DE2500779B2 - PISTON SHOE FOR A HYDROSTATIC RADIAL PISTON PUMP - Google Patents

Description

The invention relates to a piston shoe for a hydrostatic radial piston machine with an H-shaped Guide surface, which is attached to a piston guide ring divided into two guide surface parts by a groove and which are two separate hydrostatic cylinders connected to the associated cylinder Has storage pockets.

Such a piston shoe is known from DT-PS 3 02 469. The hydrostatic Bearing pockets extend in the direction of the Η web of the guide surface, i.e. parallel to the rotor axis, and from the lateral guide parts into the Η-bar of the guide surface. Such a piston shoe contributes significantly to reducing the friction between the piston shoe and piston guide ring and enables the pressure that can be achieved in hydrostatic radial piston machines to be increased. Particularly However, high pressures and high speeds could not previously be achieved with these piston shoes. If a certain high pressure range, especially at high speeds, has been exceeded, increase the leakage and the friction are disproportionately strong, the stronger the higher the pressure in the Machine rise. The efficiency of the machine decreased accordingly. The causes of this phenomenon were difficult to determine and were not recognized for a long time.

The invention is based on the knowledge that the above-described defect is not, as originally assumed, lies in the machine as such, but in a relatively small flaw in the previous one Formation of the hydrostatic bearing of the piston shoe.

In the narrow sealing gap between the guide surface of the piston shoe and the one that cooperates with it The guide surface of the piston guide ring creates "unsafe zones" in which the pressure is not computationally detectable or which changes or can change in an uncontrollable manner. In general is known to take place when pressurized fluid of greater pressure enters a gap from one end and At the other end of the gap there is a lower pressure, the pressure in the gap from the side is higher Pressure towards the side of low pressure from approximately linear or in the form of a slightly curved curve. The pressure in such a gap can therefore be expressed as the arithmetic mean of the pressures between the assume both ends of the gap or something below it. However, if the gap extends over a larger area, the pressure of the pressurized fluid can increase

ίο no longer have an effect over the entire extent of the fitting gap. Rather, pressure fluid only passes over part of the extension into the gap; at what depth and according to what law the pressure decreases difficult to determine. On average, the entry depth is a few millimeters, e.g. B. 3 to 5 mm, this depth the more precisely the surfaces lying on top of one another are machined, the less it is. As a result of the resulting "Unsafe zone" has one piston shoe less, the other more friction and leakage, even if the Piston shoes are made in the same way. Relative speeds between piston shoe and Piston guide ring, accuracy and fineness of the surface and the material used play a role also an uncontrollable and unpredictable role. In particular, there is a risk that low relative speeds, the surfaces sliding on each other due to insufficient lubrication tend to compress and at high relative speeds due to the formation of hydrodynamic support fields stand out from each other impermissibly.

The invention is based on the object of providing a piston shoe of the type identified at the outset - according to the generic term of claim 1 - to be designed so that the boundary surfaces of the hydrostatic bearing pockets at high relative speeds between the piston shoe and piston guide ring do not assume the property of undefined hydrodynamic support fields and with low relative speeds between the piston shoe and piston guide ring are not unlubricated stay.

The invention accordingly consists, according to the characterizing part of claim 1, in that the hydrostatic bearing pockets in the lateral guide parts lying outside the connecting web the H-shaped guide surface and are elongated in the circumferential direction, and that in the Areas remaining in the direction of rotation that are not occupied by the hydrostatic bearing pocket Arranged on the lateral guide parts running transversely to the direction of rotation, continuous drainage grooves iind.

The invention ensures that none of the guide parts of the piston shoe are too extensive Sealing or boundary surfaces of the hydrostatic bearing pockets arise. The sealing surfaces are shortened in such a way that even when they are in close contact with one another there is still pressure fluid in the fitting gap remains and therefore the sealing zone changes from an uncertain, unpredictable to a predictable one and technically controllable »safe zone«. Due to the elongated in the direction of rotation Training of the storage pockets can achieve the desired effect particularly reliably by a

h ¹ ) a large ratio of "safe zone" to "unsafe zone" is achieved and a more stable and operationally reliable guidance of the piston shoe can be achieved. Friction and leakage can be reduced to a minimum,

while the efficiency of the machine and its performance is increased accordingly. In particular is The invention is also of importance for high-performance, lightweight machines. For example without risk of overheating machines with 300 to 350 bar and 5000 rpm with a weight of only 11 kg and 40 to 150 kW can be operated.

The invention will be explained in more detail on the basis of the exemplary embodiments shown in the figures. In detail shows

Fig.) A longitudinal section through a radial piston machine with built-in piston shoe,

Fig.2 shows a cross section through Fig. 1 along the Section line III !,

3 shows a longitudinal section through an embodiment of a piston shoe according to the invention according to FIG. 1 and 2,

Fig.4 shows a cross section through Fig.3 along the Section line IV-IV,

Fig.5 shows a cross section through Fig.3 along the Section line V-V,

6 shows a plan view of the piston shoe according to FIG. 3,

7 shows a longitudinal section through a piston guide ring with a piston shoe inserted in the same,

8 shows a longitudinal section through a rotor part known per se, which is used to hold a piston and a piston shoe is formed, and

F i g. 9 shows a longitudinal section through another embodiment of a piston guide ring.

