DE1025722B - Radial piston machine (pump, motor or coupling) with spherical pistons - Google Patents

Description

Radial piston machine (pump, motor or coupling) with spherical Piston The invention relates to a radial piston machine, which acts as a pump, as a motor or can be used as a coupling and is provided with a spherical piston, which is guided in a rolling and sliding manner in a liner in the cylinder bore is used with play, which is an independent expansion of the liner compared the cylinder bore allows.

Piston machines with a spherical piston that is rolling and sliding is guided in a liner inserted in the cylinder bore are known. It is also known per se, a liner with play in a cylinder bore to lead so that the sleeve can expand.

According to the invention, the machine is designed in such a way that the Liner has about the same heat absorption capacity as the piston and with its inner end is resiliently mounted and that between it and the cylinder bore a holding means is arranged, which the liner a limited mobility permitted relative to the cylinder bore in the radial direction, but an axial displacement the liner prevents.

Since the liner and piston have approximately the same heat absorption capacity, they become roughly the same due to the friction of the piston in the liner Temperature warmed. This has the advantage that the clearance between the pistons and the sleeve does not change when it is heated and must therefore be made particularly small can without fear of jamming of the piston in the sleeve. As a result of the resilient mounting of the inner end of the liner and as a result of Possibility of their movement relative to the cylinder bore in the radial direction the liner deform elastically under the pressure of the piston in such a way that this reduces the pressure with which the pole faces of the piston forming the piston are reduced The ball rest on the running surface of the liner. This will reduce the wear and tear between the sleeve and these pole faces of the ball are reduced. As a result of the leeway will also prevents the liner from cooling down too quickly and thereby significantly becomes colder than the spherical piston.

The liner is preferably made in a manner known per se Tungsten carbide bound by a binder. Such carbides are known to be used for parts of cylinder pumps.

As a result of the claimed configuration, the machine can with higher Piston speeds and higher pressures can be operated without affecting the Leakage increases and the volumetric efficiency - is reduced: A Embodiment of the invention is illustrated in the drawing. In this Fig. 1 shows a longitudinal section through the piston machine to be operated as a pump or motor with spherical pistons and with piston liners, according to the invention with clearance are inserted into the cylinder bore, Fig.2 a kept on a larger scale Section through the cylinder block of FIG. 1 to illustrate the clearance between the piston liner and cylinder bore as well as a sealing ring -between the inner end of the liner and the wall of the cylinder bore, and also a snap ring to secure the liner to the cylinder bore at the side Displaceability within certain limits is represented by the degree of the clearance in the cylinder bore are given, Fig. 3 is a partially in section A side view showing one of the cylinders of the cylinder block shown in FIG can be seen on an enlarged scale, and Fig. 4 shows the plan belonging to Fig. 3, partly however in sectional view.

As mentioned, the machine can be operated as a pump or motor. In the following explanation it is assumed that it serves as a pump.

As Fig.1 shows, the machine has an annular cylinder block 1, which is mounted circumferentially on a pin 2, which is rigid with a cover 3 connected is. This cover is screwed to a housing 4. The one from the left through a Seal 6 protruding through into the housing 4 The drive shaft is connected to the annular cylinder block 1 by a coupling 5, sleeves 8 are used in the radial bores. There is rolling in every can and a spherical piston 9 is guided in a sliding manner with play, which is positioned on the inner circular, to the pin 2 eccentric raceway of a ring 10 that sits in the housing 4 runs and surrounds the cylinder block 1. By centrifugal force or that prevailing in the cylinders Pressure of the conveyed medium, the ball pistons 9 are constantly on the track of the Ring 10 pressed against them, rotating about axes that correspond to the axis of the ring 10 lie parallel. This rotation has previously meant that the pole faces of the pistons, d. H. the spherical surfaces located on the axis of rotation tend to be on the sleeves to eat. The object of the invention is to avoid this.

