The present invention is based on a fuel injector of the type set forth in the main claim.
Inwardly-opening injection valves, both for direct injection in the high-pressure area and for manifold injection in the low-pressure area, usually have a valve seat in a ball/cone type of construction. That is, at the sealing point formed with the valve seat, the valve needle is configured with a ball or has a spherical form, and the valve seat is conical or hollow frustoconical.
However, in this type of fuel injectors, eccentricities, caused by the manufacturing process, of the seat contact points at the valve needle and at the valve seat often lead to leakages of fuel during operation of the valve.
A fuel injector provided with a spherical closing member is discussed, for example, in the German Patent DE 198 59 484 A1. A fuel injector for high-pressure injection of fuel from a central high-pressure delivery line into combustion chambers of an internal combustion engine has a valve seat, a valve ball and a guide member guiding the valve ball, which for its closure, presses the valve ball onto the valve seat, and for its opening, exposes the valve ball to an initial tension of a spring; the valve ball in the open state is lifted off from the valve seat by a high-pressure jet the valve ball in the open state is lifted off from the valve seat by a high-pressure jet which is supplied via an output throttle bore by a control chamber connected to a central high-pressure delivery line. The valve seat has an approximately steep-walled funnel shape having a right-angled to acute-angled cone angle. Because of the steep-walled funnel shape, the centering of the valve ball is assisted upon closure of the injection control valve, and a radial displacement of the valve ball with respect to a diffuser and the output throttle bore is prevented.
The German Patent DE 103 38 081 A1 discusses a further fuel injector of the type indicated above. In the fuel injector described there, an armature is formed in one piece with a valve needle. Provided in the valve needle are flow-through openings which direct the fuel, flowing through the fuel injector, to a sealing seat. The valve needle is operatively connected by welding to a spherical valve-closure member that, together with a valve-seat member, forms a sealing seat, and downstream of the sealing seat, a spray-orifice disk has formed in it at least one spray-discharge orifice from which fuel is injected into an intake manifold. The inner sealing of the fuel injector with respect to the intake manifold is dependent on the processing when manufacturing the fuel injector. During production of the valve-closure member with the sealing seat formed on it, a high surface quality with a relatively good sealing associated with it is attained by grinding and honing; however, this is qualified by the subsequent processes such as pressing the valve-seat member into the valve sleeve, and the joining of the components by a welded seam.
The above-mentioned fuel injectors having a spherical valve-seat member and hollow frustoconical valve-seat member have the disadvantage that eccentricities of the seat contact points at the valve needle and at the valve seat, caused by the manufacturing process, lead to leakages of fuel during operation.
In contrast, the fuel injector of the exemplary embodiment of the present invention having the characterizing feature of the main claim has the advantage that, because of the stiffness-reducing elements provided on the valve-seat member and/or on the valve-closure member, the seat area of the fuel injector is made elastically softer, and therefore eccentricities at the seat contact points are elastically pressed over by the contact force. The fuel leakage during operation therefore becomes less. The wear of the fuel injector thereby becomes less as well, because due to the elastic conformation of the two seat elements, the contact force is distributed on a larger seat area. The contact force may also be selected to be less. The wear and the operating speed of the valve are positively influenced in this manner.
An especially positive effect is achieved if both the valve-seat area and the valve-closure member are provided with stiffness-reducing elements, an optimal conformation of the two components thereby resulting.
A stiffness-reducing element is formed particularly easily from the standpoint of production engineering by providing a recess in the form of a circumferential groove encircling an outer peripheral surface of the valve-closure element. A stiffness-reducing element may be produced in this easy manner in the valve-seat member as well, by providing a groove in the inner peripheral surface of the valve-seat member that extends almost to the seat-contact point. Because support material is missing behind the seat-contact point, it is made soft.
To reduce the stiffness of the valve-seat member, it is likewise advantageous if it is made thin-walled, so that it becomes flexible or soft in this thin-walled area. The stiffness is reduced still further if the valve-closure member has both an outer circumferential recess in the form of a circumferential groove, and moreover a second stiffness-reducing recess in an inner area.
