EP0300274A1 - Axial-pistons machine with differential pistons - Google Patents

Abstract

An axial piston machine, the pistons of which are designed as stepped pistons and delimit a first cylinder space (27) and a second cylinder space (29), the pistons being driven on the drive side by an axially displaceable drive surface (13) on which they slide in a slide bearing with a pressure pocket, which is connected to the first cylinder chamber by a channel, is to be designed in such a way that the slide bearing is relieved depending on the respective operating state of the axial piston machine (1). This is achieved in that the second cylinder chamber (29) is connected to a second pressure pocket (55) on one of the two sliding surfaces (35, 36) by a second channel (53) separate from the first channel (52).

Description

The invention relates to an axial piston machine according to the preamble of claim 1.

It has been proposed, for various reasons, to design the at least one piston of an axial piston machine as a stepped piston, which results in two cylinder spaces. The cylinder rooms can be connected to two separate flow lines to e.g. to achieve a throughput distribution, cf. US Pat. No. 3,126,835, or one of the two cylinder spaces, can also only serve to press the piston or pistons against an existing drive inclined surface or an optionally existing cylinder drum against the control mirror, cf. DE-PS 707 462.

To improve the sliding bearing between the piston and the drive surface, it is known to create a fluid cushion, fed by the associated cylinder space, such as a pressure pocket between the sliding surfaces, which reduces the surface pressure and thus the friction and closure of the piston-side sliding surface and the drive surface of the sliding bearing, ie , brings about a certain relief of the plain bearing.

The invention has for its object to design an axial piston machine with step piston of the type mentioned in such a way that the relief of the plain bearing depending on the respective operating state of the axial piston machine.

This object is achieved by the characterizing features of claim 1.

The invention is based on the knowledge that, in the known embodiment, a hydrostatic mounting of the pistons on the drive surface due to the fluid cushion as a function of the respective load, i.e. of the axial force with which the piston is pressed against the drive surface is not possible because the pressure force component, which is dependent on the pressure in the second cylinder chamber, is not taken into account. However, both the pressure in the first cylinder chamber and that in the second cylinder chamber can change for various reasons, e.g. in an axial piston machine with two throughput circuits due to different power consumption of the connected consumers.

In the embodiment according to the invention, the drive-side slide bearing of the piston is provided with a second hydrostatic bearing which is independent of the first hydrostatic bearing and which is connected to the second cylinder chamber by a channel and which is therefore effective as a function of the pressure in the second cylinder chamber. The piston forces actually present are thus taken into account to relieve the sliding bearing, which leads to a more balanced hydrostatic bearing of the piston.

There are pressure pockets for three- or multi-stage pistons to be provided in the appropriate number, ie a pressure pocket with a separate connecting duct leading to the associated pressure chamber is to be arranged for each cylinder chamber of the piston.

In the context of the invention, it is possible to form the hydrostatic bearings according to the invention on the flat sliding surfaces between a swash plate and a sliding shoe receiving the piston head and / or between the surface of a spherical piston head and the spherical inner surface of a bearing shell or spherical cap receiving the latter.

The features contained in claims 2 to 11 lead to simple and practical design, which enable simple and inexpensive production and ensure good function.

• Fig. 1 eine erfindungsgemäß ausgestaltete Axialkolben­maschine im axialen Schnitt;
• Fig. 2 die Kolbenanordnung der Axialkolbenmaschine im axialen Schnitt und in vergrößerter Darstel­lung;
• Fig. 3 die Gleitfläche eines Gleitschuhs für die Kolbenlagerung in der Draufsicht.

The invention is explained in more detail below on the basis of a preferred exemplary embodiment illustrated in a drawing. It shows:

• 1 shows an axial piston machine designed according to the invention in axial section;
• Figure 2 shows the piston arrangement of the axial piston machine in axial section and in an enlarged view.
• Fig. 3 shows the sliding surface of a sliding shoe for the piston bearing in the plan view.

The essential individual parts of the axial piston machine, generally designated 1 in FIG. 1, are a housing 4 consisting of a cup-shaped housing part 2 and a housing cover 3, and the cup-shaped housing part 2 or the cavity 5 of the housing 4 passing through the central axis 6 and in the radial wall 7 of the housing part 2 and in the housing cover 3, the drive shaft 8, a cylinder 9 with a plurality of diametrically opposed or star-shaped arranged essentially axially extending piston bores 11, in which correspondingly sized pistons 12 are slidably mounted, which can be driven by an axially displaceable sliding surface 13.

