EP0319707A2 - Fuel injection pump for internal-combustion engines, particularly for diesel engines - Google Patents

Abstract

In the case of a fuel injection pump for internal combustion engines of vehicles, a damping device (40) is provided for eliminating so-called vehicle jerks, which allows rapid adjustment movements of a speed adjustment lever (32) connected to the accelerator pedal to take effect only with a delay on the delivery rate setting of the fuel injection pump. For this purpose, the damping device (40) has a damping chamber (45) delimited by a damping cylinder (41 - 43) and a damping piston (44) displaceable therein, which has two parallel throttles (47, 48) and thus antiparallel non-return valves (46) , 49) is connected to the pump interior (11). The damping piston (44) is connected to a damper lever (37), on which the speed adjustment lever (32) is supported via a preloaded drag spring (36). The damper lever (37) is connected via a control spring (31) to a control lever (29) which actuates a quantity adjusting member (28) which determines the force metering, so that an adjusting movement of the speed adjusting lever (32) has a delayed effect on the latter.

Description

State of the art

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

A major disadvantage of passenger cars equipped with diesel internal combustion engines is the vehicle jerking at low engine speeds, which, in addition to full-load and part-load jerking, mainly occurs due to the acceleration and deceleration process triggered by rapid accelerator pedal actuation. In order to largely eliminate this jerking of the vehicle, diesel internal combustion engines with fuel injection pumps are additionally provided with damping devices which, when rapidly "accelerating" or "accelerating", take the appropriate action Changes in the fuel injection quantities caused by the fuel injection pump have a delayed effect.

In a known fuel injection pump of the type mentioned (DE-OS 34 27 224), the hydraulic damping device is arranged between the speed adjustment lever of the fuel injection pump and the vehicle body coupled to the accelerator pedal, the damping cylinder being connected to the body and the damping piston via a piston rod to the speed adjustment lever is. A throttle is arranged in a longitudinal axial bore of the damping piston, which connects two damping chambers located on opposite sides of the piston. The speed adjustment lever is connected in a rotationally fixed manner to an adjustment shaft which can be pivoted in the pump housing of the fuel injection pump and to the end of which projects rigidly into the pump interior. The control spring connected to the control lever acts on the lever. The accelerator pedal engages the speed adjustment lever via compression springs. When the accelerator pedal is pressed quickly, the speed adjustment lever follows its movement only with a delay because it is supported on the body by the damping device. As the torque increases, the internal combustion engine, which is suspended from the body by means of flexible buffers, tilts to one side about its longitudinal axis. The speed adjustment lever is supported on the body via the damping device and is pivoted in the direction of reducing the fuel injection quantity. Conversely, the internal combustion engine tilts to the other side with a rapidly decreasing torque, the speed adjustment lever being displaced by the damping device in the direction of a larger amount of fuel. The damping device thus has a delaying effect when accelerating and the other a differentiating effect when changing the amount of fuel due to the deflection of the internal combustion engine. In the opposite direction, ie when "accelerating", the damping device acts accordingly. The jerking of the vehicle is actively damped by the negative feedback of the engine movement and the metered amount of fuel. The damping effect, however, is always the same when "accelerating" and "accelerating" and does not therefore achieve optimal suppression of vehicle jerking in all cases.

Advantages of the invention

The fuel injection pump according to the invention with the characterizing features of claim 1 has the advantage that the acceleration and deceleration damping can be achieved individually and without dead paths in the required range. The two throttles enable the acceleration and deceleration damping to be set separately. For both damping directions, the delay times can be determined independently of one another by the pretensioned trailing spring or return spring and by the cross section of the throttle bores, thus ensuring an optimal setting that largely eliminates the jerking of the vehicle.

Advantageous further developments and improvements of the fuel injection pump specified in claim 1 are possible through the measures listed in the further claims.

An advantageous embodiment of the invention results when unthrottled flow paths between the damping chamber and pump interior are connected in parallel with the throttles in such a way that they are only released in the regions of the displacement path of the damping piston in which idle paths of the Speed adjustment lever occur, ie in the areas of the speed adjustment lever pivoting in which no injection takes place yet. In this way, the response behavior of the fuel injection pump with respect to avoiding vehicle jerk is further improved.

A particularly advantageous embodiment of the invention results from claim 7. At higher speeds of the internal combustion engine and the associated pressure rise in the pump interior, the pressure valve opens and opens a further unthrottled flow path between the damping chamber and pump interior. As a result, the damping device is automatically ineffective at higher speeds, since in this speed range, due to the high kinetic energy of the flywheels, vehicle jerking does not occur and damping is not necessary.

drawing

The invention is explained in more detail in the following description with reference to an embodiment shown in the drawing. The drawing shows a detail of a fuel injection pump for a diesel internal combustion engine in a schematic representation.

