DE102012211283A1 - Leakage and slip reduced valve - Google Patents

Abstract

The invention relates to a valve (10) with a valve body (12), in which a valve member (28) opening or closing a valve seat (32) or a spherical closing element (64) is accommodated. These can be actuated by means of an actuator (16) against a spring force of a closing spring (18). When the valve seat (62) is closed, the valve member (28) or the spherical closing element (64) is acted upon by a system pressure which is present in the high-pressure region (60) of the valve body (12). The valve body (12) has an area (52) with reduced stiffness, which is designed as an undercut (54) or a recess (56). This is located below or next to the valve seat (32) in the valve body (12).

Description

State of the art

DE 100 00 501 A1 refers to a fuel injection valve for internal combustion engines. A fuel injection valve for internal combustion engines comprises a valve body in which in a bore, a valve member against a closing force in the axial direction is arranged to be movable. The valve member has at its end a substantially conical valve member tip, which comes with a part of its lateral surface, which serves as a valve sealing surface, at a formed on the combustion chamber end of the bore valve seat to rest. At the transition of the valve member to the valve member tip an annular groove is formed. This undercuts the valve sealing surface in part, thereby forming a ring collar, which is resilient. The cone angle of the valve sealing surface is dimensioned somewhat larger in the open position of the valve member than the cone angle α of the valve seat, so that the annular collar is first placed on the valve seat during closing movement of the valve member to the outer edge formed as a sealing edge and is deformed inwardly by the further closing movement. The sealing edge is not pressed into the valve seat, whereby the seat diameter remains substantially unchanged over the life of the fuel injection valve.

Disclosure of the invention

According to the invention, the valve body or a valve member of a fuel injector, in which a valve seat opening or closing valve member or closing element is received, which is actuated by an actuator against a spring force of a closing spring and the valve member or the closing element with a closed valve seat of a in High-pressure region of the injector system pressure is applied to design such that the valve body or the valve member comprises a procured as an undercut or as recess or as undercut stiffness reduced area, which is executed below or next to the valve seat in the valve body of the fuel injector.

As a result of the stiffness-reduced region, which is proposed according to the invention, in the material of the valve body, it can be achieved that the system pressure prevailing in the high-pressure region of the valve body of the fuel injector, i. the pressure that is generated by a high-pressure delivery unit or by a high-pressure accumulator, or is present from this, can be used to a targeted deformation of the reduced in terms of its rigidity material area of the valve body or the valve member. In particular, it can be achieved with a corresponding configuration of the stiffness-reduced region, that the valve seat formed in the valve body can be made considerably more elastic. As a result, the system pressure prevailing in the high-pressure region of the injector can lead to a targeted adaptation of the components, i. valve member and closing member on the other hand and the corresponding seat surfaces of the valve seat, which are executed in the valve body, are used.

For example, the system pressure can be used such that in the contact area, i. in the region of the seat surface of the valve body no pressure expansion but a slight constriction takes place, which corresponds to a likewise occurring constriction of the example, needle-shaped valve member. This means that the geometry of the valve body adapts to that of the valve member sealing surface. As a result, on the one hand leaks can be avoided, which in turn ensures a tightness of the valve seat over the life of the fuel injector proposed according to the invention. Furthermore, the solution proposed by the invention can improve the parts yield in a new part, i. be achieved in a newly manufactured fuel injector by geometric compensation of manufacturing inaccuracies. Furthermore, with such a fuel injector, there is an increase in particulate robustness, i. Otherwise, the formation of leakage paths is avoided or reduced, since a targeted adaptation of the components in the sealing or seating area is effected by the system pressure prevailing in the high-pressure area.

Furthermore, the solution proposed according to the invention ideally enables the elimination of the relative movement, i. a slip between the valve body and the valve member or at least a significant reduction occurring relative movements.

By the proposed design according to the invention, either a compression deformation can be prevented or ensured that the two wear partners are exposed to the same deformation, resulting in a significant reduction of the relative movements occurring between these two wear partners, i. the occurring slip leads. By reducing the slip wear is inevitably eliminated, which in turn an increase in the robustness of the valve seat against particles is reached, since with less slippage, each of the particles inevitably causes less damage.

