DE1289359B - Fuel injection system - Google Patents

Description

The invention relates to a fuel injection system for internal combustion engines, in which the fuel is passed to the injection valve after the end of the delivery automatically closing member, such as a check valve, is supplied and where the between the closing cross-section of the shut-off element and the injection valve located section of the injection line is in constant communication with a room, as a partial delimitation one in the sense of an enlargement or reduction of the room has resilient wall that lasts for the duration of each injection below that in one direction from the limited by the closing member on the pump side Clear out and in the opposite direction out of said section of the Injection line out on the resilient wall acting fuel pressure one that coincides with the installation position of the wall or is slightly displaced in relation to this Takes position.

In fuel systems of this type, the elastically compliant one falls Assigned the task to the injection line after each injection was completed to relieve in order to ensure a post-spray-free operation. This discharge happens in the following way. The immediately after the end of the injection of the Injection nozzle running back to the injection pump and delivering fuel to it Pressure wave is the way to the pump through which meanwhile automatically in its closed position returned shut-off device blocked. On the other hand, it runs on the elastically yielding one Wall, which releases a storage volume by dodging and only when it is opened of the shut-off device at the beginning. the next injection in their starting position returns. In the meantime, after subsiding in the injection line the pressure wave a resting pressure lying above atmospheric pressure, which in its The height depends on the current operating status of the machine and the dimensions the components of the system. So it arises, for example, with multi-cylinder Injection internal combustion engines with identical dimensions of the individual working cylinders assigned fuel system parts in all injection lines between two Injections always have the same static pressure, which creates favorable conditions are given for a satisfactory coordination of the injection system. The absolute The level of the static pressure is essentially determined by the amount of the fuel exerted adjustment force counteracting restoring force of the evading wall 1 or of the course of this restoring force over that of the wall when evading distance covered. This allows the wall to evade during the injection bent forward, datfi when the shut-off element is open in the flexible wall, equilibrium of forces prevails under the in the one direction from the pump side through the closing member limited space and in the opposite direction from that between the Closing cross-section of the shut-off element and the section located on the injection valve the fuel pressure acting out of the injection line.

In a known injection system of this type, the path that the relieving bodies supporting the resilient wall after each injection is completed when dodging, only travels against the force of a spring limited a hydraulically formed elastic stop. This arrangement points the great defect that it is under the influence of the incoming from the injector high-frequency pressure waves to overshoots of the relieving body, whose The amplitude and frequency usually change from one injection to another. this in turn leads to uneven relief volumes and thus to fuel quantity scatter. As tests have shown, there is also a regularity in the course of the overshoots due to the smallest tolerances in the geometric dimensions of the fuel injection system unavailable. There is another consequence of these overshoots in that the fuel pressure in the injection line is often between two successive injections temporarily or permanently falls below the vapor pressure, which ultimately leads to cavitation erosion in the injection lines.

According to the invention, these deficiencies are remedied by one of the movements the resilient wall damping device. This causes an overshoot certainly avoided. The damping device within the scope of the invention have any design suitable per se. A hydraulic one is recommended Damping, for example, in such a way that the resilient wall or one attached to it articulated piston-after each injection in a liquid-filled and .with a throttling drain hole provided space evades into it.

What the design of the resilient wall or this bearing body is concerned, there are several possible embodiments in this regard. A first proposal is to use the 'elastically flexible' in a manner known per se Train wall as a piston and in a central bore of the check valve respectively. Another possibility is as an elastically flexible wall to provide a resilient membrane in a manner known per se.

As for the preload. the elastic wall, by spring force, -there is the possibility of one-sided closing of the wall, as is known per se burden or they in a further embodiment of the invention between them in their Pre-tensioned springs fixing the initial position. This latter Installation method makes it possible by a corresponding coordination of the springs and the Impact surfaces of the wall to ensure that the latter after each injection under the effect of the pressure waves arriving from the injection line in the direction Injection pump and under the action of the negative pressure waves coming from the injection line dodges in the direction of the injection nozzle.

Finally, the possibility of the loading spring should be pointed out train the resilient wall as a bellows.

Three exemplary embodiments of the invention are shown in the drawing.

A b b. 1 shows a fuel injection system in which the elastic flexible wall than guided in a central bore of the check valve Piston is formed, A b b. 2 a system with basically the same structure however, after the end of the injection, the piston which yields elastically is held in its installation position between two preloaded springs; A. b b. 3 illustrates a fuel injection system in which the self-acting Shut-off element is designed as a piston valve, which is also the elastic represents yielding wall.

