DE102014207587A1 - Fuel injection valve for internal combustion engines and a method for operating the same - Google Patents

Abstract

Fuel injection valve for internal combustion engines having a nozzle body (14) in which a pressure chamber (15) is formed, which can be filled with fuel under high pressure, and with a at least partially in the pressure chamber (15) arranged piston-shaped nozzle needle (23), which with a Nozzle seat (22) for opening and closing at least one injection port (20) cooperates, can flow through the fuel from the pressure chamber (15). Furthermore, an electric actuator (25) is provided, which cooperates at least indirectly with the end face of the nozzle needle (23) facing away from the nozzle seat and which can change its extent in the longitudinal direction of the nozzle needle (23) as a function of the electrical control signal. The actuator (25) is acted upon by a tension spring (30) in the direction of the nozzle seat (22).

Description

The invention relates to a fuel injection valve for internal combustion engines, as used for example for the injection of fuel into a combustion chamber of an internal combustion engine, and a method for operating the fuel injection valve.

State of the art

From the prior art fuel injection valves, which are used for direct injection of fuel into combustion chambers of internal combustion engines, well known, such as from DE 100 24 703 A1 , In this case, the injection systems, as used in particular for supplying fuel to self-igniting internal combustion engines, often operate according to the so-called common-rail principle. In this case, fuel is compressed by a high-pressure pump and fed to a high-pressure accumulator, discharged from the lines for the respective injectors, through which the fuel is ultimately injected into the combustion chambers. The injection valves have injection ports through which the fuel exits at high pressure, whereby it is finely atomized and is available for combustion in the combustion chamber. For opening and closing of the injection openings, a nozzle needle is provided, which is designed piston-shaped and is arranged longitudinally movable within the fuel injection valve. This interacts with a nozzle seat and thereby opens and closes one or more injection openings.

The movement of the nozzle needle usually happens according to the servo-hydraulic principle. In this case, the end face of the nozzle needle, which is remote from the nozzle seat, acted upon by the fuel pressure in a control chamber and is pressed by this hydraulic force in its closed position. If the pressure within the control chamber is lowered, for example by connecting the control chamber to a low-pressure chamber, then the nozzle needle moves in the longitudinal direction and releases the injection openings. To lower the pressure in the control chamber is a control valve, which is opened and closed with an electric actuator. This magnetic actuators or piezo actuators are used, which switch accordingly fast.

The known fuel injection valves are relatively complicated, since on the one hand the nozzle itself with the nozzle needle, the injection ports and the fuel supply must be made with high precision and on the other hand, a control valve that controls the pressure in the control room and thereby controls the actual movement of the nozzle needle. As a result, the fuel injection valve requires comparatively many components, many of which must be manufactured with high precision in order to ensure sufficient functionality.

Advantages of the invention

In contrast, the fuel injection valve according to the invention has the advantage that only a few components are needed and thereby a very simple, yet effective construction of the fuel injection valve is made possible. For this purpose, the fuel injection valve on a nozzle body, in which a pressure chamber is formed, which can be filled with fuel under high pressure. In the pressure chamber, a piston-shaped nozzle needle is arranged, which cooperates with a nozzle seat for opening and closing at least one injection opening, via which fuel can flow out of the pressure chamber. In addition, an electrical actuator is present, which interacts at least indirectly with the nozzle seat facing away from the front side of the nozzle needle and can change its extension in the longitudinal direction of the nozzle needle depending on the electrical control signal. The actuator is acted upon by a tension spring in the direction of the nozzle seat, so that it is arranged under compressive stress between the tension spring and the nozzle needle.

By this arrangement, it is possible that the actuator shortened by its change in length, the distance between the tension spring and the nozzle needle. By taking advantage of the inertia of the actuator and possibly other body so the nozzle needle can be moved away from the nozzle seat before it is closed again by the force of the tension spring. As a result, the injection openings can be opened for a short, but nevertheless sufficiently long period in order to introduce the required amount of fuel into the combustion chamber.

In a first advantageous embodiment, the actuator is designed as a piezoelectric actuator. As a result, its extension in the longitudinal direction of the nozzle needle can be changed very quickly by a corresponding electrical voltage on the piezoelectric actuator and injections thus take place in rapid succession.

Advantageously, the actuator can be energized so that its length in the longitudinal direction of the nozzle needle is shortened by switching off the electrical voltage applied to the actuator. This can also be done in an advantageous manner with the interposition of a compensating body between the actuator and the nozzle seat facing away from the end face of the nozzle needle, which can be used to change the bias of the tension spring by using compensation body with different thicknesses.

The actuator is biased in an advantageous manner directly by the tension spring at least indirectly against the nozzle seat facing away from the end face of the nozzle needle, so that the shortening of the actuator directly affects the nozzle needle. Advantageously, moreover, between the tension spring and the actuator, an impulse mass may be provided which, by its inertia, influences the time duration which the nozzle needle remains open. Depending on the mass of this pulse mass, the characteristic changes when opening and closing the injector.

