EP2519732A1

EP2519732A1 - Electromagnetically actuated volume control valve, in particular for controlling the delivery volume of a high-pressure fuel pump

Info

Publication number: EP2519732A1
Application number: EP10778969A
Authority: EP
Inventors: Winfried Eckart; Valentin Szermutzky; Ersin Dogan; Juergen Koreck; Matthias Maess
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2009-12-29
Filing date: 2010-11-04
Publication date: 2012-11-07
Anticipated expiration: 2030-11-04
Also published as: KR101506475B1; KR20120096934A; EP2519732B1; WO2011079989A1; ES2704993T3; KR20140140131A; CN102686868B; KR101736081B1; DE102009055356A1; CN102686868A

Abstract

The invention relates to an electromagnetically actuatable volume control valve, in particular for controlling the delivery volume of a high-pressure fuel pump. The volume control valve comprises a movement chamber (28), which can be filled with a fluid (30), a moving part (22) of an electromagnetic actuating device arranged in said chamber, and a stop (26). When the moving part (22) rests against the stop (26), a contact area is present between the moving part (22) and the stop (26). The contact area is defined by a surface of the moving part (22) and a surface of the stop (26). The contact area is smaller than the total area of the moving part (22) or the stop (26).

Description

description

title

Electromagnetically actuated quantity control valve, in particular for controlling the delivery rate of a high-pressure fuel pump

State of the art

The invention relates to an electromagnetically actuated quantity control valve according to the preamble of claim 1.

From the market known quantity control valves, which have an electromagnetically actuated valve element. Thus, the high pressure pump supplied amount of fuel in the fuel injection system

Internal combustion engine to be influenced.

It is also known to provide an armature of the electromagnet, for example, with longitudinal bores in order to adjust the damping occurring during the movement of the armature can. Through such axial bores in the armature fluid, so fuel, transported from one axial side of the armature to the other side. As an alternative to an axial bore in the armature, it is also known to provide axial grooves on a peripheral wall of the armature, which also allow a fluid exchange between the two sides of the armature.

Disclosure of the invention

The invention provides an electromagnetically actuated quantity control valve according to claim 1. Advantageous developments are in

Subclaims specified. For the invention important features can be found also in the following description and in the drawings, the features both alone and in different combinations may be important to the invention, without being explicit again

is pointed out.

The quantity control valve according to the invention has a in one

5 housing section in two directions movable anchor, with a

Movement direction is limited by a stop. The housing section can be filled with fluid. If the anchor abuts against the stop, then there is one

Contact surface determined by the surface area of the two contact elements, the armature and the stop, being less than the total area of the L0 anchor or stop.

An advantage of the invention is that during an attraction movement, i. a movement of the armature on the stop, in the area of the contact surface before the contact in connection with the fluid forms a pressure cushion, L5 which determines the speed of movement before the impact of the armature on the

Stop reduced. This effect is called squeezing effect.

Another advantage of the invention is evident in a peel, i. a movement of the armature away from the stop, starting from a contact 20 of the armature to the stop. In the area of the contact surface arises

Volume, which is now refilled with the fluid. The reduction of the contact area compared to the total area of the armature or stop makes it possible to reduce a so-called hydraulic sticking of the armature to the stop, and thus to reduce switching times.

25

Impact deceleration during the tightening movement and reduction of hydraulic sticking during the peeling movement will increase the NVH (Noise, Vibration & Harshness) characteristics of the quantity control valve, i. the properties relating to noise, vibration and roughness are influenced in a positive way.

The impact delay reduces the pulsation of the pressure during the tightening movement. Also Preller, ie a multiple impact in the tightening movement by resilient properties of the components involved, 35 are minimized. A reduction of cavitation tendency is due to the time damped pressure curve and thus a slight tendency to locally suddenly occurring pressure differences achieved.

Due to the design of the respective surfaces of the armature and the stopper 5, especially with regard to the size and shape of the contact surfaces is a

Compromise between the impact damping and the reduced hydraulic bonding achieved.

