DE19519192C1 - Injector - Google Patents

Abstract

The injection valve for fuel injection systems has a needle nozzle (2) fitted in a valve body (1), a fuel feed (12) and a control device. The injection rate is to be precisely adjustable. This is attained in that there is a pressure chamber (11) which is connected to the fuel feed (12) via a primary throttle (14) and to a relief chamber (31) via a secondary throttle (32). The invention is applicable to diesel fuel injection systems.

Description

The invention relates to an injection valve according to the Oberbe handle of claim 1.

Such an injector is, for example, by EP-A 0 531 533 known. This publication deals with one Diesel injector with a high pressure system (common Rail system) in which the fuel is a high-pressure accumulator is fed via a high pressure pump. This one under high Pressurized fuel is then taxed accordingly tion of the individual cylinders of a diesel engine via on spray valves supplied. The injectors each controlled by a solenoid valve, for example also enable individual injection times.

In particular, to get injectors with which too a pre-injection is possible to reduce consumption, exhaust gas to improve values, noise, etc. Tile can be switched quickly at high injection pressures. At high storage pressures when using a solenoid valve a pre-injection difficult because the switching times of the Solenoid valve are too long and the full stroke of the valve must be run through so that reproducible conditions, for example the injection quantity can be achieved. also is the formation of the injection rate, i.e. H. slow opening, However, the nozzle needle closes quickly, whereby the For injection rate according to a map can hardly be possible.

It is an object of the present invention to provide an injection valve til with which it is possible to provide the injection rate to regulate precisely, d. that is, smallest reproducible pre injection quantities, slow increase in injection rate  Injection begins when nozzle nozzle closes quickly to enable del.

This object is achieved according to claim 1. Before partial further training is known in the subclaims draws.

In contrast to controlling the valve by means of a Solenoid valve offers control by means of a piezo actuator the ability to change gears extremely quickly and to control the valve intermediate position. It is also through the special design of the injection valve, in particular of the throttles, the pre-injection quantity even at the lowest Pre-injection quantity by reducing the injection rate (Reduction of the nozzle needle stroke) reproducible.

By carefully tuning the chokes according to the Measures according to claim 2, the one Spray valve designed as a so-called 2/2-way valve be characterized by a simple design, because with this type only a simple seat valve for control the nozzle needle is required.

In the following, the invention is illustrated by an illustration explained.

The illustration shows a 2/2-way valve with piezo actuator.

The injection valve shown in the figure consists of an elongated housing 6 , on the lower end of which a screw nut 3 is screwed on. With this union nut 3 , an intermediate washer 4 and a nozzle body 1 , in which a nozzle needle 2 is guided, are held from the lower end of the housing 6 . Both the intermediate disk 4 and the nozzle body 1 have a central bore 35 in which the nozzle needle 2 is guided so as to be displaceable in the axial direction. The Düsenna del 2 is at its end in the state shown on an annular nozzle seat 36, in which Be rich nozzle holes 37, 35 are provided, closing the nozzle needle. 2 At the other end, the nozzle needle 2 is provided with a pressure pin 5 , which is arranged in a spring chamber 30 provided in the housing 6 and is acted upon by a nozzle spring 7 arranged in the spring chamber 30 , so that the nozzle needle 2 is easily pushed toward the nozzle seat 36 is tensioned and closes it. The other end of the nozzle spring 7 is located on the opposite of the pressure pin 5 , the end of the spring chamber 30 , with an adjusting disk 9 arranged between them for adjusting the nozzle spring biasing force. With the pressure pin 5 , a closing piston 8 is connected at one end, which is partially encompassed by the nozzle element of FIG. 7 and ends at the other end in the region of a first pressure chamber 11 .

A control device for the nozzle needle 2 is fixedly connected to the housing 6 in the upper part of the injection nozzle. A hydraulically translated piezo drive is provided in the interior of the control housing and consists of a piezo actuator 20 which is mounted in a closure 21, which is sealed by an O-ring 22 . A circlip 24 secures the piezo actuator 20 in the control housing in the axial direction. The electrical connection to the piezo actuator 20 is established via the electrical connections 23 . The piezo actuator 20 bears against a primary piston 19 , which acts on a plate spring 16 , which has a large diameter. Inside the primary piston 19 , a secondary piston 39 is easily seen, which is firmly connected to a valve needle 27 . In the secondary piston 39 , a small spring 17 is provided, which is arranged between an inner surface of the primary piston 19 and the secondary piston 39 and presses the valve needle 27 onto a valve seat 40 which is connected to a secondary throttle 32 . The secondary throttle 32 communicates with the first pressure chamber 11 in communication, further comprising a bore is connected via a primary throttle 14 and 13 with the under high pressure fuel inlet 11 in connection. The fuel inlet 12 is connected via an inlet bore 10 to a second pressure chamber 41 , which is formed by a recess in the housing 6 in the region of the nozzle needle 2 , the nozzle needle being stepped in this region, so that control surfaces for the nozzle needle 2 be formed.

