DE102014217408A1 - Damping element of a piston pump of a vehicle brake system - Google Patents

Abstract

In a damping element (34) of a piston pump, in particular for a vehicle brake system, with a damping chamber (36) which is disc-shaped with two opposite end faces and filled with a damping medium, and a first damping membrane (38), with which the damping chamber (36) is limited to a first end face, and a second damping diaphragm (40) with which the damping chamber (36) is limited at its second end face, according to the invention on the inside to the damping chamber (36) at least one of the damping membranes (38; formed in the damping chamber (36) projecting spacer pin (48).

Description

The invention relates to a damping element of a piston pump, in particular for a vehicle brake system, with a damping chamber which is disc-shaped with two opposite end faces and filled with a damping medium, and a first damping membrane, with which the damping chamber is limited at a first end face, and a second Damping membrane with which the damping chamber is limited at its second end face. Furthermore, the invention relates to a use of such a damping element in a pump element of a piston pump of a vehicle brake system.

State of the art

Damping elements of the type mentioned are made DE 10 2010 040 218 A1 known and are used in the outlet of piston pumps to drain the local fluid flow as possible with little pulsation. Pressure pulsations of the fluid flow are basically due to the opening and closing of an associated exhaust valve on the cylinder / piston arrangement of the piston pump.

Out DE 197 32 771 A1 a piston pump is known, which is inserted into a cylinder bore of a hydraulic block of a hydraulic vehicle brake system. To damp pressure pulsations and to reduce pressure peaks due to the discontinuous promotion of the piston pump, the cylinder bore is closed on the side of a displacement chamber by means of a damping membrane. The damping membrane is a deep-drawn part made of sheet metal with a circumferential, deeply formed bead at its edge, which allows axial movement of a bottom of the damping membrane by elastic deformation of the damping membrane. The elastic deformability of the damping membrane and the axial mobility of its bottom dampens pressure changes in the associated outflow space. For additional improvement of the damping of the pressure pulsations, a damper body may be arranged in the outflow space. The damper body consists of an elastomer, in particular PTFE (polytetrafluoroethylene). To improve its damping properties, it has radial ribs and an annular cavity.

The invention has for its object to provide a piston pump of a vehicle brake system with a damping element, which is achieved in a particularly cost-effective manner, a high degree of damping of pressure pulsations and pressure peaks.

Disclosure of the invention

According to the invention, a damping element of a piston pump is geschafffen, in particular for a vehicle brake system, with a damping chamber which is disc-shaped with two opposite end faces and filled with a damping medium, and a first damping diaphragm, with which the damping chamber is limited at a first end face, and a second damping membrane, with which the damping chamber is limited at its second end face. According to the invention, a spacer pin projecting into the damping chamber is formed on the inner side of at least one of the damping diaphragms facing the damping chamber.

With the solution according to the invention, an outwardly sealed cavity is created by means of two damping membranes, which can also be referred to as a damping pill. In the cavity, a damping medium is filled. The damping medium is protected, in particular, from that brake fluid which is conveyed by vehicle brake systems through its outlet region in the case of piston pumps. Thus, a non-DOT-resistant medium can be used as a damping medium. The damping membranes of the invention particularly advantageously limit a pillow-shaped cavity, wherein the damping membranes have on at least one end face of the pad a preformed, profiled surface which has a high degree of deformability transversely to the end face. The two such damping membranes form particularly large effective areas for attacking the fluid flow to be damped. They allow an alternating transmission of shocks and pressure peaks on first a damping diaphragm surface and then further through the damping medium through to the second damping diaphragm surface.

In the damping element according to the invention is located in the damping chamber, at least one spacer pin by means of which the two damping membranes kept at a distance and thereby excessive compression of the located in the damping chamber damping medium can be avoided. The spacer pin according to the invention thus specifies a path of movement for the damping membrane around which it can deform without the damping element being damaged. Furthermore, with the spacing pin or movement stop according to the invention, a movement of one of the damping membranes to the adjacent damping membrane can be pressure-conductively or mechanically transmitted. This function of the spacer pin according to the invention is particularly advantageous if a plurality of damping elements according to the invention are arranged in a stack next to each other. These inventive arrangement of damping elements will be explained separately below.

