WO2014191175A1

WO2014191175A1 - Positive displacement pump, especially rotary vane pump

Info

Publication number: WO2014191175A1
Application number: PCT/EP2014/059308
Authority: WO
Inventors: Fuad Koldzic; Thomas Wekenmann
Original assignee: Zf Lenksysteme Gmbh
Priority date: 2013-05-28
Filing date: 2014-05-07
Publication date: 2014-12-04
Also published as: DE102013105436A1

Abstract

The invention relates to a positive displacement pump, especially a rotary vane pump for delivering a fluid for a fluid-operated device of a steering system. Said pump comprises: a rotor (3) in the peripheral surface of which slots are produced and extend at least substantially radially over the entire width of the rotor, displaceable vanes (5) being arranged in the slots and being guided along the contour of a variable cam ring (2) during rotation of the rotor (3); and an end plate and a control plate (6) that enclose the rotor (3) and the cam ring (2) between them. The control plate and/or the end plate contain a rear vane channel (9) which cooperates with rear vane compartments to force the vanes (5) onto the cam ring (2). The flow rate in the rear vane channel (9) decreases from the pressure zone towards the intake zone and/or increases from the intake zone towards the pressure zone. The reduction can take the shape of a crescent.

Description

Positive displacement pump, in particular vane pump

The invention relates to a positive displacement pump, in particular vane pump according to the closer defined in the preamble of claim 1.

A vane pump of this type is known for example from DE 10 2009 000 155 A1. In a vane pump, the wings are pressed by a hydraulic pressure to the outside against the inner contour of a cam ring. This hydraulic pressure is applied to the wings over a constant geometry of a

Hinterflügelkanales provided in ring form. By a

Cross-sectional constriction of the Hinterflügelkanales in the region of the transitions between the pressure and the suction side and a radial wing movement arises in

Pressure range a higher rear wing pressure than in the suction area. Basically, however, the rear wing pressure is constant both on the suction side and on the pressure side regardless of the individual blade positions. The rear wing channel is provided in the transition region between the suction and the pressure area with a break.

The wings move during a revolution in guides, so-called rotor slots in the rotor (also called rotor) radially from a slot core from the inside outwards in the direction of the cam ring and back again. In the transition region between the pressure side and the suction side of the wing is therefore exposed to the greatest pressure difference (so-called zero stroke). This allows the radial

Wing pressure to the outside against the cam ring may not be sufficient.

In order to stabilize the wing in hydraulic equilibrium, it is necessary to increase the support in the rear wing area, the farther the wing is pushed in the direction of the slot core, ie inwards. This pressure support is the same for all wings in the respective areas (pressure / suction) and is determined by the Ringkanal- and Hinterflügelkaneldrosselung and the slot clearance between the wing and slot. Regardless of the sash position, the highest pressure is always applied to all sashes. This adversely affects a higher wear and also causes a greater power consumption. By the described extreme Pressure difference of low pressure and high pressure, the wing is suddenly exposed to high pressure. This also creates a high leakage in the

Rear wing area. Favorable by a lack of hydraulic support in the hindwing area also takes place in an adverse manner overflow at the vane radius.

The present invention has for its object to provide a positive displacement pump of the type mentioned, in which eliminates the disadvantages mentioned above or at least largely avoided, especially in which no high wear and less leakage occurs.

According to the invention, this object is achieved by the characterizing part of

Claim 1 mentioned feature solved.

Due to the radial movement of the wings, the rear wing channel is filled with a fluid as a pressure medium, generally oil, or the oil is displaced therefrom. The

Displacement takes place when the wings are pushed through the cam ring to the center of the axle.

By the solution according to the invention, namely a reduction and / or increase of the flow volume, the oil volume in the rear wing channel is now permanently changed with the stroke movement. In this way, in each case an optimal Hinterflügeldruck can be generated in a defined manner. With increasing speed of

Displacement pump, due to the cam ring movement, the wing insert is getting smaller and the throttling parallel to it ever larger.

The reduction or increase in the flow volume can be done in accordance with the invention by reducing the width and / or the depth of Hinterflügelkanales. Preferably, the reduction or increase is carried out continuously.

In a structural embodiment of the invention can be provided that the Hinterflügelkanal changed sickle-shaped. If a sickle-shaped reduction along the inner diameter of the Hinterflügelkanales runs, so you also achieved at the same time

Sealing surface enlargement and thus a leakage oil minimization.

The Hinterflügelbereich or Hinterflügelkanal has virtually at least one non-coaxial to the axis of the rotor contour (on the inside and / or

Outer diameter of the Hinterflügelkanales).

Advantageously, the rear wing channel in the transition region between the suction and the pressure region with at least one radially extending

wedge-shaped demarcation or interruption provided. This demarcation should be as small as possible. Upon rotation of the rotor, the wings are thus supplied by the contour of Hinterflügelkanales so variable with the required amount of oil.

Due to the wedge shape widening radially outwards, there is only a short time

Interruption of the oil supply instead, whereby always a good oil supply in the

Hind wing area is present and high sudden pressure differences are avoided. The transition is thus more homogeneous.

In a further embodiment it can be provided that the rear wing channel begins in the entrance area to the printing area by a ramp. By forming a preferred inclined ramp while maintaining a high pressure, the volume of oil in the Hinterflügelkanal is gradually increased to full flow. The inclined plane of the ramp with the resulting gradual increase in the groove depth in the transition to the high pressure area thus ensures a high pressure in the Hinterflügelkanal, thereby ensuring a greater supply of oil.

By reducing the flow volume in the rear wing channel of

Pressure range in the direction of the suction area is increased with decreasing space of the hydraulic pressure and thus pressed the wing each rising homogeneously against the inner wall of the cam ring. The reversal with the same advantage is achieved by increasing the flow volume in the suction area accordingly.