With the aforementioned advantages is also achieved that a low L0 strength-critical load and low erosion and thus increased

Lifetime of the components involved, such as welds, sleeves, or similar. is reached.

This also makes it possible to guarantee an exact delivery rate over the entire L5 service life as well as short operating times.

In an advantageous embodiment of the quantity control valve introduces

Venting volume, which is connected to an axial channel within the armature, to the fact that during the peeling movement, a rapid refilling 20 of the volume arising in the region of the contact surface is achieved. The

Venting volume is also advantageous in the tightening movement, since the fluid, which is located in the region of the contact surfaces, can flow off quickly.

In a further advantageous embodiment of the quantity control valve 25 exists a dead volume, which is included in the abutment of the armature at the stop between the two contact partners and has no connection to an axial channel. During the tightening movement, the dead volume shortly before the abutment of the armature against the stopper causes the fluid in the dead volume to be pinched off and thus also acts as a pressure cushion between the armature 30 and the stop. Thus, with a small contact area a

achieved strong cushioning by means of effective as a pressure pad dead volume.

In an advantageous embodiment of the quantity control valve exists radially

35 within the contact surface a first vent volume and radially outside the contact surface a second vent volume. That means that at the Tightening movement, the fluid on both sides, ie radially inward and radially outward, can flow. The advantage is evident in the removal movement. The volume created in the region of the contact surface can be refilled from two sides and the effect of the hydraulic bonding is further reduced.

In an advantageous embodiment of the quantity control valve is the

Embodiment with first and second vent volume such

configured such that both vent volumes are connected via a connection and only one of the vent volumes is connected to openings of the axial channels. As a result, the venting of the two venting volumes can be guaranteed and no further axial channels with openings in both venting volumes are necessary.

In a further advantageous embodiment of the quantity control valve, a surface of the armature or of the stop is made non-magnetic.

As a result, a magnetic separation is achieved and prevents that when a concern of the armature to the stop a separation of the two

Contact partner is possible only under great effort. Likewise, a non-magnetic material may have a higher strength than the material of the armature or the abutment, which increases the wear resistance and thus the life of the quantity control valve.

In an advantageous embodiment of the quantity control valve is the

Texture of a surface, which is the contact surface associated, characterized by a profiling. By profiling can be the

Quetscheffekt and hydraulic bonding, so adjust the behavior during the tightening and Abziehbewegung in the area of concern of anchor and stop exactly.

Hereinafter, exemplary embodiments of the invention will be explained with reference to the drawings. In the drawing show:

Figure 1 is a simplified diagram of a fuel injection system of a

Internal combustion engine; Figure 2a is a sectional view of a simplified schematic of a

Electromagnet (without coil) of a quantity control valve in a tightening movement;

FIG. 2b shows a sectional view of the electromagnet (without coil) of the FIGURE

2a in a peeling motion;

FIG. 3a shows a sectional view according to FIG. 2a with an armature with a circular contact surface;

L0

Figure 3b is an axial plan view corresponding to a direction of purple on the

Anchor according to the figure 3a;

4a shows a sectional view according to Figure 2a with a stop with a

L5 circular contact surface;

Figure 4b is an axial plan view corresponding to a direction IIIb on the

Stop according to the figure 4a;

FIG. 5a shows a sectional view according to FIG. 2a with an armature with an annular contact surface;

Figure 5b is an axial plan view corresponding to a direction of purple on the

Anchor according to the figure 5a;

25

FIG. 6a shows a sectional view according to FIG. 2a with an armature with an annular contact surface;

Figure 6b is an axial plan view corresponding to a direction of purple on the

30 anchor according to the figure 6a;

FIG. 7a shows a sectional view according to FIG. 2a with an armature with an annular contact surface and a groove;

Figure 7b is an axial plan view corresponding to a direction of purple on the

Anchor according to FIG. 7a; Figure 8 is a sectional view of a stopper body;

Figure 9 is a sectional view of a stop anchor;

Figure 10a is a sectional view of a stop anchor; and

Figure 10b is an axial plan view of a stop body according to

Direction IIIb of Figure 10a.