In the present exemplary embodiment, the cylinder 9 is formed by a cylinder drum, which is arranged on the drive shaft 8 by means of a central hole and is non-rotatably connected to it by a toothed coupling 14, and, with its end face 15 facing away from the sliding surface 13, bears against a control mirror 16 which bears against a control plate 17 is formed, which is fastened by screws or centering pins to the housing cover 4, in which two supply and discharge lines 18, 19, 21, 22 for the fluid, in the present case oil, are formed. In the control plate 17 there are two pairs of opposing, kidney-shaped control channels 23, 24, which correspond to axial flow channels 25, 26, which are connected to the piston bores 11 and the supply and discharge lines 18, 19, 21, 22.

The piston bores 11 and piston 12 are step bores and correspondingly dimensioned step pistons, as a result of which first cylinder spaces 27, which are delimited by the end face 28 of the pistons 12, and second cylinder spaces 29, which are delimited by the step surfaces 30 of the pistons 12, are formed are, in each case in the first cylinder space 27, the throughput channel 25 and in the second cylinder space 29, the second throughput channel 26 arranged radially inward from the first throughput channel 25.

The pistons 12 have spherical piston heads 32 at their drive-side ends, which are pivotally supported on all sides in the piston heads 32 above and behind-reaching calottes 33 of slide shoes 34. The sliding shoes 34 lie with flat sliding surfaces 35 on the flat inclined surface 36 of a swash plate 37, which is fitted on its drive side with a sliding ring 38 made of wear-resistant material, and whose angle w, which it encloses with a radial transverse plane of the axial piston machine, for the purpose of changing the Throughput volume of the axial piston machine 1 can be changed arbitrarily. On their side facing the cylinder 9, the sliding shoes 34 have shoulders 39 and, with a projection 41 containing the spherical caps 33, they pass through a retraction plate 42 in holes 43, the shoulders 39 abutting the retraction plate 42, both axially by means of a spherical support head can also be supported radially, which can be acted upon axially against the inclined surface 36 by means of a compression spring (not shown). 3 shows the swash plate 37 which can be pivoted for the purpose of changing the throughput volume, for reasons of simplification, at right angles to the central axis 6, i.e. Throughput volume = 0 or minimal.

Between the sliding surface 35 of the sliding block 34 and the sloping surface 36 of the swash plate 37, hydrostatic bearings, generally designated 49 and 51, are formed, in which fluid or oil cushions in communication with the cylinder spaces 27, 29 are connected by recesses through channels 52, 53 formed first and second pressure pockets 54, 55 are effective, which act on the associated piston 12 as a function of the existing pressure in the cylinder spaces 27, 29 against the piston force shown as arrow 58, in order to significantly reduce the latter and thus in the Bearings 49, 51 to reduce the resulting friction. When the piston 12 is supported by means of a sliding block 34 with the inclination angle of the inclined surface 36 remaining the same, it is possible to create a balance between the piston force 58 and the resulting counterforce 59 of the bearings 49, 51. The balanced storage is possible because the pressure pockets 54, 55 are dimensioned correspondingly large in their axially effective size.

In the context of the invention it is possible to arrange third and fourth pressure pockets 56, 57 in at least one of the spherical sliding surfaces 46, 47, which form hydrostatic bearings for the piston joint 48 due to a corresponding connection with the cylinder spaces 27, 29.

The first channel 52 starting from the first cylinder space 27 and the associated first and third pressure pockets 54, 56 and the second channel 53 starting from the second cylinder space 29 and the associated second and fourth pressure pockets 55, 57 form separate pressure systems which pass through the sliding surfaces 35, 36, 46, 47 are separated from each other. As a result, the pressure in the associated cylinder space 27 or 29 can only affect the associated hydrostatic pads.

In the present exemplary embodiment, a sleeve 61 is inserted axially into each central piston 12 in a central longitudinal bore 62 and fastened to it, for example by pressing, gluing, pinning or screwing, the sleeve 61 having an axial passage through which the swash plate 37 faces away from it Throttle 63 arranged at the end and a channel section 69 (bore) enlarged in cross section compared to the latter. At its end facing the piston head 32, the sleeve 61 automatically forms the third pressure pocket 56 due to the lack of a spherical shape of its end face.

The first channel 52 consists of a section of the longitudinal bore 62, the throttle 63, the channel section 69, the first and the third pressure pockets 54, 56 and a channel section 65 connecting the latter to one another in the sliding block 34.

The second channel 53 consists of a radial channel section 66 in the piston 12 in the vicinity of its stepped surface 30, a circumferential groove 67 or taper on the sleeve 61, a channel section 68 and, in the present case, extending radially from the circumferential groove 67 to the fourth pressure pocket 57 in the form of a spherical zone a channel section 70 connecting the pressure pockets 55, 57 to one another, in the present case oblique.

