EP0999360A1 - Fluid metering control valve - Google Patents

Abstract

The fuel dosing valve has a valve housing (5) with a valve chamber (4) communicating with feed and discharge lines (10,9) and a housing bore (14) containing an axially sliding sealing element (2), cooperating with a valve seat (6) for the discharge line. The seal element is spring-biased against the valve seat and is lifted from it via a valve rod (1) fitting through the discharge line. The valve rod and the sealing element may be coupled together.

Description

The invention relates to an apparatus and a method for Valve control in a metering device for fluid.

A metering device for fluid with a control valve is known, for example for high-pressure injection of diesel (see, for example, K. Prescher, W. Bauer, W. Schafflitz: common-rail injection systems with speed-independent characteristics and high injection pressure - a future potential for the diesel engine VDI Verlag, 15th International Vienna Motor Symposium April 28-29, 1994, Row 12).
A conventional control valve is constructed so that a fluid inlet and a fluid outlet open into a valve chamber. The fluid drain can be closed by means of a sealing element, for example by resting the sealing element on a valve seat of the fluid drain. The mode of operation of the control valve consists in the rapid release of the largest possible flow cross-section between the fluid inlet and the fluid outlet, so that the pressure in a working chamber connected to the control valve, in which a piston is movably arranged, also decreases rapidly.
With a conventional control valve, the problem arises that at a high pressure of the fluid (typically 500 bar2500 bar with a diesel injector) a high force is required to actuate the control valve, which requires a correspondingly powerful drive.
For example, for an inward-opening control valve with a diameter of the valve seat of dv = 2 mm and a pressure p of the fluid in the valve chamber of 1500 bar, there is a hydraulic closing force on the sealing element of 471 N. Since the control valve not only relieves, but also to be opened quickly, the force exerted for opening must be significantly higher. At the same time, the high force with which the control valve is loaded in the closed state results in a high mechanical load on the valve seat. A reduction in the dimensions of the control valve has strict limits for fluidic and mechanical strength reasons. In addition, the imprint of a high actuation force is associated with a not inconsiderable mechanical loss due to a deformation of the components exposed to pressure.

The object of the present invention is a Control valve for a metering device for fluid with a to provide improved switchability.

The object is achieved by the features of claims 1 and 15 solved.

The idea of the invention essentially consists in arranging the sealing element axially displaceably in a housing bore opening into the valve chamber, wherein it can be pressed in a sealing manner onto a valve seat of the drain. The sealing element is arranged in the housing bore either in a fluid-tight manner or subject to leakage.
A valve tappet is guided through the outlet, through the stroke of which the sealing element can be displaced at least within the valve chamber. The valve tappet thus controls the opening and closing of the control valve. In addition, an inlet pressurized with fluid opens into the valve chamber, so that when the outlet is open, a fluid flow occurs from the inlet through the valve chamber into the outlet.

The control valve can be used for all types of fluids be, for example for liquids such as water, gasoline and diesel, or for gases such as B. methane, alcohol or Air.

The present invention has the advantage that in the closed state, ie when the sealing element closes the drain, the force on the sealing element can be adjusted in the axial direction. In addition to a pressure balance on the sealing element in the axial direction, the magnitude of an axially acting force is advantageously adjustable in both directions.
As a result, the force required to switch the control valve on the sealing element can be reduced considerably. It is thus possible to use a wide range of actuators to actuate the valve tappet even with a high fluid pressure in the valve chamber.
A pressure balance of the sealing element also advantageously results in less influence on the stroke of the control valve by pressure waves.
Advantageously, the present invention enables a larger diameter of the valve seat and thus a lower load due to the lower mechanical stress.
In addition, there is advantageously a greater dethrottling of the control valve with the same stroke of the sealing element. Advantageously, there is also less mechanical loss of compression due to the lower opening force requirement.
Due to a larger valve seat diameter and thus a stronger dethrottling, the use of a directly driven injector is made possible.

Advantageously, the valve seat of the drain is specially matched to a sealing head of the sealing element. For example, the valve seat is preferably conical in the case of a rounded or conical sealing head
It is also advantageous if the housing bore on its side facing away from the sealing element is provided with a return line that is as unpressurized as possible, so that leaking fluid can be removed through the fit between the sealing element and the bore.

