FI128949B - A bearing arrangement of a rotary piston - Google Patents

Abstract

The invention relates to a storage device for a rotary piston, which storage device comprises an eccentric storage means (1) and associated bearings (7, 8). In rotary piston machines equipped with prior art bearings, it happens that the working pressure, the variation in load force due to power transmission and the eccentricity of the piston and bearing means act in alternating directions and cause changes in the position of the rotary piston and deviations in the rotation of the piston center. According to the invention, the bearing means (1) and the bearings (7, 8) form a support / bearing element (F) to which a center shaft (6) connected to the rotary piston (2) has been coupled in an eccentric manner. The support / bearing element has been used to support the combination of the axial and rotational movement of the rotating piston (2) and the central shaft (6) and to facilitate the resistance of movement by directing the pressure transmitted through the central shaft (6) and bearing through a bearing (8 ) and the bearing means (1) against a concave surface of a support bearing (7), and the movements of an outer end (G) of the rotating structure of the movable rotary piston (2) and other piston surfaces have been stabilized so as to follow wall surfaces formed in a movement space (9) for the piston.

Description

The invention relates to a rotary piston bearing arrangement comprising at least one eccentric bearing member and associated bearings. U.S. Pat. No. 4,086,038 A discloses a rotary piston bearing arrangement of this type, in which an eccentric wheel as a bearing member is connected to the rotary piston eccentrically via an eccentric shaft so that the rotational movements of the piston members and the rotary piston rotate about the central axis of the piston. the eccentric wheel as a bearing member is connected to the rotary piston by a fixed extension of the eccentric shaft, whereby the random impulses and oscillations due to the transmission are displaced as axial pressure by the oscillating motion between moving and static parts. U.S. Pat. No. 5,431,551 A discloses a piston bearing arrangement for a rotary piston machine in which the eccentric and the eccentric shaft connected thereto are a unitary fixed transmission and bearing member, and the axial and rotary movement and the eccentric wheel is in fixed S eccentric coupling to the rotary piston so that the rotational motion about the central axis of the rotary piston ro 20 is left without severe support, so the resistance to rotation + is strong, and the load impulses from the drive shaft and the operating pressure change instability of the combination of axial and rotational motion, which with unstable support of the rotational movements of the piston bodies causes frictional S friction and kinetic energy losses in the moving and staa of the rotary piston machine; between the parts.

N Patent publication FI 124756 B discloses a bearing arrangement for a rotary piston machine comprising a support ring around the central axis of the piston movement space, by which the movements of the rotary piston are unstable by aligning the bearing member inside the piston cavity with the center ring and the operating pressure. for a greater distance from the support ring and the central axis of the piston movement space between the moving and static parts of the rotary piston machine, frictional friction and variations in the distance between the transmission wheel and the transmission wheel camshaft on the drive shaft.

The object of the invention is to eliminate the above drawbacks and to provide a rotary piston bearing arrangement for stabilizing the parallelism and constant distance between the central axis of the rotary piston and the central axis of the piston movement and the constant distance between each other and the parallelism of the rotary piston position with the piston movement walls. the transmission members are movable relative to each other. It is a further object of the invention to provide a rotary piston bearing arrangement in which the motion resistance loading the combination of axial and rotational motion from varying directions via the rotary piston center axis is alleviated by bearing the piston center axis in a rotationally pivotal position on the inner circumference of the fixed piston bearing so that the support of this and the combination of rotational movement is statically severe and the rotational movements of the piston members are regular in the rotational pulses of the piston and follow the state of movement of the piston.

In order to achieve these objects, the invention is characterized by what is set forth in the characterizing part of appended claim 1.