In the embodiment of a radial piston machine according to FIGS. 1 and 2 with the fluid flow through »working chambers formed by the cylinder 38 is the rotor 9 by means of bearings 18 in the Housing 14 rotatably mounted. In cylinders 38 the pistons 8 run radially outwards and inwards in a known manner, whereby they are connected via ports 16, 17, Control orifices 89, 90 and rotor ducts 87, optionally via a control plate 88 and a control body 15, take in fluid and release it again to the outside. The pistons 8 are, as is also known, with Provided piston shoe beds in which pivot joint parts 22 of the piston shoes 7 are pivotably mounted or are pivotally connected to the piston. The piston pivot joints taper radially outwards to narrow piston shoe necks 25 (Fig. 4), each in pass over a piston shoe central part 21, which in turn runs parallel to the axis of the rotor 9 and is narrower than the rotor slot 91 into which it enters when the rotor rotates. At its ends carries the piston shoe, which is H-shaped in plan, the guide parts 6, which are perpendicular to the rotor axis and extend perpendicular to the piston shoe central part 21, that is, parallel to the guide surface 10 of the piston guide ring 12 run against which they rest and from which they are guided to execute the piston stroke.

Between its guide parts 6, the piston shoe 7 is corresponding to its H-shaped design divided by slot-like recesses 63 into which t> o the rotor webs 13 enter between the rotor transverse slots 91 as the rotor 9 rotates. The piston guide ring 12, which can be mounted stationary or rotating, can have an uninterrupted guide surface on the inside 34 of a guide part 35 (FIG. 9) or two guide t> -> surfaces 33 (Fig. 1, 2, 7), which by a in the Piston guide ring 12 protruding annular groove 19 are separated from one another. In order to achieve a maximum long piston stroke, it is essential that the piston shoe 7 with slot-shaped recesses 63 is provided so that the piston shoe with its radially outermost parts on the rotor webs J3 can pass into the rotor transverse slot 91. The guidance of the piston 8 also serves to enable a long piston stroke which is arranged on the rotor webs 13 and delimits the rotor transverse slots 91 Piston guides 92 (Figs. 1, 2, 8).

As in particular from FIG. 6, the hydrostatic bearings of the piston shoe 7 are essentially formed by two storage pockets 2, which are in the longitudinal direction of the piston shoe guide parts 6, so in the circumferential direction of the rotor, and extend through channels 24 with the associated, as a working chamber serving cylinder 38 are connected. The hydrostatic bearing pockets are arranged in such a way that their center lines related to the longitudinal extent of the pockets each from the axially inner delimiting edge of the guide part 6 has a distance 31 which is less than its distance 30 from the outer edge of the guide part 6 is. With a width 28 of the storage pocket 2, the distance 27 of the same from the Inner edge of the guide part smaller than the distance 29 of the bearing pocket from the outer edge of the guide part. This unequal dimensioning of the distances 31 and 30 or 27 and 29 is achieved that also with Deformation of the piston shoe under the pressures of the pressure fluid an equal penetration of the same into the Sealing gap can be guaranteed.

Furthermore, the surface elements of the guide surfaces in the guide parts 6 of the piston shoe are small to keep and to prevent gap widening, in particular through the formation of hydrodynamic support fields, are in the direction of rotation of the piston shoe outside of each end of the bearing pockets 2 one or a plurality of continuous drainage grooves 1 or 3 running transversely to the direction of rotation are provided. It As a result, outside the longitudinal extension 97 of the bearing pockets 2 in the circumferential direction, only short ones arise Guide surfaces 4 and 5, which means that these bearing surfaces rest securely on the guide surfaces 33 and 34, respectively of the piston guide ring 12 guaranteed. The risk of the formation of hydrodynamic support fields, in particular at the tips of the guide parts 6 is practically eliminated. This can also be done also contribute to the fact that the guide surface parts 4 and 5 are made narrower than the guide parts 6. A further advantage is such a design of the storage pockets 2 that they only have a length 96 of parallel Edges are limited and on these edges up to a total longitudinal extension 97 of the storage pocket semicircular delimiting edges with a radius of half the dimension of the width 28 of the storage pocket connect. Such a design of the storage pockets is particularly easy to manufacture. But it is also possible simple rectangular or other cross-sectional shapes for the bearing pockets of the hydrostatic Provide storage.

If one assumes that, as studies have shown, the pressure fluid depends on the pressure and speed about 1 to 5 mm deep into the gap between the guide surfaces of the piston shoe that lie against one another 7 and the piston guide ring 12 penetrates, the width of the web-like guide surface elements is preferably 4 and 5 are approximately 1 to 6 mm in size. The dimension of the sealing surface thickness is the most appropriate 1 to 8 mm, but 1 to 4 mm are usually sufficient. In

It can also be less than 1 mm for particularly compact units. For areas of more than 4 mm Expansion (sealing surface thickness or web thickness) there is already a risk of overheating because under Under certain circumstances, the mentioned inlet flow no longer penetrates deep enough into the sealing gap. This danger is the greater, the higher the relative speed between the guide surfaces that slide closely together is.

For this purpose 3 sheets of drawings

Claims (2)

Patent claims: 1. Piston shoe for a hydrostatic radial piston machine with an H-shaped guide surface, which rests on a piston guide ring divided into two guide surface parts by a groove and which are two separate hydrostatic cylinders connected to the associated cylinder Having storage pockets, characterized in that that the hydrostatic bearing pockets (2) in the outside of the connecting web (21) lying lateral guide parts (6) of the H-shaped guide surface (20) are located and in Circulation direction are elongated, and that in the remaining in the direction of rotation, not from the hydrostatic bearing pocket occupied surfaces on the lateral guide parts (6) transversely to To! Upright running, continuous drainage grooves are arranged. 2. piston shoe according to claim!, Characterized in that in each of the two end parts the two lateral guide parts (6) two drainage grooves (1,3) are arranged.