The same reference numerals are used for functionally equivalent elements and sizes in all figures.

Figure 1 shows a fuel injection system 1 of an internal combustion engine in a much simplified representation. A fuel tank 9 is connected via a suction line 4, a Vorforderpumpe 5 and a low-pressure line 7 with a (not explained in detail) high-pressure pump 3. To the high-pressure pump 3, a high-pressure accumulator 13 ("common rail") is connected via a high-pressure line 1 1. A quantity control valve 14 with an electromagnetic actuator 15 - hereinafter referred to as an electromagnet 15 - is arranged hydraulically in the course of the low pressure line 7 between the Vorforderpumpe 5 and the high pressure pump 3. Other elements, like

For example, valves of the high-pressure pump 3 are not shown in the figure 1. It is understood that the quantity control valve 14 may be formed as a unit with the high-pressure pump 3. For example, an intake valve of the high-pressure pump 3 can be forcibly opened by the quantity control valve 14.

During operation of the fuel injection system 1, the pre-demand pump 5 delivers fuel from the fuel tank 9 into the low-pressure line 7. In this case, the quantity control valve 14 determines the quantity of fuel supplied to the high-pressure pump 3.

Figure 2a shows a simplified representation of a section of

Quantity control valve 14, and the electromagnet 15. The elements shown in Figure 2a have a rotational symmetry about a central longitudinal axis of a housing portion 20 substantially. Shown is the substantially hollow cylindrical housing portion 20, and in this a generally markable as a moving part, displaceable in the direction of the longitudinal axis anchor 22 and fixed to the armature 22

Connected valve element 24. The housing portion 20 is limited in the right part of the drawing by a stop 26. In one in the

Housing portion 20 formed and generally as a movement space

markable armature space 28 is located on both sides of the armature 22, a non-visible in the drawing fluid 30. Between an inner

Peripheral wall 32 of the housing portion 20 and an outer peripheral wall

34 of the armature 22 is a circumferential annular gap 36, which is shown exaggerated.

In the present case, the armature 22 has four axial channels 38, two of which are visible in the sectional view of FIG. 2a. The channels 38 can either be designed as bores in the armature 22 or as a groove on the peripheral wall 34 of the armature 22, as shown.

In an end position in the direction of the arrow 42, the end face of the armature 22 is located on the stop 26 in the region of a contact surface directly. The contact surface is defined in the apparatus of Figure 2a by the front surface of the armature 22 and interrupted only by the mouths of the channels 38.

The contact surface is generally composed of the overlapping surfaces of armature 22 and stop 26. The individual surfaces can in the

Contrary to the approximately plane-parallel surfaces shown in Figure 2a also have a different surface shape, such as a convex, concave or wave-like surface shape, so that they form the contact surface upon contact by a nested fitting.

In the operating situation of the electromagnet 15 shown in Figure 2a, the armature 22 is moved together with the valve element 24 in the drawing to the right, which corresponds to the tightening movement. This is symbolized by an arrow 42. The tightening movement is characterized in that the moving part, here the armature 22, on a non-movable part, here the

Stop 26, too moved. After concern of the anchor 22 on the stop 26, the armature 22 is moved away from the stop 26 or pulled away. This is the stripping movement. An opening or closing of the valve is not meant with the tightening or Abziehbewegung.

The total area of the armature 22 on the front side, that is to say on the side facing the stop 26, corresponds to the plan view surface from the direction IIIa. The plan view surface takes neither the mouths of the axial channels 38 nor the annular gap 36. For the stop 26 exists another

Top view surface from the direction lllb and thus also another

Total area. The total area is thus defined by a plan view surface from the direction of the opposite contact partner, here the armature 22 or the stopper 26.

