EP3622170A1

EP3622170A1 - Valve for metering a fluid

Info

Publication number: EP3622170A1
Application number: EP18722483.7A
Authority: EP
Inventors: Stefan Cerny; Murat Ucal; Jochen Rose; Andreas Glaser; Matthias Boee; Axel Heinstein; Nico HERRMANN; Martin Buehner
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2017-05-10
Filing date: 2018-05-03
Publication date: 2020-03-18
Also published as: JP2020519805A; US20200386199A1; CN114876689A; WO2018206382A1; DE102017207845A1; EP4033087A1; JP7270684B2; EP3779172A1; CN114876689B; EP4033087B1; EP3779172B1; US11852106B2; JP2021179214A; KR20230043253A; CN110612390B; CN110612390A; KR20200003824A

Abstract

A valve (1) for metering a fluid, which valve serves, in particular, as a fuel injection valve for internal combustion engines, comprises an electromagnetic actuator (10) which has an armature (6) which is arranged in an armature space (16), and a valve needle (5) which can be operated by the actuator (10) by means of the armature (6), wherein the armature (6) is guided on the valve needle (5), wherein a first stop element (7), which interacts with a first end side (22) of the armature (6) during operation, and a second stop element (8), which interacts with a second end side (23) of the armature (6) during operation, are arranged on the valve needle (5) and limit a movement of the armature (6) relative to the valve needle (5), and wherein the armature (6) has a spring receptacle (25) which is open in the direction of the first end side (22) of the armature (6) and into which a spring (27), which is supported on the stop element (7), is inserted. Here, the valve (1) is embodied such that the armature (6) has at least one fluid channel (15) which, during operation, allows fluid to flow between a first region (17) of the armature space (16), which first region adjoins the first end side (22) of the armature (6), and a second region (18) of the armature chamber (16), which second region adjoins the second end side (23) of the armature (6), that the fluid channel (15) at least partially incorporates the spring receptacle (25), and that the fluid channel (15) runs at least in sections radially outward along a direction (19) which is oriented from the first end side (22) to the second end side (23) and is coaxial with respect to a longitudinal axis (4).

Description

Description title

Valve for metering a fluid prior art

The invention relates to a valve for metering a fluid, in particular a

Fuel injection valve for internal combustion engines. Specifically, the invention relates to the field of injectors for fuel injection systems of motor vehicles, in which there is preferably a direct injection of fuel into combustion chambers of an internal combustion engine.

From DE 10 2013 222 613 A1 a valve for metering fluid is known. The known valve has an electromagnet for actuating a valve needle controlling an orifice. The electromagnet is used to operate one on one

Valve needle movable anchor. Here, the armature has a valve needle adjacent to the bore, which forms a spring receptacle for a Vorhubfeder.

DISCLOSURE OF THE INVENTION The valve according to the invention with the features of claim 1 has the advantage that an improved design and mode of operation are made possible. In this case, an improved guidance between the armature and the valve needle, in particular a damping and calming of the armature, and at the same time an advantageous passage of the fluid through an armature space can take place.

The measures listed in the dependent claims are advantageous

Further developments of the valve specified in claim 1 possible.

In the valve for metering the fluid serving as armature armature is not fixedly connected to the valve needle, but mounted between stops flying. Such a stop may be formed on a stop element, which can be realized as a stop sleeve and / or stop ring. However, the stop element may also be formed integrally with the valve needle. About a spring, the anchor is in Hibernation adjusted to a relative to the valve needle stationary stop, so that the armature rests there. When the valve is actuated, the complete armature free travel is then available as an acceleration section, whereby the spring is shortened during acceleration. The Ankerfreiweg can be specified via the axial clearance between the anchor and the two stops.

A guide length between the armature and the valve needle can be increased by the spring receptacle is configured by an annular groove not adjacent to the valve needle. In this case, the spring receptacle can still advantageously be configured close to the longitudinal axis, that is to say with a small radial distance from the longitudinal axis, in order to allow an advantageous introduction of the fluid from the first region of the armature space into the spring receptacle in the case of a corresponding design of the valve.

