DE102012218544A1 - Hydraulically controlled storage chamber valve - Google Patents

Abstract

The invention relates to a hydraulically controlled storage chamber valve (1) with a storage chamber (7) and a storage piston (10) movably guided in the storage chamber (7) and a feedthrough (18) via which the storage chamber (7) is connected to a fluid supply, wherein a closing element (16) seals a valve seat (18.1) arranged on the edge of the passage (18) in a valve body (9), an opening element (20) reaching through the passage (18) in the valve body (9) and from the storage piston (10) is movable, with an axial accumulator piston stroke (KH) via the opening element (20) causing an axial opening stroke (SH) of the closing element (16), the opening element (20) pushing the closing element (16) out of the valve seat (18.1) and from a Moved closed position to an open position when the volume in the storage chamber (7) falls below a predetermined threshold value. According to the invention, a coupling between the accumulator piston (10) and the opening element (20) is designed in such a way that a corresponding actuation point (BP) between the accumulator piston (10) and the opening element (20) runs according to a predetermined movement path as a function of the accumulator piston stroke (KH) and a translation between the accumulator piston stroke (KH) and the opening stroke (SH) from the closed position to the open position of the closing element (16) and vice versa is variably set.

Description

State of the art

The invention relates to a hydraulically controlled storage chamber valve according to the preamble of independent claim 1.

Storage chamber valves are known from the prior art, in which a closing element or sealing body of a spring-assisted closed valve is moved from a valve seat or sealing seat into an open position by a pin connected to a storage chamber piston, as soon as the storage chamber volume falls below a threshold value, d. H. the storage chamber piston approaches a stop arranged in the region of the sealing seat. Such storage chamber valves can be used for example in a hydraulic brake system of a motor vehicle, which has an ABS and / or ESP functionality (ABS: Antilock Braking System, ESP: Electronic Stability Program).

To close the valve seat during a base braking or partial braking with the closing element, the driver actuates the brake pedal. As a result, a piston of a master cylinder is displaced, whereby a volume of fluid is displaced into the brake pipe. In the ESP unit with such a storage chamber valve, the accumulator piston is pushed down, and the accumulator chamber valve goes from a normal open position to a closed position. Now (only) the driver can build up brake pressure in the system. The significant amount of brake pedal travel up to this point, the driver perceives as a free travel without great drag and / or braking effect. This can be perceived by the driver as unpleasant and undesirable. The appreciably large brake pedal travel acts mainly due to the relatively large diameter of the accumulator piston, which corresponds approximately to the order of the diameter of the master cylinder, and the translation of the brake pedal. As a result of the directly proportional connection of a storage piston stroke to an opening element lift of the storage chamber valve, a rather large, actually undesirable volume intake is generated in the frequent case of basic braking or partial braking. The above parameters can only be influenced with great effort or not at all. Thus, a modified storage piston diameter creates a high cost for new parts, new assembly equipment, new layout of the ESP unit, etc. and the brake pedal ratio and the size of the brake master cylinder is specified by the vehicle manufacturer.

From the patent US 7,543,896 B2 For example, a hydraulically controlled storage chamber valve is known in which a spring-loaded ball seat valve is opened via a plunger in the accumulator piston. This is done at a specified for the system balance of power between spring biasing force and hydraulically effective force. The actuation of the ball seat valve via a cylindrical metallic plunger, which is pressed into the accumulator piston. The accumulator piston also receives a sealing ring and a guide ring. Between the accumulator piston and the closure lid, which is connected via a Halteverstemmung with the pump housing, there is a correspondingly biased compression spring. The spring force acts against the hydraulically acting force on the accumulator piston and, in the event of an excess of the spring force, causes the accumulator piston-tappet combination to be displaced in the opening direction of the accumulator chamber valve. Due to the fixed coupling of the plunger with the accumulator piston, the ratio between the axial accumulator piston stroke and the axial opening stroke of the closing element is constant over the accumulator piston stroke.

