DE3429128A1 - Fuel injection pump for internal combustion engines - Google Patents

Abstract

A fuel injection pump for internal combustion engines has a pump piston (10) guided in a pump cylinder (12), which piston defines a pump working chamber (13). During the delivery stroke the pump working chamber (13) is connected to an injection nozzle assigned to a cylinder of the internal combustion engine. A control slide valve (26) displaceable on the pump piston (10) opens a relief aperture (29) in the pump piston (10), connected to the pump working chamber (13) at the end of the delivery stroke. In order to prevent fuel being blown back from the injection nozzle into the pump working chamber (13) immediately at the end of the delivery stroke when the nozzle needle is not yet closed, the relief aperture (29) is closed by a pressure control element (31), which at least at the start of the opening of the relief aperture (29) maintains a predetermined pressure in the pump working chamber (13) and in the fuel injection line (22) by means of the control slide valve (26). <IMAGE>

Description

R. 19546
6.7.1984 gust

ROBERT BOSCH GMBH, 7OOO Stuttgart 1

Fuel injection pump for internal combustion engines

State of the art

The invention relates to a fuel injection pump for internal combustion engines of the type defined in the preamble of claim 1.

In such a fuel injection pump, the delivery or useful stroke of the pump piston and thus the Injection phase ended in that the relief opening or during the displacement movement of the pump piston Control bore in the pump piston is advanced over the control edge of the annular groove and in connection with the Ring groove occurs. This relieves the pump working space and the remaining fuel quantity in the pump working space flows during the remaining stroke of the pump piston via the relief opening and the drainage channel into the suction chamber of the fuel injection pump.

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This so-called. Absteuervorgang takes place so quickly that it has already ended before the nozzle needle of the injection valve or the injection nozzle again closes. Since with high-speed diesel engines to Achieving the highest injection pressures between the pump working chamber and the individual injection valves only return throttles and no valves can be used when the injection valve is not yet closed the combustion gases in the combustion chamber of the engine take some of the fuel out of the respective Press the delivery line carrying the injection valve into the pump working chamber via the return flow throttle. In the next injection process, this causes a reduction in the injection quantity and a delay in the start of injection.

Advantages of the invention

The fuel injection pump according to the invention with the Characteristic features of claim 1 has the advantage that the "blowing back" with simple means of the fuel is avoided. The pressure control member according to the invention in the time between Beginning of the shutdown process, so opening the discharge opening by the control slide, and closing the Maintained nozzle needle in the injection valve in the pump working space The pressure is so high that the pressure of the combustion gases is insufficient to keep the fuel above the Blow back flow restrictor.

Advantageous embodiments of the invention result from the further claims 2-10.

An advantageous embodiment of the invention results in particular from claim 2. The sliding piston

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provides a storage volume in which the controlled amount of fuel contrary to the Pressure of the pressure spring is inserted.

An advantageous embodiment of the invention results from claim 3. The intended drain hole prevents the storage volume from being pumped up and thus a gradual ineffectiveness of the pressure control member. This is sometimes the case when there is a lack of space the pressure spring is not so strong

.10 can be that the controlled amount of fuel is also pushed out again until the relief opening is closed. Then with every shutdown process the existing storage volume continues to be filled until the sliding piston is pressed together by the pressure spring rests on the housing base and the pressure control element is therefore ineffective. By arranging the drain hole accordingly The maximum storage volume is limited relative to the stroke of the sliding piston. The excess The amount of fuel flows through the drain hole into the suction chamber of the fuel injection pump. The drain hole at the same time also enables a relatively precise setting of that maintained by the pressure control valve Pressure

An advantageous embodiment of the invention results also from claim 4. Through the connecting bore, the spring space is with that surrounding the piston housing fuel-filled suction chamber of the fuel injection pump in connection. The amount that flows off via the throttle cross-section when the sliding piston is moved The amount of fuel dampens the piston movement and thus improves the pressure characteristics of the pressure control member.

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An advantageous embodiment of the invention also results from claim 7, in particular in conjunction with claim 8. By means of these measures a technically simple implementation of the pressure control valve according to the invention is given. The throttle cross-section is to be dimensioned in such a way that, on the one hand, a sufficiently high There is pressure in the pump working chamber and, on the other hand, after the nozzle needle in the injection valve has closed the fuel can flow largely unhindered through the relief opening.

drawing

The invention is based on exemplary embodiments shown in the drawing in the following description explained in more detail. Show it:

1 shows a detail of a longitudinal section of a fuel injection pump,

Fig. 2 each in an enlarged view

and FIG. 3 shows a longitudinal section of the pump piston (excerpts) and the control slide

of the fuel injection pump in FIG. According to one and first and second exemplary embodiments.