The targeted deformation of the valve body can by a recess, an undercut, an undercut or the like can be ensured, the effect of which is that under or in addition to the valve body of the fuel injector valve seat formed in terms of its stiffness reduced material area.

The system pressure prevailing in the high-pressure region of the valve body deforms the stiffness-reduced region in the valve body such that its geometry adapts to the geometry of the valve member or of a closing element of spherical design, for example.

The system pressure prevailing in the high pressure area of the valve body, i. the pressure generated by a high-pressure delivery unit or by a high-pressure accumulator or the like deforms the area of the valve seat in the form of a slight constriction. In this context, it is important that the deformations of the valve member, be it designed as a conical valve member with a conical seat, be it set as a spherical closure member in a correspondingly configured valve seat, pursue in the same direction, i. Both contact partners can be deformed in the same way in the area of the valve seat. In this case, the slip between the two contact partners is minimized as well as possibly due to particulate matter adjusting leakage.

In one embodiment of the solution on which the invention is based, both a needle-shaped valve member and, for example, a ball-shaped closing element are provided at its high pressure, i. provided with a bore to the system pressure-assigning side. The bore is preferably located opposite a high pressure passage formed in the valve body which extends concentrically with the axis of symmetry of the valve body.

The holes in the needle-shaped valve member or in the ball-shaped closing element have the same function as a trained in the sitting area backlash or a puncture. Thus, on the one hand, the deformation of the valve body can be specifically defined by the formation of a recess or an undercut and also prevented. About the bore in the valve member, be it needle-shaped, it is designed as a spherical valve member, the valve member can undergo the same deformation as the valve body.

In both embodiments of the solution proposed by the invention, i. when forming a conically shaped valve seat, as well as in the formation of a ball seat, i. when using a spherical closure element, the seat angle is in the region of the valve seat with respect to the axis of symmetry of the valve body, for example in the range between 25 ° and 90 ° (flat seat).

Advantages of the invention

The proposed solution according to the invention advantageously advantageously enables the elimination of the relative movement or at least a significant reduction in the relative movement, i. occurring slip in the region of the valve seat between the seating surfaces on the valve body and the relative to this movable needle-shaped valve member or spherical closure element. It is ensured that the two wear partners, i. the needle-shaped valve member or the ball-shaped closing element on the one hand and the seat surfaces of the valve seat in the valve body on the other hand are subjected to the same deformation. This leads to a significant reduction of the relative movement, i. the slip between these components. Furthermore, by the proposed solution according to the invention, the avoidance of leaks can be achieved, or seen ensuring the tightness of the closed valve seat over the life of the fuel injector away. Also, an increase in particle robustness, i. A robustness against material damage due to trapped particles can be achieved, so that the formation of leakage paths can be at least significantly reduced if not completely avoided. The high pressure in the high-pressure region of the inventively proposed fuel injector high pressure, be it by a high-pressure pump, he produced by a high-pressure accumulator, is used so that the contact region of the valve body has no pressure expansion but a slight constriction, which is analogous to the constriction of the needle-shaped valve member.

With regard to the reduction of leakage, the back turns, recesses or undercuts in the valve body or the valve member are not exclusively used only to reduce the rigidity in this area but to improve the tightness by elasticity. The back turns or recesses or undercuts also provide targeted by the targeted use of the upcoming high pressure in the closed state of the valve seat, the elastic region of the valve body or the valve member to deform the shape of the counter body, so that the formation otherwise any leakage paths due to the same direction Deformation of the two wear partners on the valve seat is selectively prevented.

Brief description of the drawings

With reference to the drawings, the invention will be described in more detail.

It shows:

1 a section through a fuel injector,

2 an embodiment of a valve seat,

3 a first embodiment of a valve seat proposed according to the invention,

4 shows a second embodiment of the present invention proposed valve seat,

5 a further, third embodiment of the present invention proposed valve seat with spherical designed closing element and

6 a possible, further fourth embodiment of the present invention proposed valve seat as a conical seat with axial bore in the valve member.

Embodiments of the invention

The representation according to 1 is to take a section through a fuel injector.