S +> According to the invention, in the rotary piston bearing arrangement, a support bearing and a convex side fixed to the static component of the rotary piston movement space of the rotary piston are movably coupled to the concave side of the support bearing 2 with the bearing member in the middle and parallel to the pivot axis. the bearing eccentrically with respect to the hub axis forms a support / bearing element with which the rotary piston is suspended in the piston movement space by coupling the fixed central axis of the rotary piston with a bearing to the bearing member connected to the support bearing so that the center of the rotary piston is equal to the bearing member, 5 parts of the length of the circumference of the circumference of the space formed as the rotational space of the central axis of the piston in the space of movement of the piston, and the eccentric structural mass of the rotary piston is directed in a different direction as an eccentric structure of the bearing member, and one or more support / bearing members are formed with a bearing arrangement to reduce the movement resistance of the rotary piston and to support axial and rotational movement. In this case, the orbit of the central axis connected to the rotary piston is formed substantially in the shape of a circular arc with the circumference of the rotary space formed in the piston's motion space; and the position of the rotary piston in its state motion resistance is reduced.

In a preferred embodiment of the invention, the extreme end of the rotating piston torsional structure and other piston members extend close to the working distance of the wall surfaces formed in the piston movement space. This ensures that the rotational movement of the piston torsional structure at the extreme end and of each other piston member is controlled and supported in a regular shape and length and optimized along the wall surfaces formed in the piston movement space.

Other sub-requirements are explained in the text below.

S N 20 In the following, the invention will be explained with reference to the accompanying drawings, in which

S + TY Fig. 1 shows a cross-sectional and side view of a rotary piston bearing arrangement according to the invention, 3 N Fig. 2 shows the rotary piston bearing arrangement according to Fig. 1 in cross-section and N perpendicular rear view, Fig. 3 shows a rotary piston bearing arrangement according to Figs. after a position change in which the rotation of the piston members by a 45 degree rotation of the central axis and the bearing member has moved a 180 degree rotation, and Fig. 4 shows the rotation piston bearing arrangement according to Fig. 3 in cross-section and rear view.

The figure shows a cross-sectional view of an applied rotary piston bearing arrangement according to the invention, in which two support / bearing elements are formed parallel to the deck walls. Fig. 2 shows a cross-section of an applied rotary piston bearing arrangement according to the invention, in which the central shaft connected to the rotary piston is bearing-connected to a bearing eccentrically in the bearing member, so that the bearing member is movable and eccentric in relation to the central axis. Fig. 3 shows a cross-section of an embodiment of bearings according to the rotary piston bearing arrangement according to the invention, in which the central axis of the rotary piston is connected to the bearing member and the bearing bearing is securely attached to the rotary bearing of the rotary piston and the bearing member. a position relative to each other and to the central axis of the piston movement space, and from a transmission wheel fixed to the central axis of the rotary piston, which is connected to the drive shaft of the rotary piston machine by means of a second drive wheel. Fig. 4 shows a cross-section of an applied support bearing on the outer circumference of a bearing member belonging to a rotary piston bearing arrangement according to the invention, by means of which the bearing member is statically and bearing-mounted on the rotary piston machine.

a bearing in the rotating member, wherein the central axis connected to the rotary piston is connected to the bearing member such that the distance of the central axis from the central axis of the piston is half the length of the central axis orbit diameter, the piston torsion structure and the lever arm structure at the junction of the pivot the axis of rotation moves, as well as the position of the convex side of the non-central structural mass of the bearing member according to Fig. 3 against the concave side of the support bearing and the position of the rotary piston according to Fig. 3 in the piston movement state.

The figures show a bearing member 1, a rotary piston 2, a transmission member 3, a component 4, a cover plate 5, a central shaft 6, a support bearing 7, a bearing 8, a piston movement space 9, a bearing housing 10 and a locking member 11. According to Figures 1 and 2 the rotary piston 2 is placed in a piston movement space. 9 end surfaces parallel to the wall of the static component 4, and the bearing member 1 is mounted on a rotary piston machine bearing a support bearing 7 and placed in a bearing housing 10 adjacent to the piston movement space 9, the shaft shaft N is concentric and parallel to the piston movement space is in the bearing member 1 parallel to the pole axis N of the bearing member 1 and eccentrically at a distance r.

