EP2556252A1

EP2556252A1 - Annular seal element

Info

Publication number: EP2556252A1
Application number: EP11705181A
Authority: EP
Inventors: Oliver Gaertner; Wolfgang Schuller; Michael Schuessler
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2010-04-07
Filing date: 2011-02-09
Publication date: 2013-02-13
Also published as: JP2013527899A; DE102010003674A1; CN102834613A; CN102834613B; WO2011124405A1; US20130199365A1

Abstract

In an annular seal element (36), in particular for a hydraulic piston pump (10), for sealing off a pressurized region (24) filled with a fluid, one end face (44) is pressed onto a contact surface (50) of a piston (14), and the end face (44) is formed with a sealing contour (46) in such a way that the sealing contour (46) can be deformed elastically on the contact surface (50) by the pressure exerted.

Description

description

title

Ring-shaped sealing element prior art

The invention relates to an annular sealing element, in particular for a hydraulic piston pump, for sealing a pressure area filled with a fluid, in which an end face is pressed against a contact surface of a piston. Furthermore, the invention relates to a hydraulic piston pump with an annular sealing element and a vehicle brake system with a hydraulic piston pump.

Annular sealing elements for sealing a pressure area of

hydraulic piston pumps are usually axially on a piston and slide when retracting and extending the piston in a cylinder on an inner circumferential surface of the cylinder, on a so-called sealing surface over. The sealing element is usually positioned between the cylinder and the piston so that it is pressed with one end face on a contact surface of the piston. This end face of the sealing element is a substantially flat surface.

DE 102 40 052 A1 discloses a sealing and guiding device, in particular for a cylindrical pumping element. This device includes a

Sealing element made of an elastic material and a guide element made of a substantially inelastic material, wherein the sealing element is non-positively and / or positively connected fixedly connected to the guide element, so that the sealing element and the guide element are formed as a common assembly. The sealing element comprises a lip arrangement which is arranged at a predetermined angle to the circumference of a surface to be sealed of a moving piston element. This allows the sealing element, the piston element in the pressureless and pressurized state seal, since it always provides forces in the direction perpendicular to the outer circumference of the piston member due to its elasticity.

In order to produce large sealing forces between the sealing element and the piston element, the sealing element preferably has a region which, in the pressurized state of the sealing element, provides additional force to the lip arrangement for pressing the sealing element against the piston element. This is intended to further improve the safety of the seal.

The object of the invention is to provide a sealing element which allows a good seal, in particular between the end face of the sealing element and the corresponding contact surface of the piston. The sealing element should also compensate for form inaccuracies of the contact surface of the piston and thus create a good fit.

Disclosure of the invention

According to the invention, an annular sealing element is provided, in particular for a hydraulic piston pump, for sealing a pressure area filled with a fluid, in which an end face is pressed against a contact surface of a piston, and in which the end face is formed with a sealing contour such that the sealing contour passes through the applied pressure is elastically deformable on the contact surface.

The hydraulic piston pump comprises a cylindrical piston, which is mounted in and retracted in an inner space of a cylinder. The interior of the cylinder is bounded by a cylindrical wall. Between the cylindrical wall and the piston, an inventive annular sealing element is arranged, which seals a filled with a fluid pressure area in the interior of the cylinder. When the piston is moved out of the cylinder, a negative pressure is built up in the pressure region and the piston sucks fluid into the pressure region via an inlet valve. During retraction, the piston forces the fluid through an outlet valve from the pressure area into a hydraulic system to do work. In the present case, a fluid is to be understood as meaning a gas or also a hydraulic fluid, such as a hydraulic oil based on mineral oil or glycol.

The annular sealing element according to the invention comprises an inner and outer lateral surface and an end face. The inner surface of the

Sealing element abuts against an outer circumferential surface of the piston and the outer circumferential surface of the sealing element on the inner circumferential surface of the

Cylinder, at the so-called sealing surface. During retraction and extension of the piston in and out of the cylinder, the sealing surface and the outer surface of the sealing ring move relative to each other.

The end face of the sealing element is pressed, for example by means of a return spring, which is mounted within the pressure range, against a contact surface - a shoulder of the piston - and thus held in position.

