EP3309393A1 - Hydrostatic fluid displacement machine - Google Patents

Abstract

The invention relates to a hydrostatic displacement machine (1) having a cylinder drum (3) arranged around a rotation axis (2) and provided with at least one piston recess (4), in each of which a piston (5) is longitudinally displaceable. 5) is supported by means of a support element on a thrust-producing track (7), and the cylinder drum (3) is supported in the region of an end face on a housing (9, 9a), wherein at least one sliding bearing point (G1; G2; G3; G4) a sliding bearing component (30; 31; 35; 36) is fastened to the displacement machine (1) on a sliding partner forming the sliding bearing location. The slide bearing component (30; 31; 35; 36) is bonded by magnetic pulse welding to one of the sliding partners of the sliding bearing point (G1; G2; G3; G4).

Description

The invention relates to a hydrostatic displacement machine with a cylinder drum arranged about a rotation axis, which is provided with at least one piston recess, in each of which a piston is arranged to be longitudinally displaceable, wherein the piston is supported by a support member on a thrust generating track, and the cylinder drum in the region of Front side is supported on a housing, wherein at least one sliding bearing point of the positive displacement machine, a sliding bearing component is attached to a sliding bearing forming the sliding partner.

The invention further relates to a method for fastening a sliding bearing component to a sliding partner of a sliding bearing of a hydrostatic displacement machine with a cylinder drum arranged about a rotation axis, which is provided with at least one Kolbenausnehmungen, in each of which a piston is arranged longitudinally displaceable, wherein the piston by means of a support member is supported on a huberzeugenden career, and the cylinder drum is supported in the region of an end face on a housing.

In such displacement machines, for example, axial piston machines or radial piston machines, which can be designed or operated as a pump or motor, it is known, at corresponding sliding bearing points, where between two moving components of the positive displacement machine as a sliding partner of the sliding bearing a relative movement occurs, sliding bearing components to reduce the To install friction and wear. By reducing the friction and wear by the sliding bearing components at the sliding bearing points of the efficiency of the positive displacement machine and its life is increased. The sliding bearing points can continue to be hydrostatically relieved.

At one of the piston recess and the longitudinally displaceable piston formed sliding bearing point of a generic positive displacement machine, it is known to press a plain bearing bush in the piston recess of the cylinder drum or curl up. The plain bearing bush consists of a non-ferrous metal. The plain bearing bush reduces friction and wear between the piston and cylinder drum, thus increasing the efficiency and life of the positive displacement machine. When pressure is applied at high pressure in the displacement chamber formed by the piston recess and the piston during operation of the positive displacement machine and the friction of the piston in the piston recess forces in the axial direction on the plain bearing bush. In order to prevent the sliding bearing bush from migrating out of the piston recess in the axial direction, the forces resulting from pressurization with the high pressure and the friction of the piston must be lower than those resulting from the material tension of the sliding bearing bushing holding or clamping forces acting between the plain bearing bushing and the cylinder drum provided with the piston recess and act by the press-fitting or the rolling of the plain bearing bush. In order to build sufficient holding or clamping forces without a collapse of the plain bearing bush to the central axis of the piston recess occurs, a minimum wall thickness of the plain bearing bush is required. Different materials are used for the cylinder drum and plain bearing bushing. Due to the different coefficients of thermal expansion of the cylinder barrel and arranged in the piston recess of the cylinder barrel plain bearing bush, the effect of incidence of the plain bearing bush is amplified in temperature fluctuations. In addition, the required minimum wall thickness for the plain bearing bush arranged in the piston recess leads to a reduction of the usable piston diameter and thus of the piston surface of the piston arranged in the piston recess, whereby the displacement volume of a pump or the displacement of a motor is restricted. The minimum wall thickness of the plain bearing bush arranged in the piston recess thus leads to a reduction in the power density of the hydrostatic displacement machine.

At one of the end face of the cylindrical drum and a housing-side control mirror formed sliding bearing a generic positive displacement machine, it is known to pour a sliding bearing layer of a tribologically favorable material, such as a non-ferrous metal on the front side of the cylinder drum or aufzusintern. The infusion or sintering of such a plain bearing layer However, the front of the cylinder drum causes a high production and manufacturing costs with correspondingly high costs. In addition, it is already known, at this sliding bearing between the control mirror and cylinder drum, the control mirror, which is provided with kidney-shaped control geometries for distributing the pressure medium volume flow from an inlet and outlet port in the housing to kidney-shaped control recesses in the control mirror for Kolbenausnehmungen completely from a sliding bearing material, such as a Non-ferrous metal, run and arrange this multimetal control mirror between the housing and the cylinder drum and fastened to the housing rotationally fixed. In order to allow the distribution of the pressure medium volume flow in the control recesses of the control mirror, an axial minimum thickness of the control mirror for the integration of the kidney-shaped control geometries is required. In a solid, consisting of a non-ferrous metal control mirror, in which the kidney-shaped control geometries are integrated increases by the required axial extent of the control mirror whose mass and thus the cost of the raw material of the sliding bearing material. In addition, a solid, made of non-ferrous metal control mirror leads by the required axial extent of the control mirror to an increase in the axial space of the positive displacement machine.