Figures 2 and 4 show the diagonal of the torsion structure of the rotary piston 2 from the axis of rotation K formed at the junction of the piston torsion structure and the lever arm structure to the extreme end G of the piston n 20 n through the dotted line and the open shaft S the main direction of the axial load pressure = the contact point E on the convex side of the eccentric structural mass of the bearing member 1 against the concave side of the support bearing 7, and the remaining rotational pulsation of the piston torsional structure 2 is illustrated by an arc.

N 25 As shown in Fig. 2, the piston bodies are in the initial position of the rotational pulsation with the rotary axis K formed in the piston at the starting rotational support area A, and during the rotational pulsation the rotary piston 2 moves about the rotational axis K formed at the junction of the lever arm structure. , which is at a distance of a length r1 from the central axis 0 of the piston movement space 9, and the load pulses acting on the central axis 6 due to the eccentricity and operating pressure of the movable rotary piston 2 are damped by the bearing cover and the outer circumference 7 of the bearing member 1.

The central shaft 6 of the rotary piston connected to the bearing member 1 at a distance r from the hub shaft N rotates as it moves at a distance r from the central axis O of the piston movement space 9 while rotating the concave side of the bearing member 1 of the bearing member 1 and the convex side of the support bearing 7 the eccentric end of the piston torsional structure G is oriented in a different direction than the convex body of the structural mass eccentric to the piston central axis 6 of the bearing member 1, and in each rotational pulsation the bearing member 1 rotates the support member 7 and the piston 2 eccentric - —they are synchronized to the same speed.

The support bearing 7 attached to the static component 4 of the piston movement space of the rotary piston machine and the convex side are a bearing member 1 movably connected to the concave side of the support bearing 7, the central hub axis N being aligned concentrically and parallel to the center axis O of the piston movement space 9, the hub shaft 20 - a bearing 8 eccentric to the spindle N form a support / bearing element I, R on which the rotary piston 2 is suspended in the piston movement space 9 by connecting a fixed S central shaft 6 of the rotary piston with a bearing 8 to a bearing member 1 connected to a support bearing 7 6 is parallel to the hub axis N of the bearing member 1 at a distance r having a length substantially 0.5 parts of the circumferential diameter of the space formed by the piston's central axis rotation space 9 in the piston movement space 9, and the eccentric structure of the rotary piston 2 is different oral as an eccentric structure of the bearing member 1, and one or more support / bearing members F are formed with a bearing arrangement for reducing the resistance of movement of the rotary piston 2 and for supporting axial movements and rotational movement.

According to the embodiment of Figures 2 and 4, a space having a circumferential diameter of 0.1465 parts of the side length of a square rotary piston 2 is formed in the piston movement space 9 in the orbit R of the central shaft 6, the rotational area of the piston members delimited by curved wall surfaces B and C, and the bearing 8 is fixed parallel to the hub axis of the bearing member 1 for a radius r of 0.5 parts of the length of the orbital diameter R of the central shaft 6 and 0.1035 parts of the distance between the central axis 6 of the rotary piston 6 and the piston arms 7 and the ball bearing 7 the length of the central diameter is 3.7 times the diameter of the orbit R of the central shaft 6, the length of the radius r1 is 0.5 parts of the length of the ball ring or slider in the support bearing 7, and a portion of the bearing ball 7 extends to each of the support balls 7 or a slip joint and moved When the rotary piston 2 follows the movement space 9 of the piston, the slow axial movement of the rotary shaft K with its essential stops is supported by aligning the rotary shaft K with the closest sliding joint or bearing ball part G of the bearing bearing 7, and the torsional structure of the piston extends from the rotary shaft

In each 30-degree rotational pulsation of the rotary piston 2, the 120-degree rotational movement of the bearing member 1 on the support bearing 7 and the 120-degree displacement of the eccentric structural mass of the rotary piston 2 about the central axis O of the piston movement space 9 are synchronized to the same rotational frequency.