Description of the embodiment

The fuel injection pump of the distributor type known per se and only schematically shown in FIG. 1 (see DE-OS 34 27 224, FIG. 2) has a pump housing, indicated by 10, which encloses a pump interior 11. The pump interior 11 is filled with fuel by means of a feed pump 12. The pump interior 11 is under a pressure of 6 - 8 bar. In synchronism with the feed pump 12, a pump piston 13 is set into a reciprocating and at the same time rotating movement via a cam drive 14. The pump piston 13 slides in a cylinder sleeve 15, which is seated in the pump housing 10, and delimits a pump work chamber 16 therewith. The pump work chamber 16 is via a longitudinal groove 17 in the end section of the pump piston 13, an inlet opening 18 in the cylinder sleeve 15 and a channel 19 in the pump housing 10 connectable to the pump interior 11. The pump working space 16 is connected via a pressure valve 20 and a channel 21 to an annular channel 22 in the pump piston 13. From the annular channel 22, a distributor groove 23 branches off in the pump piston 13 and cooperates with outlet channels 24, which are distributed over the circumference of the cylinder liner 15 and of which only one is shown. Each outlet channel 24 is connected to a connection opening 25 for an injection nozzle. An axial channel 26 leads from the pump working space 16 in the pump piston 13 to a transverse channel 27. The transverse channel 27 works together with a quantity adjusting element 28 which is axially displaceable on the pump piston section projecting into the pump interior 11. As long as the transverse channel 27 is covered by the quantity adjusting member 28, the pump piston 13 delivers high-pressure fuel from the pump work space 16 via the pressure valve 20, the channel 21, the annular channel 22 and the distributor groove 23 into one of the outlet channels 24. At the moment where the transverse channel 27 emerges from the quantity adjustment member 28, the pump work space 16 is connected to the pump interior 11 and is relieved. The high-pressure delivery to the connection openings 25 is abruptly stopped. The relative position of the quantity adjusting member 28 relative to the pump piston 13 thus determines the amount of fuel that is to be injected via the outlet channels 24.

To actuate the quantity adjustment member 28 engages it a spherical arm of a two-armed control lever 29, which is mounted on a pin 30 fixed to the housing. On the other arm of the control lever 29 engages on the one hand a centrifugal speed governor, not shown, and on the other hand (shown in the drawing above) via a control spring 31, a speed adjustment lever 32 which can be pivoted arbitrarily in the direction of arrow 33 via an accelerator pedal, not shown. A return spring 34 serves to reset the speed adjustment lever 32 if the actuating force on the accelerator pedal is lost. The two-armed speed adjustment lever 32 can be rotated about a pivot axis 35 fixed on the pump housing 10. The coupling between the speed adjustment lever 32 and the control spring 31 takes place via a preloaded drag spring 36 which is supported on the one hand on a lever arm of a damper lever 37 and on the other hand on the arm of the speed adjustment lever 32 remote from the return spring 34. The pretensioned drag spring 36 presses the lever arm of the speed adjustment lever 32 against a stop 38 which is arranged on the lever arm of the damper lever 37 remote from the drag spring 36. The damper lever 37 itself is pivotally arranged on the pivot axis 35 of the speed adjustment lever 32.

The damper lever 37 is part of a damping device 40 which serves to improve the smooth running of the internal combustion engine when the speed adjustment lever 32 is actuated quickly and eliminates the so-called vehicle jerking when the accelerator pedal is depressed or released quickly. The hydraulic damping device 40 is arranged in the pump interior 11 and comprises a damper housing 41 with a longitudinal bore 42 which is closed at both ends, a guide sleeve 43 which can be displaced in the longitudinal bore 42 and a damping piston 44 which slides in the guide sleeve 43. Damper housing 41 and guide sleeve 43 form in known Wise a damping cylinder which, together with the one end face of the damping piston 44, delimits a damping chamber 45. The damping chamber 45 is on the one hand via a first check valve 46 and a first throttle 47, both of which are arranged in the damping piston 44, and on the other hand, via a second throttle 48 and a second check valve 49, both of which are arranged in the damper housing 41, with the pump interior 11 in Connection. The connection between the outlet of the first throttle 47 and the pump interior 11 is ensured by a first radial bore 60 in the guide sleeve 43 and a first radial through opening 61 in the damper housing 41. The diameter of the through hole 61 is very large compared to that of the radial bore 60, so that even with a sliding movement of the guide sleeve 43 relative to the damper housing 41, the through hole 61 always releases the radial bore 60 towards the pump interior 11. The two check valves 46, 49 are arranged such that the blocking direction of the first check valve 46 towards the pump interior 11 and that of the second check valve 49 towards the damping chamber 45 are directed. The lever arm of the damper lever 37 carrying the stop 38 is articulated to the damping piston 44, while the lever arm of the damper lever 37 carrying the pretensioned trailing spring 36 is coupled to the control spring 31.