When tightening the volume of a portion 44 of the

Anchor space 28 steadily reduced. Thus, the existing in the section 44 fluid 30 is displaced. The fluid 30 flows out of this section 44 in accordance with the arrows 46 drawn.

By a viscosity of the fluid 30 and the movement of the armature 22 in the direction of the stop 26, a so-called crushing effect occurs. Of the

Quetscheffekt means a hindrance to the displacement of the fluid 30. This is indicated in Figure 2a by double arrows 48. With the squeezing effect, an impact damping of the armature 22 is made possible. That the armature 22 can fly at high speed on the stop 26 and the impact of the armature 22 on the stop 26 is damped by the crushing effect and a pressure pad resulting therefrom.

The crushing effect depends on the contact surface between anchor 22 and stop 26. The pressure pad extends in the illustrated in Figure 2a quantity control valve 14 corresponding to the illustrated double arrows 48 between the overlapping surfaces of the armature 22 and the

Attack 26. As shown, the surfaces of the armature 22 and abutment 26 in FIG. 2a, except for the annular gap 36 and the mouths of the axial channels 38, completely overlap. The operating situation in FIG. 2b corresponds to the pull-off movement corresponding to the arrow 43 against the tightening movement in FIG. 2a. Between the operating situations in FIGS. 2a and 2b, an impact of the armature 22 on the abutment 26 takes place. According to the operating situation in FIG

5 the impact again a volume in the area of the contact surface between the

Anchor 22 and the stopper 26. The volume is filled with the fluid 30 via the axial channels 38 corresponding to the arrows 47. Depending on the viscosity of the fluid 30 and the profile of the armature 22 and the stop 26, a so-called hydraulic bonding may occur, which is the

L0 pull-off aggravates.

In the following figures, usually only the tightening movement is shown.

The sectional view of Figure 3a shows a section of the quantity control valve L5 14 with an electromagnet 15 in a simplified representation, following the representation principle of Figure 2a. The armature 22 in this case has a cylindrical projection 62 with a circular surface 60. The circular surface 60 defines the contact surface. The surface 60 is smaller than the total area of the armature 22.

20

The material of one of the contact surface forming surfaces of the armature 22 or the stopper 26 is made non-magnetic. This can be done for example by a chrome plating, which also represents a wear-resistant surface.

25

The surface 60, in contrast to Figure 3a also have a different shape, in which case the opposite stop 26 has a corresponding, the shape of the surface 60 receiving shape. For example, the surface 60 may have a concave shape and the stop in the corresponding area may have a convex shape.

Likewise, the surface 60 may be configured such that when a gap between the armature 22 and the stop 26 is present. For example, if a radially outwardly increasing distance from the surface 35 60 and stop 26 is provided in the region of the contact surface, the gap is created radially outwards. This gap allows fluid from a radial outside the contact surface lying in the area of the volume

Can flow contact surface and prevents hydraulic sticking or

is reduced. Despite the gap can be in the tightening movement of the

Squeezing effect can be used.

The surface 60 may be characterized by a profiling. This can be designed differently. For example, a profile in the form of concentric circles makes it difficult for the fluid 30 to flow in the radial direction during the application and removal movement. This means that compared to a smooth surface during the tightening movement

Pressure pad and the peeling movement, the hydraulic bonding are more pronounced.

In contrast, a ray of a center of the leads

Surface outgoing profiling that it is the fluid 30 is facilitated in the tightening and Abziehbewegung to flow in the radial direction. This means that in comparison to a smooth surface during the tightening movement the pressure pad and during the stripping movement the hydraulic bonding are less pronounced.

FIG. 3b shows the axial plan view of the armature 22 corresponding to the direction lilac in FIG. 3a. For graphic reasons, only the upper half of the armature 22 is shown. The lower half, not drawn, is mirror-symmetrical. In FIG. 3b, the axial channels 38 and the cylindrical projection 62 with the circular surface 60 can be seen. Furthermore, one half of the double arrow 48 can be seen, which is the

Pressure pad represents. The peripheral wall 34 limits the anchor 22.