1 shows a valve 10 for a fuel injector in which a fuel feed 14 in a valve body 12 is admitted. About a in 1 not shown in detail high-pressure pumping unit or acted upon by such a high-pressure accumulator is under high pressure, ie system pressure, stagnant fuel in the fuel inlet 14 at. In the valve body 12 of the fuel injector 10 is also an actuator 16 taken, which is formed in the present case as an electromagnet. Through a magnetic core 20 of the actuator 16 extends a closing spring 18 , which is a needle-shaped valve member 28 applied. The closing spring 18 extends through the magnetic core 20 into which a magnetic coil 22 is admitted.

The closing spring 18 rests on a throttle plate 24 starting in which there is an outlet throttle 26 located. This in the illustration according to 1 needle-shaped valve member 28 includes a valve plate 30 that of the closing spring 18 is acted upon in the closing direction. With the needle-shaped valve member 28 becomes a valve seat 32 closed at a sealing diameter.

2 shows a section through a valve seat.

2 shows that the valve member 28 a lateral surface 40 having. The valve member 28 is in a range above the sealing diameter 34 according to 2 in a first diameter 48 executed, according to an extending in the axial direction constriction 46 in a second diameter 50 , By means of the sealing diameter 34 becomes the valve seat 32 on the seat 42 locked. Accordingly, the valve seat 32 through the sealing diameter 34 on the lateral surface 40 of the valve member 28 and the seat 42 in the area of the valve seat 32 of the valve body 12 trained is shown. Im in 2 illustrated state is the valve seat 32 from the contact partners, ie the needle-shaped valve member 28 and the valve body 12 closed.

3 shows a first embodiment of an inventively proposed valve seat in a fuel injector.

The representation according to 3 it can be seen that, unlike in 2 illustrated embodiment of the valve seat 32 the valve body 12 a high pressure area formed in the manner of a drop 60 having. The high pressure area 60 is from a valve body surface 58 of the valve body 12 limited and as an undercut 54 educated. By the backstitch 54 that is in the material of the valve body 12 is created in the valve body 12 below the horizontal plane, passing through the sealing diameter 34 is formed, a stiffness-reduced area 52 , Out 3 shows that in this reduced in terms of its stiffness range 52 in the high pressure area 60 Pending system pressure in effective direction 68 acts. This means that the valve body 12 in just this stiffness-reduced area 52 through the effective direction 68 the system pressure experiences a constriction in the radial direction inwards, ie on the sealing diameter 34 of the needle-shaped valve member formed here 28 to.

With the valve seat closed 62 thus occurs within the stiffness reduced range 52 of the valve body 12 the same elastic deformation as on the needle-shaped valve member 28 in the range of the sealing diameter 34 occurs. Both deformations, ie the deformation of the seat 42 in the area of the closed valve seat 62 and the elastic deformation in the form of a constriction on the needle-shaped valve member 28 run in the same direction, so that a self-adjusting relative movement, ie occurring slip in the region of the closed valve seat 62 during operation of the fuel injector 10 by actuating the actuator 16 if not completely eliminated, then at least significantly reduced.

The representation according to 3 In addition, it can be seen that the here needle-shaped valve member 28 below the sealing diameter 34 a constriction 46 extends, with respect to their lateral surface 40 in a second diameter 50 passes, which is less than the first diameter 48 the needle-shaped valve member 28 ,

4 shows a second embodiment of the present invention proposed valve seat. Unlike in 3 illustrated first embodiment of the invention proposed solution is in accordance with the second embodiment 4 a turn 56 in the lateral surface 40 the needle-shaped valve member 28 executed. This is also in the high pressure area 60 so that's within the high pressure range 60 effective system pressure - indicated by reference numerals 68 - As shown on the stiffness reduced area 52 acts according to this second embodiment variant. Along the sealing diameter 34 with which the seat surface 42 of the valve seat 32 it works together in the in 4 illustrated embodiment also to a deformation by the in the high pressure area 60 pending system pressure is caused. Through the recess 56 in the needle-shaped valve member 28 becomes the valve seat 32 elastic, in addition, the system pressure is used to form defects in the valve body 12 compensate. It is the same direction deformations both on the needle-shaped valve member 28 as well as on the seat 42 of the valve seat 32 one. For completeness, it should be mentioned that the needle-shaped valve member 28 above the recess 56 a first diameter 48 which then in the said recess 56 passes. Below the sealing diameter 34 on the needle-shaped valve member 28 , in particular in the area of a constriction 46 goes the sealing diameter 34 which is essentially the first diameter 58 corresponds to a second reduced diameter 50 back. Also in the illustration according to 4 is the valve seat 32 as a closed valve seat 62 shown.

