DE102011080287A1 - Piston pump for vehicle braking system, has supply piston for supplying fluid and piston return spring, which is designed as volute spring, where supply piston is guided in cylinder and is sealed by annular sliding seal against cylinder - Google Patents

Abstract

The piston pump (10) has a supply piston (14) for supplying fluid and a piston return spring (49), which is designed as a volute spring. The supply piston is guided in a cylinder (12) and is sealed by an annular sliding seal (17) against the cylinder. A supply unit is provided for supplying fluid to the supply piston and a discharge unit is provided for discharging the fluid from the supply piston.

Description

State of the art

The invention relates to a piston pump, in particular a vehicle brake system, with a delivery piston for conveying fluid and a piston return spring.

Piston pumps of the above type are required in vehicle brake systems, such as an anti-lock braking system (ABS), for conveying pressure medium. The pressure media are usually fluids, such as brake fluid. Typical piston pumps for such vehicle brake systems comprise a cylindrical housing or a cylinder, which serves as a running surface for a delivery piston located therein. The delivery piston serves to push out the pressure medium from the cylinder. In addition, inlet and outlet valves for the pressure medium are located on the piston pump. Sealing elements on or in the piston pump are required to prevent or reduce leaks.

The inlet and outlet valves serve to control the pressure medium flow during the compression phase achieved with the delivery piston. The inlet valve prevents the pressure medium from flowing back into the suction area during the compression phase. The outlet valve prevents backflow of the pressure medium from the pressure or compression side into the cylinder. The inlet and outlet valves are typically designed as spring-loaded ball valves.

Disclosure of the invention

According to the invention, a piston pump, in particular a vehicle brake system, is provided with a delivery piston for conveying fluid and a piston return spring in which the piston return spring is configured as a worm spring or spiral spring.

The piston return spring according to the invention is characterized in that it extends substantially in a plane and thereby spirals outwards from a center in a helical or helical manner. The piston return spring thus has the shape of a substantially flat screw or spiral and thus stands in contrast to conventional piston return springs, which are formed as a helical spring with turns in the direction of a longitudinal axis. The piston return spring according to the invention has a particularly low space requirement and, in conjunction with other elements, makes it possible to provide a pump which is both particularly functional and cost-effective. In particular, such a piston pump has extremely small dead volume. Furthermore, it is particularly advantageous with regard to the remaining installation situation of such piston pumps of vehicle brake systems that the piston return spring according to the invention requires a particularly small axial installation space. The piston pump according to the invention can therefore be made particularly small in terms of their longitudinal extent, which has a very advantageous overall effect on the overall dimensions and the total material requirements for the piston pump and the cylinder housing.

The delivery piston of the piston pump according to the invention is particularly preferably guided in a cylinder and sealed by an annular sliding seal against the cylinder. The sliding seal seals an interior of the cylinder from such that from this even at high pressure largely no fluid between the piston and cylinder inside can pass. In particular, the sliding seal also improves the pressure build-up dynamics of the delivery piston.

Alternatively or additionally, the delivery piston is advantageously sealed in the cylinder by means of a membrane seal.

The membrane seal is attached to both the cylinder and the piston in each case sealingly and fixedly, extends substantially radially and can be deflected in the axial direction. With the deflection, the diaphragm seal for the delivery piston creates the axial movement space required for the pressure build-up in the cylinder. At the same time the membrane seal seals the interior of the cylinder completely, since it is attached to this stationary and not sliding. The membrane seal thus creates a completely fluid-tight and leak-free piston pump. The membrane seal is preferably fastened by means of a retaining ring in the cup shape of a forming part. The retaining ring is preferably glued or pressed.

Furthermore, a feed for supplying fluid to the delivery piston and a discharge for discharging the fluid from the delivery piston are preferably provided on the piston pump according to the invention, and the supply and / or the discharge is designed with a forming part which is designed in particular to be substantially cup-shaped.

Forming parts are produced purely by plastic shaping and not by machining. They are very inexpensive to produce, since the necessary forming processes of plastic shaping, such as pressing into a mold or punching, can be kept short in time. In addition, there is no or little Tool wear on. Even burr formation and a risk from adhering chips can be largely avoided. The danger that emanates from adhering chips in the system, especially in vehicle braking systems of importance. The forming part according to the invention, for the supply and / or the discharge of the fluid in the piston pump, is preferably designed substantially cup-shaped. The cup shape is a form which can be produced particularly well by means of forming. It is very well suited to encase a component inside the cup and to define along with it flow paths. Advantageously, therefore, the inflow from the cup edge takes place axially into the cup shape. The outflow preferably takes place centrally through the cup bottom out of the cup shape.