With increasing speed, the rear wing area increases by one

Displacement of the cam ring, bringing the rear wing area accordingly

pressure is relieved.

Hereinafter, an embodiment of the invention will be described in principle with reference to the drawing.

It shows:

1 shows a longitudinal section through a vane pump as positive displacement pump.

Figure 2 shows a control panel of the vane pump according to the invention.

Vane pumps as positive displacement pumps of the type mentioned are well known, which is why below only in detail for the invention essential parts.

A vane pump may be provided for conveying a fluid, such as hydraulic oil, for a power steering system of a passenger car.

In an outer ring 1 of a housing of the vane pump is a cam ring 2, arranged in the interior of the cam ring 2 runner or rotor 3, with a

Drive shaft 4 is rotatably connected, stored. The rotor 3 is provided with radially outwardly open slots, in which wings 5 are guided displaceably. The wings 5 are radially outward against the inner circumference of the cam ring 2. The cam ring 2 surrounds the rotor 3 and, together with the rotor and a control plate 6 with the blades 5, adjoins one another in the circumferential direction successive working chambers.

At least via the control plate 6, the suction and / or pressure side supply of the working chambers in the suction takes place by means of a suction kidney 7 and in the pressure range of Vane pump via a pressure kidney 8. About an annular Hinterflügelkanal 9, the wings 5 are acted upon in their Hinterflügelräumen with fluid pressure.

The Hinterflügelkanal 9 is in a part-circular annular channel 9a, located in the

Rear wing area of the suction side is located in the control panel and a first

Defined pressure range and divided into a second part-circular annular channel 9b or second pressure region which extends over the pressure side of the control plate 6.

As can be seen from FIG. 2, the width of the part-circular annular channel 9b decreases in a sickle-shaped manner from the pressure region in the direction of the suction region.

spirally.

As can be seen from the figure 2, the crescent-shaped reduction runs along the inner diameter of the annular channel 9b, whereby an enlargement of the

Sealing surface 10 in the high pressure region between the annular channel 9b and the

Through hole to the shaft 4 continuously increased by the corresponding radially outwardly shifted and decreasing in width Hinterflügelkanal 9.

The Hinterflügelkanal or part-circular annular channel 9a in the figure 2 extends coaxially with the same groove width and groove depth.

In the figure 1, a solution is alternatively shown, wherein the annular channel 9b decreases in the pressure region in the direction of the suction and the annular channel 9a widens sickle-shaped in the suction region in the direction of the pressure range. Thus, the same effect of a variable oil supply for a homogeneous

Wing pressure reaches the cam ring.

Another embodiment may be that the annular channel 9b in

Pressure range runs continuously and the sickle shape is provided with the widening toward the pressure area sickle only in the suction area.

In the transition region between the suction and the pressure region of the rear wing channel 9 with a wedge-shaped delimitation or interruption 1 1 through the Side walls of the "wedge", which separate the two part-circular ring channels 9a and 9b, provided. A radially extending wall of the wedge thus limits the annular channel 9a, while the second wall defines the beginning of the annular channel 9b. If necessary, several interruptions can be provided.

Subsequently, in the direction of the pressure range, the annular channel 9b begins with an inclined ramp 12 (see FIG. 2). The inclined ramp 12 begins at the surface of the control plate and extends axially obliquely down to the bottom of the groove of the annular channel 9b. The ramp-shaped lowering to the bottom of the groove can also be carried out stepwise by a plurality of ramps 12 arranged one behind the other.

The high-pressure supply of oil for the vane pump via the two grooves or holes 13 and 14th

LIST OF REFERENCE NUMBERS

1 outer ring

2 cam ring

3 rotor

4 drive shaft

5 wings

6 control plate

7 suckling kidneys

8 print kidneys

9 rear wing channel

9a part-circular ring channel

9b part-circular ring channel

10 sealing surface

1 1 wedge-shaped break

12 sloping ramp

13 groove / bore

14 groove / bore

Claims

claims

1 . Positive displacement pump, in particular vane pump for conveying a fluid for a consumer of a steering system, with a rotor (3), in its peripheral surface over its width extending, at least approximately radially extending slots are introduced, in which slidable wings (5) are arranged, the the contour of an adjustable cam ring (2) are guided along during rotation of the rotor (3), and with a front plate and a control plate (6) between the rotor (3) and the cam ring (2) between them, wherein the control plate and / or the front plate comprises a rear wing channel (9) which cooperates with rear wing spaces for pressing the wings (5) against the cam ring (2), characterized in that the flow volume in the rear wing channel (9) is from the pressure area in the direction of

Suction area reduced and / or increased from the suction area towards the pressure area.

2. positive displacement pump according to claim 1, characterized in that the width and / or depth of the Hinterflügelkanales (9) is reduced.

3. positive displacement pump according to claim 1 or 2, characterized in that the width of the Hinterflügelkanales (9) reduced sickle-shaped.

4. positive displacement pump according to claim 3, characterized in that the reduction of the Hinterflügelkanales (9) extends along the inner diameter.

5. positive displacement pump according to one of claims 1 to 4, characterized in that the rear wing channel (9) in the transition region between the suction and the

Pressure range has an interruption (1 1).

6. positive displacement pump according to claim 5, characterized in that the

Break (1 1) is wedge-shaped.

7. positive displacement pump according to one of claims 1 to 6, characterized in that the Hinterflügelkanal (9) in the entrance area to the pressure range by a ramp (12) begins.

8. positive displacement pump according to claim 7, characterized in that the ramp (12) has an oblique course.

9. positive displacement pump according to claim 7 or 8, characterized in that a plurality of ramps (12) are arranged in steps one behind the other.