In a combination of an anchor with straight flow holes and arranged on the valve needle stopper with a large outer diameter, it is conceivable that there is an overlap between the flow bore and a configured on a corresponding stop element abutment surface (stop).

As a result, a part of the damping surface between the armature and the

related stop element lost. It also decreases in the area of

End positions of the anchor on the stop elements also a free

Flow cross-section.

Although the resulting situation has the advantage of a low adhesion effect when releasing the armature of the respective stop element in an actuation process, but also leads to a for damping a collision or for

Anchor calming desired damping is reduced. Especially when closing the valve, this can lead to the fact that in terms of the desired driving times too long a period for sufficient reassurance of the armature is required. With regard to possibly very short pause times, for example less than 1, 2 ms, as they may be desired in a multiple injection, thus resulting in significant

Disadvantages of a near the valve needle designed straight flow bore through the anchor.

Advantageously, by a proposed fluid channel an advantageous passage of fluid through the armature space and at the same time an impairment of a damping behavior can be reduced, which is particularly advantageous for a calming of the armature when closing the valve. This can also by the structural design of the stop surface on the stop element at least largely uninfluenced by the passage of the fluid through the anchor setting or setting the desired damping can be achieved.

A further development in which a point of a first opening of the fluid channel which is radially outwardly far from the longitudinal axis lies closer to the longitudinal axis than a point of a second opening of the second point which is radially outermost from the longitudinal axis

Fluid channel, has the advantage that at the first end side of the armature advantageously a longitudinal axis near discharge of the fluid can be carried in the fluid channel, while on the second end side of the armature laying the opening of the fluid channel in a further remote from the valve needle area is possible , In the development according to claim 2 results in particular the advantage that an overlap of the opening of the fluid channel can be reduced to the second end face of the armature with a stop surface on the second stop member or completely avoided. Specifically, the maximum far inward point of the second opening of the fluid channel may lie radially outside a stop surface of the second stop element. Corresponding advantages can be realized in the development, in which a centroid of a first opening of the fluid channel is closer to the longitudinal axis than a centroid of a second opening of the fluid channel. The development according to claim 3 has, inter alia, the advantage that a manufacturability of the fluid channel is made possible or improved by means of a bore. An advantageous measure for this purpose is specified in claim 4.

The development according to claim 5 has the advantage that on the one hand

aerodynamically favorable design of the fluid channel can be realized. On the other hand, if appropriate, a production engineering favorable embodiment of

Fluid channels are realized, as is possible in particular according to the embodiment according to claim 6. In this case, according to the embodiment according to claim 7, an optimization in terms of a tilt angle, with which an axis of the oblique bore is tilted relative to the longitudinal axis, can be realized in an advantageous manner, wherein the tilt angle

For example, given given specifications for the opening on the second end face of the armature can be kept optimally small. Furthermore, the cross-section available for the passage of the fluid along the coaxial direction can thereby be increased over the entire course through the armature as a result of the design of the oblique bore, if this makes sense in the respective application.

In the development according to claim 8, an optionally with inserted spring (Ankerfreiwegsfeder) remaining space for the passage of the fluid in an advantageous manner be co-used. The development according to claim 9 allows in particular a use of the spring receptacle along its entire extent along the

Longitudinal axis.

5 In the development according to claim 10, the fluid channel can be configured in an advantageous manner by production technology easy to be realized coaxial blind holes.

Thus, in an advantageous manner, a combination of an armature travel spring located in the armature can be realized with an armature which has a radially outward direction

extending fluid channel, in particular an oblique bore having. This combination makes it possible to realize a maximum large damping surface between a stop element and the armature. Specifically, in this case a reduction of the damping surface can be avoided by an overlap with the corresponding opening. As in the embodiment of a valve preferably a plurality of fluid channels

are provided, which are preferably realized instead of conventional flow holes, a significant impact on the operation of the valve, in particular a significantly improved damping result. For example, two to ten fluid channels, in particular two to six fluid channels, can be realized. Such 0 fluid channels in this case together with the spring receiving at least partially

include. This can also improve the flow behavior. In principle, however, is also an embodiment with only a single fluid channel or a

Combination with at least one proposed fluid channel with at least one conventional through-hole conceivable.

