DE2044522A1 - Rotary or rotary piston machine - Google Patents

Description

Rotary or rotary piston machine The invention relates to rotary piston or rotary piston motors or pumps for a wide variety of flow media.

In the description below, these motors or pumps are intended as Rotary piston machines are called. These are in particular rotary piston machines with two, one inside the other, on different eccentric axes rotating components with the outer component opposite the inner component rotates at twice the speed, the inner component at right angles to the axis of rotation with two Wings is provided and the outer component in the same direction a cross-sectional shape has, in which an inwardly directed node projection is provided and both interacting components are designed and arranged such that they between them divide the area into two separate rooms.

There are many advantages with such motors or pumps, in that these machines can be operated at relatively high speeds. on this way the throughput of flow medium in the unit of time for a given The size of the machine increased with the, compare with bigger and slower ones Machines, resulting savings in costs for weight and space requirements.

The effects of the leaks are thereby reduced, if different Dimensions of the structural units with the required spatial gap widths and tolerances are established.

However, in contrast to rotating turbine systems, for example the rotary piston machines described are through in their permissible speeds a centrifugal imbalance is severely limited, which is reflected in the asymmetrical shape of the inner and outer component is justified, which creates unbalanced forces, which increase with the square of the speed.

The object of the invention is to eliminate this disadvantage.

The object is achieved in that the outer component for the flow through the machine has openings which are in the vicinity of said inwardly directed Node projection are arranged and the radial depth of the outer component in the peripheral region in the vicinity of said openings is formed in such a way that by the distribution of the material in the outer component as the component rotates an absolute or extensive dynamic equilibrium is achieved.

The openings of the outer component preferably extend over at least a substantial part of the axial length of this component 5, and the peripheral wall of the component has a constant cross-sectional shape along its axial extent.

In a preferred arrangement, the thickness of the wall and the shape of the openings of the component formed such that the outer component is substantially has a cylindrical outer surface which is concentric with the axis of rotation, so that the losses due to fluid friction are largely reduced.

An embodiment of the invention will be described below with reference to the accompanying drawings are explained in more detail.

Show it: Fig. 1 and Fig. 2 one longitudinal and one Cross section through a rotary piston machine according to the invention.

The rotary piston machine shown in the drawing consists of a fixed outer housing 2, which is closed by two opposing walls 4, 6 will. The wall 4 carries a fixed guide component on an extension 4a 8 and has a passage 8a for the flow medium, which enters the guide component 8 leads. The wall 6 carries a bearing 10 for an external rotating component 12. A second coaxial bearing 14 for said component 12 is from the extension 4a worn.

An inner rotating member 16 that has a length along its length has a constant elliptical cross-section, is eccentric within the component 12 mounted on the guide component 8 by means of roller bearings 9.

A stub shaft 18, which is in a remote end bearing 22 in the Guide part 8 is mounted, carries a pinion 19 which is in an internally toothed ring 20 engages, which is attached to the inner member 16, so that when rotating the outer Component 12 causes a rotation of the inner component 16 in the same direction will. The translation is chosen so that the inner component 16 with half Speed of the outer component 12 is driven.

Between the bearings 9 there is essentially one in the guide component 8 rectangular opening 24 is formed, which extends about 90 ° of the circumference in this Part extends. The inner component 16 itself has two diametrically opposed Openings 26 (Fig. 2) of the same angular extent, which alternate when turning the get inner component with the opening 24 in correspondence.

The outer member 12 consists of a main body portion 12a of FIG one substantially constant cross-section, except for a partition 15. The body part 12a is attached between two end plates 12b, 12c. The cross-sectional shape of the inner The surface of the body part 12a has an inwardly directed knot projection 28, and the cross-sectional profiles of the two components 12, 16 are related to one another designed such that the inner component 16 the space within the outer component 12 divided so that two separate areas are formed alternately.

The openings 26 of the inner component 16 open into the corresponding Areas. In the outer component 12 there are two in the vicinity of the node projection 28 Openings 30 in communication with the annular space 54 between the outer member 12 and the housing 2.

