DE4340061C2 - Swashplate type axial piston machine - Google Patents

Description

Axial piston machine in swash plate design with a rotating cylinder drum inside a housing that has a plurality of cylinders in it longitudinally displaceable piston arranged on a concentric to the axis of rotation Has pitch circle and rests against a housing-fixed control floor, the Pistons are engaged with an active surface that can be positioned at an angle to the axis of rotation and the cylinder bores with connection openings to control channels in the Control floor are provided and the shear force support within the axial Extension of the cylinder drum is arranged.

Such axial piston machines are known in the art and can be found especially for hydrostatic drives with high pressure pumps and motors Use. These axial piston machines can with constant or change Lich funding volume. The present invention relates preferably on units with constant delivery or swallowing volume, but it is also applicable to variable volume axial piston units. The rotating one Cylinder drum is supported against a control surface fixed to the housing. The Control surface has kidney-shaped control channels or symmetrical to each other Breakthroughs on the connection between the intake and pressure channels and make the bores of the pistons in the cylinder drum. The gap is necessary so that a hydrostatic lubricating film between the webs of the control surface and which can form the cylinder drum, the friction of the rotating Cylinder drum lowers and a trouble-free and smooth running of the Machine enables. In order to keep this gap as small as possible, To reduce leakage rate, the cylinder drum is supported by a compression spring pressed against the control surface and on the other hand pressurized by the fact that a connection between the cylinder bores and the control channels Openings is made, the diameter of which is smaller than the diameter the cylinder bores. By the latter measure, the cylinder drum pressed against the control surface due to the fluid pressure in the cylinder bore, where the contact pressure is proportional to the load on the machine.  

The relieving pressure surface on the control floor is designed so that the resultant of the pressing piston force (F _k ) and the resultant of the relieving pressure forces on the control floor (F _e ) lie on one line. In order not to obtain a tipping moment that increases leakage oil, the resulting piston _{shear force} (F _kq ) must be supported at the point of intersection of the plane by the sliding _{shoe joints} with the engine _axis . Constructively, this problem is solved by an axially pulled neck from the cylinder drum for shaft support (DE 35 03 437, GB-PS 15 93 731) or by pulling out over the slide shoes in an external bearing. From DE-OS 31 30 501 an axial piston machine is known, in which the pistons are connected to a rotating slide disc via connecting rods. The use of articulated connecting rods prevents the above-mentioned piston lateral force from being generated, but at the same time increases the overall length of the machine.

The first-mentioned design of an axial piston machine supports the transverse piston forces the pulled-out cylinder block neck mentioned above, which has an internal toothing has on the drive shaft and has the disadvantage that the pulled out Cylinder block neck enlarges the installation space of the engine from the inside. Further is the strength of the neck due to the required small wall thickness and the large jump in diameter to the actual cylinder block is critical, because here at the Notch transition occurs.

A possible pulling out of the cylinder block over the sliding blocks in the outer position tion causes a strong undesirable increase in installation space and is also in the production too expensive.

It is therefore desirable to find a constructive solution in which the pre drawn neck is omitted or can be made shorter and concentric to the Pitch circle lying axis of rotation is reduced in diameter, so that the ge total space is reduced, and in addition there should be more space for the elements of the Slide shoe contact pressure and tipping protection can be created.

It is therefore an object of the present invention to host the axial piston machine economic way to construct a compact design of the axial piston machine results.  

This object is achieved in that the housing fixed Control floor has openings and / or webs that have different radial Have distances from the center of the engine and / or have different dimensions, and the an asymmetrical pressure field for generating a compensation moment build up a tilting moment in the lateral force support is effective in the opposite direction.

The advantage of this invention is that by shifting the shear force Support in the interior of the cylinder drum, more precisely, in the area of axial extension of the cylinder drum, the length and the diameter of the  Cylinder drum or the length of the entire axial piston machine can be reduced can, because the cylinder block neck or the pulled-out collar is omitted. It is also possible to generate the asymmetrical pressure field at least one of Provide additional surface exposed to high pressure.

According to a first advantageous embodiment of the invention, this is preceded suggest that the lateral force support and torque transmission within the axial extension of the cylinder drum by an axially parallel toothing on the Drive shaft takes place.

Furthermore, it affects the installation space of the axial piston machine according to a second one Embodiment of the invention advantageously from when with axial piston machines External bearing of the cylinder drum, the lateral force support within the axial Extension of the cylinder drum by mounting the cylinder drum on the Outside diameter of the cylinder drum takes place and the torque transmission within the axial extension of the cylinder drum by an axially parallel Teeth on the drive shaft. This eliminates the usual storage requirements high collar on the cylinder block. As for external storage via the teeth inside the cylinder drum only transfers the torque from the drive shaft the cylinder drum takes place, the shaft can be reduced in diameter, whereby the pitch circle can be retracted and thus also the installation space decreased.

