or radially inner surfaces of these ring grooves. The seal achieved is heavily dependent on tolerances.

The invention has for its object to provide a generic rotary piston internal combustion engine, the cylinder chamber is reliably sealed.

This object is achieved with the characterizing features of the main claim. With the arrangement according to the invention of the sealing rings and their prestressing in the direction of the respective counter surface, it is achieved that only one ring groove is required for each sealing ring and the respective counter surface is flat, i.e. can be designed without an annular groove, so that there is a large degree of independence from skill tolerances. The sealing ring can lie on the respective counter surface over a large area, which improves the sealing effect and additionally ensures heat dissipation if, for example, the sealing ring is flushed with lubricant on one side. Because only one annular groove has to be provided for each sealing ring, the manufacturing outlay is reduced.

The subclaims are directed to advantageous developments of the rotary piston internal combustion engine according to the invention.

The invention is explained below with reference to schematic drawings, for example and with further details.

Fig. 1

einen Längsschnitt durch eine erfindungsgemäße Drehkolben-Brennkraftmaschine,

Fig. 2

eine Ansicht des Kurbelgetriebes von rechts gemäß Fig. 1,

Fig. 3

eine Ansicht der Kolben mit Kolbenträger, gesehen gemäß Fig. 1 von links,

Fig. 4

eine vorteilhafte Ausführungsform einer Abdichtung zwischen zwei beweglichen Teilen.

Fig. 5

eine axiale Ansicht eines Kolbenträgers mit Kolben und

Fig. 6

eine Schnittansicht der Anordnung gemäß Fig. 5, geschnitten längs der Linie VI-VI.

They represent:

Fig. 1

2 shows a longitudinal section through a rotary piston internal combustion engine according to the invention,

Fig. 2

2 shows a view of the crank mechanism from the right according to FIG. 1,

Fig. 3

2 shows a view of the pistons with piston carrier, as seen from FIG. 1 from the left

Fig. 4

an advantageous embodiment of a seal between two moving parts.

Fig. 5

an axial view of a piston carrier with pistons and

Fig. 6

a sectional view of the arrangement of FIG. 5, taken along the line VI-VI.

1, a rotary piston internal combustion engine has a housing, designated overall by 2, which consists of a motor housing 4 and a gear housing 6. The motor housing consists of two shells 4a, 4b, which enclose between them an inwardly open annular cylinder space 8, and whose shell 4a is blocked with the transmission housing 2. A total of 4 pistons, not shown in FIG. 1, circulate in the cylinder chamber 8, two of which are fastened diametrically opposite one another to one of two piston carriers 10 and 12. The piston carriers are provided towards the cylinder chamber 8 with such peripheral surfaces that they complement the inner surface of the cylinder chamber to a circular cross-section, the one piston carrier forming a running surface for the pistons not attached to it.

The piston carrier 12 is connected in a rotationally fixed manner to a hollow shaft 14 which projects into the gear housing 6 and has a radial arm 16 which is connected to a crankshaft 20 via a connecting rod 18.

Similarly, the piston carrier 10 is rigidly attached to a shaft 22 which extends within the hollow shaft 14 into the gear housing 6 and ends in a radial arm 24 which is connected to a crankshaft 28 via a connecting rod 26.

The crankshafts 26 and 28 are mounted in a crankcase 30 and end in gearwheels 32, 34 connected to them in a rotationally fixed manner, which mesh with a gearwheel 26 fixed to the gearbox housing. The crankcase 30 is rotatable within the gear housing 6 and extends with an output shaft 38 through the gear housing.

The number of teeth of the gears 32, 34 and 36 are matched to one another such that the crankshafts 20 and 28 rotate during one revolution of the crankcase 30 Turn twice so that each working space formed between the pistons in the cylinder space 8 increases and decreases twice in the course of a complete revolution, so that a four-stroke working method can be carried out in the presence of an intake duct and an exhaust duct, not shown.

FIG. 3 shows a view according to FIG. 1 from the left with the shell 4a partially cut open. The two piston carriers 10 and 12 are visible, the diameter of the piston carrier 12 being shown somewhat enlarged, and one each of the pistons 38 and 40 fastened to the piston carriers. The working space 42 enclosed between the pistons 38 and 40 is just minimal in size and is located in the area of a spark plug 44, which is provided when the internal combustion engine is operating as a gasoline engine.

Fig. 4 shows the formation of a mechanical seal, as it can be used at points designated by X in Fig. 1 between two movable components, that is, the housing shell and piston carrier or the two piston carriers. In the example shown, the seal sits between the shell 4a and the piston carrier 10. The shell 4a is provided with an annular groove 46, in which a sealing ring 47, which acts as a sliding ring, is arranged, which over a large area rests against the piston carrier 10 in the annular groove 46. In order to hold the sealing ring 47 in a rotationally fixed manner in the shell 4a and to press it against the piston carrier 10, blind holes 48 are distributed over the circumference of the annular groove 46, in each of which a spring 50 is arranged which presses a pin 52 into a recess in the sealing ring 47 . It goes without saying that a pin does not have to be present in each of the blind holes, since the rotation lock is already achieved, for example, with three pins distributed at equal angular intervals. To evenly press the sealing ring 47 against the piston carrier 10, it is advantageous to distribute a plurality of springs 50, for example 18, evenly over the circumference of the annular groove 46.