O 20 The rotational pulses of the rotary piston 2 movable in the piston movement space 9 are rotated about the axis of rotation K formed in the piston at the rotation support areas R, A, B and C, and the extreme end G of the rotating structure of the rotary piston 2 extends from the center axis O = from the central axis 6 of the rotary piston 6 to the extreme end G of the torsional structure plus the radius r of the orbit R of the central axis 6, and the central axis 6 of the rotary piston has a fixed length to all piston members 0.5 parts S of the length of the piston diagonals such that in the movement space 9 N close to the working clearance distance formed by the wall surfaces.

The extreme end G of the rotating structure of the rotary piston 2 and the other piston members extend

in the vicinity of the running surfaces formed in the rubber space 9. According to Figures 3 and 4, the rotary piston 2 has been moved from the position according to Figures 1 and 2 by 1.5 rotational pulses a total of 45 degrees, ending in a position where the direction of action of the operating pressure changes and where the axis of rotation K changes from rotational support area A to rotational support area B at a distance of the radius r1 from the central axis O of the piston movement space 9, and the central axis 6 connected to the rotary piston is simultaneously moved along a circular orbit R 180. The rotation 1 in the central axis 6 is rotated axially by the central axis 6. 180 degree rotation. As shown in Figures 1 and 3, the central shaft 6 is fixedly locked by the locking member 11 to the rotary piston 2 and the piston rod and other piston bodies at the extreme end of the piston torsion structure about 30 degrees of rotational axis K, and the central shaft 6 has a separate shaft at each end. 1 and the support / bearing element F of the rotary piston 2 and the central shaft 6 connected thereto formed by the bearing 8, with which the central shaft 6 and the rotary piston 2 are jointly supported so that the contact of the transmission member 3 and the bearing member 1 connected to the central shaft 6 is movable. the rotary piston is prevented and the movements of the central axis 6 of the rotary piston and the transmission member 3 fixed thereto by the locking member 11 are stabilized to rotate the orbit R surrounding the hub axis N of the bearing member 1 and rotate 20 = in line according to the rotational movement of the rotary piston 2.

S 8 The rotational movements of the central axis 6 of the rotary piston and the transmission member 3 attached thereto rotate in a stabilized orbit R. j 2 The bearing 8 is at a distance r from the hub axis N of the bearing member 1, the length of which is substantially S 0.1035 part of the distance N25 between the central axis 6 of the rotary piston and the extreme end 25 of the piston torsional structure.

The feedthroughs of the central shaft 6 in the static components 4 of the piston movement space 9 are covered with cover plates 5 so that the support / bearing elements F of the rotary piston 2 and the central shaft 6 connected thereto are in the cover plate 5 and bearing housing 10 from operating pressure, flue gas or e.g. As shown in Fig. 4, the piston members are in the middle of the rotational pulsation with the axis of rotation K formed in the piston being in the center of the rotational support region B, and the rotational movement of the piston torsional end at the remaining part of the rotational pulsation is illustrated by an arc. According to the embodiment shown in Figures 1-4, the rotational movement of the central shaft 6 and the transmission member 3 attached thereto rotates about the central axis O of the piston movement space 9 along the orbit R and rotates about the central axis 6, and the rotary piston 2 and the connected central shaft 6 support / bearing element F are formed. by attaching the bearing member 1 with a support bearing 7 to a static component of the rotary piston machine with the hub axis N oriented parallel and parallel to the central axis O of the piston movement space 9 and connecting the central axis 6 to the bearing member 8 connected to the bearing member 1 at a distance and radius r that when the rotary piston 2 is moved in its state of movement 9, the central shaft 6 and the transmission wheel 3 attached thereto move about the hub axis N of the bearing member 1 in a rotationally rotating manner R and rotate about the central shaft 6 so that the torque lines connected to the rotary piston 2 n the rotational movement of the central shaft 6 and the rotational movements of the piston about the axis of rotation are functional and bearing-supported.

