WO2012059267A1 - Fuel injection system of an internal combustion engine - Google Patents

Abstract

The invention relates to fuel injection system of an internal combustion engine, comprising a tank (2), which is connected via a booster pump (1) to a pump interior (3) of a high-pressure pump (5), the pump interior (3) being connected via a dosing unit (10) to a pump working space (9), and furthermore the pump interior (3) being hydraulically connected to a return flow line (7) via an overflow valve (16), which comprises a valve housing (17), a valve plunger (18), and a valve spring (19) which is arranged in a spring space (15), characterized in that the spring space (15) is connected via a throttle circuit to the hydraulic space connected to the dosing unit (10). According to the invention, a fuel injection system is provided, in which the filling pressure of a pump working space (9) can be adjusted depending on the delivery quantity. This is achieved in that the spring space (15) is connected via a throttle circuit to the hydraulic space connected to the dosing unit (10).

Description

 Description title

Fuel injection system of an internal combustion engine prior art

The invention relates to a fuel injection system of an internal combustion engine, with a tank which is connected via a pre-pressure pump with a pump interior of a high-pressure pump, wherein the pump interior is connected via a metering unit with a pump working space and further the pump interior via an overflow valve, comprising a valve housing, a valve piston and arranged in a spring chamber valve spring, is hydraulically connected to a return line.

Such a fuel injection system of an internal combustion engine is known from DE 10 2008 042 089 A1. In this fuel injection system, the switched hydraulic space of the metering unit is connected via a fuel line with three pump working spaces of the high-pressure pump. The overflow valve of this fuel injection system has a hollow-bore piston with an inserted throttle, which connects the spring chamber of this overflow valve with its inlet. By this configuration, the form at the entrance of the metering unit should be more balanced than previously regulated and squeaking noises should be reliably avoided even when using connecting cables made of steel.

Furthermore, it is known to interconnect the hydraulic space connected by the metering unit via a so-called zero-feed throttle with the tank or a supply line to the admission-pressure pump. By means of such a zero-feed throttle, a possible leakage of the metering unit should be removed at a set zero delivery.

The invention has for its object to provide a fuel injection system in which the filling pressure of a pump working space is dependent on the flow rate adjustable. Disclosure of the invention

Advantages of the invention

This object is achieved in that the spring chamber is connected via a throttle circuit with the hydraulic space connected by the metering unit.

By this throttle circuit, which acts as a pressure divider, depending on the pressure, which controls the metering unit, a higher or lower pressure in the spring chamber of the overflow valve, which is more precisely a differential pressure control valve is set. The pressure upstream of the overflow valve thus consists of the purely mechanical portion of the valve spring characteristic and the hydraulic pressure in the spring chamber. Since the pressure in the spring chamber can be varied, it is also possible to vary the pressure upstream of the overflow valve.

In a further development of the invention, the throttle circuit is a line connection with a throttle on. Since the metering unit and the overflow valve are normally integrated directly into the pump housing of the high-pressure pump, the line connection may be formed, for example, as a connecting channel. In this case, the throttle is realized by a throttle element inserted into the connecting channel or by a diameter reduction in the manufacturing process of the line connection.

In a further development of the invention, the spring chamber is connected to the return line, wherein in a further embodiment in the return line a Rückströmdrossel is turned on. In this case, the return line can also be connected to the line connection at any point behind the switched throttle, wherein the Rückströmdrossel downstream of this connection point must be turned on in the return line.

In a further embodiment of the invention, the throttle has a lower throttle rate than the Rückströmdrossel. In other words, the flow cross section through the throttle is greater than that through the Rückströmdrossel. By this vote increases with open metering unit, the pressure in the spring chamber, while with the metering unit closed, the pressure in the spring chamber gradually drops to about the return pressure level. By appropriate adjustment of the diameter of the throttle and the Rückströmdrossel the pressure difference between the open position and the closed position of the metering unit can be set almost arbitrarily. In a further development of the invention, the throttle and / or the Rückströmdrossel is a filter, which may be formed, for example, in a further development as a gap filter, upstream. Through such a filter or slit filter chokes are reliably protected from dirt particles.

In a further embodiment of the invention, a Absteuerleitung the spill valve is connected to the return line. Likewise, in a further embodiment, bearing lubricant discharge lines of the high-pressure pump are connected to the return line. Due to these refinements, a compact design of the fuel injection system in the region of the high-pressure pump is possible, in that all corresponding lines in the high-pressure pump open into the return line, which is then connected in a suitable manner to the tank via an external line connection.

In summary, the following is achieved by the embodiment according to the invention:

- A flow rate-dependent filling pressure is applied, for example, high filling pressures at high filling requirements and low filling pressures, if only small amounts of fuel must be transported, set.

- It is achieved a significantly extended work area, that is, it can be adjusted stable levels of variable pressure. With a single overflow valve (with only one setting) different pressure levels can be achieved by varying the throttle diameters of the throttle and the backflow throttle.

- It is achieved a low component load, especially the valve spring.

- It is achieved a cost reduction because of the avoidance of variations and the avoidance of the use of high quality valve springs, at the same time the control pressures are higher than in known solutions adjustable.