Description of the exemplary embodiments

In Fig. 1 is a schematic representation of a longitudinal section a distributor fuel injection pump shown, in which in a known manner a pump piston via a cam disk 11 from a further not shown

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provided drive is driven in such a way that it has both a translational and a executes rotational movement. The pump piston 10 is in this case in a cylinder 12 which is closed at the end displaceable, in which it delimits a pump working space 13. The cylinder 12 is in a pump housing 14 held, which has a suction chamber 15, the cam 11 and the protruding from the cylinder 12 Part of the pump piston 10 surrounds. The suction chamber is provided by a feed pump, not shown kept filled with fuel. The fuel flows in via inlet 16.

The pump piston 10 has a central axial bore 18, in the end face delimiting the pump working space 13 17 of the pump piston 10 opens. The axial bore 18 'is in connection with a transverse bore 19, in an annular groove 20 on the circumference of the pump

piston, 10 opens. A longitudinal distributor groove extends from the annular groove 20 21, which cooperates with delivery or injection lines 22 running in the pump housing 14. The injection lines 22 are corresponding to the number of cylinders to be supplied with the associated Internal combustion engine distributed on the circumference of the cylinder 12. With fast-running diesel engines each injection line 22 leads via a return flow throttle to the associated injection nozzle.

Longitudinal grooves 23 extend from the end face 17 of the pump piston 10, via which grooves occur during each suction stroke of the pump piston 10, the pump working space 13 with a suction bore 24, which extends from the pump suction space 15 to the cylinder 12 and passes through the cylinder wall, is connected. The suction hole 24 is by means of a solenoid valve

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lockable.

On the projecting into the suction chamber 15 portion of the pump piston 10 slides axially displaceably a control slide valve 26 which is actuated in known manner by a centrifugal speed governor via a control rod 27 and the useful or delivery stroke of _t and therefore the maximum delivery and ■ the end of injection controls. The control slide 26 has an inner annular groove 28 which is open towards the outer circumference of the pump piston 10 and which cooperates with a transverse bore 29 in the pump piston 10. The transverse bore 29 is connected to the axial bore 18 and is therefore in constant communication with the pump work chamber 13. The axial bore 18 and the transverse bore 29 thus form a relief opening for the pump work chamber, which is closed by the control slide 26 and depending on the position of the control slide 26 a smaller or larger stroke of the pump piston 10 is released. The left flank of the annular groove 28 in FIG. 1 forms a control edge. The annular groove 28 is connected to a discharge channel 30 which opens into the suction chamber 15 and is designed as a radial bore and which is closed off by a pressure control member 31 or 31 '(FIGS. 3 and 4). The pressure control member 31, 31 'is designed such that a predetermined pressure is maintained in the pump working chamber 13 for a short time at the beginning of the opening of the relief opening by the control slide 26, namely until the nozzle needle in the injection nozzle closes.

The pressure control member 31 in the embodiment according to For this purpose, FIG. 2 shows a sliding piston 32 seated on the mouth of the discharge channel 30 and having a

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Pressure spring 33 on. The sliding piston 32 is guided in a housing, which in this case is controlled by the control valve 26 is formed. In the structural design, the control slide 26 has a blind hole 34 on which The bottom of the drainage channel 30 opens. In the blind hole 34 the displacement piston 32 is axially displaceably guided and is at the bottom of the blind bore 34 pressed by the pressure spring 33, which is on the other hand on a the blind hole 34 closing closure part 35 supports. The closure part 35 is provided with an axial bore 36 through which the spring space is connected to the suction chamber 15. The axial bore 36 has a defined throttle cross section on. At a distance from the bottom of the blind bore 34 opens into this a radial bore 37. · The axial length of the sliding piston 32 is dimensioned such that the sliding piston 32 in its rest or basic position, in which it rests on the base of the blind bore 34, the radial bore 37 closes.

The operation of the pressure control member 31 is as follows

During the delivery stroke of the pump piston 10, fuel is sent to the injection nozzle via the injection line 22 promoted and injected there into the associated cylinder of the internal combustion engine. The delivery stroke is ended as soon as the transverse bore 29 of the relief opening during the stroke movement of the pump piston 10 Control edge of the annular groove 28 exceeds. The one that now begins during the remaining stroke of the pump piston During the shutdown process, fuel flows out of the pump working chamber 13 via the axial bore 18 and transverse bore 29 Relief opening formed in the drainage channel 30 and moves here while filling a storage volume

