DE1015689B - Radial piston machine - Google Patents

Description

Radial piston machine The invention relates to a radial piston machine which can be used as a liquid pump or as a liquid motor, in particular devices of this type which are able to work under high liquid pressures of several 100 kg / cm 2.

Pumps for generating such high pressures are already used in aircraft used to control aircraft systems, etc. However, it does occur during manufacture one suitable for these purposes, simple, powerful and compactly structured Pump up trouble.

With the invention, a high pressure pump is now to be created, which perfectly fulfills all the demands made, but also for other purposes be used. can.

Pumps for generating such high pressures use a rotating cylinder block with circular cylinder bores that are at the same distance from one another around the axis of the block. Pistons work in the cylinder bores, their back and forth movement takes place with the aid of an eccentrically arranged counter pressure ring, on the inner surface of which the outer ends of the pistons rest. If a plane is laid through the axis of the cylinder block and the axis of the eccentric ring, then all pistons located on one side of the plane move outwards in the cylinder bores, which corresponds to the suction stroke of a pump, and a.Ile on the other side The pistons located in the plane move inwards, which corresponds to the pressure stroke of a pump. A facility, e.g. B. a fixed control disc provided with semicircular or kidney-shaped inlet and outlet slots, connects the cylinder bores in the usual way first to the inlet and then to the outlet of the pump.

When generating high hydraulic pressures, the cylinder block, the bearings etc. are subjected to high stresses causing excessive wear and tear Leakage and cause a change in performance. Suggestions have already been made been used to reduce or even out these tensions. These, suggestions resulted however, too intricate and expensive structures.

The aim of the invention is therefore a structure that allows the high Keeping tensions within a permissible range while keeping a simple and inexpensive execution to use.

The cause of many of these undesirable stresses and bends is the tendency of the cylinder block to tilt about an axis directed transversely to the axis of rotation of the cylinder block. The invention is therefore intended to -. Torque, which causes this tendency to tilt, can be canceled or at least greatly reduced in a very simple and effective manner.

For this purpose, according to the invention, the control mirror side End face of the cylinder block has an annular collar of L-shaped cross section attached, which comprises the control mirror disc on its outer periphery, the Provide the surface opposite the control plate of the control disc with an annular groove is which. via at least one channel with: the high pressure slot in connection stands. This creates a direction transverse to the axis of rotation on the cylinder block Torque exerted that counteracts the tendency to tilt the block and thereby has a balancing effect. This torque also acts in the support bearing at the same time of the block occurring torque counter.

The invention has and is still to seek many other advantages other objects that can be derived from the description of the objects illustrated in the drawings Execution result. The description is only intended to explain the general teachings of the invention, but is not to be construed in a limiting sense.

In the drawings, FIG. 1 is a longitudinal section through a radial piston machine, FIG. 2 is a section along line 5-5 in FIGS. 1, 3 . Diagrammatic schematic section showing the forces acting on the pump cylinder block.

The pump structure has a rotating cylinder block 1 which rotates about an axis 2 (Fig. 3). In the embodiment shown, the radia.Jen cylinder bores in the cylinder block 1 are distributed around the axis 2 at the same distance from one another.

A piston 9 is radially movable in each cylinder bore, the outer end of which has a convex surface 10 which cooperates with an inclined surface or conical surface 11 of an eccentrically arranged counter-pressure ring 12.

The walls forming the cylinder bores each have a semicircular projection 15 (FIG. 3) which is radial to the axis 2 and whose concave side faces the counter-pressure ring 12. In this way, a long guide surface is created for each piston 9 , which takes up the counter pressure of that side force which is exerted by the counter pressure ring 12 on the piston.

The cylinder block 1 has a hub portion 16 directed to the left (Fig. 3) which is rotatably supported by a bearing, the rollers 17 of which lie between an inner race 18 attached to the hub 16 and an outer race 19 carried by the liner 20. The sleeve 20 is carried by a hub. Which protrudes from the left-hand hinged wall of the pump housing 23 inward. A right-hand flange 21 of this sleeve 20 limits the movement of the race 19 to the right (Fig. 1) - The left-hand end of the sleeve 20 has an outer flange 22 which rests on a shoulder of the pump housing 23 , which together with its flange 24 and your cover 25 forms an essentially completely closed jacket for the pump parts.