5 shows a further, third embodiment of the present invention proposed valve seat, designed here as a ball seat.

In the illustration according to 3 becomes a stiffness-reduced area 52 in the material of the valve body 12 through an undercut 54 educated. Instead of an undercut 54 could be in the material of the valve body 12 Alternatively, a recess 56 or an underdog 56 be executed. Alone, crucial for the training of the stiffness-reduced area 52 is a weakening of the material of the valve body 12 in the area of the valve seat 32 ie below the valve seat or next to the valve seat 32 in the valve body 12 , This causes a slip reduction due to the pressurized surface.

In the in 5 illustrated third embodiment of the present invention proposed valve seat is the stiffness-reduced area 52 below the seat 42 of in 5 shown ball seat. The in 5 shown ball seat comprises a spherical shaped closing element 64 , which in the closed state to the in a cone angle 44 arranged seats 42 of the valve seat 32 as shown in 5 is employed. This in 5 according to the third embodiment of the present invention proposed valve seat shown spherical shaped closing element 64 is by an actuator not shown here 16 , for example, by the in 1 already described electromagnet operated.

From the illustration according to 4 can be seen that in the material of the valve body 12 of the fuel injector 10 an undercut 54 is introduced - in 5 indicated by dashed lines. This backstitch 54 extends in the material of the valve body 12 one with reference number 72 identified high-pressure channel around, ie in the circumferential direction with respect to the high-pressure passage leading to the system pressure 72 , 4 further shows that between the ball-shaped closing element 64 and the seat 42 in the valve body 12 , formed in the seat angle 44 a circumferential contact line 70 established. Inside the valve body 12 trained undercut 54 is the effective direction 68 the system pressure registered in this second embodiment of the present invention proposed valve seat 32 in the high pressure channel 72 pending. 5 further shows that the high pressure channel 72 concentric with the central axis of the valve body 12 - dotted lines - running.

The embodiment according to 5 It can also be seen that the ball-shaped closing element 64 a hole 66 includes.

The here in the spherical closure element 64 engineered drilling 66 ensures that the valve member, in this case, the ball-shaped closing element 64 , which undergoes the same deformation as the valve body 12 ,

Out 5 it can be seen that the effective direction 68 the system pressure in the backstitch 54 just so that it leads to an elastic deformation of the area of the seat 42 of the valve seat 32 that comes below the line of contact 70 between the seats 42 and the shell of the spherical closure member 64 lies. This area is due to the effective direction 68 the system pressure slightly elastically deformed upward, so that a partially dome-like contact of the spherical closure element 64 at such deformed areas of the seat 42 of the valve seat 32 results. Instead of an undercut 54 could - dashed here in the material of the valve body 12 indicated - in the valve body 12 also be formed a recess or an undercut. It is essential that the material below the here spherically formed closing element 64 stiffness reduced areas 52 in the material of the valve body 12 generates elastic deformation of the valve seat, and a significant reduction if not a complete elimination of leakage can be achieved.

The representation according to 6 is a further, fourth embodiment of the inventively proposed valve seat, here executed as a conical seat, refer to.

6 shows that in this embodiment variant of the inventively proposed valve seat 32 in the valve 10 in the valve body 12 an undercut 54 for displaying a stiffness-reduced area 52 is executed. Unlike in 4 illustrated embodiment of the there procured as a ball seat valve seat 32 , the underdog passes 54 in the designed as a conical embodiment of the present invention proposed valve seat 32 in the valve body 12 in a steeper angle of attack. This also results in a steeper course of the effective direction 68 , in which the system pressure, ie the high pressure starting from the high pressure passage 72 on the area below the closed valve seat 62 lies, works.

At the in 6 designed as a conical seat valve seat 32 the high pressure acting in the high pressure channel 72 pending through the hole 66 at the lower end of the needle-shaped valve member 28 such that the needle-shaped valve member 28 in the region of its tip, ie in the region of the stiffness-reduced region 52 expands radially outwards, while due to the effective direction 68 the system pressure in the backstitch 54 the lower part of the seats 42 deformed upward, so that the valve member seat surface 41 and the seat 42 in the valve body 12 to be moved towards each other and the tightness of the valve seat 32 in its closed state 62 is significantly improved.