At the inner ends of the openings 50 is a recess 31 in the inner circumference of the body part 12a formed in such a way that this area of the body parts is permanently at a distance from the inner component 16, and the openings 30 are in connection with this area of the space between the components. whereby each wing of the 5 inner ones. Components 16 passed a projection 28a, which is the beginning the recess 51 indicates.

The mode of operation of the rotary piston machine is explained below will. It can be assumed that the components move counterclockwise, from the position shown in Fig. 2, rotate. It is reminded that that the angular velocity of the outer component 12 is twice as great as that of the internal components.

We in lig. 2, the interior space 52a is just beginning through the movement of the one: flag els of the inner component 16 past the openings 30 to be formed while the upper one of the openings 26 aligns with the opening 24 begins to cover so that the space 32a with the passage 8a in connection got.

A second inner space 32b just became in communication with the openings 50 brought, as a result of the movement of the other wing, past the projection 28a.

With a further rotation, the space 52a is enlarged, the order of the day 24 acts as an inlet for the flow medium so that it passes through the guide member 8 flows, while the space 32b becomes smaller, so that the flow medium through the Openings 50 is conveyed into the annular space 34 and through an outlet conduit 36 exits. After one complete revolution of the outer component 12, while the inner component 16 of which has made a half turn are the openings again in the position shown (the inner component is around its axis of symmetry inverted so that the spaces 32a and 32b with the opposite sides of the inner Component are connected).

In this way, the indicated space 32b became the suction space 32a of the previous half turn and in connection with the openings 30 brought by the wing moved past the projection 28a and the upper Opening 26 at this moment opposite openings 30 from the knot projection 28 was separated.

The same work cycle is repeated equally in each case, whether the rotary piston machine works as a motor or a pump.

It can be seen, however, that the machine is also clockwise can be actuated, the openings 30 then serve as an inlet for the flow medium and the opening 24 as an outlet.

It can be seen that the outer component is cylindrical has outer surface that is concentric with the axis of rotation and has a stronger one radial wall depth in the area of the X-note projection 28 has. The arrangement of the openings 30 in this area is used as a recess on wall material to be viewed and is designed in such a way that the material that passes through in this area the reinforcement is present, is compensated, so that the outer component is in dynamic equilibrium when turning. This can result in very high Speeds can be achieved without inadmissible vibrations occurring.

The inner component itself is constructed symmetrically around its axis of rotation. In addition, the losses due to the fluid friction in the annulus 34 kept to a minimum due to the cylindrical shape of the outer member. The presence of circumferentially extending outer regions of the openings 30, the recesses in the circular profile of most of the circumference form, do not change this favorable friction characteristic, since in each case radial Flow components in the flow medium in these areas due to the or there is leakage through the openings.

The ability to work at high speeds also allows friction Avoid seals by adding manufacturing tolerances to mating ones Profiles are used between the two components. Between the components are arranged in this way fixed distances, with labyrinth seals 38 (Fig. 1) can be used so that another source of frictional losses is avoided will. The leeks are relative to the amount flowing through very low, since the extent of the flow through the rotary piston machine is due to the high speed is very high and consequently the relatively small areas are only minor Paths for the leakage losses between the two components can result. To the However, end faces of the rotating components are also possible planar friction surfaces provide that are made of a suitable material so that a mutual Sliding is allowed and due to the lack of gaps there is no possibility of it Leakage is given.

The high speed of the rotary piston machine also increases the Flywheel action generated by the rotating masses, in particular from the external component, deliberately as a result of dynamic equilibrium more difficult to manufacture than before.

The direction of the flow of the fluid through the rotary engine is chosen so that the best for the application for which the machine is intended Effect is achieved.