The guide sleeve 43, together with the damping piston 44, delimits on one end face a control chamber 50 which is connected to the pump interior 11 via a radial inlet duct 51. The other end of the guide sleeve 43 is covered with an end plate 52, which also serves as a guide for a compression spring 53. Guide sleeve 43 and end plate 52 delimit a pressure chamber 53 receiving relief chamber 54, which is connected via an outlet channel 55 to a fuel return line, which is indicated by the arrow 56 is indicated. The compression spring 53 is supported on a stop plate 57, the spatial position of which can be adjusted within the relief space 54 by means of an adjusting pin 58 which can be screwed into the damper housing 41. The prestress of the compression spring 53 can be adjusted by turning the adjusting pin 58 more or less.

In order not to make the damping device 40 active in the area of the idle travel of the speed adjustment lever 32, i.e. when no injection has yet taken place, two unthrottled flow paths are connected in parallel with the throttles 47, 48, which flow in certain areas of the adjustment movement of the damping piston 44 Connect the damping chamber 45 bypassing the two throttles 47, 48 to the pump interior 11 and thus cancel the throttling effect. Since, at different speeds of the internal combustion engine and thus the fuel injection pump, these idle paths of the speed adjustment lever 32 lie in other displacement ranges of the damping piston 44, these flow paths also shift accordingly in the adjustment range of the damping piston 44 by shifting the guide sleeve 43, which changes with increasing speed of the internal combustion engine and thus with it increasing pressure in the pump interior 11 in the drawing to the right against the action of the compression spring 53. The first flow path 67 is formed by a bypass bore 62 bypassing the first throttle 47 in the damping piston 44, the first radial bore 60 forming a control opening in the guide sleeve 43 and the first through opening 61 corresponding to this in the damper housing 41. The diameter of the first radial bore 60 is chosen so large that, depending on the position of the damping piston 44 relative to the guide sleeve 43, only the mouth of the first throttle 47 or additionally the mouth of the bypass bore 62 from the guide sleeve 43 to the pump interior 11 are released. The second unthrottled flow path 68 between the damping chamber 45 and the pump interior 11 is provided by an annular groove 63 in the damping chamber 45, by an axial groove 64 in constant communication with the annular groove 63 on the circumference of the damping piston 44, a second radial bore 65 in the guide sleeve 43 and a second through opening 66 is formed in the damper housing 41. The diameter of the passage opening 66 is chosen so large that the second radial bore 65 in the guide sleeve 43 to the pump interior 11 is released over the entire displacement range of the guide sleeve 43. The annular groove 63 in the damping chamber 45 is designed such that it is closed off from the rest of the damping chamber 45 after a certain displacement path of the damping piston 44, which depends on the relative position of the damping piston 44 and guide sleeve 43. The axial groove 64 in the damping piston 44 has a length such that the annular groove 63 remains connected to the second radial bore 65 in the guide sleeve 43 over the entire displacement path of the damping piston 44. Depending on the displacement position of the guide sleeve 43, the damping piston 44 requires a more or less large displacement path in order to close the annular groove 63 with respect to the damping chamber 45 - and thus to block the flow path 68 - or to release it again - and thus to open the flow path 68 -. This flow path 68 is thus effective in both directions of the displacement movement of the damping piston 44, while the first unthrottled flow path 67, as a result of the first check valve 46 located in the flow path 67, only moves the damping piston 44 to the left in the drawing, i.e. when the speed adjustment lever 32 is adjusted in Direction of smaller fuel flow rates, can take effect.