The operating situation in FIG. 3 a is as follows: According to the operating situation in FIG. 2 a, the tightening movement, the armature 22 is moved to the right with a valve element 24 corresponding to an arrow 42 in the drawing. The volume of the portion 44 of the armature space 28 is steadily reduced and the fluid flows in accordance with arrows 46 from the

Part 44 out. The crushing effect arises between the circular surface 60 and the overlapping part of the surface of the stop 26. The crushing effect creates a pressure pad according to the double arrow 48 and an impact damping of the armature 22 is ensured. Because the surface 60 is smaller than the total area of the armature 22, this results

Pressure pad not in the area of the total surface of the armature 22, but only in the area of the smaller contact surface.

In a pull-off movement of the armature 22, not shown, a volume L0 arises in the region of the contact surface, which extends over the circular surface

60 is defined. This volume fills via a vent volume 65 radially from the outside, wherein the vent volume 65 in turn fills via the axial channels 38. As a result of the surface 60 being smaller than the total area of the armature 22, the hydraulic bonding is reduced in comparison to FIGS. 2a and 2b L5.

The reduced in comparison to Figure 2a contact surface in Figure 3a thus allows a reduction in the impact speed in the tightening movement of the armature 22 by the squeezing effect and a reduction of the hydraulic bonding in the peel-off movement of the armature 22 by a ventilation of

Contact area.

The sectional view of Figure 4a shows a section of the quantity control valve 14 in a simplified representation, following the representation principle of Figure 25 2a. The stop 26 has a cylindrical projection 62 with a

circular surface 60 on. The circular surface 60 is smaller than the total area of the abutment 26. Thus, as in FIGS. 3a and 3b, the contact area decreases in comparison to FIG. 2a.

In FIG. 4b, the axial plan view of the stop 26 is corresponding to FIG

Can be seen direction lllb of Figure 4a with the cylindrical projection 62 and the circular surface 60. Furthermore, one half of the double arrow 48 can be seen, which represents the pressure pad. The inner one

Peripheral wall 32 of the housing portion 20 limits the plan view shown

35 of the stop 26. The operating situation in FIG. 4a substantially corresponds to that of FIG. 3a. A pull-off movement, not shown, essentially corresponds to the explanations regarding FIGS. 3a and 3b.

The cylindrical projection 62 and thus the circular contact surface 60 are formed on the armature 22 in FIGS. 3a and 3b, and on the stop 26 in FIGS. 4a and 4b. The contact surface and thus the pressure pad can, according to the double arrows 48 of the corresponding figures 3a to 4b, that is also achieved by a correspondingly reversed profiling of the armature 22 and the stopper 26. The following exemplary embodiments are therefore to be understood as meaning that an approximately equivalent function with respect to the contact surfaces and the pressure pad can also be achieved by a correspondingly inverted shape or profiling of the opposing contact partners. When profiling a desired ventilation through the axial channels 38 is also to be considered.

The sectional view of FIG. 5a, following the illustration principle of FIG. 2a, shows in a simplified representation a detail of the quantity control valve 14 with an electromagnet 15. In this case, the armature 22 has one

hollow cylindrical projection 64 with an annular surface 61, wherein axial channels 38 are radially outside of the hollow cylindrical projection 64. The annular surface 61 is smaller than the total area of the armature 22.

The contact area of FIG. 5a is smaller in comparison to the contact area in FIG. 3a, assuming the same circular outside diameter of the cylindrical projection 62 in FIG. 3a and the hollow cylindrical projection 64 in FIG. 5a.

Furthermore, there is a dead volume 66, which is limited by the hollow cylindrical projection 64.