In a further advantageous embodiment, the pressure chamber is hydraulically separated from a low-pressure chamber by a cutting disk, wherein the nozzle needle protrudes through an opening in the cutting disk. This makes it possible that not all parts of the fuel injection valve are acted upon directly by the high pressure, but that the actuator is arranged in a low-pressure chamber. In particular, if the actuator is designed as a piezoelectric actuator, its sealing against the surrounding the piezoelectric actuator fuel is less expensive. Advantageously, while the low-pressure space is connected to a low-pressure line, wherein in the low-pressure space always a pressure of less than 15 bar, preferably less than 10 bar, prevails.

drawing

In the drawing, an inventive fuel injection valve is shown schematically in longitudinal section.

Description of the embodiment

In the single FIGURE of the drawing, an inventive fuel injection valve including associated fuel supply is shown schematically, wherein the fuel injection valve is shown in longitudinal section. The fuel injection system includes a tank 1 , in which fuel is kept under ambient pressure. From the tank 1 the fuel reaches a high-pressure pump 3 that compresses the fuel and a high pressure line 2 in a high-pressure accumulator 5 promotes, is kept in the fuel under high pressure. From the high-pressure accumulator 5 lead pressure lines 6 to the individual fuel injection valves, wherein in the present drawing, only one fuel injection valve 10 shown is the via the pressure line 6 with the high-pressure accumulator 5 connected is.

The fuel injector 10 has a holding body 12 on and a nozzle body 14 , wherein in the nozzle body 14 a pressure room 15 is formed, via the pressure line 6 can be filled with fuel under high pressure. At the combustion chamber end of the nozzle body 14 is a valve seat 22 formed, of which an injection port 20 goes out, through the fuel from the pressure chamber 15 can be introduced into a combustion chamber. A low pressure room 16 is from the high pressure room 15 through a cutting disc 27 separated, with the cutting disc 27 an opening 28 that of a piston-shaped and longitudinally movably arranged nozzle needle 23 is enforced. The nozzle needle 23 works with the nozzle seat 22 together and opens and closes by their longitudinal movement of the injection port 20 ,

The nozzle seat 22 opposite end face of the nozzle needle 23 is located on an actuator 25 at which a momentum body 29 connects, which is designed for example as a metallic cylinder. The actuator 25 is preferably formed as a piezoelectric actuator. But there are also other actuators conceivable, for example, those that use magnetostrictive properties, or actuators that operate on the electromagnetic principle. Between the impulse body 29 and the holding body 12 is a tension spring 30 arranged under pressure bias. By the force of the tension spring 30 becomes the momentum body 29 against the actuator 25 and this against the nozzle needle 23 pressed, so that a total of a closing force on the nozzle needle 23 is exercised, this in the direction of the nozzle seat 22 suppressed.

The low pressure room 16 in which is the actuator 25 , the impulse body 29 and the tension spring 30 is located above a low pressure line 18 with the tank 1 connected, wherein in the low pressure line 18 a check valve 19 is arranged so that a certain minimum pressure in the low pressure space 16 is maintained. The pressure is a maximum of a few bar, but not more than 15 bar, preferably not more than 10 bar. Depending on the design, the check valve 19 also omitted, so that in the low-pressure chamber of the tank 1 is prevailing ambient pressure.

The opening 28 in the cutting disc 27 is sized so that between the nozzle needle 23 and the opening 28 only a minimal gap remains and so only to a small flow of fuel between the high-pressure chamber 15 and the low-pressure room 16 through the gap between the nozzle needle 23 and the opening 28 comes.

The operation of the fuel injection valve is as follows: At the beginning of the injection is the actuator 25 energized, the electrical connection of the actuator 25 with a corresponding control device via a line not shown in the drawing happens. However, it is not necessary that the actuator 25 is permanently energized when the injection valve is closed, as the injection valve by the spring 30 is held in the closed position even with de-energized actuator. At least immediately before injection, the Actuator, however, be extended by energization, causing the actuator 25 in the longitudinal direction of the nozzle needle 23 lengthens and reaches its maximum extent in this longitudinal direction. In the high pressure room 15 There is a high pressure in the accumulator 5 is provided while in the low-pressure room 16 a low return pressure prevails. If an injection takes place, then the energization of the actuator 25 retracted, and this shortens in the longitudinal direction of the nozzle needle 23 , This will cause the nozzle needle 23 from the nozzle seat 22 pulled away, this movement support hydraulic forces acting on parts of the sealing surface 24 the nozzle needle 23 act or on any existing, separate paragraphs on the nozzle needle 23 which are not shown in the present drawing. Through the resulting opening between the sealing surface 24 the nozzle needle 23 and the nozzle seat 22 Fuel now flows out of the pressure chamber 15 into the injection opening 20 and from there into the combustion chamber of the corresponding internal combustion engine.