According to the invention, the end face is provided with a specific sealing contour, which has elastic properties. This sealing contour is elastically deformed due to the applied pressure on the contact surface of the piston. The sealing contour conforms precisely to a specific surface structure of the contact surface and seals it substantially fluid-tight. Due to the

Deformation of the sealing contour adapts the end face to the contact surface better than an end face with a substantially flat surface. The

Tightness of the sealing element is advantageously increased. In particular, manufacturing-related unevenness of the contact surface of the piston can be compensated in this way. Leakages of the hydraulic piston pump are reduced especially at low back pressures and thus increases the efficiency of the pump.

According to a first advantageous development of the annular sealing element, the sealing contour has at least one sealing lip.

In such a development, the sealing lip can taper in cross section or have a dome-like shape. The sealing lip is elastically deformable and abuts against the contact surface when pressure is applied. In particular, a relatively narrow sealing lip fits due to their high Flexibility on bumps in the contact surface, such as dents or surveys, very good.

According to a second advantageous development of the annular sealing element, the sealing contour has a plurality of sealing lips, which are designed to be corrugated in cross section.

A sealing contour with several sealing lips provides a particularly effective

Seal available. This proves to be advantageous if there are high pressures in the pressure range of the piston pump. The sealing contour can, for example, as a so-called corrugated plate with preferably 10 to 15 individual

Be formed sealing lips. The individual sealing lips deform elastically when pressure is built up on the end face of the sealing element, so that the individual sealing lips optimally adapt to the surface structure of the contact surface.

Furthermore, the sealing lips can also - viewed in cross section - elastically deform by laterally applied pressure. This lateral pressure is present when high pressures prevail in the pressure area and fluid is forced into a region between the end face of the sealing element and the contact surface of the piston. In such a case, the fluid presses the sealing lips in the direction of the outer jacket surface of the sealing element and the sealing lips fit tightly against the contact surface and prevent leakage of the fluid in the direction of the wall of the cylinder.

Sealing lips with a wave shape in cross section adapt particularly well to a contact surface with little unevenness.

According to a third advantageous development of the annular sealing element, the sealing contour has a plurality of sealing lips which taper in cross section.

This sealing contour with multiple sealing lips also provides a particularly effective seal. The sealing contour may also be formed as a so-called corrugated plate with preferably 10 to 15 individual sealing lips. The individual sealing lips deform elastically when pressure is built up on the end face of the sealing element, so that the individual sealing lips of the Optimally adapt the surface structure of the contact surface. Sealing lips, which taper in cross section, are particularly suitable for contact surfaces, which have greater unevenness in the surface structure. The sealing lips can adapt well with their tips, for example, to depressions or grooves and effectively seal them.

According to a fourth advantageous development of the annular sealing element, the sealing contour is formed spirally in plan view. Such a spiral sealing contour is arranged in a spiral

Sealing lip formed, which may be designed, for example, dome-like or tapered in cross section. The sealing contour preferably has 8 to 15 turns. The spiral shape allows a good seal over a large area. The tips or crests of the sealing contour are slightly elastically deformed under pressure and fit well on the contact surface of the piston.

Already by slight deformation unevenness or flaws in the contact surface are better balanced than by a front side with a

continuous, substantially straight surface.

According to a fifth advantageous development of the annular sealing element, at least one, in particular two, high-pressure-side sealing lips are integrally formed on the side facing away from the end face of the sealing element.

The high-pressure side sealing lip is arranged on the opposite side of the front side. The sealing lip has two legs, which on the one hand with the

Sealing surface, d. H. with the inner circumferential surface of the cylinder, and on the other hand with the outer surface of the piston each form a defined angle. The high pressure side sealing lip closes closely against the sealing surface of the cylinder and the outer surface of the piston. The high-pressure side sealing lip may be formed in its contour such that a part of a

Valve housing is received, so that the valve housing on the outer circumferential surface of the piston supports the sealing element.

According to a sixth advantageous embodiment of the annular

Sealing element is the Dichtlement a molded plastic injection molded part. Such a sealing element is in one piece, preferably formed from an elastomer or elastomeric material. It is inexpensive to manufacture and easy to assemble in the manufacturing process with other components. According to a seventh advantageous development of the annular sealing element, the sealing element is integrally formed on a valve housing.

In such a case, the sealing element with the valve housing forms a single component. This element is preferably in one

Injection molding of plastic produced inexpensively and is easy to use in the hydraulic piston pump.

