DE2037760A1 - Axial piston pump or motor - Google Patents

Description

2037760 Dipl.-Ing. H. Sauenland ■ Dr.-lng. R. King

¹ ^ ^α . .,. -.'-. Bergen ⁵ ^ ^ö

Patent Attorneys · 4000 Düsseldorf · Cecitienallee 76 · Telephone 43Ξ7as

Our file: 26 012 July 29, 1970

Mitsubishi Jukogyo Kabushiki Kaisha, 10, Marunouchi 2-chome, Chiyoda-ku, Tokyo , Japan

"Axial piston pump or motor"

The invention relates to an axial piston pump or a corresponding motor, in particular to a support for axial piston pumps or motors with axially displaceable in a cylinder block at the free ends Piston arranged sliding shoes and one of these with a with respect to a shaft connected to the cylinder block, angle-adjustable swash plate holding in sliding contact and a retaining ring mounted on a spherical pressure piece. In particular, the invention relates to application such a retaining ring for an adjustable axial piston pump or motor, the adjustment being carried out by corresponding change in inclination of the swash plate is achieved. ™

An axial piston pump designed in this way and having a variable delivery rate is shown in FIG. 1. The pump has a rotating shaft 01, a cylinder block 02 fixedly arranged on the shaft and one opposite of the shaft 01 in different angular positions adjustable swash plate 03. At a distance from the shaft 01 a plurality of axially extending cylinders 04 are arranged in the cylinder block 02, in which a corresponding number is axially slidably supported by piston 05.

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Each piston 05 is connected at its end facing the swash plate 03 via a ball joint 06 to a sliding shoe 07, which is held in sliding contact with the surface of the swash plate 03 by a conventional retaining ring 08. Therefore, when the cylinder block rotates 02, walk the bearings in the cylinders 04 piston 05 back and forth and thus create suction and a discharge liquid, the retaining ring 08 serves ₉ the shoes 07 to press against the swash plate 03, as the shoes themselves would otherwise detach from the swash plate, due to the inertia of the reciprocating pistons 05 and the sliding shoes 07 as well as the centrifugal force of the sliding shoes 07 »

In order to achieve the desired contact between the sliding blocks and the swash plate, according to the embodiment shown in FIG spherical pressure piece 010 arranged, the © inem spherical Seat 09 is adapted in the middle part of the retaining ring 08 and by a spring 011 against the swash plate 03 is pressed.

Since the spherical pressure piece 010 and the retaining ring 08 relative drelien to the fixed swash plate 03 ^ performs the ring 08 _f as shown in FIG. 2 emerges ₉ over a range of an angle θ of dpppeltan angle of inclination of the Schiefsclieibe 03 corresponds ,, © Ine wobble .

The above-described conventional support ring for the retaining ring has a Rein® from Ma © ht @ Il © mo So _{9 is} when the rotational speed of the shaft 01! Constant; _{9 is} the inertia of the piston 05 and the ßl @ ± tisetajla @ © 7 proportional to the stroke of the piston 05 «Ia a © F Bairo © sit variable delivery rate © gb @ i der si ^ Si d®%> Mb etes? Pistons

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05 changes with the change in the angle of the swash plate 03, is thus the inertial force of the piston 05 and the sliding blocks 07 is greatest when the swash plate 03 assumes its maximum angle of inclination. Accordingly, it is necessary to hold the holding ring 08 pressed against the swash plate 03 with a force that is greater than the inertial force of the swash plate in its maximum inclination, in cases where such is adjustable Pump is used to drive a steering system, is often worked with a zero angle of inclination at which the piston do not perform a stroke. However, this means that the retaining ring 08 against the swash plate 03 with such Force remains pressed, which corresponds to the force at the maximum angle of inclination of the swash plate at which the piston perform a maximum stroke. This has a very detrimental effect on the mechanical efficiency of the Pump and the service life of the parts sliding on each other.

For this reason, it is desirable that the force pressing the retaining ring against the swash plate should be automatic changes with the inclination angle of the swash plate or the stroke of the pistons.

It should be noted that the resulting force of the from the reversing movement of the pistons 05 and "of the slide shoes 07 resulting inertia force and from the The centrifugal force resulting from the rotation of the sliding shoes 07 acts on the swash plate 03 in such a way as that from FIG. 3 emerges. This is the case because on the side where the individual pistons reach their top dead center, a separating force and on the opposite side, where the individual pistons reach their bottom dead center, a pressure contact force acts. These forces for separation and pressure contact increase with increasing

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increasing angle of inclination of the swashplate, consequently the point of application of the force for lifting or separating moves the sliding shoes gradually move from the swash plate to the side on which the inclination angle of the swash plate increases the pistons reach their top dead center.