In order to achieve a reliable seal against blow-by gases which enter the gap space 56, the sealing ring 47 is provided with a circumferential annular groove 58, into which two spring rings 60, 62 which act as sealing rings are inserted such that their gaps are mutually rotated, for example, by 180 °. The sealing rings 60, 62 can be held in a rotationally fixed manner by means of suitable means, for example pins or bulges of the base of the annular groove 58. The arrangement of the sealing rings 60, 62 on the radially outer side has the advantage that lubricant coming from the shafts 14, 22 or according to FIG. 4 can penetrate into the gap between the sealing ring 47 and the shell 4a, so that it additionally supports the installation of the sealing ring 47 on the piston carrier 10.

An extraordinarily secure seal is achieved with the seal described, the large-area contact between the sealing ring 47 and the piston carrier 10 additionally ensuring cooling of the piston carrier. It goes without saying that oil pressure can also be used to press the sealing ring 47 against the piston carrier 10, which oil pressure is supplied to the arrangement according to FIG. 4 from the left.

5, the piston carrier 10 is fastened to the shaft 22 via an internal toothing. The piston carrier 10 comprises two spokes 64, of which only the upper spoke with the piston 38 formed in one piece with it is shown. A ring part 66 is attached to the spoke 64, which rotates together with the piston carrier 22 and, together with a corresponding ring part 68 fastened to the other piston carrier, closes off the cylinder space 8 in the direction of the shaft 22.

As can be seen from FIG. 6, the piston 38 is arranged eccentrically to the cylinder space 8 when the engine is not in the operating state, so that it moves into a central position when heated due to the expansion of its material and the material of the spoke 64. The seal between the piston 38 and the inner wall of the cylinder space 8 is taken over by piston rings 70.

It is advantageous if the piston carrier 10, 12 consist of a material with a lower coefficient of thermal expansion than the material of the motor housing 4, since the motor housing 4 can be directly water-cooled, whereas the piston carrier are difficult to access for water cooling.

The illustrated embodiment of the piston carrier 10 with the spokes 64 and the ring part 66 has the following advantage:

Considerable centrifugal forces act on the piston 38 as it rotates. In addition, the entire torque is transmitted from the piston 38 to the shaft 22 via the spokes 64, so that the spokes should be made of high-strength material. Such a high-strength material generally has poor sliding properties, but these are decisive for the wall of the cylinder space 8. The ring parts 66 and 68 are therefore made of a material with good sliding properties, for example gray cast iron or coated aluminum. It is also advantageous if the gap formed between the ring part 66, 68 and the associated shell 4b, 4a of the motor housing, as shown in FIG. 6, runs vertically into the cylinder space 8. As a result, there are no sharp burrs, the piston rings 70 can reliably seal and the gaps can be sealed closer to the cylinder space 8, as a result of which the leakage losses are reduced.

Claims (8)

Rotary piston internal combustion engine, with a housing (4) which contains an annular cylinder space (8), an even number of pistons (38, 40) rotating in the cylinder space and having a circular cross section matched to the cylinder space, two piston supports (10, 12) rotatably mounted about the ring axis of the cylinder space, to which half the number of pistons are attached, wherein the peripheral surfaces of the piston carrier (10, 12) are designed such that they complement the inner surface of the cylinder space to form a circular cross section corresponding to the piston (38, 40), against which piston rings (70) provided on the piston seal, and
each with at least one sealing ring (47) received between the piston carriers (10, 12) and between each piston carrier and an opposite wall of the housing in an annular groove (46) of the housing or a piston carrier,
characterized in that
the sealing ring (47) received in the annular groove (46) of the housing (4) or one of the piston carriers (10, 12) is acted upon by a force acting out of the annular groove and bears against a counter surface of the respective piston carrier. Rotary piston internal combustion engine according to claim 1,
characterized by
that between the bottom of the annular groove (46) and the sealing ring (47) a spring (50) is arranged. Rotary piston internal combustion engine according to one of claims 1 or 2
characterized by
that a pin (52) is arranged between a blind hole (48) in the bottom of the annular groove (46) and a recess of the sealing ring (47), which secures the sealing ring against rotation. Rotary piston internal combustion engine according to claim 2 or 3,
characterized by
that the sealing ring (47) is provided on its inside the ring groove, the radially outer surface with a circumferential groove (58), in which at least one spring ring (60) sealing against the ring groove is arranged. Rotary piston internal combustion engine according to claim 4,
characterized by
that in the annular groove (58) two spring rings (60, 62) offset with their gaps are arranged. Rotary piston internal combustion engine according to one of claims 1 to 5,
characterized in that
the gap formed between each piston carrier (10, 12) and the adjacent housing surface opens approximately at right angles into the cylinder space (8). Rotary piston internal combustion engine according to one of claims 1 to 6,
characterized by
that the piston carrier (10, 12) consist of a material with less thermal expansion than the material of the housing (4). Rotary piston internal combustion engine according to one of claims 1 to 7,
characterized by
that the piston carrier with its hub has spokes (64) made of a high-strength material and an annular part (66) supplementing the inner surface of the cylinder space (8) with a tread made of a material with good sliding properties.

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