To save space, it is advantageous if the restoring element is attached within the valve chamber.
On the other hand, to achieve better switching dynamics, it is advantageous if the valve chamber is as small as possible. In this case, it is advantageous to mount the reset element outside the valve chamber.
Furthermore, it is advantageous if the valve seat and the sealing element are designed such that there is a high sealing contact surface between the sealing element and the housing.

Both fluids and fuels (petrol, Diesel, kerosene, alcohols etc.) and water can be used as also gases like methane, butane or air.

Of course, the control valve is not just for control an injector, but to control general Dosing devices suitable, for example for atomization on surfaces or for cooling.

Figur 1 zeigt ein herkömmliches Steuerelement für einen Einspritzer,

Figur 2 zeigt eine Ausführungsform des erfindungsgemäßen Steuerventils,

Figur 3 zeigt eine weitere Ausführungsform des Steuerventils,

Figur 4 zeigt das erfindungsgemäße Steuerventil als Teil eines Einspritzers,

Figur 5 zeigt eine Wirkung des Steuerventils,

Figur 6 zeigt eine weitere Ausgestaltung des Steuerventils.

The invention is illustrated schematically in more detail in the following exemplary embodiments.

FIG. 1 shows a conventional control element for an injector,

FIG. 2 shows an embodiment of the control valve according to the invention,

FIG. 3 shows a further embodiment of the control valve,

FIG. 4 shows the control valve according to the invention as part of an injector,

FIG. 5 shows an effect of the control valve,

Figure 6 shows a further embodiment of the control valve.

In Figure 1 is a sectional side view conventional 2/2-way control valve shown.

A valve chamber 4 is present in a valve housing 5, in which a sealing element 2 is located. The sealing element 2 is by means of a return element 3 in the form of a compression spring on the mouth of an outlet designed as valve seat 6 9 pressed into the valve chamber 4. The valve seat 6 has a diameter at its contact with the sealing element 2 dv on.

The valve chamber 4 is through an inlet opening into it 10 pressurized with fluid F. The inlet 10 is with a Flow throttle 7 equipped. Through the outlet 9 protrudes Valve tappet 1, which rests on the sealing element 2. The distance between valve lifter 1 and outlet 9 is so far executed that the fluid F through without significant throttling this fit can drain off; the valve lifter 1 is so fluidly permeable through the outlet 9. The valve housing 5 settles for easier manufacture composed of an upper part 501 and a lower part 502.

In the closed state, the sealing element is through the Reset element 3 and the pressure of the fluid F on the sealing element 2 pressed onto the valve seat. The valve lifter 1 is either lifted off the sealing element 2 or presses with one generally comparatively little force on the sealing element 2. As a result, the sealing element 2 is fluid-sealing on the valve seat 6. The pressure P of the fluid F in the valve chamber 4 is at a maximum and corresponds to that at the inlet 10 pressure applied.

During an opening process, the valve lifter 1 of a - not shown - drive in the direction of the valve chamber 4 moved so that the sealing element 2 in the valve chamber is pushed into it. By the associated lifting the sealing element 2 from the valve seat 6 becomes a flow cross section of procedure 9 released, through which the Pressure fluid F from the valve chamber 4 in the discharge without pressure or under a low pressure 9 drains away. This arises in the valve chamber 4 and Inlet 10 a pressure drop, for example, a the inlet 10 connected hydraulic or mechanical-hydraulic System is controllable. The balance of power on Sealing element 2 is now essentially by the restoring element 3 and the valve lifter 1 determined.

To close the control valve, valve tappet 1 is closed moves the drive, not shown, back to its starting position, whereby the sealing element 2 by hydraulic Forces and the force exerted by the restoring element in the valve seat 6 is moved back. The reset element 3 also serves the purpose of lowering the control valve Pressure of the fluid F in the valve chamber 4 closed and to keep tight. The flow restrictor 7 influences the pressure build-up in the valve chamber 4 or the pressure reduction at a Inlet 10 connected hydraulic system.

Figure 2 shows a sectional side view schematically an embodiment of a control valve according to the invention.

In contrast to the conventional control valve in Figure 1 opens now additionally a bore 14 in the valve chamber 4, wherein the sealing element 2 has a leakage over a length L in the Bore 14 is guided. The size of the leak or throttling is, for example, by the gap width between the Sealing element 2 and the housing 1 and by the length L of the Sealing element 2 adjustable in the bore 14.