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the sliding piston 32 against the force of the pressure spring 33. Since, on the other hand, the rear side of the sliding piston 32 is also loaded by the pressure in the suction chamber 15 is, a certain pressure is required to move the displacement piston 32, which is determined by the dimensioning the pressure spring 33 is fixed. The shift pressure for the shift piston 32 is now designed so that in the pump working space 13 with the start of the shutdown process up to at least the point in time the ■ the nozzle needle has reliably closed the injection nozzle again, such a pressure can be maintained will prevent fuel being blown back by the engine's combustion gases when the engine is still open The nozzle needle via the backflow throttle into the delivery line 22 and the pump working space 13 is reliably prevented. If the sliding piston 3 2 by the the amount of fuel flowing out is pushed back until the radial bore 37 is released, so that it flows the further amount of fuel via this radial bore 37 into the suction chamber 15. So that is from the sliding piston 32 maximum released storage volume is set. By the distance between the radial bore 37 and the base of the blind bore 34, the maximum storage volume can be set so that the amount of fuel stored here through the displacement piston 32 with the start of the opposite displacement movement of the pump piston until it is closed again the relief opening in the pump working space 13 can be pushed back. Trained as a throttle Axial bore 36 dampens the axial displacement of the displacement piston 32.

The pressure control member 31 'according to the embodiment in Fig. 3 is of a the relief channel 30 closing check valve 38, which here as a ball

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check valve is formed, formed. The check valve 38 is integrated in the control slide 26, for which this has a blind hole 39, the base of which forms a valve seat 40 for the ball 41. A valve closing spring 42 is supported on the one hand on the ball 41 and on the other hand on a blind hole 39 that closes off Closing piece 43 from. The locking piece carries an axial bore 44 with it in the same way and for the same purpose as the closure part 35 in FIG defined throttle cross-section, via which the valve interior with the suction chamber 15 of the fuel injection pump communicates. The discharge channel 30 is designed as a throttle, the throttle cross-section is dimensioned so that on the one hand a sufficiently high pressure in the pump working space at the beginning of the shutdown process 13 is maintained and after closing the nozzle needle in the injection valve, the fuel over the check valve 3 8 can flow off.

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Claims (10)

R. 19546 6.7.1984 Bö ROBERT BOSCH GMBH, 7OOO Stuttgart 1 claims 1.) Fuel injection pump for internal combustion engines, in particular for high-speed diesel engines, with a pump piston guided in a pump cylinder, with a pump working chamber delimited by the pump piston, which can be filled with fuel during the suction stroke of the pump piston and can be connected to an injection nozzle during the delivery stroke of the pump piston a control slide which is axially displaceable on the pump piston and which opens or closes at least one relief opening on the outer circumference of the pump piston, which is connected to the pump work space, depending on the stroke position of the pump piston, a control edge of the control slide controlling the relief opening being formed by a radial flank of an inner annular groove in the control slide facing the pump piston , which is connected to a drainage channel leading to the outside, characterized in that the drainage channel (30) is closed with a pressure control member (31; 31 ') which is at least at the beginning of the 3429 Ί - 2 - R. 19546 Open the relief opening (29, 18) by the control slide (26) a predetermined pressure in the pump working space (13) and the fuel injection line supplied by it (22) maintains. 2. Fuel injection pump according to claim 1, d a through characterized in that the pressure control member (31) has one on the mouth of the Has discharge channel (30) seated sliding piston (32) with pressure spring (33). 3. A fuel injection pump according to claim 2, characterized in that the sliding piston (32) is guided in a housing which also accommodates the pressure spring (33) and that an outlet bore (37) extending through the piston housing opens radially in the sliding area of the sliding piston (32) . 4. Fuel injection pump according to claim 2 or 3, characterized in that in the spring space surrounding the pressure spring (33 ') (34) of the housing opens into a connecting bore (36) which extends through the housing wall and which has a defined throttle cross-section. 5. Fuel injection pump according to claim 3 and 4, characterized in that the axial length of the sliding piston (3 2) is dimensioned such that the outlet bore (37) at on the mouth of the discharge channel (30) seated sliding piston (32) closed by this is. 6. Fuel injection pump according to one of the claims 3-5, characterized - 3 - R. 19546 that the housing is formed by the control slide (26) itself. 7. Fuel injection pump according to claim 1, characterized in that the Pressure control member (31 ') of a non-return valve (38) closing off the relief channel (30) is formed. 8. Fuel injection pump according to claim 7, characterized in that.in A throttle is arranged in series with the check valve (38) and that the "throttle" is preferably is formed by the drainage channel (30) itself. 9. Fuel injection pump according to claim 7 or 8, characterized in that the check valve (38) is integrated in the control slide (26). 10. Fuel injection pump according to claim 9, characterized in that in the valve chamber (3 9) accommodating the valve closing element (41) and the valve closing spring (42) an outwardly leading connecting channel (44) with a defined throttle cross-section opens.