A rotary piston machine acting as, for example, a motor for a compressible flow medium with a direction of rotation counterclockwise, whereby the openings 50 act as an outlet, has the advantage that if the flow medium before flowing through the openings 50 is at a high pressure relative to the outlet pressure is located, an additional drive can be obtained from a power change is generated at the outlet openings and by the shape of the openings can still be increased, as explained in FIG. 2, so that the outlet flow a speed component on the outer component ill direction of rotation of the outer component. The fixed inlet opening 24 can be equipped with a shut-off device be provided, which has a variable circumferential and / or axial extent, so that the speed and torque can be controlled by the device is set accordingly. An example of such a device is shown in Fig. 1 with the reference numeral 42 the upper edge of a curved component indicated, which is rotated around the axis of rotation of the inner component by the extent of the opening 24 to change in scope, while with 44 the left edge of a cylindrical Hülsenbautelis is indicated that can be moved along the guide member 8, so that the axial extent of the opening 24 is reduced. For these settings are external hand-operated devices (not shown) are provided One For example, a rotary piston machine acting as a pump for a compressible flow medium, with a counterclockwise rotation, would when using the above shut-off devices mentioned allow a regulation of the flow, while at a clockwise direction of rotation control of the outlet pressure is possible.

A rotary motion counterclockwise is a rotary piston machine advantageous for non-compressible flow media used as a motor or pump is effective because the flow through the openings 30 has a reaction turbine effect results, which can be increased by the special design of the openings, while the developed centrifugal forces still support the flow. The control of the speed and torque of the engine and the flow rate as well the pressure at the pump is due to the non-compressibility of the flow medium by throttling devices in the supply line better than by the one mentioned above Shut-off device causes.

The interacting components can also have other profiles than those shown in FIG. For example, the wings of the Inner component formed in a substantially pointed shape, as a such an arrangement simplifies the attachment of sliding sealing components to the wings, which engage the inner periphery of the outer member.

Patent claims:

Claims (10)

Claims 1. Rotary piston machine with two nested, components rotating on different eccentric axes, whereby the outer component rotates at twice the speed of the inner component, the inner component is provided with two wings transverse to the axis of rotation and the outer one Component in the same direction has a cross-sectional shape in which a after inwardly directed node projection is provided and both interacting components are designed and arranged in such a way that they separate the surface between them Divide rooms, characterized in that the outer component (12) for the flow through the machine has openings (30) which are in the vicinity of said inward directed node projection (28) are arranged and the radial depth of the outer Component in the circumferential area in the vicinity of said openings (30) formed in this way is that by the distribution of the material in the outer component (12) in the Rotation of the component achieved an absolute or extensive dynamic equilibrium will. 2. Rotary piston machine according to claim 1, characterized in that the openings (30) of the outer component (12) at least over a substantial Part of the length of the component (12) extend and the peripheral wall of the component (12) a constant cross-sectional shape at least along the axial extent of said Has openings (3Q). 3. Rotary piston machine according to claim 1 or 2, characterized in that that the outer component (12) has a substantially cylindrical outer surface has concentric to the axis of rotation. -4. Rotary piston machine according to Claims 1 to 3, characterized in that that a guide component (8) is arranged within the inner component (16) and one Opening (24) with two diametrically opposed openings (26) in the inner Component (16) can be brought into conformity alternately. 5. Rotary piston machine according to claim 4, characterized in that the guide component (8) carries or forms bearings (9) for the inner component (16). 6. Rotary piston machine according to claim 4 or 5, characterized in that that the Fuuuungsbauteil (8) a part concentric with the axis of rotation of the outer Component (12) and a support part for the bearing (22) of the outer component (12) forms. 7. Rotary piston machine according to one of claims 4 to 6, characterized in that that the opening (24) of the guide component (8) axially and / or on the circumference in the extension is adjustable. 8. Rotary piston machine according to one of claims 1 to 7, characterized in that that an outer housing (2) encloses the inner and the outer component (16, 12) and has an inner wall substantially concentric with the outer periphery of the outer component (12). 9. Rotary piston machine according to one of claims 1 to 8, characterized in that that non-contacting sealing devices (38) between the components (12, 16) and are arranged in the vicinity of the stationary parts of the rotary piston machine. 10. Rotary piston machine according to one of claims 1 to 9, characterized in that that said opening (30) radially inward and circumferentially opposite the axis of rotation of the outer component (12) is inclined such that the radially inner end of the opening (30) leads in the direction of rotation of the outer component (12). L e r s e i t e