In the present exemplary embodiment, the third and fourth pressure pockets 56 and 57 are located in the spherical surface 47 of the piston head 32 and the first and second pressure pockets 54 and 55 are located in the sliding surface 35 of the sliding block 34. However, it is also possible to place the pressure pockets in the to form the corresponding sliding surface. The circumferential groove 67 or the distance between the channel sections 66 and 68 is dimensioned smaller than the length 1 of the sleeve 61, so that the latter has sections at its ends with which it is fully and firmly received in the longitudinal bore 62.

The function of the axial piston machine 1 is generally known, and a functional description is therefore omitted. In summary, it should be noted that due to the more balanced piston forces 58 and counter forces 59 a low-friction and therefore long-lasting bearing of the sliding shoes 34 on the swash plate 37 and the piston heads 32 is achieved, depending on the respective pressure in the cylinder spaces 27, 29, ie depending on the power to be applied by the axial piston machine 1.

In the present exemplary embodiment, the first pressure pocket 54 has a circular shape and the second pressure pocket 55 has a circular ring shape, wherein they are arranged concentrically to one another. In order to improve the separation or sealing of the pressure pockets 54, 55 from one another, in the present exemplary embodiment an annular groove 71 is arranged between them, each at a distance from them, which is connected to the cavity 5 of the housing 4 by a channel 72 extending through the sliding block 34, ie is vented.

Claims (12)

1. axial piston machine (1), the pistons (12) of which are designed as stepped pistons and delimit a first cylinder chamber (27) and at least one second cylinder chamber (29), the pistons (12) being driven on the drive side by an axially displaceable drive surface (13) , on which they slide in a slide bearing with a pressure pocket (54, 56) which is connected to the first cylinder space (27) by a channel (52, 63, 65),
characterized,
that the second cylinder chamber (29) is connected by a second channel (53) separate from the first channel (52) to a second pressure pocket (55, 57) on one of the two sliding surfaces (35, 36, 46, 47) of the sliding bearing. 2. axial piston machine according to claim 1,
characterized,
that the first and second pressure pockets (54, 55) are formed in the sliding surface (35) of a sliding block (34). 3. axial piston machine according to claim 1 or 2,
characterized,
that the first and second channels (52, 53) run at least on a longitudinal section of the piston (12) longitudinally through the piston (12). 4. axial piston machine according to claim 3,
characterized,
that the channels (52, 53) run coaxially to one another. 5. axial piston machine according to claim 3 or 4,
characterized,
that the first and / or second channel (52, 53) runs in a sleeve (61) inserted into the piston (12) or is limited by the latter. 6. axial piston machine according to claim 5,
characterized,
that the second channel (53) in the region of the longitudinal section of the piston (12) is formed by a recess (67) like a groove, in particular an annular groove on the peripheral surface of the sleeve (61). 7. axial piston machine according to claim 5 or 6,
characterized,
that the recess (67) on the circumferential surface of the sleeve (61) through a transverse channel (66) which preferably extends in the vicinity of the step surface (30) and / or through a transverse channel (68) extending in the region of the piston head - (32) with the second cylinder space (29) and / or with the second pressure pocket - (55). 8. Axial piston machine according to claim 7, characterized in that the transverse channel (66 and / or 68) is formed or designed as a throttle, or that a throttle is used in the transverse channel (66 and / or 68). 9. axial piston machine according to one of claims 1 to 8,
characterized,
that the piston (12) has a spherical piston head (32) which is pivotally mounted in a spherical cap (33) of a swash plate (37) or a slide shoe (34) slidably supported thereon, and the first and second pressure pockets or a third and a fourth pressure pocket (56, 57) is arranged in at least one of the two spherical sliding surfaces (35, 36) of the piston joint (48), preferably in the spherical sliding surface (47) of the piston head (32). 10. axial piston machine according to one of claims 1 to 9,
characterized,
that the second or fourth pressure pocket (55, 57) is arranged concentrically to the first or third pressure pocket (54, 56), preferably surrounds the latter in a ring. 11. axial piston machine according to claim 10,
characterized,
that between the first and the second pressure pocket (54,55,56,57) a, preferably annular recess (71) is provided in one of the sliding surfaces, preferably in that of the sliding shoe (34), which through a channel (72) with the Cavity (5) of the housing is connected. 12. Axial piston machine according to one of claims 3 to 11,
characterized,
that a throttle (63) on the sleeve (61) is preferably formed or inserted into the sleeve (61) at the end of the sleeve (61) facing away from the swash plate (37).

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