In the published patent application DE 42 02 388 A1 For example, a hydraulic brake system for a motor vehicle is described. The brake system described comprises a hydraulically controlled storage chamber valve with a biased by a first compression spring closing element which seals a valve seat in a valve body, and a plunger which is connected to a loaded by a second compression spring accumulator piston and the closing element presses out of the valve seat, if between the spring biasing forces and a hydraulically effective force is a specified balance of forces. In these constructions of storage chamber valves, the sealing body of the spring-assisted closed valve is moved into the open position by a pin connected to the accumulator piston as soon as the accumulator chamber volume falls below a threshold value, ie the accumulator piston approaches the stop. Due to the fixed coupling of the plunger with the accumulator piston, the ratio between the axial accumulator piston stroke and the axial opening stroke of the closing element is constant over the accumulator piston stroke.

Disclosure of the invention

The hydraulically controlled storage chamber valve according to the invention with the features of independent claim 1 has the advantage that when used in a hydraulic brake system, a reduction in volume and thus a Pedalwegverlängerung are made possible during a basic braking.

The essence of the invention is the variable, the Speicherolbenhub dependent translation between a Speicherolbenhub and a Opening element stroke or closing element stroke. That is, the ratio of the accumulator piston stroke to the orifice member stroke may be expressed and determined as a function of the accumulator piston stroke or as a function of the closure member stroke. This variability is inventively achieved by a change in position of an operating point of the opening element on the accumulator piston.

Embodiments of the present invention allow the transition from a closed position, in which the closing element is held by a pressure difference can be moved in an open position by a "normal" Speicherolbenhub, ie by a translation of Speicherolbenhub to closing element or Öffnungselementhub with a This means that the closing element can be moved with great force, and if the closing element is in the open position, ie can be moved virtually without force, then embodiments of the present invention produce a large closing element stroke due to a small accumulator piston stroke this state, the translation of Speicherolbenhub to closing element or Öffnungselementhub a value less than 1 on.

Embodiments of the present invention provide a hydraulically controlled storage chamber valve which comprises a storage chamber and a storage piston movably guided in the storage chamber and a passage via which the storage chamber is connected to a fluid supply, wherein a closing element has a valve seat arranged at the edge of the feedthrough A valve member body passes through the passage in the valve body and is movable by the accumulator piston, wherein an axial Speicherolbenhub causes an axial opening stroke of the closing element via the opening element, wherein the opening element presses the closing element from the valve seat and moves from a closed position to an open position, when the volume in the storage chamber falls below a predetermined threshold. According to the invention a coupling between the accumulator piston and the opening element is designed so that a corresponding actuation point between the accumulator piston and the opening element in dependence of the Speicherolbenhubs in accordance with a predetermined trajectory and a translation between the Speicherolbenhub and the opening stroke of the closed position to the open position of the closing element and vice versa variable.

The measures and refinements recited in the dependent claims advantageous improvements of the independent claim 1 hydraulically controlled storage chamber valve are possible.

It is particularly advantageous that the movement path of the actuation point can run continuously and / or suddenly. As a result, any changes in the ratio of the accumulator piston stroke to the opening stroke can be predetermined in an advantageous manner, and the behavior of the accumulator chamber valve can be optimally adapted to the respective brake system. For example, a particularly gentle or flat or a particularly steep or a sudden change in the ratio of the accumulator piston stroke to the opening stroke can be specified via the accumulator piston stroke. In addition, the translation can be particularly flat in a given first area and particularly steep in a second area. The transition from the first to the second area and vice versa can be done for example by a jump.

In an advantageous embodiment of the hydraulically controlled storage chamber valve according to the invention, the trajectory of the actuation point can be a length ratio between a clear distance of the actuation point to a fixed in relation to the valve seat articulation point and / or bearing point of the opening element and a clearance of the operating point and a contact point of the opening element with the closing element change. The change in the aspect ratio represents a change in the transmission piston stroke to the opening stroke of the shutter member in the vertical direction.

In a further advantageous embodiment of the hydraulically controlled storage chamber valve according to the invention, the shape and dimensions of the opening element and / or shape and dimensions of an end face of the accumulator piston can predetermine the path of movement of the actuation point between the accumulator piston and the opening element. The opening element and / or the end face of the accumulator piston may, for example, have at least one curved area. The at least one curved region and / or at least one actuation region of the end face can be arranged, for example, rotationally symmetrically centered on the end face and / or with a predetermined distance from the central axis of the accumulator piston.