Furthermore, the forming part is advantageously designed with an inflow section, an outflow section and a sealing section which seals against each other.

For this purpose, the forming part is preferably designed with depressions and / or elevations, so that lines or channels result solely from the forming part or from the interaction of this with other components on or in sections of these components. Cables and channels can be produced without milling or drilling process.

Further, a cylinder is preferably provided in the piston pump, which is encompassed by the forming part.

Designed in this way, the lines and channels can be arranged particularly easily, in particular in the longitudinal direction of the pump cylinder, between the latter and the surrounding forming part. The forming part engages around the cylinder particularly advantageously over a portion of its longitudinal extent. The inlet is located at a portion of its longitudinal extent. The fluid guide extends along the cylinder to another portion where the fluid is directed into the interior of the cylinder.

The piston pump according to the invention is also particularly advantageous equipped with a cylinder for guiding the delivery piston, which is designed with a forming part. The forming part is preferably designed cup-shaped stepped.

It thus achieved the above-mentioned advantages of forming in contrast to a machining production. The stepped cup shape creates interiors with different sized cross-sectional areas, which can be advantageously used for different functional areas. Preferably, a first region is designed with a large cross-sectional area, in which a seal is arranged to an adjacent eccentric drive. In particular, in this first region, a seal, particularly preferably in the form of a membrane seal, arranged. Advantageously, in this first region with a large cross-sectional area, the screw return spring designed according to the invention is provided, which supports the delivery piston in a springy manner. The bottom of the cup shape may be advantageously used as a surface for forming openings for an inlet valve and / or an outlet valve. The openings can be made by a simple punching process with high dimensional accuracy. Also, sealing surfaces, in particular a seat for a closing body of an exhaust valve, can be advantageously formed in this way.

Preferably, in the piston pump, the cylinder, an intake valve and an exhaust valve are provided, and the intake valve and the exhaust valve are disposed at a front end of the cylinder.

The inlet and outlet valves are thus concentrated in one area. In this area, two functions are combined without the inlet and the outlet of the fluid negatively influencing each other. The cable routing is also concentrated on this area. Thus, short lines are realized and there are only small flow losses. Furthermore, this results in a particularly compact design.

In an advantageous embodiment, the inlet valve is designed as a hinge valve.

The inlet valve can be designed as a closing element with a flap, a pivotable plate or tab, or a cuff. Hinges may be used to guide the closing element during its pivoting or folding movement. The hinge is preferably designed as a flexible section or as a foil section, on which a donation of the adjacent hinge parts can be largely free of resistance. This represents a very compact and cost-effective design of the inlet valve. It is particularly advantageous to arrange such an inlet valve on an end face of a cylinder. Furthermore, the inlet valve is preferably designed as a ring element which optionally covers a plurality of openings arranged at a distance from the ring. The hinge valve may return solely due to the elasticity of its material from the deflected position to its normal position or by means of a ring spring, plate spring, conical spring or worm spring particularly space-saving springs biased.

In a further advantageous embodiment, the outlet valve is a seat valve with a Valve seat and a valve body or closing body designed. An opening in the valve seat can be closed by means of the valve body, which applies to the valve seat and seals there. Preferably, the valve body is resiliently biased by a coil spring against the valve seat. The valve body is preferably designed with a ball, in particular with resilient bias by means of a helical spring. Such an outlet valve can be arranged particularly space-saving in the center of a designed as an annular hinge valve inlet valve, in particular on the end face of a cylinder, as explained above.

Exemplary embodiments of the solution according to the invention will be explained in more detail below with reference to the attached schematic drawings. It shows:

1 a perspective view of a first embodiment of a piston pump according to the invention,

2 a longitudinal section of the piston pump according to 1 .

3 a perspective longitudinal section of a first Umformteils the piston pump according to 1 .

4 a perspective longitudinal section of a second Umformteils the piston pump according to 1 .