5

Specifically, therefore, a configuration can be realized, in which it is with respect to a

Stop surface on the relevant stop element to no overlap between the relevant opening or the relevant openings of the at least one fluid channel and the stop surface on the stop element more comes. Thereby o the maximum damping surface is available.

Brief description of the drawings

Preferred embodiments of the invention are described in the following description with reference to the accompanying drawings, in which:

Elements are provided with matching reference numerals, explained in more detail. Show it: 1 shows a valve in an excerpt, schematic sectional view according to a first embodiment.

2 shows a valve in an excerpt, schematic sectional view according to a second embodiment.

3 shows a valve in an excerptional, schematic sectional view according to a third exemplary embodiment, and FIG. 4 shows a valve in an excerptional, schematic sectional view corresponding to a fourth exemplary embodiment.

1 shows a valve 1 for metering a fluid in a bleed-off,

schematic sectional view according to a first embodiment. The valve 1 may be formed in particular as a fuel injection valve 1. A preferred application is a fuel injection system, in which such fuel injection valves 1 are designed as high-pressure injection valves 1 and are used for direct injections of fuel into associated combustion chambers of the internal combustion engine. In this case, liquid or gaseous fuels can be used as the fuel. Accordingly, the valve 1 is suitable for metering liquid or gaseous fluids.

The valve 1 has a housing (valve housing) 2, in which a stationary inner pole 3 is arranged. A in this embodiment within the housing. 2

arranged valve needle 5 is guided with respect to the housing 2 along a longitudinal axis 4.

At the valve needle 5, an armature (armature) 6 is arranged. On the valve needle 5, a stop element 7 and a further stop element 8 are also arranged. To the

Stop elements 7, 8 are stop surfaces 7 ', 8' is formed. The armature 6 can in this case be moved relative to the valve needle 5 between the stop elements 7, 8 during an actuation along the longitudinal axis 4, with an anchor path 9 being predetermined. The longitudinal axis 4 can be used here as a longitudinal axis 4 of the valve needle 5 or as

Longitudinal axis 4 of the armature 5 are designated. The armature 6, the inner pole 3 and a solenoid, not shown, are components of an electromagnetic actuator 10th On the valve needle 5, a valve closing body 11 is formed, which cooperates with a valve seat surface 12 to a sealing seat. Upon actuation of the armature 6, this is accelerated in the direction of the inner pole 3. If the armature 6 strikes against the stop 7 'of the stop element 7 and thereby actuates the valve needle 5, then fuel can be injected via the open sealing seat and at least one nozzle opening 13 into a space, in particular a combustion space.

The valve 1 has a return spring 14, which the valve needle 5 via the

Stop element 7 adjusted to its initial position in which the sealing seat is closed.

The armature 6 is based on a cylindrical basic shape 20 with a through hole 21, wherein the armature 6 is guided on the through hole 21 on the valve needle 5. Here, the basic shape 20 of the armature 6 has a length 24 between a pole 3 facing the first end face 22 of the armature 6 and one of the inner pole. 3

remote from the second end face 23 of the armature 6. The armature 6 is arranged in an armature space 16. Here, the first end face 22 adjoins a first area 17 of the armature space 16. Furthermore, the second end face 23 adjoins a second area 18 of the armature space 16. In operation, fuel is allowed to pass through the armature via at least a portion of its length 24 through at least one fluid channel 15.

The armature 6 has a spring receptacle 25. The fluid channel 15 in this case includes the spring seat 25 with a. Thus, the fluid channel 15 leads at least over part of the spring receptacle 25. The spring receptacle 25 is opened on the end face 22 of the armature 6. A spring support surface 26 on which a spring 27 partially arranged in the spring receiver 25 is supported is formed by the bottom 26 of the spring receiver 25. The feather

27 is further supported on the stop surface 7 'of the stopper 7 from. Upon actuation of the armature 6, the spring 27 is shortened relative to its initial length, wherein it can completely dip into the spring seat 25. Furthermore, the spring 27 in this embodiment with beveled spring ends 43,

44 designed. This results in an even better edition. Furthermore, a reduced wear and a more uniform application of force on the one hand in the armature 6 on the spring support surface 26 and on the other hand on the stop 7 'of the stop element 7. At the armature 6, a guide web 28 is formed in this embodiment.

