DE2206000C2 - Hydrostatic machine ston slide shoe - has narrow, straight, transverse sealing rib enclosing recess in movement direction - Google Patents

Abstract

The slide shoe for the piston of a hydrostatic radial piston machine is hinged to its respective piston. In its sliding surface is a closed recess supplied with the working medium under pressure and enclosed by a sealing rib, round which is a groove with open ends at right angles to the direction of movement. Hydro-dynamic supporting faces are formed in the end portion in the travel direction of the sliding surface. The portion of the sealing rib enclosing the recess (10) in the direction of movement runs straight and at right angles to the latter. The rib is very narrow in relation to the extension of the hydrodynamic supporting face in the direction of movement (14), and also to the area of the recess.PS.

Description

The invention relates to a slide shoe for the pistons of a hydrostatic piston machine the preamble of claim 1.

From DE-OS 19 36 431 a sliding shoe is known in which a channel opens in the middle of the sliding surface, which is connected by grooves with a recess concentric to the mouth in the sliding surface, which the It is used to build up a hydrostatic relief pressure field. This recess is of an annular shape Surrounding sealing ridge, which in turn surrounds an annular groove that intersects the long sides of the sliding block. Grooves extending from the center of the narrow side and running parallel to the longitudinal axis open into the annular groove. This creates approximately triangular support surfaces at the corners of the sliding block. These increase the load-bearing capacity of the sliding shoe, especially in depressurized operation, due to hydrodynamically generated pressure fields between the support surfaces and their bearing surface. The pressure medium for the formation of these pressure fields is fed back to the interior of the housing through the annular groove. However, such a sliding shoe has the disadvantage that under certain operating conditions that of the lubrication of the moving parts is used, im Working medium located inside the housing is sucked out of the housing interior and through the channel, the connects the recess in the sliding surface of the sliding shoe with the cylinder bore, to the outside with the Useful electricity is conveyed away. This phenomenon occurs especially when the machine is depressurized Operation at high speeds is to be explained in such a way that it is about the hydrodynamically effective Areas of the sliding surface build up pressure fields, some of which are in contact with the cylinder bore standing recess in the sliding surface are reduced if the pressure in this is lower than in the Pressure field. The consequence of this is that the lubrication conditions deteriorate and, as a result, damage, in particular on the sliding shoes.

This is due to the circular shape of the sealing ridge and its large ridge width, as this is in Area of the longitudinal sides of the sliding shoe has such an extent in the direction of movement that a can form hydrodynamic pressure field and the consequences described above occur.

The object of the invention is to create a sliding shoe which, in addition to good running properties, is particularly good the suction of the pressure medium from the interior of the housing to the outside, d. H. to the consumer outlet prevented.

This problem is solved by the features listed in the characterizing part of the main claim

The design according to the invention has the advantage that there is no hydrodynamic on the narrow sealing web Can build up pressure field, could reach the recess via the pressure medium and that of the hydrodynamic pressure fields lying outside the grooves no pressure medium into the recess flows.

Advantageous developments of the subject matter of the invention emerge from the subclaims.

Embodiments of the invention are shown in the drawing. This shows in

Fig. La and Ib a sliding shoe in section and in Top view, shown in use in a radial piston machine,

F i g. 2 and 3 modifications of the slide shoe according to FIGS. 1 a and 1 am a plan view.

The sliding shoe 1 has a shaft 2, which is in a Foot 3 passes. A ball head 4 is located on the shaft 2

♦ 5 arranged, through which the sliding shoe 1 with a Piston 5 is articulated, which is sealed in a cylinder bore 6 of a cylinder body 7 The sliding shoe rests with a sliding surface 8 on a counter-sliding surface 9 'of a Guide member 9 on. The sliding surface is approximately - seen from below - rectangular, d. H. she has two parallel side edges and a slightly rounded front and rear edge that point in the direction of movement of the sliding shoe. In this sliding surface there is a closed, approximately triangular recess 10 arranged, the shape of which is determined by a narrow sealing web 11 surrounding it. One side of the Recess 10, which is delimited by section 11 'of the sealing web and in the direction of movement is in front, forms a straight line and forms an angle of 90 ° with the direction of movement. The Sealing webs surround narrow grooves 12, 13 on the outside, which open into the interior of the housing. At the front end of the Slide shoe, a remaining surface of the slide surface forms a support surface 14, at the rear end forms such Remaining surface a support surface 15. A longitudinal bore 16 penetrating the shaft 2 opens into the Recess 10 and connects them via a longitudinal drilling

tion 17 in the piston with the cylinder bore 6.