Two half shells are advantageously formed with the two damping membranes, which are connected to one another in a fluid-tight manner at the circumference of the damping chamber. The two damping membranes thus form two halves of a damping cushion, wherein these two halves can be manufactured largely as equal parts cost. The two half-shells can advantageously be connected in a materially bonded manner, in particular by splicing or gluing, in order to delimit the cavity forming a cushion.

The damping membranes according to the invention are preferably designed as two thermoformed shells, which are connected by means of ultrasonic welding or gluing. In this case, the spacer pin or spacer according to the invention can also counteract a fracture of such shells.

The spacer pin according to the invention is advantageously designed self-deformable, in particular elastically deformable. With the distance pin of this type, the damping behavior of the damping element can be selectively adjusted or predefined by means of the physical properties of the damping membranes, the damping medium and the spacer pin. These physical properties include in particular the elasticity or spring stiffness and the damping behavior of these individual components of the damping element according to the invention.

At least one of the damping membranes is preferably designed with at least one annular bead. With the annular bead pressure peaks are optimally absorbed. The bead allows movements of the damping membrane transversely to their surface orientation. Therefore, a plurality of such beads are particularly advantageous. The profiling of the damping membrane may correspond to that of a loudspeaker, this being advantageous, in particular in combination with a circular damping chamber, when the profile rings are then particularly preferably arranged concentrically with respect to the axis.

The at least one damping membrane is also advantageously formed with a PEEK film. PEEK (polyetheretherketone) is a high-strength material with a melting temperature of approx. 335 ° C. Formed with this material, the damping membrane is particularly robust and resistant to wear. Alternatively, the at least one damping membrane is formed with a metal foil. A metal foil is an alternative to a plastic film, such as a PEEK foil, that is easy to handle.

The damping medium is preferably also a shock absorbing medium, which is particularly compressible. A damping pad filled according to the invention with a compressible medium leads to an advantageously elastic behavior of the damping element, whereby, after the compression of the medium, elastic compression of the compression movement also occurs. In particular, air or another gas is suitable as a compressible medium. As a damping medium advantageously a coarse-pored material is used. This medium is shock absorbing and can also be unstable to brake fluid. In addition, a filling of the pad with a combination of a shock absorbing and a compressible medium is beneficial.

According to the invention, a piston pump of a vehicle brake system is further provided with a pump element and an above-mentioned damping element according to the invention. The damping element is advantageously connected in flow-conducting manner with the pump element. The pump element is preferably disposed in a bore which is frontally bounded by a bottom, wherein the damping element is arranged on the bottom. With such a development, the damping element is arranged with little installation effort directly on the pump element, in particular in that bore in which the pump element is located.

Alternatively or additionally, in the piston pump according to the invention, the pump element is advantageously formed with a cylinder from which leads out a fluid line, wherein the at least one damping membrane is arranged in front of the fluid line and the underlying damping chamber is covered by a lid attached to the cylinder. Such a construction can be realized with very few components and correspondingly easy to install.

Preferably, a spacer pin is formed on each of the damping membranes. The two damping membranes can thus be kept largely identical.

The spacer pin is also advantageously designed as a projecting into the damping chamber bulge of the damping membrane itself. The spacer pin can thus be provided largely cost-neutral.

Furthermore, the spacer pin is preferably formed in the center of the end face of the damping membrane. The spacer pin centrally supports the damping membrane there and uniformly creates the desired support and protection effect over the entire surface Absorbing membrane. Furthermore, it is ensured with this arrangement of the spacer pin that form a central axis of action in a stacked arrangement of damping elements whose spacers.

The invention is further directed to a damping element, in particular according to the above-mentioned inventive type, in which at least one of the damping membranes has a peripheral edge having a radially directed recess at at least one circumferential location. With such a depression movement or exchange of medium in the vicinity of the damping element according to the invention at its end face in the radial direction is possible. Such a movement of medium is particularly advantageous in that the damping movement of the damping element should be determined solely by the Dämpfugnsmedium and not by a medium in the vicinity of the damping element. According to the invention it is ensured that in particular the medium, which is located on the end faces of the damping element according to the invention, can flow freely raial. This free radial flow is particularly advantageous when two or more damping elements or damper pills according to the invention are arranged to form a damper stack.

The peripheral edge of the damping elements according to the invention is advantageously designed as a survey to a radially inner peripheral ring of the Dämmungsmembran and the recess in the peripheral edge of the end face is formed in the plane of the peripheral ring. Dier recess is therefore deeper relative to the peripheral edge in the axial direction, and advantageously by exactly the amount that is also the adjacent peripheral ring deeper.