In addition, a hydraulic piston pump is provided with an annular sealing element.

The piston pump according to the invention comprises a cylinder and a piston which can be retracted and extended in the cylinder. An annular sealing element according to the invention is arranged between the piston and an inner circumferential surface, the so-called sealing surface, and seals a fluid-filled one

Pressure range inside the cylinder according to the features discussed above.

Furthermore, a vehicle brake system is provided with a hydraulic piston pump.

Such a vehicle brake system, for example, an anti-lock braking system (ABS), a traction control system (TCS - traction control system), an electronic stabilization program (ESP) or a

electrohydraulic braking system (EHB). In such systems, it is particularly advantageous if the hydraulic piston pumps a low

Leakage or have a high density to provide optimal performance of the braking system at a long mileage available. Furthermore, the leakage in vehicle brake systems must not be too high, so that functional impairments on adjacent components are prevented. Brief description of the drawings

Exemplary embodiments of the solution according to the invention are explained in more detail below with reference to the accompanying drawings, in which:

1 shows a longitudinal section of a hydraulic piston pump with a first embodiment of a sealing element according to the invention,

2 is a perspective view of the detail II in Fig. 1 on an enlarged scale,

3 is a perspective view of a second embodiment of a sealing element according to the invention that is integrally formed on a valve cage,

4 shows the cross section IV-IV in Fig. 3,

Fig. 5 shows a cross section of a third embodiment of a

sealing element according to the invention.

Description of embodiments

Fig. 1 illustrates a section of a hydraulic piston pump a cylinder 12 and a retractable in the cylinder 12 and extendable

Piston 14.

The piston 14 comprises an inlet valve 16. The inlet valve 16 is arranged in a valve housing 18, which is clamped on a holder 20. The valve 16 is intended to suck fluid by means of a lifting movement of the piston 14 through an inlet device 22 in a pressure region 24 in the interior of the cylinder 12 and through an outlet, not shown with an outlet valve under pressure from the pressure region 24 in a hydraulic system for the performance of To promote work. The fluid is present a brake fluid.

The valve housing 18 is cup-shaped designed as a cage in the interior of which a helical return spring 26 is located, which urges against a spherical closing body 28. The closing body 28 thereby abuts against a valve seat 30, which is formed on the end face of the piston 14. The piston 14 is resiliently biased in the axial direction by means of a return spring 32 arranged in the pressure region 24. The return spring 32 is based on Fig. 1 at its left end supported on an end face of the cylinder 12 and urges at its right end against a spring support 34 which is formed as a part of the valve housing 18. The spring support 34 is thus fixedly coupled to the piston 14, so that the return spring 32nd

accordingly urges against the piston 14 via the spring support 34.

When the piston 14 is pressed out with respect to FIG. 1 to the right from the cylinder 12 by means of the return spring 32, the closing body 28 of the

Inlet valve 16 lifted from the valve seat 30 against the force of the helical return spring 26, since a negative pressure in the cylinder 12 is established. During this movement of the piston 14, the inlet valve 16 is opened and fluid is sucked into the pressure region 24 via the inlet device 22.

When the piston 14 is pressed in relation to FIG. 1 to the left in the cylinder 12 by means of an eccentric, not shown, then the inlet valve 16 closes, the (not shown) outlet valve is opened and the fluid is from the pressure area 24 in a hydraulic system for Promoting work.

Between the piston 14 and the cylinder 12, an inventive annular sealing element 36 is disposed of an elastic material, with which the pressure region 24 is sealed in the cylinder 12. The sealing element 36 is pressed onto the piston 14 and is located axially on the outer surface of the

Piston 14 on. At this outer lateral surface, the sealing element 36 is held in place by means of the clamped to the holder 20 valve housing 18 in which the valve housing 18 engages positively and non-positively in the sealing element 36.

The sealing element 36 (see also Fig. 2) has on the side of the

Pressure region 24 faces, a high pressure side sealing lip 38 with two legs 40, 42, which on the one hand with the inner circumferential surface of the

Cylinder 12 and on the other with the outer circumferential surface of the piston 14 each include a certain angle α, ß. In this high-pressure side

Sealing lip 38 engages a part of the valve housing 18 and holds this. The sealing element 36 is thus radially inward against the inner circumferential surface of the cylinder 12 to slide there during the strokes of the piston 14 along and seal it.