FIG. 5b shows the axial plan view of the armature 22 corresponding to a direction lilac according to FIG. 5a with the hollow-cylindrical projection 64, the annular surface 61 and the dead volume 66. The armature 22 is bounded by the peripheral wall 34 and further includes the axial channels 38. The arrows 48 represent the pressure pad. The operating situation in FIG. 5a essentially corresponds to that of FIG. 2a. Shortly before the abutment of the armature 22 against the abutment 26, the fluid 30, which is located in the dead volume 66, is closed by the venting volume 65 located radially outside 5. As a result, in addition, the fluid 30 in the dead volume acts as a pressure pad, resulting in a similar effect, as in a circular surface 60 of Figure 3a and 3b. This means that in this case the effective pressure pad surface is greater than the contact surface.

L0

A pull-off movement, not shown, essentially corresponds to the

Explanations to Figure 3b, wherein a filling in the region of the contact surface and the trapped dead volume 66 similar to Figure 3b occurs radially from the outside via the vent volume 65.

L5

The sectional view of Figure 6a shows, following the representation principle of Figure 2a, in a simplified representation of a section of the quantity control valve 14 with an electromagnet 15. The armature 22 in this case has a hollow cylindrical projection 64 with an annular surface 61, wherein the axial channels 38th radially inside the hollow cylindrical projection

64 lie. The annular surface 61 is smaller than the total area of the armature 22.

In FIG. 6b, the axial plan view of the armature 22 corresponding to a direction lil to the figure 6a with the hollow cylindrical projection 64 and the annular surface 61 can be seen. The armature 22 is bounded by a peripheral wall 34 and further includes the axial channels 38 radially inwardly of the hollow cylindrical projection 64. The arrows 48 represent the pressure pad.

30

The operating situation in FIG. 6a is as follows: Due to the movement of the armature 22 in the direction of the arrow 42, a pressure cushion according to the double arrows 48 forms shortly before the abutment of the armature 22 against the stop 26. In the radially inside of the hollow cylindrical projection 64 lying mouths 35 of the axial channels 38 exists within the annular surface 61 a

Vent volume 65. The armature 22 has no dead volume 66 as in Figure 5a and 5b and the fluid 30 may be radially inside the hollow cylindrical

Projection 64 flow through the axial channels 38. Since the annular surface 61 is closed with the annular gap 36, the fluid 30 can flow when applying the armature 22 to the stop 26 substantially only in a direction 5 and that radially inwardly.

For the withdrawal movement, not shown, the design of the armature 22 means that a filling of the volume, which arises in the removal movement in the region of the annular surface 61, by the fluid 30 L0 occurs, which is radially within the hollow cylindrical projection 64, ie in the vent volume 65, is located. The vent volume 65 is filled via the channels 38.

The sectional view of Figure 7a shows a representation similar to that of L5 Figure 5a, but with additional grooves 68 in the hollow cylindrical projection

64 of the armature 22. The annular surface 61 is thus interrupted by the radial grooves 68. The armature 22 has only two axial channels 38 in this case. The annular surface 61 is smaller than the

Total area of the armature 22.

20

FIG. 7b shows the axial plan view of the armature 22 corresponding to the direction lil to that of FIG. 7a with the hollow cylindrical projection 64, the interrupted annular surface 61 and the radial groove 68. The armature 22 is bounded by the peripheral wall 34 and further includes the axial channels 38 radially outwardly of the hollow cylindrical projection 64.

The double arrows 48 represent the pressure pad.

The operating situation in FIG. 7a substantially follows the description for FIG. 5a. Compared with Figures 5a and 5b, the reduced as pressure pad

30 effective area by replacing the dead volume 66 of Figure 5a and 5b in

Shape of a central first vent volume 65 within the

hollow cylindrical projection 64. Thus, the fluid 30, which is located within the hollow cylindrical projection 64, on the radially outside of the hollow cylindrical projection 64 lying second

35 bleed volume 65 drain into the channels 38. The effective as a pressure pad

Surface is thus equal to the contact surface. The arrow 67 in FIG. 7b indicates how the fluid 30 moves out of the first vent volume 65 into the second vent volume 65 during the tightening movement of the armature 22 and drains off directly via the axial channel 38.