In a further advantageous embodiment of the hydraulically controlled storage chamber valve according to the invention, the opening element can be designed as a rotatably mounted angular element with a first leg and a second leg, wherein the first leg over a first curvature region with the second leg connected is. The rotatable mounting of the opening element can take place on the bearing seat which is stationary with respect to the valve seat and on which a free end of the first leg is mounted. Alternatively, the rotatable mounting of the opening element can take place at a storage point connected to the storage piston, wherein the opening element then has at least one fixed in relation to the valve seat articulation point.

In a further advantageous embodiment of the hydraulically controlled storage chamber valve according to the invention, the opening element on the first leg between the fixed bearing point or articulation point and the first curvature region may have a further curvature region.

Embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description. In the drawings, like reference numerals designate components that perform the same or analog functions.

Brief description of the drawings

1 shows a schematic sectional view of the invention essential parts of a first embodiment of a hydraulic storage chamber valve according to the invention in a closed position.

2 shows a schematic sectional view of the first embodiment of a hydraulic storage chamber valve according to the invention in an open position.

3 shows a schematic sectional view of the invention essential parts of a second embodiment of a hydraulic storage chamber valve according to the invention in an open position.

4 shows a schematic sectional view of the invention essential parts of a third embodiment of a hydraulic storage chamber valve according to the invention in a closed position.

Embodiments of the invention

1 to 4 show exemplary embodiments of a hydraulically controlled storage chamber valve according to the invention 1 . 1' . 1'' , which is exemplary in a stepped receiving bore 5 a fluid block 3 or pump housing is arranged.

How out 1 to 4 as further seen, the illustrated embodiments of the hydraulically controlled storage chamber valve include 1 . 1' . 1'' one storage chamber each 7 and one in the storage chamber 7 movably guided accumulator piston 10 . 10 ' . 10 '' and an implementation 18 over which the storage chamber 7 connected to a non-visible fluid supply. Between the storage chamber 7 , which is connected to an invisible fluid discharge, and the fluid supply, a valve assembly is arranged, which a valve body 9 and a closing element designed as a ball 16 includes. The over a non-visible first compression spring biased closing element 16 seals a valve seat 18.1 in the valve body 18 off, which at the storage chamber 7 opposite edge of the implementation 18 is arranged. An opening element 20 . 20 ' . 20 '' goes through the implementation 18 in the valve body 9 and is from the accumulator piston 10 . 10 ' . 10 '' emotional. An axial accumulator piston stroke KH effects via the opening element 20 . 20 ' . 20 '' an axial opening stroke SH of the closing element 16 , wherein the opening element 20 . 20 ' . 20 '' the closing element 16 from the valve seat 18.1 pushes and moves from a closed position to an open position when the volume in the storage chamber 7 falls below a predetermined threshold. According to the invention, a coupling between the accumulator piston 10 . 10 ' . 10 '' and the opening element 20 . 20 ' . 20 '' designed so that a corresponding actuation point BP between the accumulator piston 10 . 10 ' . 10 '' and the opening element 20 . 20 ' . 20 '' as a function of the accumulator piston stroke KH runs according to a predetermined trajectory and a translation between the Speicherolbenhub KH and the opening stroke SH from the closed position to the open position of the closing element 16 and vice versa variable.

In the following description, the axial opening stroke SH of the closing element corresponds 16 the Öffnungselementhub ÖH, since the opening element 20 . 20 ' . 20 '' not in one piece with accumulator piston 10 . 10 ' . 10 '' executed and due to a spring bias at a contact point P always in contact with the closing element 16 is.

To close the valve seat 18.1 in a base braking or partial braking with the closing element 16 the driver presses the brake pedal. As a result, an unrepresented piston of a master cylinder, not shown, is displaced, whereby a volume of fluid is displaced into the brake pipe. As a result, in a storage chamber valve according to the invention 1 . 1' . 1'' , which is connected via the non-visible fluid supply to the master cylinder, the accumulator piston 10 . 10 ' . 10 '' pressed down, and the storage chamber valve 1 . 1' . 1'' moves from the normal open position to the closed position. The inventive change in the translation between the Speicherolbenhub KH and the opening stroke SH as a function of the accumulator piston stroke KH in accordance with a predetermined trajectory, the volume of the storage chamber accumulator valve 1 . 1' . 1'' reduced in the frequent case of basic braking or partial braking and thereby the effective pedal travel of the brake pedal are extended, so that the driver perceives advantageously no significant brake pedal travel as free travel without drag and / or braking effect.