According to the invention, the liner 8 has approximately the same heat absorption capacity like the spherical piston 9, and it is resiliently supported with its inner end and has limited mobility in the radial direction with respect to the cylinder bore. For this purpose, it is inserted into the cylinder bore 7 with clearance 16. Against Displacement in the longitudinal direction of the bore 7 is the sleeve 8 by a snap ring 17 secured. which engages in annular grooves 18 and 19, which in the opposite Walls of the liner of the cylinder bore are provided. At the inner end is the liner 8 bevelled spherically on the outside. The conical surface 20 formed there is based on a sealing ring 21, which is at the bottom of the cylinder bore in a provided there is an annular groove and ideally from a high temperature insensitive polyplast, such as silicone aluminum. The sealing ring prevents that the COI from the cylinder bore through between the liner and bore provided clearance 16 seeps through to the outside.

The snap ring 17 is pretensioned at the bottom of the annular groove 18 of the Liner 8 on. After the parts have been assembled, the annular groove 18 lies namely the annular groove 19 opposite, which is provided in the wall of the cylinder bore. Here is this Ring groove 19 dimensioned so deep that the ring can disappear completely in it, if when inserting the liner into the cylinder block through its conical Will widen at the end of 20. As Fig. 2 shows, the two grooves 18 and 19 are wider, than it corresponds to the strength of the snap ring 17. When reassembling it then lays down the ring on the opposite flanks of the two grooves 18 and 19, where he is pressed against these flanks by the tension of the sealing ring 21, which acts on the conical end 20 of the liner.

So that the bushes can be replaced after they have worn out, the cylinder block has windows 22 (FIG. 4) through which the annular grooves 19 are accessible are. The ends of the ring 17 are located in these windows. These ends can therefore be found Spread open with a tool inserted through the window and thereby open the snap ring 17 expand so much that it releases the annular groove 18 of the liner so that this can be pulled out. In the absence of special precautions, the snap rings could become move outward when fatigued or broken. To prevent that, it is best to guide a wire 23 into the free space between your snap ring 17 and the bottom of the annular groove 19 and bends the ends of this wire in the window 22 around, as Fig.4 shows. As a result, the snap ring is then also secured in its position. if he should tire or break.

If the machine works as a pump, then each ball piston exercises on his own Pressure stroke from a lateral pressure on the rear side of the liner. As a result of the clearance between the liner and cylinder bore is the liner this pressure flattened a little. But this has the consequence, the play of the piston ball at their polar surfaces, d. H. at the ends of their axis of rotation to enlarge. These Increased play between the piston ball and liner prevents this in the known Seizure observed in constructions on the polar surfaces. By flattening the liner the total amount of oil leakage between the piston ball is apparently also reduced and liner can pass through. This leads to a beneficial increase in volumetric efficiency. Also makes it easier to enlarge the game on the Polar surfaces of the piston balls prevent the passage of any dirt particles that are underneath Circumstances in the Ö1 can be present. However, the margin 16 between Liner and the cylinder bore so tightly dimensioned that it prevents the deformation of the liner keeps within permissible limits. If the liner is therefore subjected to unusually high loads exposed as they z. B. can occur if a foreign body between the ball piston and the liner comes, then the liner can be attached to the wall of the cylinder bore create and is supported by it. This is important because the liners consist of hard metal, i.e. of a 'material that is usually only a low one Has tensile strength.

As hard metal for the manufacture of piston balls and liners We recommend the use of tungsten carbide, which is finely ground through serving as a binder cobalt is bound. Such a hard metal is extraordinary wear-resistant. The machining of the parts 8 and 8 made from this hard metal 9 is done by grinding with very low tolerance limits. When grinding the Ring grooves 18 provided in the liners are rounded off at the corners. about notch effects to avoid at these points, which would affect the strength. at a pump with a piston diameter of 22 mm is the tolerance limit for the ball diameter to ± 0.635 #i and the tolerance limits for the clearance the liner to 0.75 et. Also the tolerance limits for the roundness and deviation the surface lines of the straight line amount to 0.75 #x. The leeway 16, with which the liner is fitted into the cylinder bore is at least 1.27 w, but can be up to 3.05 #t due to the permissible deviations.