If a generic displacement machine is provided with sliding shoes, by means of which the pistons are supported on a thrust-generating running surface, for example a fixed or inclination adjustable swash plate, a further sliding bearing between the shoe and the tread is formed. At this sliding bearing point, it is known to solder on a front side of the shoe from a non-ferrous metal plain bearing plate. However, the soldering of such a colorful metallic board on the running surface of the shoe causes high production and manufacturing costs and thus high costs.

If the displacement machine is designed as a displacer displaceable in the displacer volume, the track is formed by a swash plate which is adjustable in the inclined position. Between the adjustable in the inclined position swash plate and a swash plate receptacle of the housing in this case a further sliding bearing is formed. It is known to arrange at the sliding bearing between the swash plate and swash plate holder of the housing consisting of a non-ferrous plain bearing shell to friction and To reduce wear between the housing and the tiltable adjustable in the inclined position swash plate. This additional plain bearing shell must be machined from all sides fitting and fixed in the swash plate receptacle of the housing, using a pin. Such additional sliding bearing shell and their fixation in the housing also causes high costs.

The present invention has for its object to provide a generic displacement machine available, which is improved in terms of attachment of the sliding bearing component and allows a lower material usage for the sliding bearing component.

This object is achieved in that the sliding bearing component is materially connected by magnetic pulse welding with one of the sliding of the sliding bearing. The sliding bearing component according to the invention by magnetic pulse welding to the sliding partner of the sliding bearing firmly bonded and thus welded. When Magnetpulsumformen a magnetic pulse is generated by the energy input several, consisting of different materials components can be welded together with little manufacturing effort, so that with low manufacturing costs of a tribologically favorable material, such as a non-ferrous metal, existing sliding bearing component with a sliding partner made of steel the plain bearing point can be connected and thus bimetallic components can be manufactured on plain bearings of a hydrostatic displacement machine with little manufacturing effort.

By magnetic pulse welding of the sliding bearing component on a sliding partner of the sliding bearing point, a flat and cohesive connection of the sliding bearing component can be achieved with the sliding at a low production cost. With magnetic pulse welding, various materials of the sliding bearing component, which allow tribologically favorable properties to reduce friction and wear, can be firmly bonded to different base materials of the sliding partner. Compared to a sintering or welding of the sliding bearing component on the sliding partner thus the production and manufacturing costs for the attachment of the sliding bearing component can be reduced. As a material of the sliding partner and thus the component of the positive displacement machine can a steel or cast material are used, on which the sliding bearing component is welded by means of magnetic pulse welding.

According to one embodiment of the invention, the sliding bearing is formed by the piston recess of the cylinder barrel and the piston as sliding partners, wherein the sliding bearing component is formed by a plain bearing bush, which is materially connected by magnetic pulse welding with the piston recess of the cylinder drum as a sliding partner. The existing example of a non-ferrous plain bearing bush is thus joined by means of magnetic pulse welding in the piston recess of the cylinder drum. By magnetic pulse welding a plain bearing bush in the piston recess of the cylinder drum as a joining process, a cohesive attachment of the plain bearing bush in the piston recess of the cylinder drum can be achieved. In magnetic pulse welding, the sliding bearing material of the sliding bearing component is welded to the material of the cylinder drum. Compared with attachment of a plain bearing bush in the piston recess by rolling or pressing the wall thickness of the plain bearing bush can be significantly reduced because the holding forces of the plain bearing bushing to avoid their emigration from the piston bore, by welding the plain bearing bushing with the cylinder barrel and not by the residual stress the plain bearing bush are generated. With the magnetic pulse welding a collapse of the plain bearing bush is still effectively avoided due to the welding of the plain bearing bush in the piston recess of the cylinder drum to the central axis of the piston recess. Furthermore, with the magnetic pulse welding, the wall thickness of the plain bearing bush with the same functionality can be reduced to a few tenths of a millimeter, preferably a maximum of 0.5 mm. By reducing the wall thickness of the plain bearing bush, the piston diameter and thus the piston area of the piston can be increased and thus the delivery or absorption volume of the positive displacement machine according to the invention can be increased. As a result, an increased power density of the positive displacement machine according to the invention can be achieved.