Also in this embodiment is by training the bore 66 at the lower end of the needle-shaped valve member 28 ensures that this undergoes the same deformation as the valve body 12 in the area of the valve seat 32 ,

Following the solution proposed according to the invention, this not only the tightness of the valve seat 32 in the closed state 62 but also significantly reduces the occurrence of leakage. On the one hand, the relative movements between the contact partners involved in the valve seat 32 ie, between the needle-shaped valve member 28 and the ball-shaped closing element 64 on the one hand and the seat 42 of the valve seat 32 On the other hand, due to this achieved reduction of relative movements particles will inevitably produce less wear on the contacting surfaces of the contact partners. This is due to the fact that the length of the relative movements is considerably reduced by the proposed solution according to the invention, since with less slippage, ie a reduced relative movement between the contact partners in the region of the valve seat 32 each particle produces less damage.

The inventively proposed solution according to the in 3 to 6 illustrated variants makes it possible, by deliberately placed recesses, undercuts or undercuts, the internal pressure of a high pressure area 60 in the valve body 12 for a targeted deformation of the kontancing components, the needle-shaped valve member 28 and the ball-shaped closing element 64 on the one hand and the seat 42 of the valve seat 32 by training stiffness-reduced area 52 on the other hand to use for a targeted elastic deformation of these parts.

The proposed solution according to the invention allows an improvement of Gutteileausbringung in new parts by geometric compensation in the production of unavoidable remaining tolerances and a significant improvement in the robustness of such valves 10 by reducing the possibility of training leakage paths.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 10000501 A1 [0001]

Claims (8)

Valve ( 10 ) with a valve body ( 12 ), in which a valve seat ( 32 ) opening or closing valve member ( 28 ) or a closing element ( 64 ) received by means of an actuator ( 16 ) against a spring force of a closing spring ( 18 ) is actuated, wherein the valve member ( 28 ) or the closing element ( 64 ) with the valve seat closed ( 62 ) of one in the high pressure area ( 60 ) of the valve body ( 12 ) system pressure is applied, characterized in that the valve body ( 12 ) as an undercut ( 54 ) or as a recess ( 56 ) executed stiffness-reduced area ( 52 ) located below or next to the valve seat ( 32 ) in the valve body ( 12 ) lies. Fuel injector according to claim 1, characterized in that in the high pressure area ( 60 ) system pressure the stiffness reduced area ( 52 ) in the valve body ( 12 ) deformed such that its geometry to the geometry of the valve member ( 28 ) or the spherically formed closing element ( 64 ) adapts. Fuel injector according to one of the preceding claims, characterized in that in the high-pressure region ( 60 ) prevailing system pressure the valve body ( 12 ) in the region of the valve seat ( 32 ) deformed in the form of a slight constriction. Fuel injector according to one of the preceding claims, characterized in that the valve member ( 28 ) or the ball-shaped closing element ( 64 ) each have a bore ( 66 ) having a system pressure leading high-pressure channel ( 72 ), such that the closing element 64 is exposed to the same deformation as the valve body 12 , Fuel injector according to one of the preceding claims, characterized in that, the stiffness-reduced region ( 52 ) of the valve body ( 12 ) in a direction of action ( 68 ) of system pressure in the high pressure area ( 60 ) is applied, such that a seat ( 42 ) of the valve seat ( 32 ) in the valve body ( 12 ) is deformed radially inwardly. Fuel injector according to one of the preceding claims, characterized in that a seat angle ( 44 ) by the seat ( 42 ) of the valve seat ( 32 ) with respect to an axis of symmetry of the valve body ( 12 ), is formed at an angle between 25 ° and 90 °. Fuel injector according to one of the preceding claims, characterized in that the valve seat ( 32 ) as a ball seat with a spherical closing element ( 64 ) is executed. Fuel injector according to one of the preceding claims, characterized in that the valve seat ( 32 ) as a conical seat with conically extending valve member seating surfaces ( 41 ) on the valve member ( 28 ) is executed.

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