In a pull-off movement of the armature 22, not shown, the resulting volume in the area of the annular contact surface 61 fills radially from two directions: on the one hand radially from the outside through the second

Venting volume 65 and via the axial channels 38 tracked fluid 30, on the other radially from the inside by the first vent volume 65 and the over the axial channels 38 and the grooves 68 tracked fluid 30th

Figure 8 shows a simplified representation of a section of

Quantity control valve 14. Shown is the housing portion 20 and in this the armature 22, connected to the valve element 24 as in Figure 2a. Furthermore, a fixed to the housing portion 20 stop body 73 is shown with a stop 27. The contact area between the armature 22 and stop 27 according to the arrows 48 is smaller than the total area of the armature 22.

A pull-off movement of the valve element 24 with the armature 22 is characterized in that the armature 22 moves in the direction of the arrow 43 toward the stop 26. Between the armature 22 and the stopper body 73, the pressure pad according to the double arrows 48 builds up before an impact or concern of the armature 22. In this case, the fluid 30 can flow off via the vent volume 65 and the channels 38 in accordance with the arrows 46.

In an unillustrated tightening movement of the armature 22, i. one

Movement of the armature 22 away from the stop 27, the volume between the contact surface between the armature 22 and stop 27 must be refilled with the fluid 30. For this purpose, the fluid 30 flows from the vent volume 65 and the channels 38 after. Figure 9 shows a section of a quantity control valve 14 with two

fixed abutment bodies 73 with the stops 26 and 27, which limit the movement of the valve element 24 by one with the

Valve element 24 firmly connected stop anchor 72 serve. Of the

Stop anchor 72 is movable in the housing portion 20 along the longitudinal axis. The valve member 24 is connected in a manner not shown with the armature 22, wherein the armature 22 is located on the right side of FIG 9. The annular contact surface between the stop anchor 72 and the stop 26 according to the arrows 48 is smaller by the venting volumes 65 in the stopper body 73 than the total area of the stop anchor

72nd

By way of example, the operating situation in FIG. 9 shows the moment shortly before abutment of the stop anchor 72 against the stop 26, i. the dressing movement. Here, a pressure pad according to the double arrows 48 formed between the overlapping surfaces of the stop anchor 72 and the stopper 26 and the stopper body 73 and the fluid 30 is on the

Vent volumes 65 in the armature space 28 according to the arrows 46 displaced. Analog forms at an arrow 42 opposite

Movement of the valve element 24, a pressure pad on the stop 27 from.

An unillustrated peeling movement of the stop anchor 72 of the

Stop 26 opposite to the arrow 42 has the result that in the region of the contact surface resulting volume between stop anchor 72 and

Stop 26 is filled with the fluid 30 from the venting volumes 65.

10a shows a simplified representation of a section of the quantity control valve 14, or the electromagnet 15. Shown is the housing portion 20, and in this a longitudinal axis along the slidable stop anchor 72 with a peripheral wall 74. The displaceable

Stop anchor 72 is fixedly connected to the valve element 24. The

Valve element 24 is guided radially in the stationary stop body 73. An inner circumferential wall 78 of the stopper body 73 defines with an outer peripheral wall 80 of the valve element 24 a guide gap 79 for guiding the valve element 24. The guide gap is shown exaggeratedly large. The stopper body 73 is characterized in that it in a direction purple, ie in the direction of the stop armature 72, a conical

Has a diameter jump 82. The conical diameter jump 82 corresponds to an enlargement of the inner diameter in the direction of purple starting from the peripheral wall 78 and continues until the stop 26. Furthermore, the stop body 73 on the stop armature 72 side facing a groove 68th

L0 The groove 68 extends from the diameter jump 82 in radial

Direction beyond the diameter of the peripheral wall 74 of the stop anchor 72 to the peripheral wall 32 of the armature space 28. The groove 68 connects the vent volume 65 within the diameter jump 82 with the armature space 28. By the diameter jump 82 and the groove 68 results

L5 an interrupted by the groove 68, annular contact surface. The

Contact area is smaller than the total area of the armature 22.