Fig. 2 shows the annular sealing element 36 of FIG. 1 in an enlarged view. On the side opposite the high-pressure-side sealing lip 38, an end face 44 with a low-pressure-side sealing contour 46 is arranged. This sealing contour 46 has an arrangement of some,

in particular 8, sealing lips 48, which taper in cross section. The sealing lips 48 rest with their tips on a contact surface 50 of the piston 14 (see Fig. 1). If pressure is exerted on the end face 44 of the sealing element 36 - during retraction of the piston 14 via the return spring or at

Driving in the piston 14 into the cylinder 12 via the eccentric drive - so deforms the sealing contour 46 elastically on the contact surface 50 of the

Piston 14. The tapered sealing lips 48 tilt to the side, make contact with the contact surface 50 and seal in this way a range between the outer surface of the piston 15 and the inner circumferential surface of the cylinder 12 substantially fluid-tight.

Fig. 3, 4 and 5 show an annular sealing element 36 which with a

Valve housing 18 is formed as a one-piece component 52. This one-piece component 52 is present as a molded plastic injection molded part, which is particularly inexpensive to manufacture. The valve housing 18 of the component 52 has four webs 54 which receive and guide the closing body 28 of the inlet valve 16 inside. Further, the webs 54 with the holder 20 of the piston 14 are frictionally clamped (see Fig. 1).

The sealing element 36 of the component 52 has a sealing contour 46 with several, in particular 1 1, arranged in an annular, elastically deformable

Sealing lips 48 on. 3 and 4, the sealing lips 48, when viewed in cross section, taper to a point, whereas the sealing lips 48 in FIG. 5 have a wave-shaped cross-section. Under the influence of pressure p, the tapered or wave-shaped sealing lips 48 are pressed against the contact surface 50 of the piston 14 and deform elastically.

As is apparent from FIGS. 4 and 5, on the one hand a pressure is exerted perpendicular to the end face 44 of the sealing element 36, namely by the spring force of the return spring 32 during the retraction of the piston 14 from the cylinder 12 or by the eccentric during the driving in of the piston 14 into the cylinder 12 (see also Fig. 1). This will be the

End face 44 of the sealing element 36 pressed against the contact surface 50 of the piston 14 and the sealing lips 48 of the sealing contour 46 deform accordingly.

On the other hand, the fluid in the pressure region 24 also exerts a pressure parallel to the end face 44, d. H. perpendicular to the protruding sealing lips 48. These lie thereby according to this pressure direction of the fluid to the

Contact surface 50 and seal the contact surface 50 fluid-tight.

Claims

claims

1 . Ring-shaped sealing element (36), in particular for a hydraulic

Piston pump (10), for sealing a filled with a fluid

Pressure region (24), in which an end face (44) is pressed against a contact surface (50) of a piston (14),

characterized in that the end face (44) with a sealing contour (46) is formed such that the sealing contour (46) by the pressure exerted elastically on the contact surface (50) is deformable.

2. annular sealing element (36) according to claim 1,

characterized in that the sealing contour (46) at least one

Sealing lip (48).

3. annular sealing element (36) according to claim 1,

characterized in that the sealing contour (46) has a plurality of sealing lips (48), which are formed wave-shaped in cross-section.

4. Annular sealing element (36) according to claim 1,

characterized in that the sealing contour (46) has a plurality of sealing lips (48) which taper in cross-section.

5. Annular sealing element (36) according to any one of the preceding claims, characterized in that the sealing contour (46) is formed spirally in plan view.

Annular sealing element (36) according to one of the preceding claims, characterized in that the sealing element (36) on the

At least one, in particular two high-pressure side sealing lips (38, 40) are integrally formed on the front side (44).

7. annular sealing element (36) according to any one of the preceding claims, characterized in that the Dichtlement (36) is a molded plastic injection molded part. 8. annular sealing element (36) according to one of the preceding claims, characterized in that the sealing element (36) a

Valve housing (18) is integrally formed.

9. Hydraulic piston pump (10) with an annular sealing element (36) according to one of the preceding claims.

10. Vehicle brake system with a hydraulic piston pump (10) after

Claim 9.