The variable from Speicherkolbenhub KH dependent translation between Speicherolbenhub KH and Öffnungselementhub ÖH or opening stroke SH of the closing element 16 is in the illustrated embodiments of the invention by specifying a trajectory for the actuation point BP of the accumulator piston 10 . 10 ' . 10 '' at the opening element 20 . 20 ' . 20 '' reached.

When the closing element 16 is in the closed position and held there by a pressure difference, that can be moved with great force, then the transition of the closing element 16 caused in the open position by a "normal" large Speicherolbenhub KH, so that the translation of Speicherolbenhub KH to opening stroke SH of the closing element 16 in this state is given with a value of about 1. When the closing element 16 in the open position, ie can be moved virtually force-free, then the translation of Speicherolbenhub KH to opening stroke SH of the closing element 16 in this state with a value of less 1 given, so that a large opening stroke SH of the closing element 16 can be generated by a small Speicherolbenhub KH.

How out 1 to 4 can be seen, the illustrated embodiments of the invention achieve the variable ratio of Speicherolbenhub KH to opening stroke SH of the closing element 16 in that the trajectory of the actuation point BP depends on the shape and dimensions of the opening element 20 . 20 ' . 20 '' and / or shape and dimensions of an end face 12 . 12 ' . 12 '' of the accumulator piston 10 . 10 ' . 10 '' is predetermined. Here, the trajectory of the operating point BP between the accumulator piston 10 . 10 ' . 10 '' and the opening element 20 . 20 ' . 20 '' be predefined with a continuous and / or erratic course. The actuation point BP of the accumulator piston 10 . 10 ' . 10 '' at the opening element 20 . 20 ' . 20 '' may, for example, due to a curved area 26 . 26 ' . 26 '' . 14 of the opening element 20 . 20 ' . 20 '' and / or an end face 12 . 12 ' . 12 '' of the accumulator piston 10 . 10 ' . 10 '' move along the given trajectory. This means that only the opening element 20 . 20 ' . 20 '' or just the face 12 . 12 ' . 12 '' of the accumulator piston 10 . 10 ' . 10 '' or both the opening element 20 . 20 ' . 20 '' as well as the face 12 . 12 ' . 12 '' of the accumulator piston 10 . 10 ' . 10 '' at least one curved area 26 . 26 ' . 26 '' . 14 having a displacement of the actuation point BP of the accumulator piston 10 . 10 ' . 10 '' at the opening element 20 . 20 ' . 20 '' along the given path of movement causes. Furthermore, on the frontal surface 12 . 12 ' . 12 '' of the accumulator piston 10 . 10 ' . 10 '' at least one operating area, 14.1 . 14.1 ' . 14.2 . 14.2 ' in which the contact point BP during the operation of the closing element 16 is arranged. The at least one operating area, 14.1 . 14.1 ' . 14.2 . 14.2 ' can be performed, for example, as an increase, depression with a curved or even course.