5 a longitudinal section of a second embodiment of a piston pump according to the invention,

6 a longitudinal section of a third embodiment of a piston pump according to the invention and

7 a detail of an intake valve variant of the piston pump according to 6 ,

In 1 is a piston pump 10 , in particular for a vehicle brake system, shown having a cup-shaped cylinder 12 in the form of a first forming part. In the cylinder 12 is based on the 1 on the left side a membrane seal 14 which are essentially across the cylinder 12 extends. In the center of the membrane seal 14 there is a delivery piston 16 , which at its inwardly directed front end by means of a sliding seal 17 in the cylinder 12 is guided fluid-tight. The delivery piston 16 is also at its outwardly facing end portion with the membrane seal 14 connected fluid-tight. The membrane seal 14 is then in turn at its radially outer edge with the cylinder 12 connected fluid-tight. Furthermore, the piston pump comprises 10 another cup-shaped forming part 18 , The outward-facing end of the delivery piston 16 can by means of a rotatable eccentric, not shown in the cylinder 12 be pushed into it.

The cylinder 12 is stepped with a circular cylindrical section 19 with a large radius and a circular cylindrical section 20 designed with a comparatively small radius. The forming part 18 is also stepped with a circular cylindrical section 21 with a large radius and a circular cylindrical section 22 designed with a comparatively small radius.

The section 21 essentially has one to the section 20 corresponding cylindrical shape and is on the section 20 stuck or pressed. The section 20 also has three over the circumference of the section 20 evenly distributed indentations 23 on which each in the axial direction of the section 20 or the piston pump 10 each one channel or gap 24 between the cylinder 12 and the forming part 18 produce. Through this column 24 can brake fluid as fluid in the interior of the cylinder 12 reach.

The pumping process or conveying process of the piston pump is triggered 10 by the external excitation of the delivery piston 16 , The excitation is preferably carried out by means of the eccentric, the so on the delivery piston 16 acts, that this in the axial direction of the cylinder 12 moved back and forth.

In 2 are also a return spring 26 , a promotion room 28 , a sealing element 30 , an inlet opening 32 , a sealing element 34 , a sealing spring 36 , an outlet opening 38 , a production opening 40 as well as a line 42 to see.

The inlet opening 32 and the sealing element 30 together form an inlet valve 44 , The outlet opening 38 and the second sealing element 34 together form an outlet valve 46 ,

Furthermore, on the forming part 18 a lead 48 formed, which on the cylinder 12 , frontally on the conveyor area 20 , rests, and thus a sealing point 50 forms.

You can see it in 2 further between the section 20 of the cylinder 12 and the section 21 of the formed part 18 one of the three columns 24 which is one of the lines 42 forms. Through these lines 42 can brake fluid from the outside to the intake valves 44 reach. Fits the three columns 24 are on the end face of the cup-shaped cylinder 12 the three inlet openings 32 arranged. The brake fluid thus passes from the outside first in front of the sealing element 30 , The sealing element 30 is designed as an annular disc, which all three inlet openings 32 cover and close in this way. The sealing element 30 is by means of the return spring 26 against the front of the cylinder 12 pushed and held in this way there in addition.

Furthermore, in 2 the membrane seal 14 , which with the delivery piston 16 is coupled, particularly well to recognize in the cut. In addition to the membrane seal 14 there is a piston return spring 49 , which is helical shaped and also extends substantially in the radial direction. By means of the piston return spring 49 and the return spring 26 which, as already described, the sealing element 30 pretensioned, is the delivery piston 16 in the direction of the cylinder 12 biased out.

The return spring 26 is located at one end on the delivery piston 16 and at the other end to the sealing element 30 at. In this way, the spring force acts on the delivery piston 16 and there, if necessary, on the sliding seal 17 as well as on the sealing element 30 ,

When aspirating brake fluid in the piston pump 10 is by means of the delivery piston 14 on the sealing element 30 creates a suction, so that the sealing element 30 the inlet openings 32 free, so that the brake fluid in the delivery chamber 28 can occur. The movement of the delivery piston 14 for this suction is done by means of the piston return spring 49 and the return spring 26 , which the delivery piston 14 with receding eccentric from the cylinder 12 crowd out.