The end surface facing away from the valve chamber 4 also stands the sealing element 2 in connection with an unpressurized Return line 16.

The sealing element 2 is composed of a sealing head 201, by means of which the outlet 9 can be closed, and a piston rod 202, which is firmly connected thereto and which is arranged in the bore 14 so as to be axially displaceable. The diameter ds of the piston rod 202 is selected so that it corresponds to the diameter dv of the valve seat 6. By the ratio of the cross-sectional area as of the piston rod 202, namely as = π · ds 2nd 4th to the cross-sectional area av of the valve seat 6, namely av = π · dv 2nd 4th , the resulting force acting axially on the sealing element 2 can be specifically coordinated. In the case of the same surface area occurring in this exemplary embodiment, ie av = as, complete pressure compensation on the sealing element 2 is brought about in a simple manner.

In Figure 3, another embodiment is shown schematically as a sectional side view, in which the sealing head 201 is designed as a poppet valve. In contrast to the exemplary embodiment in FIG. 2, the valve lifter 1 and the sealing element 2 form a unit. In addition, the restoring element 3 is articulated outside the valve chamber 4 on the valve tappet 1, for example by means of a snap ring or a Seeger ring, so that the sealing element 2 is pulled onto the valve seat 6 and is not pressed.
This arrangement achieves a reduction in the size of the valve chamber 4 which is advantageous for the dynamics of the control of the control valve, while on the other hand a larger space requirement of the control valve has to be accepted.

In this figure too, the piston rod 202 of the sealing element 2 with leakage over the length L of the fit between Piston rod 202 and housing 5 out. Alternatively, you can the fit in the bore 14 by means of at least one on Sealing element 2 attached sealing means fluid-sealing be executed, e.g. B. by means of a sealing ring.

Figure 4 shows the use of that shown in Figure 2 Control valve as part of a servo valve controlled high pressure diesel injector.

A drive housing 11 contains a working piston 13, a coupling rod 19, a nozzle needle spring 18 and a nozzle needle 17 within a bore. The working piston 13 forms with the drive housing 11 on its side facing away from the coupling rod 19 a working chamber 12 which is pressurized with a fluid supply line filled with fluid F. 8 is connected via an inlet throttle 24. Furthermore, the working chamber 12 is fluidly connected to the inlet 10 of the valve chamber 4.
The bore of the drive housing 11 is expanded in the form of a spring chamber 15 at the level of the coupling rod 19. In the spring chamber 15 there is the nozzle needle spring 18, which is articulated to the coupling rod 19 and presses it in the direction of the nozzle needle 17.
A fluid chamber 22 is present on the nozzle needle 17 and is in fluid communication with at least one injection nozzle 23 via a wide fit between the nozzle needle 17 and the drive housing 11.

In the initial state, the control valve is closed, i.e. that the sealing element 2 rests on the valve seat 6 in a sealing manner. This builds up in the valve chamber 4 and the inlet 10 the pressure of the fluid F at maximum, namely to that of the fluid supply line 8 delivered pressure. This maximum Pressure is also present in the fluid-filled working chamber 12, so that the nozzle needle by this pressure force of the working piston 13 17 via the coupling rod 19 onto a nozzle sealing seat 21 presses and so seals the at least one injection opening 23. The nozzle needle 17 is additionally by the nozzle needle spring 18 pressed into the nozzle sealing seat 21. One opposite directional force experiences the nozzle needle 17 and thus the working piston 13 by the pressure of the fluid F in the Fluid chamber 22, which has another branch of the fluid supply line 8 is delivered. The pressurized in the direction of movement Areas 20 of the nozzle needle 17 are smaller than exposed to the fluid F in the working chamber 12 pressure-effective surface of the working piston 13, which here the Working chamber 12 delimiting the end face of the working piston 13 corresponds.

Only from the ratio of the end face of the working piston 13 to the pressurized surfaces 20 of the nozzle needle 17 results from the same pressure of the fluid F in the Working chamber 13 and in the fluid chamber 22 a maximum deflection of working piston 13 and nozzle needle 17 on the injection nozzle 23. The nozzle needle spring 18 carries essentially to ensure a safe closure of the injection nozzles 23 at a low pressure of the fluid F in the Fluid feed line 8 at.