A b b. 1 shows the upper part of a pump element of a multi-cylinder injection internal combustion piston engine in section. The pump piston is denoted by 1, its guide bushing by 2, the pump chamber by 3 and the connecting piece of the pump element provided with an internal thread is denoted by 4 . A pressure pipe connection 7, provided at both ends with an external thread 5 and 6, is inserted into the nozzle 4, the thread 5 of which is used to connect the injection line (not shown). A sleeve 8 is clamped between the pressure pipe connection 7 and the guide bush 2 of the pump piston 1, in which the cylindrical shaft 9 of a check valve 11 loaded by a spring 10 is guided. The shaft 9 is provided with longitudinal grooves 12, which ensure a constant connection of the pump chamber 3 with an annular groove 14 upstream of the seat 13 of the check valve 11. At the beginning of the effective delivery, the valve 11 lifts against its loading spring 10 from its seat 13 and enables the fuel to enter the injection line. A piston 16 is housed in a central bore 15 of the check valve 11, which after the end of the injection, ie when the check valve 11 has returned to its seat 13, under the action of the then coming from the injection line and through a bore 17 in the check valve 11 pressure waves accumulating on it evade against the force of a spring 18 into a fuel-filled space 19 which is only connected to the pump space via a narrow and therefore throttling bore 20. The evasive movement of the piston 16 is thus hydraulically damped from the start, so that an overshoot of the piston 16 when evasive is definitely avoided.

The fuel system according to A b b. 2 basically corresponds in its structure to that according to A b b. 1. It differs from the latter only in a different design of the check valve 21, which leads to a structure smaller in diameter. The check valve 21 is designed as a smooth hollow cylinder seated directly behind the pump chamber 3, which has longitudinal grooves 23 extending from the seat 22 and extending through it on the outside. The check valve 21 is loaded by the spring 27, which is supported on the one hand in the pressure pipe socket 7 and on the other hand via the relief piston 24 and its return spring 25 against the bottom of the valve.

With the arrangement according to A b b. 3, the relief piston, which moves towards the pump chamber 3 after the end of the injection, and the non-return valve are combined into a single component in the form of a pot piston 29 open to the injection line, which is loaded against the conveying direction by a relatively weak spring 30 and maintains contact on the pump side with a Spring 31, which in turn rests on a valve plate 35, which is provided with recesses on the circumference and a throttle bore 32 in the middle and rests on a plate 34 clamped between the guide bush 33 of the pot piston 29 and the guide bush 2 of the pump piston 1. At the beginning of the effective delivery, this valve plate 35 lifts from the plate 34, taking along the spring 31 and the piston 29, as a result of the pressure gradient developing over the throttle bore 32 to the space 36, so that fuel is unthrottled through the recesses on the circumference of the valve plate 35 or can flow into the space 36 largely unthrottled. Under the fuel pressure subsequently building up in this space 36, the piston 29 deviates so far that the radial bores 37 in the sleeve 33 are opened and the path into the injection line is opened for the fuel. After the end of the injection, the piston 29 returns to its starting position, in the course of which it closes the bores 37 and then gives way to the pump chamber 3 against the force of the spring 31 against the force of the spring 31 under the oncoming pressure waves. This evasive movement takes place in a damped manner, since the fuel displaced from the space 36 in which the spring 31 is accommodated can only escape with a delay through the throttle bore 32 in the valve plate 35.

Claims (1)

Claims: 1. Fuel injection system for internal combustion engines, in which the fuel is supplied to the injection valve via an organ that closes automatically after the end of the delivery, for example a check valve, and in which the section of the injection line located between the closing cross-section of the shut-off element and the injection valve is in constant communication with is a space that has as a partial delimitation an elastically flexible wall in the sense of an enlargement or reduction of the space, which for the duration of each injection under the space delimited by the closing member on the pump side in one direction and out in the opposite direction the said section of the injection line out on the resilient wall acting fuel pressure assumes a position coinciding with the installation position of the wall or slightly displaced relative to this position, characterized by the movements of the elastic n flexible wall damping device (20, 28, 32). 2. Fuel injection system according to claim 1, characterized in that the resilient wall (16, 24, 29) or a piston hinged to it after each injection into a liquid-filled space (19 , 26, 36) dodges into it. 3. Fuel injection system according to claim 1 or 2, characterized in that the resilient wall is formed in a manner known per se as a piston (16) and is guided in a central bore (15) of the check valve (11). 4. Fuel injection system according to claim 1 or 2, characterized in that the resilient wall is designed in a manner known per se as a resilient membrane. 5. Fuel injection system according to one of claims 1 to 3, characterized in that the resilient wall (24, 29) is clamped between preloaded springs (25, 27 or 30, 31) which fix them in their initial position. 6. Fuel injection system according to claim 1, characterized in that the loading spring of the resilient wall is designed as a bellows.