According to a further embodiment of the invention, the sliding bearing point is formed by a front side of the cylinder barrel and the housing as a sliding partner, wherein the sliding bearing component is formed by a circuit board, which is integrally connected by magnetic pulse welding to the cylinder barrel or the housing. Magnetic pulse welding can be a tribologically favorable material Board are added in a simple manner on the control surface forming a front side of the cylinder drum, wherein a cohesive connection or welding of the sliding bearing material is achieved with the cylinder drum. By magnetic pulse welding a tribologically favorable material existing board on the front side of the cylinder drum can with respect to a pouring or sintering of a sliding bearing layer on the front side of the cylinder drum with the same functionality a significant reduction in manufacturing and manufacturing costs for a provided with a sliding bearing layer on the frontal control surface Cylinder drum can be achieved. Alternatively, it is possible by magnetic pulse welding, with low manufacturing and manufacturing costs and low material usage of plain bearing material to attach a plain bearing layer directly to the housing cohesively and thus to weld, where the cylinder drum rests with the front side. If the plain bearing layer welded onto the housing is provided with kidney-shaped control geometries for distributing the pressure medium volume flow from an inlet and outlet port in the housing into the piston recesses, further advantages result with regard to a simple construction and a cost-effective production, since there are no pins positioning a separate control mirror and the Pins receiving bores are required. In addition, the welding of a sliding bearing layer on the housing allows the function of a non-ferrous metal control mirror to achieve a small axial space.

According to a further embodiment of the invention, wherein the support element is formed by a piston arranged on the shoe, the sliding bearing is formed by a bearing shoe designed as a support element and the raceway, wherein the sliding bearing component is formed by a circuit board, by magnetic pulse welding to the sliding shoe materially connected is. With magnetic pulse welding, a circuit board of a sliding bearing material, for example a non-ferrous metal, can be joined in a material-locking manner on a running surface of a sliding shoe, with which a piston is supported on the impact-producing raceway, with little manufacturing and production effort. Magnetic pulse welding achieves a material-locking connection and thus welding between the sliding shoe and the sliding bearing material. Favor the board of the sliding bearing material is added to the shoe blank, which can then be finished by appropriate mechanical machining. Compared to a soldering a plain bearing plate on a shoe blank can be achieved with the magnetic pulse welding according to the invention with the same functionality with respect to a reduction of friction and wear reduced manufacturing costs and manufacturing costs.

If the track is formed by a tiltable adjustable in the swash plate to achieve a variable displacement or displacement of the positive displacement machine, the sliding bearing can be formed by the swash plate and a swash plate receptacle of the housing of the positive displacement machine according to a further embodiment of the invention, wherein the Sliding bearing component is formed by a sliding bearing shell, which is integrally connected by magnetic pulse welding with the swash plate or with the swash plate receptacle of the housing. The plain bearing shell is thus connected by means of magnetic pulse welding with the swash plate or alternatively with the swash plate receptacle of the housing. By magnetic pulse welding a corresponding plain bearing shell on the swash plate or on the swash plate in the housing of the displacement machine can also be achieved with low construction and manufacturing costs a sliding bearing with a sliding bearing on the swash plate bearing, in which a low material usage of the plain bearing shell is made possible and a complex fixing a plain bearing shell in the housing by pin is no longer necessary.

The sliding bearing component may consist of a non-ferrous metal, in particular bronze or brass. Such materials are characterized by tribologically favorable properties. By magnetic pulse welding, however, other plain bearing metals that offer tribologically favorable properties can be joined to a sliding partner, which may consist of a steel material or a cast material in a simple manner cohesively and bimetallic components are produced.

The positive displacement machine according to the invention can be designed as one-stroke or multi-stroke and operated as a pump or motor.

The magnetic pulse welding of a sliding bearing component on a corresponding sliding partner of a sliding bearing can be used in a design of the positive displacement machine as a radial piston machine or as an axial piston machine. The Axial piston machine can be designed as a swash plate machine with a cylinder drum rotatably mounted about the rotation axis or as a swash plate machine with a rotatably arranged about the rotation axis track.

A method according to the invention for fastening a slide bearing component to a sliding partner of a sliding bearing of a hydrostatic displacement machine with a cylinder drum arranged about a rotation axis, which is provided with at least one piston recess, in each of which a piston is longitudinally displaceable, wherein the piston by means of a support element on a stroke-generating track is supported, and the cylinder drum is supported in the region of an end face on a housing, characterized in that the slide bearing component is integrally connected by magnetic pulse welding with the sliding of the sliding bearing. Magnetic pulse welding as a joining method according to the invention for cohesive attachment of a sliding bearing component to a component of a sliding bearing of the positive displacement machine can be used at all sliding bearings of the positive displacement machine to allow for low manufacturing and manufacturing costs and low material usage of the costly sliding bearing material reduced friction and increased wear resistance.