The movement of the nozzle needle 23 occurs despite the action of the tension spring 30 because the mass of the pulse body 29 larger than the mass of the nozzle needle 23 , This is the inertia of the pulse body 29 larger than the nozzle needle 23 and this essentially moves alone with a shortening of the actuator. Since the injection is very fast - not more than about a millisecond in the normal injection cycles - is with a corresponding dimensioning of the mass of the pulse body 29 ensures the required opening time. To end the injection, either the force of the tension spring 30 be used after a certain period of the pulse body 29 accelerated and thus over the actuator 25 the nozzle needle 23 closes. The closing of the injector can also be done by the fact that the actuator 25 is energized again and its length in the longitudinal direction of the nozzle needle 23 Expands what the nozzle needle 23 again in contact with the nozzle seat 22 suppressed. Because the momentum body 29 even in this case already a certain way towards the nozzle needle 23 has gone back, must the impulse body 29 through the actuator 25 back again and against the force of the tension spring 30 be pressed into its original position. In particular, piezoelectric actuators can readily apply very high forces, although small, but sufficient for this application stroke. Since the required stroke is usually less than 100 microns, this can be done quickly and reliably to reach the initial state before the next injection.

It can also be provided that the washer 27 eliminates and all components, so the nozzle needle 23 , the actuator 25 , the impulse body 29 and the tension spring 30 , in high pressure. In this case, the return line is eliminated 18 , which also offers the advantage that no amount of leakage occurs and thus the required amount of compressed fuel passing through the high pressure line 3 be made available, can be lowered.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10024703 A1 [0002]

Claims (10)

Fuel injection valve for internal combustion engines with a nozzle body ( 14 ), in which a pressure chamber ( 15 ) is formed, which can be filled with fuel under high pressure, and with at least partially in the pressure chamber ( 15 ) arranged, piston-shaped nozzle needle ( 23 ) fitted with a nozzle seat ( 22 ) for opening and closing at least one injection opening ( 20 ) cooperates, via the fuel from the pressure chamber ( 15 ) and with an electric actuator ( 25 ), which at least indirectly with the nozzle seat facing away from the end face of the nozzle needle ( 23 ) and its extension in the longitudinal direction of the nozzle needle ( 23 ) depending on the applied electrical voltage at the actuator ( 25 ), characterized in that the actuator ( 25 ) of a tension spring ( 30 ) in the direction of the nozzle seat ( 22 ) is acted upon. Fuel injection valve according to claim 1, characterized in that the actuator ( 25 ) is designed as a piezoelectric actuator. Fuel injection valve according to claim 1 or 2, characterized in that the length of the actuator ( 25 ) in the longitudinal direction of the nozzle needle ( 23 ) by switching off the on the actuator ( 25 ) voltage applied shortened. Fuel injection valve according to claim 1, 2 or 3, characterized in that the actuator ( 25 ) directly or with the interposition of a compensating body on the nozzle seat facing away from the end face of the nozzle needle ( 23 ) rests. Fuel injection valve according to one of claims 1 to 4, characterized in that the tension spring ( 30 ) the actuator ( 25 ) at least indirectly against the nozzle seat facing away from the end face of the nozzle needle ( 23 ). Fuel injection valve according to one of claims 1 to 5, characterized in that the tension spring ( 30 ) with the interposition of a pulse mass ( 29 ) the actuator ( 25 ) in the direction of the nozzle seat ( 22 ). Fuel injection valve according to one of claims 1 to 6, characterized in that the pressure chamber ( 15 ) from a low-pressure space ( 16 ) by a cutting disc ( 27 ) is hydraulically separated, wherein the nozzle needle ( 23 ) through an opening ( 28 ) in the cutting disc ( 27 protrudes. Fuel injection valve according to claim 7, characterized in that the actuator ( 25 ) in the low-pressure space ( 16 ) is arranged. Fuel injection valve according to claim 7 or 8, characterized in that the low pressure space ( 16 ) with a low-pressure line ( 18 ), whereby in the low-pressure space ( 16 ) always a pressure of less than 15 bar, preferably less than 10 bar prevails. Method for operating a fuel injection valve for internal combustion engines with at least partially in a pressure chamber ( 15 ) arranged, piston-shaped nozzle needle ( 23 ) fitted with a nozzle seat ( 22 ) for opening and closing at least one injection opening ( 20 ) and with an electric actuator ( 25 ), which at least indirectly with the nozzle seat facing away from the end face of the nozzle needle ( 23 ) and its extension in the longitudinal direction of the nozzle needle ( 23 ) depending on the applied electrical voltage at the actuator ( 25 ), wherein the actuator ( 25 ) of a tension spring ( 30 ) in the direction of the nozzle seat ( 22 ), characterized by the following method steps: - energizing the actuator ( 25 ) in such a way that it extends in the longitudinal direction of the nozzle needle ( 23 ), - changing the energization of the actuator ( 25 ) so that the actuator ( 25 ) and thereby the nozzle needle ( 23 ) from the nozzle seat ( 22 ) moves away.

Images