It follows that in a conventional support bearing for the retaining ring, in which this over its middle Part independently of a change in the angle of the swash plate or the point of application of the separating force against the swash plate is pressed, the point of application of the separating force and the contact point of the retaining ring on the Swashplate (or the center of the shaft) are far apart when the tilt angle of the swashplate is large and thus the pressing force of the retaining ring 08 must be increased considerably. However, this is in the With regard to a long service life of the sliding parts of the retaining ring 08 and the spherical pressure piece 010, this is not the case he wishes.

The object on which the invention is based is therefore to provide a support for the retaining ring of an axial piston pump or to create a motor that does not have the disadvantages of the known devices, rather has a high mechanical efficiency with a long service life. This object is achieved according to the invention by an element sliding axially on the shaft and against the swash plate by at least one elastic element pressable annular slide on which the spherical pressure piece is axially slidably mounted and under action an elastic auxiliary element arranged between this and a slide in such a manner in a spherical seat of the retaining ring is arranged that when the angle of inclination of the swash plate is exceeded over a certain The value of the retaining ring with the Uia catch edge of the slider

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comes into contact with a point that is remote from the pivot point of the retaining ring on the side on which the pistons assume their top dead center.

The known devices and the device according to the invention are illustrated in the drawings with reference to FIG Embodiments described in more detail below. Show it:

1 shows a longitudinal section through the essential parts of an axial piston pump with a conventional support for the retaining ring,

FIG. 2 shows an enlarged illustration of the retaining ring according to FIG. 1,

3 shows a basic diagram of the separating force and the pressure contact force of the pistons and the sliding shoes on the surface of the swash plate,

4 shows a longitudinal section through the essential parts of an axial piston pump having a variable delivery rate with a retaining ring support according to the invention,

FIG. 5 shows a side view of a cylinder block along the line VV of FIG. 4,

6 to 8 partial longitudinal sections of the retaining ring support according to the invention along the line VI-VI of FIG. 5 with the retaining ring and the slide at different angles of inclination of the swash plate,

9 shows a graphical representation of the relationship in the displacement of the center point of the separating force and the support point of the retaining ring with respect to the angle of inclination of the swash plate and

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10 is a graph showing the relationship between the separating force or pressure contact force of the retaining ring and the inclination angle of the swash plate.

In FIGS. 4 to 8, 1 denotes a shaft which is driven by an electric motor, not shown will. A cylinder block 2 is attached to the shaft 1 by means of a keyway profile 3, in which a row (in Embodiment 9) axially extending cylinders 4 are arranged, in an angularly offset position around the Wave 1 around. Pistons 5 are slidably mounted in the cylinders 4.

A pivoting body 6 is held by an unillustrated pump housing _S is held by the pivot member 6 while a swash plate 7 ", by pivoting of the pivoting body 6 relative to the shaft 1 of the tilt angle θ of the slant plate can be adjusted.

Sliding shoes θ are each aa one end of the piston 5 over Ball joints 9 attached and held in sliding contact with the swash plate 7 by means of a retaining ring 10. at One revolution of the cylinder block 2, the pistons are reciprocating in the axial direction in their cylinders 4 driven »On the shaft 1» an annular slide 11 is slidably supported by compression springs 12 is pressed against the swash plate 7. The compression springs are between the slide 11 and the cylinder block 2 arranged. When the angle of inclination Θ of the swash plate 7 has exceeded a certain value, the slide comes 11 at a point P in the area of its peripheral edge 13 with the retaining ring 10 in contact and presses the retaining ring 10 against the swashplate »In this case it rotates Slide 11 together with the shaft 1 and the retaining ring 10

wobbles through an angle twice as large as the inclination angle θ of the swash plate while it rotates over the sliding blocks 8 at the same speed as the shaft 1. The retaining ring 10 runs through touch contact at point P of the peripheral edge

13 with the slide 11, similar to when bevel gears in Are engaged, the point P moving over the circumference of the retaining ring 10 or the edge 13.

A spherical pressure piece 14 is slidably mounted on the hub 15 of the slide 11, which is supported by an between him and the slide 11 arranged auxiliary spring 16 against the swash plate 7 is pressed. The spherical pressure piece 14 is adapted to a spherical seat 17 in the Inside the retaining ring 10 is arranged. The printing block

14 presses the retaining ring 10 against the swash plate 7.

The auxiliary spring 16 is dimensioned so that the force exerted by it on the pressure piece 14 is less than that is exerted by the compression springs 12 on the slide 11 force.