It proves to be extremely advantageous to design the kidneys and webs of the control floor fixed to the housing asymmetrically with respect to the mirror axis of an arbitrarily selected coordinate system, so that the sum of the torques acting on the cylinder about the X axis is approximately zero. Due to the asymmetrical configuration of the control kidneys according to the invention, the hydrostatic pressure field is designed in such a way that a torque which is directed counter to the tipping moment arises on the X-axis of the cylinder drum. The center of gravity of the sum of the pressure forces in the kidneys and the sealing webs (Fe) is now slightly shifted, so that there is a distance (es) from the resultant piston forces (F _k ).

In addition to the possibility of passing through the asymmetrical pressure field on the control floor To form different sized pressure kidneys, it proves to be appropriate to form asymmetrical pressure field in that the pressure kidneys different radial Clearances from the center of the engine. In addition, it is also possible For this purpose, at least one additional area exposed to high pressure must be provided.

Further advantages and details of the invention are based on several, in the cal matical figures illustrated embodiments explained in more detail. It shows

Figure 1a is an axial piston machine of the prior art in cross section with an internally mounted cylinder drum.

Figure 1b is a plan view of the control base of the axial piston machine of Fig. 1.

Figure 2 is an axial piston machine of the prior art in cross section with an externally mounted cylinder drum.

FIG. 3a shows an axial piston machine according to the invention in cross-section with an internally mounted cylinder drum;

Figure 3b is a plan view of the control base of the axial piston machine of Fig 3a with the inventive asymmetric kidneys..;

FIG. 4a shows an axial piston machine according to the invention in cross-section with an externally mounted cylinder drum;

FIG. 4b is a plan view of the control base of the axial piston machine according to Fig. 4a with the inventive asymmetric kidneys.

In Fig. 1a an axial piston machine in the swash plate design of the prior art is shown, the engine is housed in a housing 1 . A rotating cylinder drum 2 has an axial bore, on the wall of which axially parallel webs of a toothing 6 with a drive shaft 13 are attached. In the cylinder drum 2 there is a multiplicity of cylinder bores 3 , in each of which a piston 4 reciprocates longitudinally. The number of bores or cylinders depends on the desired delivery volume per revolution and is therefore based on the requirements for the axial piston machine. The cylinder drum 2 rests with its end face against a control surface 5 fixed to the housing. The cylinder bores 3 are arranged concentrically to the axis of rotation of the cylinder drum 2 . The longitudinally displaceable pistons 4 are operatively connected to a swash plate 11 via a slide shoe 15 . When the drive shaft 13 rotates, a piston stroke of the pistons 4 is caused because of the inclined position of the swash plate 11 . The cylinder bores 3 are in a certain position of the cylinder drum 2 by means of the kidneys 7 a, 7 b, 7 c, 9 a, 9 b, 9 c in the control floor 5 with the suction ( 14 ) or pressure channels in connection. Characterized in that the cylinder bores 3 are larger than the connecting openings 12 , the cylinder bores 2 are pressed against the control base 5 at a load-dependent pressure in the cylinder bores 3 . The axial (resulting) piston force F _k generated in this way is a hydrostatic relief force F _e , which, as is known, acts between the end face of the cylinder drum 2 and the control base 5 , counteracts. As already mentioned at the beginning, the relieving pressure areas on the control floor (ie the areas between the kidneys) are designed such that the resultant of the pressing piston force F _k and the resultant of the relieving pressure forces on the control floor Fe lie on one line. The resulting piston _{shear force} F _kq is supported at the intersection of the plane of the sliding shoe joints with the center line of the drive shaft 13 , which is done in this axial piston machine of the prior art by a neck 2 a pulled out of the cylinder drum 2 towards the drive shaft. In order to bring about a certain pressure of the cylinder drum 2 against the control base 5 even when the swashplate machine is depressurized and at low pressure, a spring-washer-ring combination 16 , 17 , 18 is provided, the spring 16 being on the one hand driveshaft 13 supports and on the other hand against the disc 17 , which is secured by the ring 18 .