As a result, the guide length of the armature 6 on the valve needle 5 is equal to the length 24 of the armature 6 between its end faces 22, 23rd The guide of the valve needle 5 with respect to the longitudinal axis 4 and with respect to the housing 2 results in this embodiment via the stop element. 7

In this case, the stop element 7 is guided in a guide region 30 on an inner bore 31 of the inner pole 3. In a modified embodiment, the guidance of the valve needle 5 can additionally or alternatively also be realized via the armature 6. In this case, the outer side 32 of the armature 6 extends at least partially to the inner side 33 of the housing 2. In this embodiment, instead of the guide portion 30, an annular gap between the stop element 7 and the inner pole 3 can be realized. In this embodiment, the fluid channel 15 has a helical bore 50. In this case, the fluid channel 15 preferably has exactly one oblique bore 50. The fluid channel 15 then leads via the oblique bore 50 and at least one part 51 of the spring receptacle 25.

In this embodiment, a coaxial with the longitudinal axis 4 direction 19, which is oriented from the first end face 22 to the second end face 23 results in an orientation opposite to an opening direction 52 in which the valve needle 5 is actuated when opening the valve 1.

The oblique bore 50 is configured in the armature 6 so that it extends along the coaxial direction 19 radially outward, ie away from the longitudinal axis 4, wherein in the plane between the coaxial direction 19 and an axis 53 of the oblique bore 50 is an inclination angle 54 results. However, the configuration of the oblique bore 50 is not limited to that the axis 53 lies in the same plane as the longitudinal axis 4 of the valve needle 5, as is the case in the illustrated embodiment with the plane given by the plane of the drawing.

Further, the oblique bore 50 extends in this embodiment from the first end face 22 of the armature 6 to the second end face 23 of the armature 6. Here, a first opening 55 of the fluid channel 15, which is adjacent to the first region 17, in the

End face 22, while a second opening 56 which is adjacent to the second region 18, located in the second end face 23. By extending from the first end face 22 to the second end face 23 of the armature 6 oblique bore 50 is an advantageous

hydraulic connection between the first region 17 and the second region 18 allows. As a result of the positioning of the first opening 55 close to the axis on the longitudinal axis 4, an inflow of the fluid, in particular of the fuel, from the inner bore 31 of the inner pole 3 can advantageously take place into the fluid channel 15. Due to the arrangement of the second opening 56 of the fluid channel 15 with respect to the longitudinal axis 4, which is remote from the axis, an inner part 57 of the second end face 23, on which the armature 6 engages with the second Stop surface 8 'cooperates, are given sufficiently large according to a predetermined and possibly large second stop surface 8' without the second opening 56 is located in this inner part 57 or without the

Fluid channel 15 intersects this inner part 57 of the second end face 23. In this way, a large damping surface between the second stop surface 8 'and the second end face 23 can be realized.

Since the inclined bore 50 in an advantageous manner over an entire length 58 of the

Federaufnahme 25 along the longitudinal axis 4 is blended with the spring retainer 25, results in a favorable flow behavior and with respect to the spring retainer 25 even enlarged first opening 55 of the fluid channel 15. Specifically, this is a point 60 at which the first opening 55 radially maximum of the A point 61 at which the first opening 55 has a minimum distance from the longitudinal axis 4, however, is still at the edge of the

Spring receptacle 25. Further results in the second opening 56 points 62, 63, wherein the point 62 is located at a maximum distance from the longitudinal axis 4 at the edge of the second opening 56 and wherein the point 63 minimally spaced from the longitudinal axis 4 at the edge of the second opening 56 is located. The point 62 is farther away from the longitudinal axis 4 than the point 60. Further, the point 63 of the second opening 56 is farther from the longitudinal axis 4 than the point 61 on the edge of the first opening 55. Further, there is a centroid 64 of the first opening 55 radially closer to the longitudinal axis 4 than a centroid 65 of the second opening 56th

In this embodiment, the oblique bore 50 is also configured so that the bottom 26 of the spring retainer 25 is cut by the oblique bore 50. Thus, the spring seat 25 can be used advantageously for passing the fuel and integrated over its entire length 58 in the fluid channel 15.