Via the return line 16, both the valve chamber 4 between the fit of piston rod 202 and housing 5 leaking fluid F dissipated as well as by the fit between Working piston 13 and drive housing 11 and between Nozzle needle 17 and drive housing 11 in the spring chamber 15 leaking fluid F.

To actuate the injector, the sealing element 2 is by means of of the valve lifter 1 pressed into the valve chamber 4 and thus opens the drain 9 opposite the valve chamber 4. As a result, fluid F flows out of the valve chamber 4 and out of the Inlet 10 via the outlet 9, so that the pressure in the Valve chamber 4 and the inlet 10 drops. This also decreases the pressure in the working chamber 12, so that the associated Force on the working piston 13 also drops. If the Pressure of the fluid F in the working chamber 12 has dropped so far is that the force he exerts along with that of the Nozzle needle spring 18 is less than the force exerted Pressure exerted in the fluid chamber 22 on the nozzle needle 17, so the working piston 13, the coupling rod 19th and the nozzle needle 17 moved in the direction of the working chamber 12. As a result, the nozzle needle 17 lifts from the nozzle sealing seat 21, whereby fluid F from the fluid chamber 22 through the wide fit between nozzle needle 17 and drive housing 11 through the at least one injection nozzle 23 metered into the Outside space is given.

To close the injector, the valve lifter 1 is from the valve chamber 4 retracted so that the sealing element 2 is pressed again on the valve seat 6. This increases the Pressure of the fluid F in the valve chamber 4, in the inlet 10 and in the working chamber 12 back to its maximum, from the Fluid supply value. As a result, the Fluid F in the working chamber 12 on the pressure-effective surface force of the working piston 13 is so great that the working piston, the coupling rod and the nozzle needle 17 again be moved away from the working chamber 12. This sets the nozzle needle 17 back onto the nozzle sealing seat 21 and closes the injection nozzle 23 against the fluid chamber 22. The release of fluid F into the outside space is prevented.

Common-Rail").
Das Schaltelement ist aber nicht auf diese Anwendungen eingeschränkt, sondern kann für alle Arten von Fluiden F eingesetzt werden.Such an injector is e.g. B. suitable for fuel injection into an internal combustion engine or a turbine. The control valve is due to its good switching properties at high pressure in the fluid supply line 8, typically 500 bar to 2000 bar, preferably used in a direct injection, z. B. in a gasoline or diesel direct injection (for example by means of a common high-pressure line, so-called.

Common Rail ").
However, the switching element is not restricted to these applications, but can be used for all types of fluids F.

Figure 5 shows a plot of the force on the sealing element 2 in Newtons against the pressure in the valve chamber 4 of the figure 2 and 3 shown control valves in bar. The diameter dv of the valve seat 6 is 2 mm.

As a solid line, a pressure-force curve is a conventional one Control valve (as = 0) plotted. The one with further Dashed graph shows the power of a partial pressure-balanced sealing element 2 (av> as), and as Semicolon present graph the force of a complete pressure-balanced sealing element 2 (av = as). As a narrow dash is the force on an overcompensated sealing element 2 (av <as).

So that an unwanted influence on the in the initial state in the valve chamber 4 prevailing pressure levels the throttling effect of the fit between the piston rod 202 and hole 14 may be significantly larger than that Throttling effect of the flow restrictor 7.

Due to the small diameter of the piston rod 202 of typically 2 mm and with a common in injection technology Fit for piston rod 202 with a radial Game of 3 microns can meet this requirement with a relative short length L of the throttling fit between the piston rod Reach 202 and valve housing 5.

From this figure it is clear that by means of a change the surface of the sealing element 2 in the bore 14 through the pressure of the fluid F in the valve chamber 4 on the Sealing element 2 exerted force advantageously in one wide range is adjustable, e.g. B. partially compensated, pressure balanced or overcompensated.

FIG. 6 shows a sectional side view of an outwardly opening variant of the control valve according to the invention.
The sealing element 2 is accommodated outside the valve chamber 4 in a control chamber 25 as an extension of the drain 9. The restoring element 3 is realized as a compression spring which is present within the control chamber 25 and which presses the sealing element 2 onto a sealing seat 6 of the outlet 9 which borders on the control chamber 25.