NN 20 The rotary piston 2 movable in the movement state 9 of the piston is axially slow moving at one of the rotational support areas A, B or C at a rotational pulsation S of 30 degrees S = or substantially stagnant on the support member K of the support bearing 7, and the rotation the position has moved to the beginning of the next pivot support area 2, the pivot support areas A, B and C are spaced 120 degrees apart, and the piston bodies of the square piston 2 are moved with a total of 90 N pulses at three rotational pulses, after which the position of the piston 2 and the position of the bearing member 1 in the bearing housing 10 corresponds to the position of each in its position at the beginning of the series of pulses.

According to the inventive idea, in the rotary piston bearing arrangement, the rotary piston and the central shaft support / bearing element connected thereto are formed by a support bearing permanently attached to the static component of the rotary piston machine and a bearing member pivotally attached to the support bearing, the central hub axis being aligned with the support shaft. the orbit of the central shaft connected to the rotatably connected rotary piston is stabilized to follow the rotation of the central shaft formed in the piston movement space, and the movements of the rear end of the piston torsional structure and the piston members against the concave side, the position of the piston end walls is stabilized parallel to the movement of the piston with the cover walls of the piston, a statically severe support structure is formed for the rotational and rotational movements of the central shaft of the rotary piston and the transmission wheel to be attached thereto, and the load pressure on the central axis of the piston is reduced. Within the scope of the invention, solutions different from those described above can be considered within the scope of the inventive idea formed by the claims. Thus, the suspension / bearing element in the rotating piston bearing arrangement may be in the intermediate cover between the piston movement spaces. o The rotary piston bearing arrangement according to the invention can be used in various devices N with a rotary piston. Such devices include e.g. rotary piston engines, rotary piston pumps S and other rotary piston machines. The invention is not limited to the preferred embodiments shown, but may vary within the scope of the inventive idea formed by the claims.

S S S

Claims (4)

PATENT CLAIMS A rotary piston bearing arrangement comprising at least one eccentric bearing member (1) and associated bearings (7, 8), characterized in that a support bearing (7) and a convex body mounted on the static component (4) of the piston movement space of the rotary piston machine (7) a bearing member (1) movably coupled against the concave side, the central hub axis (N) of which is aligned concentrically and parallel to the central axis (O) of the piston movement space (9), and in the bearing member (1) the hub shaft (N) ) form an eccentric bearing (8) forming a support / bearing element (F) with which the rotary piston (2) is suspended in the piston movement space (9) by connecting the fixed central shaft (6) of the rotary piston with a bearing (8) connected to the bearing member (1). (7) so that the central axis (6) of the rotary piston is parallel to the hub axis (N) of the bearing member (1) by a distance (r) of substantially 0.5 part of the length of the circumference of the circumference of the space formed as the rotational space of the central axis of the piston in the piston movement space (9), and the eccentric structure of the rotary piston (2) is in a different direction than the eccentric structure of the bearing member (1). F) a bearing arrangement is formed to reduce the resistance to movement of the rotary piston (2) and to support axial movements and rotational movement. Rotary piston bearing arrangement according to Claim 1, characterized in that the extreme end (G) of the torsional structure of the rotary piston (2) and other piston bodies extend close to the operating distance of the wall surfaces formed in the movement space (9) of the piston. Rotary piston bearing arrangement according to Claim 1, characterized in that the rotational movements E of the central shaft (6) of the rotary piston and of the transmission element (3) attached thereto rotate in a stabilized orbit (R). 3 N Rotary piston bearing arrangement according to Claim I, characterized in that the bearing (8) is at a distance (r) from the hub axis (N) of the bearing element (1) which is substantially 0.1035 parts of the central axis (6) of the rotary piston and the piston torsionally the distance between the extreme end (G) of the structure.