The valve-seat areas may also be made soft or flexible by using suitable soft materials.
For reasons of fluid mechanics, it is also advantageous if the recesses are filled with a soft material such as plastic.
An exemplary embodiment of a fuel injector according to the present invention is represented in simplified form in the drawings and is elucidated and described in detail in the following description.
a-2e show respective specific embodiments of stiffness-reducing elements which are provided on the valve-closure member.
Fuel injector 1 is made up of a nozzle body 2 in which a valve needle 3 is positioned. Valve needle 3 is in operative connection with a spherical valve-closure member 4, which cooperates with a valve-seat surface 6, located on a valve-seat member 5, to form a sealing seat. In the exemplary embodiment, fuel injector 1 is an inwardly opening, electromagnetically actuated fuel injector 1 which has a spray-discharge orifice 7.
Solenoid coil 9 is wound on a coil brace which rests against an inner pole 10 of solenoid coil 9. Inner pole 10 and external pole 8 are separated from each other by a gap. Solenoid coil 9 is energized via a line by an electric current, which may be supplied via an electrical plug contact 12. Plug contact 12 is enclosed by a plastic coating 13, which is extrudable onto inner pole 10.
An armature 19 is non-positively connected via a first flange 14 to valve needle 3, which, for example, may be joined to first flange 14 by a welded seam. Braced on first flange 14 is a restoring spring 15, which is prestressed by a sleeve 16 in the present design of fuel injector 1.
Running in armature 19 and in valve-seat member 5 are fuel channels 18a, 18b which conduct the fuel, supplied via a central fuel feed 11, to spray-discharge orifice 7 in valve-seat member 5. Fuel injector 1 is sealed off from a distributor line (not shown) by a seal 17.
In the rest state of fuel injector 1, restoring spring 15 acts, via first flange 14 at valve needle 3, upon armature 19 counter to its lift direction in such a way that valve-closure member 4 is held in sealing contact against valve-seat surface 6. When excited, solenoid coil 9 generates a magnetic field which moves armature 19 in the lift direction counter to the spring force of restoring spring 15, the lift being defined by a working gap occurring between inner pole 10 and armature 19 in the rest position.
Armature 19 also carries along first flange 14, which is welded to valve needle 3, and thus valve needle 3 in the lift direction as well. Valve-closure member 4, in operative connection with valve needle 3, lifts off from valve-seat surface 6, and the fuel arriving at spray-discharge orifice 7 via fuel channels 18a, 18b is ejected.
If the coil current is switched off, once the magnetic field has sufficiently decayed, armature 19 falls away from inner pole 10 due to the pressure of restoring spring 15 on first flange 14, whereby valve needle 3 moves counter to the lift direction. As a result, valve-closure member 4 comes to rest on valve-seat surface 6, and fuel injector 1 is closed. The electromagnetic circuit forms an actuator 28.
a through 2c show specific embodiments of stiffness-reducing elements, which are provided on the valve-closure member.
In the specific embodiment shown in
b shows a further specific embodiment in which at its downstream end, a valve needle 3 again has a rounded-off valve-closure member 4 formed integrally with valve needle 3. In contrast to the exemplary embodiment shown in
In the further exemplary embodiment shown in
The exemplary embodiment shown in
Finally,
Valve-seat member 5 has a hollow-cylindrical section 25 and, adjacent to it, a hollow frustoconical section 26 which is thin-walled and includes seat-contact point 23. Both components, i.e., valve-closure member 4 and valve-seat member 5, thereby become soft and capable of conforming.
Finally,
For reasons of fluid mechanics, the grooves both in valve-closure member 4 and in valve-seat member 5 may be filled with a soft material such as plastic, which is not shown in the figures. The exemplary embodiment of the present invention is also valid for hydraulically driven diesel nozzles.
Number | Date | Country | Kind |
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10 2006 052 817 | Nov 2006 | DE | national |
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Number | Date | Country | |
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20080149744 A1 | Jun 2008 | US |