Figur 1

eine erfindungsgemäße Verdrängermaschine in einer Seitenansicht,

Figur 2

eine zweite Ausführungsform einer erfindungsgemäßen Verdrängermaschine in einer Seitenansicht.

Further advantages and details of the invention will be explained in more detail with reference to the embodiments illustrated in the schematic figures. This shows

FIG. 1

a displacement machine according to the invention in a side view,

FIG. 2

a second embodiment of a positive displacement machine according to the invention in a side view.

In the FIGS. 1 and 2 are hydrostatic displacement machines 1 shown. The illustrated embodiments each show an axial piston machine in swash plate design as an example of a hydrostatic displacement machine 1. Inventive displacement machines 1 can be used as axial piston in Be bent axis design or designed as a radial piston machines. The same components are provided here with the same reference numerals.

The displacement machine 1 has a cylinder drum 3 rotatably mounted about a rotation axis 2, which is provided with a plurality of piston recesses 4 arranged concentrically to the rotation axis 2, which are preferably formed by cylinder bores and in each of which a piston 5 is mounted longitudinally displaceable.

The pistons 5 are supported in the region projecting out of the cylinder drum 3 by means of a respective sliding shoe 6 as a supporting element on a thrust-producing track 7, which is formed by a swashplate 8.

The swash plate 8 may be attached to a housing 9 of the displacement machine 1 - as in FIG. 1 is shown - molded or rotationally fixed, wherein the displacement machine 1 has a fixed displacement volume.

However, it is also possible according to the FIG. 2 to arrange the swash plate 8 in a swash plate receptacle 10 of the housing 9 in the inclination adjustable, whereby the displacement machine 1 has a variable displacement volume.

The cylinder drum 3 is supported in the axial direction with an end face on a housing-side control surface 11 from. The control surface 11 is provided with kidney-shaped control recesses which allow the connection of a suction connection channel 13 and a pressure connection channel 14 in the housing 9 with the piston recesses 4.

The control surface 11 is in the FIGS. 1 and 2 formed by a control mirror 15, which according to the FIG. 1 on the housing 9, for example, a housing cover 9a of the housing 9, can be integrally formed, so that the function of the control surface 11 is integrated into the housing 9, 9a, or according to the FIG. 2 can be fixed against rotation on the housing 9 and the housing cover 9a.

The control surface 11 may, as in the FIGS. 1 and 2 be flat or spherical.

The pistons 5 are connected by means of a sliding joint formed as a ball joint 20 with the respective sliding shoe 6.

The cylindrical drum 3 is penetrated by a central bore through which a drive shaft 21 arranged concentrically to the axis of rotation 2 is guided through the cylindrical drum 3. The drive shaft 21 is rotatably supported by bearings 22, 23 in the housing 9, 9a.

The cylinder drum 3 is rotatably connected by means of a driving toothing 24 with the drive shaft 21. Also shown is a pressure spring 25, which presses the cylinder drum 3 in the axial direction of the control surface 11 and supported.

The displacement machine 1 according to the FIG. 1 or 2 is provided at several points at which a relative movement between components, with sliding bearing points where a sliding bearing component is arranged on one of the two sliding partners to reduce the friction and wear. The sliding bearing component is usually made of a multicolored metallic material.

In the FIGS. 1 and 2 is a sliding bearing G1 formed between the piston recess 4 in the cylinder drum 2 and the longitudinally displaceably arranged therein piston 5. As sliding bearing component, a plain bearing bush 30 is provided, which is joined according to the invention by magnetic pulse welding in the piston recess 4, so that the plain bearing bush 30 is materially connected to the cylinder barrel 3 and the material of the plain bearing bush 30 is welded to the cylinder barrel 3.

Another sliding bearing G2 is in the displacement machine 1 of FIGS. 1 and 2 between the control mirror 15 and in the FIGS. 1 and 2 formed on the right front side of the cylinder drum 2, which forms an end-face control surface on the cylinder drum 2. According to the invention, a disk-shaped circuit board 31 consisting of a sliding bearing material 31 is joined to the end face of the cylinder drum 2 by means of magnetic pulse welding at this sliding bearing point G2. The circuit board 31 may alternatively be bonded to the corresponding end face of the housing 9, 9a, which forms the control mirror 15, by means of magnetic pulse welding.