Particularly preferably, four recesses are distributed regularly at a distance from each other at the peripheral edge. With the design of this type, a uniformly free flow of medium in the vicinity of the damping elements according to the invention is possible over the front end, in particular when these are stacked.

The invention is also directed to a damping element, in particular of the type according to the invention, in which at least one of the damping membranes has a peripheral edge which is designed to be raised relative to a remaining radially inner surface of the damping membrane. The raised peripheral edge ensures, in particular, that designed damping membranes abut one another directly at this peripheral edge only and in the center of the associated end faces an initially free axial movement of the associated damping diaphragms is possible.

Furthermore, the invention is directed to a use of such a damping element according to the invention in a pump element of a piston pump of a vehicle brake system.

In the case of such use, in particular at least two damping elements, as explained, are arranged with their end faces abutting in the pump element. The thus formed stack of damper pills allows a variably adjustable or definable damping also for different types, in particular different performances, of associated piston pumps. The at least one damping element is preferably arranged in a pump cover of the pump element or in another opening or bore of a pump housing for the pump element.

Hereinafter, an embodiment of the solution according to the invention will be explained in more detail with reference to the accompanying schematic drawings. It shows:

1 a partial longitudinal section of a piston pump according to the prior art with an associated damping element,

2 a perspective view of the damping element according to 1 .

3 the section III-III in 2 ,

4 a view according to 1 an embodiment of a piston pump according to the invention with an associated damping element,

5 a perspective view of the damping element according to 4 .

6 the section VI-VI in 5 ,

In 1 is a piston pump 10 illustrated in the prior art, in which a single pump element with a cup-shaped pump cylinder 12 is formed. The pump cylinder 12 is from an intermediate part 14 surrounded on the bottom side. In the pump cylinder 12 There is an unillustrated piston, which by means of a coil spring 16 is resiliently biased.

The piston promotes pumping movement within the pump cylinder 12 a brake fluid, not further illustrated, to an exhaust valve 18 at the intermediate part 14 is trained. The pump cylinder 12 has as a discharge or fluid line at its bottom region a central outlet opening 20 on, on the side of the intermediate part 14 from a valve seat 22 is encompassed. At the valve seat 22 is a valve ball 24 applied, by means of a spiral spring 26 is resiliently biased. The spiral spring 26 rests on the intermediate part 14 at the edge of a central passage opening 28 in which also the valve ball 24 is guided axially.

The intermediate part 14 is at his from the pump cylinder 12 facing away from a pump cover 30 encompassed. The pump cover 30 limited to the passage opening 28 out a chamber 32 in which a damping element 34 is formed in the form of a damper cushion according to the prior art. In the damping element 34 is a circular damping chamber 36 by means of two half-shell-shaped damping membranes 38 and 40 edged. The two shell-shaped damping membranes 38 and 40 are made of PEEK film and welded together fluid-tight at their periphery. In the damping chamber 36 In this way, a shock absorbing and / or a compressible medium (not shown) is received and retained. The individual shell-shaped damping membranes 38 and 40 each have several concentric beads at their ends 42 on, by means of which they are shaped in the manner of a loudspeaker diaphragm. In the center of each such circular damping membranes 38 respectively. 40 each is a flat or planar middle area 44 ,

In the 4 to 6 is an inventive embodiment of a piston pump 10 and associated damping elements 34 shown in terms of components pump cylinder 12 , Intermediate part 14 , Coil spring 16 , Exhaust valve 18 , Outlet opening 20 , Valve seat 22 , Valve ball 24 , Spiral spring 26 and passage opening 28 as in 1 is trained.

In the embodiment according to the 4 to 6 is however the chamber 32 designed to be larger in the axial direction and in this total of three damping elements according to the invention 34 axail stacked arranged. In this case, the adjacent end faces of the damping elements lie 34 so congruent side by side, that the three damping elements 34 the largely circular cylindrical chamber 32 with its three damping chambers 36 fill as far as possible.

In the case of the three damping elements arranged in this way 34 according to 4 to 6 is also a respective damping chamber 36 educated. In each of these damping chambers 36 is on an inside 46 the two damping membranes 38 and 40 one spacer pin each 48 educated. This distance pin 48 protrudes into the damping chamber 36 to about half of its axial extent. The spacer pins 48 are located respectively in the center and middle area 44 the respective end face and are as one in the damping chamber 36 protruding bulge of the damping membrane 38 respectively. 40 designed.