How out 1 to 4 it can be seen further, the opening element 20 . 20 ' . 20 '' as a pivot 28 rotatably mounted angular element with a first leg 22 . 22 ' . 22 '' and a second leg 24 . 24 ' . 24 '' executed. The first leg 22 . 22 ' . 22 '' is over a first curvature area 26 . 26 ' . 26 '' with the second leg 24 . 24 ' . 24 '' connected. The rotatable mounting of the opening element 20 . 20 ' . 20 '' occurs at a relative to the valve seat 18.1 fixed bearing point 30 at which a free end of the first leg 22 . 22 ' . 22 '' in a pivot 28 is stored. At the free end of the second leg 24 . 24 ' . 24 '' is the point of contact P with the closing element 16 arranged. This is the opening element 20 . 20 ' . 20 '' in the field of implementation 18 rotatably on the valve body 9 attached and over one at the lower end of the second leg 24 . 24 ' . 24 '' arranged actuation point BP during the opening movement on the end face 12 . 12 ' . 12 '' of the accumulator piston 10 . 10 ' . 10 '' at. Due to the two-part design of the opening element 20 . 20 ' . 20 '' and the accumulator piston 10 . 10 ' . 10 '' is advantageously the variable from Speicherolbenhub KH dependent translation between Speicherolbenhub KH and Öffnungselementhub ÖH or opening stroke SH of the closing element 16 and reducing the accuracy requirements for the manufacture, assembly and construction of the hydraulically controlled storage chamber valve 1 allows so that effort and production costs can be reduced and the functional robustness can be increased. Through contact with the accumulator piston 10 . 10 ' . 10 '' is via the opening element 20 . 20 ' . 20 '' the desired opening effect on the closing element 16 exercised. The opening element 20 . 20 ' . 20 '' can perform in its defined form 18 held and guided so that the second leg 24 . 24 ' . 24 '' essentially performs an axial movement.

In alternative embodiments, not shown, of an inventive Storage chamber valve, the rotatable mounting of the opening element takes place at a connected to the storage piston bearing point, wherein the opening element has at least one with respect to the valve seat fixed articulation point to enable the inventive displacement of the actuation point along a predetermined path of movement.

How out 1 and 2 can be further seen, comprises the end face 12 of the accumulator piston 10 in the first embodiment, centrally a rotationally symmetric curved area 14 , which with the between the first leg 22 and the second leg 24 . 24 ' . 24 '' of the opening element 20 arranged first curved area 26 cooperates so that the position of the actuation point BP changes over the course of the Speicherolbenhubs KH. In the in 1 illustrated closed position of the closing element 16 the actuation point BP has a clear distance L to the bearing point 30 and a clearance LK to the contact point P of the opening member 20 with the closing element 16 on. In the in 2 illustrated open position of the closing element, the actuation point BP has a clear distance L 'to the bearing point 30 and a clearance LK 'to the contact point P of the opening member 20 with the closing element 16 on. The contact point P moves with stroke movement SH of the accumulator piston 10 due to the first curvature 26 of the opening element 20 and the curved area 14 the face 12 of the accumulator piston 10 from the in 1 position shown in the in 2 shown position and thus changes the aspect ratio of the clear distance L to the clear distance LK 1 continuously in the aspect ratio of the clear distance L 'to the clear distance LK' from 2 , Thus, the ratio of the Speicherolbenhubs KH for Öffnungselementhub ÖH and opening stroke SH changes continuously.

How out 3 can be further seen, comprises the end face 12 ' of the accumulator piston 10 ' in the second embodiment, centrally a rotationally symmetric first increased operating range 14.1 and an increased rotationally symmetric second actuation area 14.2 , which at a predetermined distance from the central axis of the accumulator piston 10 ' is arranged. As a further difference from the first embodiment, the contact point BP 'runs along the straight first leg 22 ' which is substantially perpendicular to the second leg 24 ' runs and over a short curvature 26 ' with the second leg 24 ' connected is. Due to the two increased operating ranges 14.1 . 14.2 there are two discrete areas for the translation of the accumulator piston stroke KH to the opening element lift ÖH or opening stroke SH. In the closed position of the closing element 16 is the storage piston 10 ' far down and when approaching a stop touches the accumulator piston 10 ' the opening element 20 ' first with the first operating area 14.1 , This means that the point of contact BP 'between the accumulator piston 10 ' and the opening element 20 ' in the first operating area 14.1 is located and a first clearance L1 to the bearing point 30 having. In the first operating area 14.1 has the translation of the Speicherolbenhubs KH for Öffnungselementhub ÖH and opening stroke SH has a value of about 1 on. In the in 3 illustrated open position of the closing element 16 touches the accumulator piston 10 ' the opening element 20 ' with the second operating area 14.2 such that the point of contact BP 'between the accumulator piston 10 ' and the opening element 20 ' a second clearance L2 to the bearing point 30 having. In the in 3 illustrated open position of the closing element 16 has the translation of the Speicherolbenhubs KH for Öffnungselementhub ÖH or opening stroke SH has a value less than 1, so that the accumulator piston 10 ' a much smaller stroke than the closing element 16 performs, so that there is a significantly reduced volume absorption in the base braking.