Another sliding bearing G3 with a sliding bearing component is in the displacement machine 1 of the FIGS. 1 and 2 formed between the support element formed by the sliding shoe 6 and the raceway 7 on the swash plate 8. On the sliding block 6, according to the invention, a circuit board 36 made of a sliding bearing material is joined to the running surface of the sliding block 6 by means of magnetic pulse welding.

In the displacement machine 1 of FIG. 2 is another sliding bearing G4 shown, is attached to the means of the magnetic pulse welding a sliding bearing component to a sliding partner of the sliding bearing G4.

In the FIG. 2 the further sliding bearing G4 is formed on the swash plate bearing between the inclination adjustable swash plate 8 and the swash plate holder 10 of the housing 9. At this sliding bearing G4 a sliding bearing shell 35 is connected as a sliding bearing component with the swash plate holder 10 of the housing 9 by means of magnetic pulse welding. Alternatively, the plain bearing shell 35 can be connected to the swash plate 8 by means of magnetic pulse welding.

Claims (11)

Hydrostatic displacement machine (1) with a about an axis of rotation (2) arranged cylinder drum (3) which is provided with at least one piston recess (4), in each of which a piston (5) is longitudinally displaceable, wherein the piston (5) by means of a Supporting element is supported on a stroke-generating track (7), and the cylinder drum (3) is supported in the region of an end face on a housing (9, 9a), wherein at least one sliding bearing (G1; G2; G3; G4) of the displacement machine (1 A plain bearing component (30, 31, 35, 36) is fastened to a sliding partner forming the sliding bearing location, characterized in that the sliding bearing component (30, 31, 35, 36) is wound by magnetic pulse welding with one of the sliding partners of the sliding bearing (G1, G2, G3 G4) is materially connected. Hydrostatic displacement machine according to claim 1, characterized in that the sliding bearing (G1) of the piston recess (4) of the cylinder drum (2) and the piston (5) is formed as sliding partners, wherein the sliding bearing component is formed by a plain bearing bush (30) by magnetic pulse welding with the piston recess (4) is integrally connected. Hydrostatic displacement machine according to claim 1 or 2, characterized in that the sliding bearing (G2) from one end face of the cylinder drum (2) and the housing (9; 9a) is formed as a sliding partner, wherein the sliding bearing component is formed by a circuit board (31), which is materially connected by magnetic pulse welding to the cylinder drum (2) or the housing (9; 9a). Hydrostatic displacement machine according to one of Claims 1 to 3, characterized in that the support element is formed by a sliding shoe (6) arranged on the piston (5) and the sliding bearing point (G3) is formed by the support element and the raceway (6) designed as sliding shoe (6). 7) is formed, wherein the sliding bearing component of a circuit board (36) is formed, which is connected by magnetic pulse welding to the sliding block (6) cohesively. Hydrostatic displacement machine according to one of Claims 1 to 4, characterized in that the track (7) is formed by a swashplate (8) which can be adjusted in the oblique position, the sliding bearing (G4) being formed by the swashplate (8) and a swashplate mount (10). the housing (9) of the displacement machine (1) is formed, wherein the sliding bearing component of a sliding bearing shell (35) is formed, which is connected by magnetic pulse welding with the swash plate (8) or with the swash plate receptacle (10) of the housing (9). Hydrostatic displacement machine according to one of claims 1 to 5, characterized in that the sliding bearing component (30; 31; 35; 36) consists of non-ferrous metal, in particular bronze or brass. Hydrostatic displacement machine according to one of claims 1 to 6, characterized in that the displacement machine (1) is formed in one stroke. Hydrostatic displacement machine according to one of claims 1 to 6, characterized in that the displacement machine (1) is designed to be multi-stroke. Hydrostatic displacement machine according to one of claims 1 to 7, characterized in that the displacement machine (1) is designed as a radial piston machine. Hydrostatic displacement machine according to one of claims 1 to 7, characterized in that the displacement machine (1) is designed as an axial piston machine. Method for fastening a sliding bearing component to a sliding partner of a sliding bearing (G1; G2; G3; G4) of a hydrostatic displacement machine (1) with a cylindrical drum (3) arranged around a rotation axis (2) and provided with at least one piston recess (4) in which in each case a piston (5) is arranged so as to be longitudinally displaceable, the piston (5) being supported on a thrust-producing track (7) by means of a support element, and the cylinder drum (3) being supported in the region of an end face on a housing (9; 9a) characterized in that the sliding bearing component (30; 31; 35; 36) is connected by magnetic pulse welding with the sliding partner of the sliding bearing (G1; G2; G3; G4).

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