The cover 25 has an inlet opening 28 and an outlet opening 29 for connection to pipelines. The sleeve 20, which receives the outer race 19 of the main bearing intended for the cylinder block 1 , is held on the holding shoulder of the housing 23 by a cover 34 (FIG. 1) .

The right-hand end face of the cover 34 rests against a Kugella, -er43 which rotatably supports a keyway piece 40, one end of which is provided on the outside with keyways 51 which engage in keyways 52 of the cylinder block. The other end of the keyway piece is provided with internal keyways for receiving the drive shaft 49.

The counter-pressure ring 12, with which the pistons 9 cooperate, is rotatably supported using a plurality of balls 53. These balls 53 lie between the counter-pressure ring 12 and an outer race 54. This outer race 54 is seated in a ring 55 which has a sliding movement to adjust its eccentricity between the fastened to the inner circumference of the housing flange 24. Guides 56 and 57 can run.

The ring 55 carrying the outer race 54 has an inwardly directed flange 58 opposite which an insert ring 59 , which serves as a wear plate and is accommodated in a wall of the housing 23. Between the flange 58 and the wear plate 59 there is an axial pressure bearing 60 which limits the movement of the counter pressure ring 12 to the left (FIG. 1) . The movement of the counter-pressure ring 12 to the right is limited by a spacer ring 61 and a sleeve 62.

each cylinder bore etc. has an opening 63 at its inner end. All openings 63 are directed to the right (Fig. 1) and open on the right-hand surface of the block 1. These openings work with one of the two arcuate slots 64 or 65 of the control disc 66 ( Fig. 2) together. The upper arc slot 64 is connected to those cylinder spaces which are in the conveying position. This arcuate slot 64 is therefore connected to a channel 67 located in the cover 25 , which leads to the outlet opening 29 (FIG. 1). The arc slot 65 cooperates in a similar manner with a channel 68 located in the cover 25 which leads to the inlet opening or suction opening 28.

The control disk 66 is fastened to the central shoulder 69 of the cover 25 with a screw 70.

The left surface of the control disk 66 (Fig. 1) lies on the right surface of the cylinder block 1. These two components are held together by an end ring 71 , which lies on the right side of the control disk and on the cylinder block 1 with a spacer ring 72 interposed is attached. The spacer ring 72 can be a hundredth of a millimeter wider than the control disk 66, see above. that there is a running fit between the adjacent walls of the block 1 and the ring 71 for the control disk 66 .

The spacer ring 72 and the end ring 71 are fixed to your cylinder block 1 with a plurality of screws 73. These screws 73 are so strong and are also present in so large numbers that any tensile stress exerted on these screws by the pressure of the liquid located in the space delimited by the ring 71 and the block 1 can be neglected. Despite the existing high pressures in the device, the distance between your ring 71 and the cylinder block 1 is therefore kept essentially the same size.

There is a small radial distance between the outer circumferential edge of the control disk 66 and the inner circumference of the ring 72 , so that the cylinder block 1 can adjust its axis of rotation by itself, as is determined by the roller bearing 17 . Adjustment is easy because only a single roller bearing is required to support the cylinder block. Sufficient guidance for the cylinder block 1 results from the cooperation of the adjacent surfaces located between the cylinder block 1 and the control disk 66.

The arc slot 64 is exposed to the high outlet pressure which acts between adjacent surfaces of the cylinder block 1 and the disc 66 and tries to force these parts apart. A disc 66 enforcing channel 74 leads high-pressure liquid to the between the ring 71 and the right face of the control disc 66 situated space formed by a flat annular groove 75 miles. The area over which this pressure acts corresponds essentially to an annular strip of tape which is present at the point at which the disc 66 and the ring 71 face one another.

The left surface of the control disk 66 has a recess 76. In this way, the opposing surfaces of the cylinder block 1 and the control disk 66 are limited to a relatively narrow annular band, the width of which is chosen so that the results described below are achieved. A drainage channel 84 (FIG. 3) or several drainage channels penetrate the spacer ring 72 in the radial direction and reduce the pressure prevailing in the space on the circumference of the disk 66 and the recess 76.

