In modern internal combustion engines, in particular Diesel engines, injection systems are used in which a high-pressure pump puts the fuel at a high pressure level. The fuel acts on a high-pressure reservoir body (common rail), which when the engine is in operation is constantly under pressure or in other words is subjected to a system pressure level generated by the high-pressure pump. High-pressure lines that ensure the supply of fuel to the engine cylinders branch off from the high-pressure reservoir body. Via fuel injectors, the fuel that is delivered via the high-pressure lines is injected into the combustion chamber of the cylinders of the engine.
In common rail injection systems, the injection event into the combustion chambers of the engine is uncoupled from the pressure generation in the high-pressure reservoir body (common rail). As a result, the instant and quantity of fuel injection can be controlled by engine electronics. This makes an injection adapted to the particular engine load possible. In typical applications, a system pressure of at least 1800 bar is generated in the high-pressure reservoir body (common rail); even high pressures above 2000 bar can be generated. By means of common rail injection systems, a plurality of injections per work cycle can be achieved. Typically, this results in a preinjection, a main injection, and a postinjection.
The control of the injection event is effected with the aid of an electrical signal, which is generated by the control unit of the engine. The electrical signal serves to trigger a solenoid valve for actuating the fuel injector. This solenoid valve, via suitable hydraulics, regulates the motion of a preferably needle-shaped injection valve member, which with its tip opens or closes at least one injection opening into the combustion chamber of the engine. The injection event is initiated by actuation of the solenoid valve, as a result of which a fuel-filled control chamber is pressure-relieved by actuation of the preferably needle-shaped injection valve member. Because of the pressure relief of the control chamber, the preferably needle-shaped injection valve member moves upward, and as a result, at the tip of the injection valve member, injection openings embodied in the nozzle body are opened.
In the prior art, the solenoid valve exists in many different structural forms, as for example in German Patent Disclosure DE 196 50 865 A1. In a variant, a spherically embodied valve element is used, which is disposed at the upper end of the fuel injector and can be moved longitudinally of the fuel injector axis, which coincides with the axis of the injection valve member. In the closed state, the spherically embodied valve element seals off a conically polished valve seat.
As a further variant, the solenoid valve can also be placed in the lower region of the fuel injector, particularly in the injector body of the fuel injector. European Patent Disclosure EP 0 740 068 B1 discloses one such variant of a fuel injector. A valve member there is guided in a valve body, which is sealed off from the fuel that is at high pressure. In this way it is ensured that the fuel at high pressure does not exert any forces on the valve member. Typically, the axis of motion of the valve member, in such a variant, is offset laterally from the axis of motion of the injection valve member. Such a fuel injector is substantially more expensive to produce than a fuel injector provided with a spherically embodied valve member.
The present invention realizes a fuel injector with a valve that has a spherically embodied valve element, and this valve is placed directly in the injector body of the fuel injector. The valve is sturdy and has withstood the test of time. In a preferred feature of the present invention, the valve makes do without guidance of an armature or a pressure equilibrium. Thus this valve is very inexpensive.
The valve with the spherically embodied valve element is prestressed by a valve spring and is pressed into a closing position. When current is supplied to a magnet, an armature unit is attracted, counter to the action of the valve spring, and opens an outlet conduit from the control chamber. A control quantity flows out from this chamber, so that the preferably needle-shaped injection valve member moves into the control chamber and opens at least one injection opening on the end of the fuel injector toward the combustion chamber, so that fuel can be injected into the combustion chamber of the engine.
In the state of repose, the valve spring, via the armature, presses the spherically embodied valve element into a valve seat, which for example is embodied conically. In this state, the valve seat is sealed off by the closing force acting in the vertical direction as a result of the valve spring. The force exerted by the valve spring, in the state of repose, exceeds a contrary force generated by the system pressure in the control chamber.
The control chamber communicates with a high-pressure line via a first throttle restriction (inlet throttle restriction) and with the valve seat of the spherically embodied valve element via a second throttle restriction (outlet throttle restriction). The upper end of the preferably needle-shaped injection valve member protrudes into this control chamber. The preferably needle-shaped injection valve member is disposed vertically movably along a second axis, and this second axis extends parallel to the first axis of the valve spring. In the state of repose, fuel at system pressure is located in the control chamber and is delivered from the high-pressure line via the inlet throttle restriction. The force exerted by the fuel at system pressure on the preferably needle-shaped injection valve member ensures that the preferably needle-shaped injection valve member is not moved all the way into the control chamber. In this state, the preferably needle-shaped injection valve member closes at least one injection opening located at its tip. The fuel delivered to this injection opening via the high-pressure line can accordingly not be injected into the combustion chamber of the engine.