- There is a smaller space requirement, since with increasing control pressure in known embodiments, the spring length of the valve spring increases, especially when designing a sufficient vibration length in pressure pulsations.

- In so-called single-actuator systems (control pressure control only via the metering unit), the throttle can also take over the function of a zero feed throttle. - The Rückströmdrossel can additionally take over the spring chamber damping throttle.

Further advantageous embodiments of the invention are described in the drawings, in which an illustrated in the figure embodiment of the invention is described in detail.

Short description of the drawing

Embodiment of the invention

The single figure shows a schematic representation of the interaction of the essential components of a fuel injection system according to the invention. From a pre-pressure pump 1 is from a tank 2 fuel via a filter device in a

Pump interior 3 a high-pressure pump 5 promoted.

The high-pressure pump 5 has a pump housing, in which a pump camshaft is rotatably mounted in bearings 4a, 4b. The bearing points 4a, 4b are fuel-lubricated and via Lagerschmierstoffabführleitungen 6a, 6b of the exiting at the bearing points 4a, 4b from the pump interior 3 fuel in a return line 7, which opens into the tank 2, discharged. The pump camshaft moves via a roller tappet a pump piston 8 at a rotational movement of the pump cam shaft translationally up and down. The pump piston 8 cooperates with a pump working chamber 9, which can be connected to the pump interior 3 via a metering unit 10. With the metering unit 10, the amount of fuel to be supplied to the pump working chamber 9 is arbitrarily adjustable, for example, as a function of a pressure in a high-pressure accumulator. During an upward movement of the pump piston 8, the fuel introduced into the pump working chamber is conveyed via a high-pressure line 11 into the high-pressure accumulator. A necessary for this promotion

Suction valve for the introduced into the working space 9 fuel and a check valve to shut off the high-pressure line 1 1 are inserted directly into a pump cylinder head 12 of the high-pressure pump 5. The switched from the metering unit hydraulic space (represented by a

Connecting line 13 to the pump working chamber 9) is connected via a line connection 14 with a spring chamber of a spill valve 16 directly or indirectly. The overflow valve 16 has a valve housing 17, in which a valve piston 18 can be adjusted against the force of a valve spring 19. A valve control chamber 20 is also connected to the pump interior 3 (or the supply line to the metering unit 10) by switching on a filter. With increasing fuel pressure in the pump interior 3 by a closed metering unit 10, the valve piston 18 is moved in the direction of the spring chamber 15 and releases a discharge opening, which is connected to a discharge line 21, which also opens into the return line 7. By way of this diversion line 21, for example, at a set zero delivery rate, the fuel conveyed by the admission pressure pump 1 and not required for bearing lubrication is deactivated.

As stated, the hydraulic space (connecting line 13) connected by the metering unit 10 is connected to the spring chamber 15 via a line connection 14. In this case, a throttle 22 is turned on in the line connection 14. Furthermore, the spring chamber 15 is connected to the return line 7, wherein in the return line 7 a return flow restrictor 23 is inserted near the spring. If the line connection 14 - as shown - connected via the return line 7 to the spring chamber 15, the Rückströmdrossel 23 is arranged in each case downstream of the injection point. The throttle diameter of the throttle 22 is greater than the throttle diameter of the Rückströmdrossel 23, so that when the metering unit 10 is open, the pressure in the spring chamber 15 increases, while the pressure in the spring chamber 15 is continuously degraded with closed metering unit 10 to the pressure in the return line 7.

The throttle 22 and the Rückströmdrossel 23 filters may be upstream in particular gap filter.

Claims

claims 1 . Fuel injection system of an internal combustion engine, with a tank (2) which is connected via a pre-pressure pump (1) with a pump interior (3) of a high-pressure pump (5), wherein the pump interior (3) via a metering unit (10) with a pump working space (9) is connected and further the pump interior (3) via an overflow valve (16), comprising a valve housing (17), a valve piston (18) and in a spring chamber (15) arranged valve spring (19), hydraulically connected to a return line (7) is, characterized in that the spring chamber (15) via a throttle circuit with the of the metering unit (10) connected hydraulic space is connected. 2. Fuel injection system according to claim 1, characterized in that the throttle circuit is a line connection (14) with an on throttle (14). 3. Fuel injection system according to one of the preceding claims, characterized in that the spring chamber (15) with the return line (7) is connected. 4. Fuel injection system according to claim 3, characterized in that in the return flow line (7) a Rückströmdrossel (23) is turned on. 5. Fuel injection system according to claim 4, characterized in that the throttle (22) has a lower throttle rate than the Rückströmdrossel (23). 6. Fuel injection system according to one of the preceding claims, characterized in that the throttle (22) and / or the Rückströmdrossel (23) in each case a filter is connected upstream. 7. Fuel injection system according to claim 6, characterized in that the filter is a split filter. 8. Fuel injection system according to one of the preceding claims, characterized in that a discharge line (21) of the overflow valve (16) with the return flow line (7) is connected. 9. Fuel injection system according to one of the preceding claims, characterized in that Lagerschmierstoffabführleitungen (6a, 6b) of the high-pressure pump (5) with the return line (7) are connected. 10. Fuel injection system according to one of the preceding claims, characterized in that the return flow line (7) opens into the tank (2).