In the initial state, the piston rod 202 has the effect that the opening force of the fluid F on the sealing element 2 does not become so great that fluid F leaks out of the valve chamber 4.
During an opening process, the valve tappet (1) is withdrawn from the valve chamber 4, so that the sealing element 2 is lifted off the sealing seat 6.
To close, the valve lifter 1 presses the sealing element 2 back onto the outlet 9.

Claims (18)

Control valve in a metering device for fluid, comprising a valve chamber (4) located in a housing (5) into which an inlet (10), an outlet (9) and a housing bore (14) which can be pressurized with fluid (F), a sealing element (2) which is arranged in the housing bore (14) so as to be axially displaceable and subject to leakage and which can be pressed in a fluid-sealing manner onto a valve seat (6) of the outlet (9), a valve tappet (1), which is fluidly permeable through the outlet (9) and through whose stroke the sealing element (2) can be displaced, at least one restoring element (3) through which the sealing element (2) can be pressed onto the valve seat (6). Control valve according to claim 1, wherein
the valve seat (6) is located at the mouth of the outlet (9) in the valve chamber (4). Control valve according to claim 1, wherein
the valve seat (6) is located at the end of the outlet (9) facing away from the valve chamber (4). Control valve according to claim 3, wherein
the valve seat (6) is located within a control chamber (25), which is an extension of the drain (9). Control valve according to one of the preceding claims, the valve stem (1) and the sealing element (2) firmly together are connected. Control valve according to one of the preceding claims, which the sealing element (2) from a in the housing bore axially displaceably arranged piston rod (202) and a thus firmly connected valve head (201), the Valve head (201) can be pressed onto the valve seat (6). Control valve according to one of the preceding claims, the restoring element (3) is located in the valve chamber (4) Compression spring, which is on the housing (5) and the Supporting the sealing element (2). Control valve according to one of claims 1 to 6, wherein
the restoring element (3) is a compression spring located outside the valve chamber (4), which is articulated on the valve tappet (1). Control valve according to one of the preceding claims, which the inlet (10) with a flow restrictor (7) is. Control valve according to one of the preceding claims, which the fit between the sealing element (2) and housing (5) in the bore (14) fluidly by means of a sealing agent is sealed. Control valve according to one of the preceding claims, which is the diameter (av) of the valve seat (6) (as) of the sealing element (2) in the bore (14) corresponds. Control valve according to one of the preceding claims, which the valve chamber (4) with fluid (F) under a pressure of 500 bar to 2000 bar can be applied. Control valve according to one of the preceding claims in a fuel injector. Control valve according to Claim 13, in which the fluid (F) Diesel, gasoline or kerosene. Method for valve control in a metering device for fluid, in which there is a valve chamber (4) located in a housing (5) into which an inlet (10), an outlet (9) and a housing bore (14) which can be pressurized with fluid (F) open, a sealing element (2) is arranged in the housing bore (14) so as to be axially displaceable and subject to leakage, a valve tappet (1) which can be guided through the outlet (9) in a fluid-permeable manner and through whose stroke the sealing element (2) can be displaced, the sealing element (2) is pressed onto a valve seat (6) of the drain (9) by means of at least one restoring element (3),
in which in the starting position the sealing element (2) is pressed onto the valve seat (6) in a fluid-sealing manner, the pressure of the fluid (F) in the valve chamber (4) becoming maximum, during an opening process, the sealing element (2) is lifted from the valve seat (6) by means of a stroke of the valve tappet (1), so that fluid (F) flows out of the valve chamber (4), as a result of which the pressure of the fluid (F) in the valve chamber ( 4) and the inlet (10) is minimal, during a closing process, the sealing element (2) is pressed onto the valve seat (6) in a sealing manner. The method of claim 15, wherein
the valve seat (6) at the mouth of the outlet (9) in the valve chamber (4) is present, so that during the opening process the valve tappet (1) is moved in the direction of the valve chamber (4), the valve tappet (1) is withdrawn from the valve chamber (4) during the closing process. The method of claim 15, wherein
the valve seat (6) is provided on the end of the outlet (9) facing away from the valve chamber (4), so that during the opening process the valve tappet (1) is moved away from the valve chamber (4), during the closing process the valve tappet (1) is moved in the direction of the valve chamber (4). Method according to one of claims 15 to 17, in which
the pressure of the fluid (F) in the inlet (10) in the starting position is 500 bar to 2000 bar.

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