In practicing the invention, of course, will guide themselves the tolerance limits and the scope according to the size of the parts. So can the leeway between the liner and cylinder bore with a piston ball diameter of 50 mm 25 w and with a Kolhen ball diameter of 16 mm 12.7 w. The game between piston ball and liner can be used for piston balls with a diameter of 50 mm 25 #x and 6.35 [for piston balls 16 mm in diameter.

It has already been pointed out that the liner and the Piston balls get about the same heat absorption capacity so that they are the same fast heat up and therefore expand about the same amount. Then the initial one remains There is room for maneuver even if the pump is operated for a long time. The scope of one Liner in its bore has a heat-insulating effect, so that in contrast to known Types of the relatively much greater heat absorption capacity of the cylinder block remains without any adverse effect. So the heat cannot get off the liner so quickly flow into the cylinder block so that the liner moves as quickly as the Ball piston heated. In addition, the liner can be due to the clearance expand between it and the cylinder bore regardless of the cylinder block, so that jamming of the piston in the liner is prevented.

The advantages of the invention emerge from the following Example: With a nine-cylinder pump of known design with a 22 mm ball piston diameter, in which the balls are made from the above-mentioned hard metal and the cylinder block an alloy commercially available as "Nitralloy" was accepted a minute speed of 3600 and an oil pressure of 100 at a hydraulic Achieve a power of 15 kW. Simply by installing the carbide sleeve the invention, the speed of the same pump to 5400 per minute and the Increase the oil pressure to 200 at, so that an output of 50 kW resulted. It resulted For the reasons explained above, there is no seizure of the piston balls on theirs Pole faces.

The inflow and outflow of the medium is in a manner known per se controlled in that the inner cylinder openings 13 successively with orifices of inlet and outlet channels communicate through the pin 12 and the Cover 3 extend and are illustrated in part at 11 and 15.

The illustrated embodiment can be modified in a number of ways. So the machine can work as a motor instead of a pump. The cylinder block 1 can also be stationary and the housing can rotate with the ring 10 . Finally, instead of being arranged in a star, the cylinders could also be arranged axially parallel in a row. The raceway of the ring could be designed so that it gives each piston ball two or more strokes with each revolution of the cylinder block.

Claims (7)

PATENT CLAIM: 1. Radial piston machine (pump, motor or coupling) with a spherical piston that rolls and slides in a barrel which is inserted in the cylinder bore with a clearance which is an independent Enables expansion of the liner relative to the cylinder bore, characterized in that that the liner (8) has approximately the same heat absorption capacity as the piston (9) and is resiliently supported with its inner end and that between her and the Cylinder bore a limited mobility of the liner (8) compared to the Cylinder bore in the radial direction permitting I-valley means (17) arranged is. 2. Radial piston machine according to claim 1, characterized in that the liner (8) in a manner known per se from tungsten carbide bound by a binder consists. 3. Radial piston machine according to claim 1 or 2, characterized in that that the piston (9) consists of a bonded tungsten carbide. 4. Radial piston machine according to claim 1, characterized in that the liner (8) is beveled at its inner end (20) and between the beveled end and a seal (21) is inserted into the cylinder bore. 5. Radial piston machine according to claim 1 and 4, characterized in that in one in the liner (8) provided groove (18) a snap ring (17) is used, which in a corresponding Tut (19) protrudes into the cylinder bore. 6. Radial piston machine according to claim 5, characterized in that the groove (19) provided in the cylinder wall (1) is deep enough, when inserting the liner (8) into the cylinder bore To be able to take up snap ring (17) completely. 7. Radial piston machine according to claim 5 and 6, characterized in that the snap ring (17) is less wide than the avoidance Grooves (18 and 19) are provided in the liner (8) and in the cylinder bore to accommodate the snap ring. Publications considered: German Patent applications D4804VI / 401>, F336VIa / 18d; Austrian patent specification No. 97 0-14; Swiss Patent No. 148 590; British Patent Specification No. 592 618, 578 392, 574 991; "Metallic materials", Dr. L ü p f e r t, 1941, p. 60 to 62.