Fig. 2 shows a valve 1 in an excerptive, schematic sectional view according to a second embodiment. In this embodiment, the second opening 56 or a partial surface 56 'on the second end face 23 of the armature 6, in which the second opening 56 is located, oriented perpendicular to the axis 53 of the oblique bore 50. The partial surface 56 'of the armature 6 can in this case be configured via a circumferential groove 85 or individual countersunk holes. Specifically, first the partial surface 56 'on the second end face 23 of the armature 6 can be configured, and then the oblique bore 50 can be drilled starting from the second end face 23. This allows a right-angled impact of a drill bit on the part surface 56 'of the armature 6. Thus, in particular results in a production-optimized modification to the basis of the Fig. 1 described first embodiment, which serves in particular for improving the drilling. As a result, a fracture of a drill can be avoided because the drilling does not occur obliquely to a surface. With respect to several to be realized on the armature 6 oblique holes, the

are configured in accordance with the oblique bore 50, in this case, in particular an embodiment of the partial surface 56 'by a circumferential groove about the longitudinal axis 4, from which then go out the individual oblique bores 50 circumferentially distributed advantageous. Fig. 3 shows a valve 1 in an excerpt, schematic sectional view according to a third embodiment. In this embodiment, a bevel 66 is configured on the armature 6, which has the second end face 23 at its

Outside diameter 42 cuts. The chamfer 66 is then located between the second end face 23 and the outer side 32 of the armature 6. Preferably, the chamfer 66 is configured at right angles to the axis 53 of the oblique bore 50. On the one hand, this refinement has the advantage that production optimization is achieved, as described correspondingly with reference to FIG. 2. Furthermore, the inner part 57 of the second end face 23, on which the armature 6 cooperates with the stop face 8 ', can be made maximally large. This results in particularly large constructive freedom. In the respective

Use case, therefore, a very large hydraulic damping can be achieved.

4 shows a valve 1 in an excerptional, schematic sectional representation according to a fourth exemplary embodiment. In this embodiment, the fluid channel 15 has a first coaxial blind hole 71 and a second coaxial

Blind hole 72 on. The first coaxial blind hole 71 extends from the first end face 22 in the coaxial direction 19. The second coaxial blind hole 72 extends from the second end face 23 against the coaxial direction 19. Within the armature 6, the two blind holes 71, 72 with each other

blended. An intersection region 73 can in this case be arranged close to the bottom 26 of the spring receptacle 25 viewed along the longitudinal axis 4. This results in favorable flow conditions. When passing the fluid through the armature 6 then the blind holes 71, 72 and at least a portion 51 of the spring seat 25 can be used. As a result, in this embodiment too, the spring receiver 25 can advantageously be integrated at least partially into the fluid channel 15. In the intersection region 73, the fluid is guided in the coaxial direction 19 viewed along the longitudinal axis 4 radially outward. This also results in an advantageous introduction of the fluid, starting from the inner bore 31 of the Inner pole 3 in the fluid channel 15 and at the same time an advantageous damping on the second stop element eighth

It is thus advantageous, in particular, for a point 60 of a first opening 55 of the fluid channel 15, which point radially outward from the longitudinal axis 4, to be closer to the outside

Longitudinal axis 4 is located as a radially outwardly of the longitudinal axis 4 far outermost point 62 of a second opening 56 of the fluid channel 15. Further, it is advantageous if a

Centroid 64 of a first opening 55 of the fluid channel 15 closer to the

Longitudinal axis 4 is located as a centroid 65 of a second opening 56 of the

Fluid channel 15.