In Fig. 3 the forces are shown which act on the cylinder block 1 , -uni to tilt or tilt the cylinder block about an axis perpendicular to the axis 2. There are forces which act radially inward on the cylinder block 1 via the pistons 9, 9. and correspond to the radial components of the compressive force present between the piston surface 10 and the counter-pressure ring surface 11. These force components subject the cylinder block 1 to forces generated by the pressure in the cylinder bores. The CY total size of these radially inwardly directed forces is indicated by arrow 77 in FIG. 3 , the length of this arrow being a measure of this force.

A second arrow 78 directed radially inward corresponds to the total magnitude of the bearing counterpressure forces. These counter-pressure forces act via the rollers 17 ' and their sum corresponds to the length of the arrow 77. These two arrows are spaced from one another on the axis of rotation 2 and form a force couple that rotates around an axis perpendicular to the axis 2 and from the arrow C, is shown.

Info some of the inclined surface 11 are force components. 79 of the counter-pressure forces acting on the piston 9 are present. These force components 79 parallel to the axis 2. The total size of these forces is represented by the arrow 80, which protrudes from the shaft 2 in one of the length of the arrow stand 81 corresponding waste. Since the counter-pressure forces 79 are greater on the discharge side or pressure side of the plane P, the force 80 lies above this plane. The force 80 generates a torque C. which runs in the same direction as the torque C1 . The total size of these two torques C and C2 must be neutralized in order to prevent undesired tilting or tilting of the cylinder block 1 .

The total magnitude of the forces exerted as a result of the high pressure fluid between adjacent surfaces. of the block 1 and the control disk 66 act on the block 1 , is represented by the arrow 83 , which lies above the horizontal plane laid by the axis 2 at a distance 160.

In the same way, there are forces 82 which act on the ring 71 and therefore on the block 1 . These forces! run symmetrically around axis 2 and parallel to axis 2 and correspond to the pressure of. the liquid is exerted on that annular surface of the ring 71 which is opposite the disk 66. The arrow 85 corresponds to the total size of these forces 82 and lies on the axis, FIG.

The forces 83 and 85 form a torque C, which is the same size, but opposite in direction to the total size of the two torques C 1 and C 2. This same size is achieved by a correct choice of the opposing surfaces between control disk 66 and cylinder block 1 and between control disk 66 and ring 71 .

As mentioned, the counter pressure ring slides between the guides 56 and 57. The distance between the axis. 2 and the center axis of the counter pressure ring certain eccentricity can be adjusted in this way.

Claims (2)

PATENT CLAIMS-1. Radial piston machine with revolving. The cylinder block, their. Pistons. with an eccentric. Counter-pressure ring work together, the cylinder chambers having channels which open out at the end face of the cylinder block on the control plate side and come into connection with opposing, kidney-shaped low-pressure and high-pressure slits alternately, which are arranged in a fixed control disk, characterized in that on the Constantly mirror-side end surface of the cylinder block (1) an annular collar (71, 72) of L-shaped cross-section is attached, which comprises the control plate row (66) on its outer circumference, the surface opposite to the control plate of the control plate (66) with an annular groove (75) is provided, which is connected to the high pressure slot (64) via at least one channel (74). 2. Apparatus according to claim 1, characterized in that a recess (76) is provided in the end face of the control disc (66) on the control plate side, which recess (76) is in communication with the niccren-shaped high-pressure slot (64) in the control disc (66) . 3. Apparatus according to claim 1 and, 2, characterized in that of the cylinder block (1 *) and the attached to this, the control disc (66) comprehensive rings (71, 72) formed! Annular space is slightly wider than the thickness of the control disk (66). 4. Device according to claim 1 to 3, characterized in that at least one outlet channel (84) connected to the recess (76) is provided in the ring (72) which forms the annular space. Considered publications: German Patent No. 829 553; USA. Patent Nos. 2,506,974, 2 501 165, 2 484 j37.