How out 4 can be further seen, comprises the end face 12 '' of the accumulator piston 10 '' in the third embodiment, centrally a rotationally symmetrical flat first operating area 14.1 ' and an increased rotationally symmetric second actuation area 14.2 ' , which at a predetermined distance from the central axis of the accumulator piston 10 ' is arranged. As a further difference from the first and second embodiments, the opening element 20 '' on the first leg 22 '' in addition to between the first leg 22 '' and the second leg 24 '' arranged first curved area 26 '' another area of curvature 27 on which between the first curvature area 26 '' and the fixed bearing point 30 or articulation point is arranged. Through the two operating areas 14.1 ' . 14.2 ' there are two discrete areas for the translation of the accumulator piston stroke KH to the opening element lift ÖH or opening stroke SH. In the closed position of the closing element 16 is the storage piston 10 '' far down and when approaching a stop touches the accumulator piston 10 '' the opening element 20 '' first with the first operating area 14.1 ' , This means that the point of contact BP "between the accumulator piston 10 '' and the opening element 20 '' in the first operating area 14.1 ' is located and a first clearance L1 'to the bearing point 30 having. In the first operating area 14.1 ' has the translation of the Speicherolbenhubs KH for Öffnungselementhub ÖH and opening stroke SH has a value of about 1 on. In the in 4 illustrated closed position of the closing element 16 touches the accumulator piston 10 '' the opening element 20 '' with the first operating area 14.1 , By the in 4 shown combination of a curved (first curvature 26 '' ) and cranked (second curvature 27 ) Opening element 20 '' with the first level operating area 14.1 ' and the second raised operation area 14.2 ' the face 12 '' of the accumulator piston 10 '' can be switched suddenly from a first translation of the Speicherolbenhubs KH to Öffnungselementhub ÖH or opening stroke SH with the clear distance L1 'to a second translation of the Speicherolbenhubs KH to Öffnungselementhub ÖH or opening stroke SH with the shorter clear distance L2' when the accumulator piston 10 '' due to the lifting movement of the opening element 20 '' with the second operating area 14.2 ' touched. In the in 4 illustrated closed position of the closing element 16 has the translation of the Speicherolbenhubs KH for Öffnungselementhub ÖH or opening stroke SH has a value of about 1, so that the accumulator piston 10 '' the same stroke as the closing element 16 performs. With the touch of the second operating area 14.2 ' decreases the clear distance of the contact point BP '' to the bearing point 30 from the first distance L1 'to the second distance L2' and the translation of the Speicherolbenhubs KH for Öffnungselementhub ÖH or opening stroke SH has a value less than 1, so that the accumulator piston 10 '' a much smaller stroke than the closing element 16 performs, so that there is a significantly reduced volume absorption in the base braking.

Alternatively, other suitable combinations of the shapes and dimensions of the opening element and / or the end face of the accumulator piston can be made in order to achieve a variable course of the translation of the accumulator piston stroke for Öffnungselementhub or opening stroke. For example, only the opening element or only the end face of the accumulator piston may have a curved area, or more than two actuation areas may be provided on the end face of the accumulator piston.

Embodiments of the present invention provide a storage chamber valve which has a variable, dependent on the storage piston stroke translation between storage piston stroke and Öffnungselementhub or opening stroke.

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

• US 7543896 B2 [0004]
• DE 4202388 A1 [0005]

Claims (10)