In the figure 10b is the axial plan view of the stopper body 73rd

according to the direction IIIb according to the figure 10a and a cross section of

20 valve element 24 to see. The radial bearing of the valve element 24 is shown with the limited by the peripheral walls 78 and 79 guide gap 79. Radially starting from the peripheral wall 78 via the diameter jump 82 of the stop body 73 goes over into the stop 26. Double arrows 48 represent the pressure pad and show with the indicated peripheral wall

25 74 of the stop anchor 72 interrupted by the groove 68, annular

Contact surface on.

The operating situation in FIGS. 10a and 10b is as follows: The stop anchor 72 moves in the form of a tightening movement with the

30 valve element 24 to the stop 26 and thus the valve body 73 to. Shortly before the concerns of the stop anchor 72 on the stop 26 is formed by the fluid 30 is interrupted by the groove 68, annular pressure pad corresponding to the contact surface and the double arrows 48. The broken, annular contact surface is reduced by the diameter jump 82 and

35 relates to the overlapping surfaces of stop 26 and stop anchor

72. The fluid 30, which at the abutment of the stop anchor 72 at the Stop 26 is located in the region of the diameter jump 82, can flow via the groove 68 along the arrow 76 via venting volumes 65 in the armature space 28. As a result, the fluid 30 within the diameter jump 82 and within the groove 68 does not act as a pressure pad. By the

Guide gap 79 can flow substantially no fluid 30.

In a pull-off movement, not shown, a resulting volume in the area of the interrupted, annular contact surface is filled radially from the inside and from the outside by the venting volumes 65 with the fluid 30. The fluid 30 flows over the armature space 28 radially from the outside. Furthermore, the fluid 30 flows over the inside diameter jump 82 and the groove 68 to.

Claims

claims

1 . Electromagnetically actuated quantity control valve (14), in particular for controlling the delivery rate of a high-pressure pump (3), having a movement space (28) which can be filled with a fluid (30), a moving part (22, 72) of an electromagnetic

Actuating device (15), and a stop (26, 27), characterized in that when the moving part (22, 72) abuts the stop (26, 27) between the moving part (22, 72) and the stop (26, 27) 27) has a contact surface, that the contact surface is defined by a surface of the moving part (22, 72) and a surface of the stopper (26, 27), and that the contact surface is smaller than the total area of the moving part (22, 72) or of the stop (26, 27).

2. Electromagnetically actuated quantity control valve (14) according to claim 1 having a channel (38) in the moving part, which connects the lying on both sides of the moving part (22) areas of the movement space (28), wherein in the concerns of the moving part (22) on the stop (26, 27) via the channel (38) fillable

Vent volume (65) is present.

3. Electromagnetically actuated quantity control valve (14) according to claim 1, wherein a dead volume (66) in the abutment of the moving part (22) on the stop (26, 27) is not filled.

4. Electromagnetically actuated quantity control valve (14) according to one of claims 1 to 3, wherein radially outward and radially within the

Contact surface venting volumes (65, 67) are present.

5. Electromagnetically actuated quantity control valve (14) according to claim 4, wherein a first vent volume (67) in the concern of the Movement space (28) with the fluid (30) via a connection (38, 68) from a second vent volume (65) can be filled.

Electromagnetically actuatable quantity control valve (14) according to one of the preceding claims, wherein one of the surfaces of the contact surface consists of non-magnetic material.

Electromagnetically actuated quantity control valve (14) according to one of the preceding claims, wherein the nature of a surface which is associated with the contact surface, characterized by a profiling.

8. High-pressure fuel pump (3) comprising a quantity control valve (14) according to any one of the preceding claims.