In an embodiment of the present invention, the armature unit, in particular the armature plate, is joined together from one inner component and one outer component. The inner part and the outer part are made from two different materials, and the material for the outer part is selected in accordance with magnetic properties. The material for the inner part of the armature unit is selected in accordance with mechanical requirements in view of hardness and machinability in the vicinity of the valve element as well as with regard to the mechanical requirements of the stroke stop. The two parts of the armature may be joined to one another positively or nonpositively. The armature is not guided in the valve body of the valve; instead, the position of the armature in the closed state of the valve results from the fact that the spherically embodied valve element is aligned with the valve seat, and the armature in turn is aligned with the spherically embodied valve element. In a variant embodiment, the armature may also be embodied of a single material as a one-piece component. It is equally well possible to provide a closing element receptacle, for the closing element that for example can be embodied spherically, on the armature unit. As a result, a greater axial offset of the armature unit relative to the valve seat can be compensated for. This variant, that is, the use of a closing element guide, can be combined with the armature that can be embodied as either in one piece or, as sketched above, in two parts. The armature is guided in the magnet core of the valve with a slight radial play, so that a virtually perpendicular orientation of the armature plate relative to the face end of the magnet is ensured.
In further variant embodiments what is proposed according to the invention, the possibility exists of locating the valve seat in the interface plane between the injector body and the valve body. This disposition of the valve seat has advantages upon assembly of the fuel injector. In one embodiment, the solenoid valve assembly can be aligned via a spacer sleeve on the valve body or can be surrounded in a sleeve (cartridge) that receives the entire electromagnet valve assembly. The electromagnet and the sleeve can be joined together nonpositively or positively and are disposed as a preassembled unit in the injector body of the fuel injector proposed according to the invention.
Exemplary embodiments of the invention are shown in the drawings and described in further detail in the ensuing description.
Shown are:
In
A nozzle holder 10 includes a high-pressure line 40, which is filled with fuel, for instance Diesel fuel. The nozzle holder 10 further includes a magnet 110, which is controlled via an electrical connection 120. The magnet 110 is connected to a valve seat 130 and an injection valve member 100. If an electric current is flowing through the magnet 110, then the injection valve member 100 moves along a first axis and uncovers the communication with a control chamber 330. In this way, the fuel located in the control chamber 330 can flow out through the valve 100 and a suitable connection. As a consequence of the fuel outflow from the control chamber 330, the pressure in the control chamber 330 decreases.
In the lower part of the fuel injector there is a nozzle body 60, which includes a preferably needle-shaped injection valve member 70 to which fuel is delivered via the high-pressure line 40. To that end, there is a nozzle chamber 50, which is filled with fuel, in the nozzle body 60. A hollowed-out area 90 in the body of the injection valve member 70 is located in the vicinity of the nozzle chamber 50 and leads to a vertical reciprocating motion of the injection valve member along a second axis, which as a rule is disposed vertically, if the hydraulic force relationships vary. The hollowed-out area 90 serves to conduct fuel from the nozzle chamber 50 between the needle-shaped injection valve member 70 and the nozzle body 60. The preferably needle-shaped injection valve member 70 continues to be closely guided in the nozzle body 60 in the vicinity of the hollowed-out area 90.
The injection event is tripped in that the engine control unit, via the electrical connection 120, sends a current through the magnet 110, so that the valve member 100 opens up the communication with the control chamber 330 and thus reduces the hydraulic pressure in the control chamber 330. In this way, the injection valve member 70 moves into the control chamber 330 and uncovers at least one injection opening 80 on the end toward the combustion chamber of the fuel injector, as a result of which fuel emerges from the at least one injection opening 80 and, in the event of sufficiently high pressure in the cylinder, is atomized. An injector body 20 ensures a positive fixation of the fuel injector on the cylinder head of the internal combustion engine.