When the machine is in operation, the cylinder body 7 executes a rotary movement, as a result of which the sliding shoe executes a sliding movement in the direction of the arrow Build up a hydrostatic pressure field in the area of the recess 10, the size of which is determined by the Grooves 12, 13 opening into the housing are precisely defined. In the area of surfaces 14, 15 are formed hydrodynamic pressure fields that increase the load-bearing capacity of the sliding shoe, especially when it is not under pressure Operation come into effect. The grooves 12, 13 now prevent the pressure fields in the area of the Recess 10 are dragged, which prevents the outflow of pressure medium from the interior of the housing to the cylinder bore and result in the pump outlet. Rather, the pressure medium flows through the grooves 12, 13 to From the inside of the housing.

The fact that the surface 15 is narrowed up to the point Jes slightly behind the middle of the glide shoe Gap between sliding sole 8 and guide surface 9 'is also a tilting movement of the sliding shoe counteracted

The sealing strip 11 ', which delimits the recess 10 at the front and runs transversely to the direction of movement, has in the direction of movement such a small width that there is practically no hydrodynamic pressure field above it build up and thus no pressure medium can flow away. The recess 10 in the area of decreasing Sections of the sealing web 11 that limit the width have a larger one extending in the direction of movement Extent than the section 1Γ. As far as this measure is sufficient to build up a hydrodynamic pressure field, the pressure medium required for this is essentially taken from the recess 10 to which of the Cylinder bore 6 can flow at any time pressure medium.

The sliding shoe 10 according to the example of FIG. 2 is a modification of the sliding shoe according to FIG F i g. 1 and differs from this by a differently designed recess.

The sliding shoe 20 has a sliding surface 21 in which a trapezoidal recess 22 is arranged, which is surrounded by a narrow sealing web 23 The large base 23 'of the trapezoid closes with the Direction of movement parallel to the long side of the sliding block forms a right angle and, viewed in the direction of movement, lies in front.

The sealing web 23 is surrounded by grooves 24, 25 which open into the interior of the housing. At the front end of the The sliding surface is a sliding surface 26, and a sliding surface 27 is formed at the rear end. The rest of the structure corresponds to that of the exemplary embodiment according to FIG. 1. The operating behavior of the sliding shoe 20 also corresponds to the sliding shoe according to FIG. 1.

The sliding shoe 30 according to the embodiment of FIG. 3 is a further modification of the exemplary embodiment according to FIG. 1. The sliding shoe has a sliding surface 31 in which a circular segment-shaped recess 32 is formed, which is surrounded by a narrow sealing web 33. The tendon 33 'of the circular segment, which is in the front when viewed in the direction of movement, forms a right angle with the longitudinal side of the sliding shoe, which is parallel to the direction of movement.
The segment of the circle can be a semicircle, so the chord can be a diameter of the circle. The sealing web 33 is surrounded by grooves 34, 35 on the outside, which open into the interior of the housing. A sliding surface 36 is formed at the front end of the sliding sole 31 and a sliding surface 37 is formed at the rear end. The rest of the construction of the sliding shoe corresponds to the embodiment according to FIG. 1, and the operating behavior also corresponds to that of the sliding shoe according to FIG. 1.

1 sheet of drawings

Claims (4)

Patent claims: 1. Slide shoe for the pistons of a hydrostatic piston machine, especially radial piston machine, which is articulated to the associated piston and in its sliding surface one in itself closed, pressurized by the working medium recess is arranged by a Sealing web is enclosed and surrounded by an adjoining groove which leads to the Sides transversely to the direction of movement of the sliding shoe expires openly and in the case of the in the direction of movement located frontal area of the sliding surface formed hydrodynamically acting support surfaces are characterized in that a) of the recess (10,22,32) in the direction of movement delimiting part of the sealing web approximately in a straight line transversely to the direction of movement of the Sliding shoe runs, b) the sealing web both in relation to the extent measured in the direction of movement the hydrodynamically acting support surface (14, 26, 36) as well as in relation to the surface of the Recess is very narrow. 2. Sliding shoe according to claim 1, characterized in that the recess has the shape of a to Direction of movement has approximately symmetrically arranged triangle, one side of which with this one includes a right angle and which, viewed in the direction of movement, is in front. 3. Sliding shoe according to claim 1, characterized in that the recess (22) has the shape of a Has trapezoid, the large base side (23 ') of which, viewed in the direction of movement, lies in front and with this includes a right angle. 4. sliding shoe according to claim 1, characterized in that the recess (32) has the shape of a Has a segment of a circle whose tendon (33 '), viewed in the direction of movement, lies in front and with this includes a right angle.