Furthermore, in the damping elements 34 according to 4 to 6 each of the damping membranes 38 respectively. 40 a peripheral edge 50 on, at four circumferential locations each have a radially directed recess 52 having. The peripheral edge 50 is doing as a survey to a radially inner circumferential ring 54 the associated Dämmungsmembran 38 respectively. 40 designed. The peripheral ring 54 thus forms part of one of the circular beads 42 , The wells 52 are at the same time formed so deep that they are at their bottom to the level of the peripheral ring 54 pass. At such peripheral edge 50 are the total of four wells 52 regularly spaced from each other. Accordingly, two recesses each 52 an angle of 90 ° to the associated circular damping diaphragm 38 respectively. 40 one.

Finally, it should be noted that the peripheral edges 50 at the damping membranes 38 and 40 relative to the remaining radially inner surface 56 with their beads 42 the damping membrane 38 respectively. 40 is designed sublime. It exists on this inner surface 56 So an axial distance 58 between the axially outer side of the peripheral edge 50 and the axially outer side of the beads 42 ,

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010040218 A1 [0002]
• DE 19732771 A1 [0003]

Claims (10)

Damping element ( 34 ) of a piston pump, in particular for a vehicle brake system, with a damping chamber ( 36 ), which is disc-shaped with two opposite end faces and filled with a damping medium, and a first damping membrane ( 38 ), with which the damping chamber ( 36 ) is bounded on a first end face, and a second damping membrane ( 40 ), with which the damping chamber ( 36 ) is delimited on its second end face, characterized in that on the to the damping chamber ( 36 ) facing the inside of at least one of the damping membranes ( 38 ; 40 ) into the damping chamber ( 36 ) projecting spacer pin ( 48 ) is trained. Damping element according to claim 1, characterized in that on both damping membranes ( 38 ; 40 ) each a spacer pin ( 48 ) is trained. Damping element according to claim 1 or 2, characterized in that the spacer pin ( 48 ) as one in the damping chamber ( 36 ) protruding bulge of the damping membrane ( 38 ; 40 ) is designed. Damping element according to one of claims 1 to 3, characterized in that the spacer pin ( 48 ) in the middle area ( 44 ) of the end face of the damping membrane ( 38 ; 40 ) is trained. Damping element ( 34 ), in particular according to one of claims 1 to 4, a piston pump, in particular for a vehicle brake system, with a damping chamber ( 36 ), which is disc-shaped with two opposite end faces and filled with a damping medium, and a first damping membrane ( 38 ), with which the damping chamber ( 36 ) is bounded on a first end face, and a second damping membrane ( 40 ), with which the damping chamber ( 36 ) is bounded on its second end face, characterized in that at least one of the damping membranes ( 38 ; 40 ) a peripheral edge ( 50 ), which at at least one circumferential location a radially directed recess ( 52 ) having. Damping element according to claim 5, characterized in that the peripheral edge ( 50 ) as a survey to a radially inner peripheral ring ( 54 ) the Dämmungsmembran ( 38 ; 40 ) and the recess ( 52 ) in the plane of the peripheral ring ( 54 ) is trained. Damping element according to claim 5 or 6, characterized in that at the peripheral edge ( 50 ) distributes four wells ( 52 ) are formed regularly spaced from each other. Damping element ( 34 ), in particular according to one of claims 1 to 7, a piston pump, in particular for a vehicle brake system, with a damping chamber ( 36 ), which is disc-shaped with two opposite end faces and filled with a damping medium, and a first damping membrane ( 38 ), with which the damping chamber ( 36 ) is bounded on a first end face, and a second damping membrane ( 40 ), with which the damping chamber ( 36 ) is bounded on its second end face, characterized in that at least one of the damping membranes ( 38 ; 40 ) a peripheral edge ( 50 ), which is relative to a remaining radially inner surface ( 56 ) of the damping membrane ( 38 ; 40 ) is designed sublime. Use of a damping element ( 34 ) according to one of claims 1 to 8 in a pump element of a piston pump of a vehicle brake system. Use according to claim 8, wherein at least two damping elements ( 34 ) are arranged with their end faces abutting in the pump element.

Images