In the presented embodiments, which are described in particular with reference to FIGS. 2 to 4, can be realized in an advantageous manner that the fluid channel 15 at an exit surface 80 of the armature 6 to the second region 18 of the armature space (16) out, wherein an axis 81 of the fluid channel 15, along which the fluid channel 15 exits at the exit surface 80 of the armature 6, is oriented perpendicular to the exit surface 80. This makes it possible inter alia to form the fluid channel 15 from this side with a bore which can be introduced perpendicular to the exit surface 80 in the armature, which improves the manufacturability. In this case, the exit surface 80 can lie in an annular surface 82 running around with respect to the longitudinal axis 4, wherein the annular surface 82 is designed as a partial surface 82 of a cone-shaped jacket 83 rotationally symmetrical with respect to the longitudinal axis 4 or as a partial surface 82 of a circular disc 84 oriented perpendicular to the longitudinal axis 4. This is possible, for example, by the configuration of a peripheral groove 85 or a chamfer 66.

The invention is not limited to the described embodiments.

Claims

claims

A valve (1) for metering a fluid, particularly a fuel injector for internal combustion engines, comprising an electromagnetic actuator (10) having an armature (6) disposed in an armature space (16) and one of the actuator (10) by means of the armature (6) operable valve needle (5), wherein the armature (6) is guided on the valve needle (5), wherein on the valve needle (5) in operation with a first end face (22) of the armature (6) cooperating first stop element ( 7) and a second stop element (8) cooperating in operation with a second end face (23) of the armature (6), which limit movement of the armature (6) relative to the valve needle (5), and wherein the armature (6 ) has a to the first end face (22) of the armature (6) towards open spring receptacle (25) into which a on the stop element (7) supported spring (27) is inserted,

characterized,

the armature (6) has at least one fluid channel (15) which, during operation, has a

Passage of fluid between a first region (17) of the armature space (16) adjoining the first end side (22) of the armature (6) and a second region (18) of the armature space adjacent to the second end side (23) of the armature (6) (16) allows the fluid channel (15) at least partially incorporating the spring retainer (25) and the fluid channel (15) along one of the first end face (22) to the second end face (23) oriented and with respect to a longitudinal axis (4) Coaxial direction (19) extends at least partially radially outward.

2. Valve according to claim 1,

characterized,

in that a point (61), which is radially inward at the maximum from the longitudinal axis (4), is a first point (61)

Opening (55) of the fluid channel (15) closer to the longitudinal axis (4) is located as a from the longitudinal axis (4) radially maximum far inboard point (63) of a second opening (56) of the fluid channel (15).

3. Valve according to claim 1 or 2,

characterized,

in that the fluid channel (15) emerges at an outlet surface (80) of the armature (6) towards the second region (18) of the armature space (16) and that an axis (81) of the fluid channel (15), along which the fluid channel (15) emerges at the outlet surface (80) of the armature (6), is oriented perpendicular to the exit surface (80).

4. Valve according to one of claims 1 to 3,

characterized,

the outlet surface (80) lies in an annular surface (82) encircling with respect to the longitudinal axis (4) and in that the annular surface (82) serves as a partial surface (82) of a cone-shaped cone (83) rotationally symmetrical with respect to the longitudinal axis (4) or as a partial surface (82). a perpendicular to the longitudinal axis (4) oriented circular disc (84) is configured.

5. Valve according to one of claims 1 to 4,

characterized,

the fluid channel (15) extends continuously radially outward along the coaxial direction (19).

6. Valve according to one of claims 1 to 5,

characterized,

the fluid channel (15) has at least one oblique bore (50) which extends at least radially outward along the coaxial direction (19).

7. Valve according to claim 6,

characterized,

that the oblique bore (50) extends from the first end face (22) of the armature (6) to the second end face (23) of the armature (6).

8. Valve according to one of claims 6 or 7,

characterized,

in that the oblique bore (50) is blended with the spring receptacle (25).

9. Valve according to one of claims 1 to 8,

characterized,

in that the oblique bore (50) is cut with the spring receptacle (25) such that a bottom (26) of the spring receptacle (25) is cut by the oblique bore (50).

10. Valve according to one of claims 1 to 9,

characterized,

in that the fluid channel (15) has a first coaxial blind bore (71) running in the coaxial direction (19) from the first end face (22) of the armature (6) and a second one Coaxial blind hole (72) extending from the second end face (23) of the armature (6) opposite to the coaxial direction (19) has, which are inter-connected within the armature (6), and that the second blind hole (72) with respect to the longitudinal axis (4) radially outward than the first blind hole (71).