The space 31 in the region of the valve seat 40 forms a relief space and, if necessary, a further throttle for shaping the injection and is connected to a low-pressure run 29 in connection with which a leakage hole 33 , which opens into the spring space 30 , is connected. Next, the low pressure inlet 29 is connected to a filling inlet 34 to the working space 28 of the piezo drive and a relief bore 18 via a leakage chamber 26 with a return 25 .

The injection valve works as follows.

It is initially assumed that the piezo actuator 20 is de-energized. The valve needle 27 thus rests on its seat 40 due to the force of the spring 17 in the secondary piston 39 , as a result of which the secondary throttle 15 is closed and the connection to the low-pressure inlet 29 is thus interrupted. The high pressure is thus on the primary throttle 14 on the upper large surface of the closing piston 8 . Furthermore, the high pressure is applied to the stepped, smaller effective area of the nozzle needle 2 in the second pressure chamber 41 , so that due to the effective areas, the nozzle needle 2 (even without the action of the spring 7 ) is pressed onto its seat 36 , which openings 37 , 38 closes. The high pressure is also present on the valve seat 40 via a bore 15 and the secondary throttle 32 .

If the valve needle 27 is now opened, a fuel volume flow escapes through the secondary throttle 32 . If this volume flow is greater than the volume flow fed through the primary throttle 14 , the pressure in the first pressure chamber 11 drops above the closing piston 8 , so that the nozzle needle 2 opens, thereby releasing the injection of the fuel. If the valve needle 27 is closed, the pressure in the first pressure chamber 11 increases and the nozzle needle 2 is pressed back onto its seat 36 .

The drive device for the valve needle 27 operates as follows.

To open the valve needle 27 , the piezo actuator 20 is charged. It expands and pushes the primary piston 19 downward against the force of the plate spring 16 . The working space 28 is completely filled with fuel, whereby the secondary piston 39 is moved upward with the valve needle 27 against the spring force of the spring 17 . This will open the valve. When the piezo actuator 20 is discharged, the Ventilna del 27 is closed again accordingly.

The temperature compensation or the basic position of the valve is achieved via defined gaps between valve needle 27 and primary piston 19 and between primary piston 19 and secondary piston ben 27 . In order to ensure that the working space 28 is always completely filled, the return line 25 at the injection valve is always subjected to a low pressure.

Claims (12)

1. Injector for fuel injection systems, with

• a nozzle needle ( 2 ) arranged in a valve housing ( 1 ), which can open and close at least one injection nozzle opening ( 37 , 38 ),
• - A fuel inlet ( 12 ) which is hydraulically connected via two pressure chambers ( 11 , 41 ) with two different control surfaces of the nozzle needle ( 2 ), and
• - A control device that controls a valve needle ( 27 ) to relieve pressure on one of the control surfaces for controlling the fuel injection, characterized in that
• - One of the pressure chambers ( 11 ) communicates with the fuel inlet ( 12 ) via a primary throttle ( 14 ) and with a relief chamber ( 31 ) via a secondary throttle ( 32 ).

2. Injector according to claim 1, characterized in that the secondary throttle ( 32 ) is flow-controlled. 3. Injector according to claim 1, characterized in that the secondary throttle ( 32 ) is controllable. 4. Injector according to claim 1, characterized in that the flow-controlled secondary throttle ( 32 ) is driven by the valve needle ( 27 ). 5. Injector according to claim 1, characterized in that the relief chamber ( 31 ) is designed as a further Dros sel. 6. Injector according to claim 1, characterized records that the control device is a piezoelectric cal control device.   7. Injection valve according to claim 1, characterized in that the primary and secondary throttle ( 14 , 32 ) is designed so that the fuel volume flow through the secondary throttle sel ( 32 ) when opening the valve needle ( 27 ) is greater than through the primary throttle ( 14 ). 8. Injector according to claim 1, characterized in that the valve needle ( 27 ) is formed as a seat valve, which regulates the degree of opening of the opening of the secondary throttle ( 32 ) facing away from the pressure chamber ( 11 ). 9. Injector according to claim 6, characterized records that the piezoelectric driver is hydraulically translated. 10. Injector according to claim 1, characterized in that the valve needle ( 27 ) is non-positively connected to a secondary piston ( 39 ) of the piezoelectric Ansteuerein direction. 11. Injection valve according to claim 10, characterized in that the valve needle ( 27 ) is positively connected to the secondary piston ( 39 ) of the piezoelectric control device. 12. Injection valve according to claim 1 and 9, characterized in that between the valve needle ( 27 ) and the valve housing ( 1 ) and between a primary piston having the Ansteuerein direction ( 19 ) and secondary piston ( 39 ) and between the primary piston ( 19 ) and the Valve housing ( 1 ) column are provided, via which a small leakage can take place, whereby a work space ( 28 ) is always filled with liquid and that the pie zoelectric control device has a play-balanced, preloaded with compressive stress and clearly defined starting position in the event of thermal expansion.