In
The injection of the fuel, which is at system pressure, via a high-pressure line 40 is effected, as in the prior art, as a function of the position of a preferably needle-shaped injection valve member 70. Analogously to the prior art, the injection event is initiated by feeding an electric current into a magnet 110. In the fuel injector of the invention, the valve including the spherically embodied valve element 200 and the magnet 110 is seated inside the injector body 20. Conversely, the valves used in the prior art are used only in the upper part of the fuel injector, typically above a nozzle body 60, in a nozzle holder 10.
In
Via the high-pressure line 40, the fuel at system pressure is delivered. The high-pressure line 40 extends with a lateral offset from the axis of the nozzle holder 10 and extends through the valve body 30. In the valve body 30, the high-pressure line 40 forks. A first portion of the high-pressure line 40 extends through a cross-sectional constriction 310, which is called a D throttle restriction and has a pressure-reducing effect. If the preferably needle-shaped injection valve member 70 is open and for terminating the injection the valve is closed, and the control chamber 330 is subjected to system pressure, then system pressure also prevails below the needle-like injection valve member 70. The needle-like injection valve member 70 would for that reason, because of the action of a nozzle spring 335, close very slowly. The cross-sectional constriction 310 called a D throttle restriction reduces the pressure below the needle-like injection valve member 70, so that a greater hydraulic force is created, which markedly accelerates the closure of the preferably needle-shaped injection valve member 70.
A further segment of the high-pressure line 40 extends on the other side of the cross-sectional constriction 310 and discharges into the nozzle chamber 50. The shape, size and position of the nozzle chamber 50 can vary depending on the application; typically, the nozzle chamber 50 is disposed in the upper part of the nozzle body 60 as in
A second line segment, branching off from the high-pressure line 40 after it forks, extends through an inlet throttle restriction 320, which discharges into a control chamber 330. The preferably needle-shaped injection valve member 70 protrudes with its upper end partway into the control chamber 330, in the state of repose. The control chamber 330 also receives fuel that in the state of repose is at system pressure. The pressure of the fuel in the control chamber 330 compensates for the pressure generated by the fuel in the nozzle chamber 50, so that the preferably needle-shaped injection valve member 70 in
Communicating with the control chamber 330 is an outlet throttle restriction 340, which is provided in an outlet conduit 341 that discharges at an orifice 350 below the valve seat 342. The spherically embodied valve element 200 and the orifice 350 form the valve seat 342. The orifice 350 in this application is designed conically, so that a closing element 200 that is embodied spherically for instance and is seated in the orifice 350 seals off this orifice completely. In this way, in the position of repose, no fuel can emerge from the orifice 350 of the outlet conduit 341.
In a preferred feature of the present invention shown in
In the state of repose, a valve spring 380 exerts a closing force on the inner armature part 370 of the armature unit 352 and on the spherically embodied valve element 200, along a first axis of motion. By means of this force, the spherically embodied valve element 200 is press-fitted with the aid of the inner armature part 370 into the valve opening 350. The magnet 110, pressed in the direction of the orifice 350 via a prestressing element 390, is activated at the onset of the injection event by an electric current. As a result, the armature unit 352 is attracted, counter to the action of the valve spring 380 that acts in the closing direction. The orifice 350 of the outlet conduit 341 opens, and the control chamber 330 is pressure-relieved as a result of diversion of a control quantity.
By means of the orifice 350 opened during the injection event, the fuel can now escape from the control chamber 330, so that the pressure in the control chamber 330 drops. Because of the lesser pressure in the control chamber 330, the preferably needle-shaped injection valve member 70 moves into the control chamber 330. In the process, the injection valve member 70 executes a motion along a second axis, which extends offset from and parallel to the first axis of the valve spring 380. As a result of this motion of the preferably needle-shaped injection valve member 70, the injection valve member 70 on its lower end uncovers the at least one injection opening 80 and enables the injection of fuel into the combustion chamber of the engine.
It can be seen from the view in
In a further variant of the fuel injector of the invention, instead of a two-piece armature unit 352, including an inner armature part 370 and the outer armature part 360 in
In a further variant of the present invention, shown in
In
In
In the variant embodiments shown in
Number | Date | Country | Kind |
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102007056913.2 | Nov 2007 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP08/64831 | 10/31/2008 | WO | 00 | 5/26/2010 |