It is assumed that the device is dimensioned so that the largest possible angle of the swash plate 7 © max. is and the retaining ring 10 with the peripheral edge. 13 of the slider 11 comes into contact when the angle of inclination θ = 1/2 © max. the swashplate is. In the range of θ <.ΐ / 2 © max. the retaining ring 10 is through in its center the spherical pressure piece 14 is supported, as it turns out Fig. 7 results, while in the range θ> 1/2 0max. the retaining ring 10 is supported by the slide 11 at point P on the side where one of the pistons is essentially the upper one Reaches dead center, as shown in FIG.

This has the advantage that the support point of the retaining ring

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10, i.e. the point at which the retaining ring against the swashplate is pressed, can be kept very close to the point of application of the separating force lifting the pistons and the sliding blocks from the swash plate surface, since the The center of the separating force is shifted to the side where the pistons with increasing inclination of the swash plate angle assume their top dead center. In this way, the pressing force of the retaining ring 10 can advantageously be reduced compared to the conventional supports, which only have a spherical pressure piece.

In the diagram of FIG. 9, there is graphically the relationship between the displacement of the center point of the separating force or the support point of the separating force and the angle of inclination θ of the swash plate. The broken line χ represents the shift of the center of the separating force, while the solid line y represents the support position of the retaining ring.

As can be seen from the diagram, in the range θ <ΐ / 2 6max. the retaining ring 10 in its central part supported by the spherical pressure piece 14, while it is in the range θ> ΐ / 2 0max. supported by the slide 11 at a point on the side where the pistons reach their top dead center through the slide. Through this becomes the support point of the retaining ring at a smaller distance from the center of the separating force held.

Another advantage of the device according to the invention is that in the range of 1/2 © max. up to 9max., in which the retaining ring 10 is supported by the slide 1.1, the pressure contact force for the retaining ring automatically increases with the increase in the inclination angle θ of the swash plate.

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When the inclination angle θ of the swash plate is in the range below 1/2 Ömax. is, the auxiliary spring 16 is completely compressed, while the compression springs 12 are fully expanded, so that the peripheral edge 13 of the slide 11 with the rear end of the spherical pressure piece 14 is held in contact. In this way, the retaining ring 10 by the completely pulled apart compression springs 12 with a relatively small force against the surface the swash plate.

If the angle θ is 1/2 9max. has exceeded, the side of the retaining ring 10 on which the pistons have reached their i top dead center is brought into contact with the peripheral edge 13 of the slide 11. With a further increase in the inclination angle θ, the slider 11 retreats and the springs 12 supporting it are compressed, with the result that the pressure contact force of the retaining ring 10 is proportionally increased. In this case, the spherical pressure piece 14 still presses the retaining ring 10 against the swash plate, with a small force exerted by the extended auxiliary spring 16. In this case, the pressure piece 14 serves as a radial bearing for the retaining ring 10 and less as a means to exert a contact force.

In Fig. 10, the relationship between the inclination angle θ of the swash plate and the pressure contact force is or Separation force shown for the retaining ring. In the diagram the solid line a means the pressure contact force and the dashed line b the separation force, It can be seen from the graph that the pressure contact force of the retaining ring 10 is small when • the inclination angle θ is small, so that the force to separate the pistons 5 and the shoes 8 from the surface the swash plate 7 is relatively low. In the area

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a greater angle of inclination or a greater separation force the contact force of the retaining ring is correspondingly greater. Since the retaining ring 10 and the slide 11 are in point contact remain without sliding on each other, both elements are practically free from wear.

As can be seen from the above, there is in the inventive Device never the risk of increased acting on the pressure contact part of the retaining ring Power, so that this axial piston pump has an improved mechanical efficiency and a longer service life. While in the illustrated embodiment, the support of the retaining ring on the spherical pressure piece and the slide at an angle of inclination of 1/2 9max. placed is, this can of course also be selected differently if necessary.

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Claims (1)

Mitsubishi Jukogyo Kabushiki Kaisha, 10, Marunouchi 2-chome, Chiyoda-ku, Tokyo , Japan Claim: Axial piston pump or motor with arranged at the free ends of axially displaceable pistons in a cylinder block Sliding shoes and one of these with a shaft that is angularly adjustable with respect to a shaft connected to the cylinder block Retaining ring that holds the swashplate in sliding contact and is mounted on a spherical pressure piece, characterized by a ring on the shaft (1) axially sliding and ring-shaped, pressed against the swash plate (7) by at least one elastic element (12) Slide (11) on which the spherical pressure piece (14) is mounted so as to slide axially and under the action of a between this and the slide (11) arranged elastic auxiliary element (16) in such a way in a spherical seat (17) of the retaining ring (10) is arranged that when a certain value of the angle of inclination θ is exceeded Swash plate (7) of the "retaining ring (10) with the peripheral edge (13) of the slide (11) at a point (P) in contact which is located away from the pivot point of the retaining ring (10) on the side on which the pistons (5) their upper ones Assume dead center. 009887/1542