The following will be the delivery piston 16 from the eccentric again together with the attached sliding seal 17 axially in the direction of the outlet opening 38 the piston pump 10 pressed. This builds in the pump room 28 Pressure on. This pressure force closes the inlet valve 44 by placing the first sealing element 30 with the action of a hinged valve on the front of the cylinder 12 with the local inlet openings 32 pressed. The pump room 28 is by means of a high-pressure seal forming sliding seal 17 and moreover, by means of the membrane seal forming a leakage seal 14 sealed to the outside. Furthermore, the pressure force presses the fluid in the delivery chamber 28 through the outlet opening 38 in the direction of the sealing element 34 , This sealing element 34 is from the associated valve seat at the outlet opening 38 lifted off and the brake fluid can pass the sealing element 34 from the delivery opening 40 escape. The sealing element 34 is here by means of the sealing spring 36 against the outlet opening 38 biased to form such a seat valve.

The inlet openings 32 and the outlet opening 38 are outside the cylinder 12 through the sealing point 50 separated from each other. Thus, the brake fluid, after having the outlet opening 38 happened, not back in the wires 42 and / or the delivery room 28 reach.

In 3 are the arched dents 23 shown separately, which in conjunction with the overlying forming part 18 the wires 42 form. In addition, the inlet openings 32 and the outlet opening 38 shown, which frontally on the delivery room 28 are arranged.

In 4 is the lead 48 for sealing the inlet area of the piston pump 10 easy to recognize in relation to their outlet area. The lead 48 is formed as a neck or neck substantially circular. This lead 48 lies on a circular surface, which extends between the inlet openings 32 and the outlet opening 38 frontally on the cylinder 12 located. As a result, the already mentioned sealing point 50 , And thus formed the seal of the fluid supply and the fluid removal.

In 5 is an embodiment of a piston pump 10 shown in which no return spring 26 is provided. This is possible because by means of the helical piston return spring 49 sufficient restoring force can be generated in the axial direction to the delivery piston 16 out of the cylinder 12 herauszubewegen while brake fluid in the pump room 28 hineinzusaugen.

The 6 finally shows a cone spring 51 , the front side of the sealing element 30 is attached to this against the associated inlet openings 32 to urge. The cone spring 51 thus improves the sealing behavior of the sealing element 30 , In particular, because otherwise in this embodiment, no return spring 26 is provided, which is such a bias of the sealing element 30 against the inlet openings 32 would produce.

Claims (10)

Piston pump ( 10 ), in particular a vehicle brake system, with a delivery piston ( 14 ) for conveying fluid and a piston return spring ( 49 ), in which the piston return spring ( 49 ) is designed as a worm spring. Piston pump according to claim 1, wherein the delivery piston ( 14 ) in a cylinder ( 12 ) and by means of an annular sliding seal ( 17 ) against the cylinder ( 12 ) is sealed. Piston pump according to claim 1 or 2, wherein the delivery piston ( 14 ) in a cylinder ( 12 ) and by means of a membrane seal ( 14 ) against the cylinder ( 12 ) is sealed. Piston pump according to one of claims 1 to 3, wherein a supply for supplying fluid to the delivery piston ( 14 ) and a discharge for discharging the fluid from the delivery piston ( 14 ) are provided and the supply and / or the discharge with a forming part ( 18 ) is designed, which is designed in particular substantially cup-shaped. Piston pump according to claim 4, wherein the forming part ( 18 ) is designed with an inflow portion, an outflow portion and a sealing portion sealing against each other. Piston pump according to claim 4 or 5, wherein a cylinder ( 12 ) for guiding the delivery piston ( 14 ) provided by the forming part ( 18 ) is encompassed. Piston pump according to one of claims 1 to 6, wherein a cylinder ( 12 ) for guiding the delivery piston ( 14 ) is provided, which is designed with a forming part, which is designed in particular cup-shaped stepped. Piston pump according to one of claims 1 to 7, wherein a cylinder ( 12 ) for guiding the delivery piston ( 14 ), an inlet valve ( 44 ) and an outlet valve ( 46 ) are provided and the inlet valve ( 44 ) as well as the outlet valve ( 46 ) at a front end of the cylinder ( 12 ) are arranged. Piston pump according to one of claims 1 to 8, in which an inlet valve ( 44 ) is provided, which is designed as a hinge valve. Piston pump according to one of claims 1 to 9, in which an outlet valve ( 46 ) is provided, which is designed as a seat valve.

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