The pistons 4 have at the lower end spherical end parts 26 which are mounted in corresponding recesses in the sliding shoes 15 . The sliding shoes 15 are pressed by a hold-down ring 24 onto the sliding surface 11 by the pressure of a spherical provision 23 . The resetting experiences its force directed downwards in this figure due to the tension force of the spring 16 . The sliding shoes 15 and the end parts 26 of the pistons 4 are penetrated by bores and supply the pressure pockets 27 of the sliding shoes 15 with pressure medium for lubricating the sliding surfaces of the sliding shoes 15 .

The cylinder drum 2 is mounted on the inside, ie it is supported on the drive shaft 13 , which can be rotated in the housing 1 by means of two roller bearings 30 , 31 .

In FIG. 2, an axial piston machine of the prior art is shown, in which the cylindrical drum 2 is mounted outside. The cylinder drum 2 with a collar 2 b is pulled axially out over the sliding shoes 15 and a roller bearing 32 is arranged between the resulting outer peripheral surface and the inside of the housing. In this construction, too, the resultant of the pressing piston force F _k and the resultant of the relieving pressure forces on the control base F _e lie on one line. The resulting _transverse piston force F _kq is supported in the region of the collar 2 b.

An axial piston machine according to the invention is shown in FIGS . 3a and 3b. Here, however, the support is not, as is known from the prior art, outside the axial extent of the actual cylinder drum 2 at the intersection of the plane of the sliding shoe joints with the aid of a pulled-out neck 2 a, but within the axial extent of the cylinder drum 2 on the drive shaft 13 , which has two points With the help of roller bearings 30 , 31 is mounted at the lower and upper end in Fig. 3a.

In the normal case, the _transverse piston force F _{kq should} match the position of the supporting force F _lq . Due to the type of storage of the cylinder drum 2 according to the invention within the axial extent of the cylinder drum 2 , however, the supporting force shifts so that there is a distance eq ≠ = 0 between the _transverse piston force F _kq and the bearing force F _lq . This shift causes a tipping moment. In order to compensate for this tilting moment, the kidneys 7 , 8 and the webs 25 in the control base 5 are designed asymmetrically in order to exert a compensation torque on the cylinder drum 2 . Therefore, the resulting piston forces F _k and relief forces F _e no longer coincide (there is a distance es), so that the pressure forces are shifted in the Y direction in the selected coordinate system (see FIG. 3b).

If the pressure kidney in Fig. 3b is mirrored about the Y axis, all applications of a motor and a pump can be realized in an open and closed circuit.

In FIGS. 4a and 4b show a variant of the invention the axial piston machine is shown, in which the cylindrical drum 2 is supported on the outer diameter within the axial extent of the cylindrical drum 2. This construction also results in a shift of the forces F _k and F _e .

Claims (5)

1. Axial piston machine in swashplate design with a rotating cylinder drum ( 2 ) inside a housing ( 1 ), which has a plurality of cylinders ( 3 ) with pistons ( 4 ) which are longitudinally displaceable therein on a concentric circle of rotation on an arranged pitch circle and against a control floor fixed to the housing ( 5 ) abuts, the pistons ( 4 ) being in engagement with an active surface which can be positioned at an angle to the axis of rotation and the cylinder bores are provided with connecting openings to control channels in the control base ( 5 ) and the lateral force support ( 6 ) within the axial extent of the cylinder drum ( 2 ) is arranged, characterized in that the housing-fixed control floor ( 5 ) has openings ( 7 , 8 , 9 ) and / or webs ( 25 ) which have different radial distances from the center of the engine and / or different dimensions, and which Build up an asymmetrical pressure field to generate a compensation torque that is Lateral moment support is effective in the opposite direction. 2. Axial piston machine according to claim 1, characterized in that the transverse force support and torque transmission ( 6 ) within the axial extent of the cylinder drum ( 2 ) by an axially parallel toothing on the drive shaft ( 13 ). 3. Axial piston machine according to claim 1, characterized in that the transverse force support within the axial extent of the cylinder drum ( 2 ) by mounting the cylinder drum ( 2 ) on the outer diameter of the cylinder drum ( 2 ) and the torque transmission within the axial extent of the cylinder drum ( 2 ) by an axially parallel toothing on the drive shaft ( 13 ). 4. Axial piston machine according to one of claims 1 to 3, characterized in that the kidneys ( 7 , 8 , 9 ) and webs ( 25 ) of the housing-fixed control base ( 5 ) are designed asymmetrically with respect to the mirror axis (X) of an arbitrarily selected coordinate system , so that the sum of the torques acting on the cylinder drum ( 2 ) about the X axis is approximately zero. 5. Axial piston machine according to one of claims 1 to 4, characterized in that the asymmetrical pressure field is acted upon by at least one of the high pressure struck additional surface is formed on the pressure kidney.