Hydraulically controlled storage chamber valve with a storage chamber ( 7 ) and one in the storage chamber ( 7 ) movably guided accumulator piston ( 10 . 10 ' . 10 '' ) and an implementation ( 18 ) over which the storage chamber ( 7 ) is connected to a fluid supply, wherein a closing element ( 16 ) one at the edge of the implementation ( 18 ) arranged valve seat ( 18.1 ) in a valve body ( 9 ), wherein an opening element ( 20 . 20 ' . 20 '' ) the implementation ( 18 ) in the valve body ( 9 ) and from the storage piston ( 10 . 10 ' . 10 '' ), wherein an axial accumulator piston stroke (KH) via the opening element ( 20 . 20 ' . 20 '' ) an axial opening stroke (SH) of the closing element (FIG. 16 ), wherein the opening element ( 20 . 20 ' . 20 '' ) the closing element ( 16 ) from the valve seat ( 18.1 ) and moves from a closed position to an open position when the volume in the storage chamber ( 7 ) falls below a predetermined threshold, characterized in that a coupling between the accumulator piston ( 10 . 10 ' . 10 '' ) and the opening element ( 20 . 20 ' . 20 '' ) is designed so that a corresponding actuation point (BP) between the accumulator piston ( 10 . 10 ' . 10 '' ) and the opening element ( 20 . 20 ' . 20 '' ) as a function of the accumulator piston stroke (KH) according to a predetermined trajectory and a translation between the accumulator piston stroke (KH) and the opening stroke (SH) from the closed position to the open position of the closing element ( 16 ) and vice versa variable. Storage chamber valve according to claim 1, characterized in that the movement path of the actuation point (BP) runs continuously and / or abruptly. Storage chamber valve according to claim 1 or 2, characterized in that the movement path of the actuation point (BP) has an aspect ratio (LV) between a clear distance (L, L ', L1, L2) of the actuation point (BP) relative to the valve seat (BP). 18.1 ) fixed articulation point and / or bearing point ( 30 ) of the opening element ( 20 . 20 ' . 20 '' ) and a clear distance (LK, LK ') of the actuation point (BP) and a contact point (P) of the opening element ( 20 . 20 ' . 20 '' ) with the closing element ( 16 ) changed. Storage chamber valve according to one of claims 1 to 3, characterized in that the shape and dimensions of the opening element ( 20 . 20 ' . 20 '' ) and / or shape and dimensions of an end face ( 12 . 12 ' . 12 '' ) of the accumulator piston ( 10 . 10 ' . 10 '' ) the trajectory of the actuation point (BP) between the accumulator piston ( 10 . 10 ' . 10 '' ) and the opening element ( 20 . 20 ' . 20 '' ) pretend. Storage chamber valve according to claim 4, characterized in that the opening element ( 20 . 20 ' . 20 '' ) and / or the end face ( 12 ) of the accumulator piston ( 10 ) at least one curved area ( 26 . 26 ' . 26 '' . 14 ) exhibit. Storage chamber valve according to claim 5, characterized in that the at least one curved area ( 14 ) and / or at least one operating area ( 14.1 . 14.1 ' . 14.2 . 14.2 ) of the end face ( 12 . 12 ' . 12 '' ) rotationally symmetrical centered on the end face ( 12 . 12 ' . 12 '' ) and / or with a predetermined distance to the central axis of the accumulator piston ( 10 . 10 ' . 10 '' ) are arranged. Storage chamber valve according to one of claims 1 to 6, characterized in that the opening element ( 20 . 20 ' . 20 '' ) as a rotatably mounted angular element with a first leg ( 22 . 22 ' . 22 '' ) and a second leg ( 24 . 24 ' . 24 '' ), wherein the first leg ( 22 . 22 ' . 22 '' ) over a first curvature area ( 26 . 26 ' . 26 '' ) with the second leg ( 24 . 24 ' . 24 '' ) connected is. Storage chamber valve according to claim 7, characterized in that the rotatable mounting of the opening element ( 20 . 20 ' . 20 '' ) at with respect to the valve seat ( 18.1 ) fixed bearing point ( 30 ) takes place at which a free end of the first leg ( 22 . 22 ' . 22 '' ) is stored. Storage chamber valve according to claim 7, characterized in that the rotatable mounting of the opening element ( 20 . 20 ' . 20 '' ) at one with the storage piston ( 10 . 10 ' . 10 '' ) connected bearing point, wherein the opening element ( 20 . 20 ' . 20 '' ) at least one with respect to the valve seat ( 18.1 ) has fixed articulation point. Storage chamber valve according to one of claims 7 to 9, characterized in that the opening element ( 20 . 20 ' . 20 '' ) on the first leg ( 22 . 22 ' . 22 '' ) between the first curvature region ( 26 . 26 ' . 26 '' ) and the fixed bearing point ( 30 ) or articulation point another curvature area ( 27 ) having.

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