Vehicle jerking is mainly noticeable at low engine speeds and is shown here by the above damping device 40 largely suppressed. In the higher speed range, due to the high kinetic energy of the flywheels, vehicle jerking is no longer noticeable, so that the damping device 40 is rather superfluous and tends to have disadvantages for driving behavior. For this reason, the damping devices 40 is switched off at higher speeds, so that their damping effect is zero. For this purpose, a third unthrottled flow path 69 is provided, which connects the damping chamber 45 directly to the pump interior 11 at higher speeds and thus short-circuits the damping device 40. The third unthrottled flow path 69 is locked below a certain speed. The flow path 69 is locked and released by means of a pressure valve 70, which is designed here as a slide valve. For this purpose, a blind bore 71 is made in the damper housing 41, which is connected to the relief chamber 54 near the bottom of the bag via a relief bore 72. A control piston 73 slides in the blind bore 71, which is acted upon by the pressure in the pump interior 11 on its end face facing the mouth of the blind bore 71 and is supported with its other end face by a compression spring 74 on the bag base. The third flow path 69 is formed by two bores 75, 76 in the damper housing 41, which are connected on the one hand to the pump interior 11 and on the other hand to the damping chamber 45 and open diametrically in the blind bore 71 in a cross-sectional plane. With the two mouths of the bores 75, 76, a control groove 77 works together on the control piston 73, which, depending on the displacement position of the control piston 73, releases or blocks the passage from the bore 76 to the bore 75. By a suitable choice of the compression spring 74, the pressure valve 70 is set such that when a certain pressure in the pump interior 11 is exceeded, the control piston 73 counteracts the force the compression spring 74 is shifted so far that the bores 75, 76 are connected to one another and thus the damping chamber 45 is connected to the pump interior 11. Such an increase in pressure in the pump interior 11 occurs only at higher speeds of the internal combustion engine and thus of the feed pump 12.

The operation of the damping device 40 described above is as follows:

If the accelerator pedal is depressed ("accelerating") and thereby the speed adjustment lever 32 is pivoted in the direction of arrow 33 while tensioning the return spring 34, the specified force is fed via the drag spring 36 to the damping piston 44, which moves to the right in the drawing. As soon as the damping piston 44 has closed the annular groove 63 with respect to the damping chamber 45, the second throttle 48 only permits a further movement of the damping piston 44 with a delay. The damping piston 44 thus transmits the specified force only with a delay via the control spring 31 to the control lever 29, which in turn only moves the quantity adjusting element 28 with a delay. Thus, when the speed adjustment lever 32 is swiveled rapidly as a result of rapid accelerator pedal actuation, the injection quantity change is carried out only with a delay, so that the vehicle is accelerated smoothly. In the opposite direction, that is, when the accelerator pedal is released quickly, the return spring 34 acts on the damping piston 44 via the speed adjustment lever 32 and the stop 38, so that it is shifted to the left in the drawing. The displacement movement of the damping piston 44 is now delayed via the first throttle 47. The delayed displacement movement of the damping piston only triggers a delayed adjustment of the control lever 29 and thus the quantity adjusting member 28. This means that the vehicle is decelerated largely smoothly. After covering a certain route of the damping piston 44, the annular groove 63 is released towards the damping chamber 45 and thus the damping effect is canceled. The further transmission of the restoring movement of the speed adjustment lever 32 to the control lever 29 then takes place without damping.

Claims (10)

1.Fuel injection pump for internal combustion engines, in particular diesel internal combustion engines, with a pump piston which takes fuel from a pump-filled pump interior which is under delivery pressure and delivers it under high pressure to injection nozzles, with a quantity adjusting element, the position of which relative to the pump piston determines the fuel injection quantity delivered per pump piston stroke, with one on the quantity adjusting element for its actuation with a two-arm control lever engaging a lever arm, the other lever arm is coupled via at least one control spring to an arbitrarily actuatable speed adjustment lever, which can be pivoted against a return spring about a pivot axis fixed on the pump housing, and with a damping cylinder and one axially displaceable therein Damping piston with throttle comprising hydraulic damping device, which is used to improve the Smooth running of the internal combustion engine when the speed adjustment lever is actuated quickly permits a delayed adjustment of the quantity adjustment element, characterized in that the coupling between the speed adjustment lever (32) and the control spring (31) is carried out via a pretensioned drag spring (36), which is located on the one hand on the speed adjustment lever (32) and on the other hand on a lever arm connected to the control spring (31) of a damper lever (37) pivotable about the pivot axis (35) of the speed adjustment lever (32) and the speed adjustment lever (32) against a stop (38) on the one with the damping piston (44) articulated damper lever (37) sets that the throttle (47) arranged in the damping piston (44) includes a damping chamber (45) enclosed by damping piston (44) and damping cylinder (41, 42, 43) via a check valve (46) to the damping chamber (45) pointing the direction of passage to the pump interior (11) and that a further throttle (48) d he damping chamber (45) connects to the pump interior (11) via a further check valve (49) with the blocking direction pointing to the damping chamber (45). 2. Fuel injection pump according to claim 1, characterized in that to the throttles (47,48) unthrottled flow paths (67,68) between the damping chamber (45) and the pump interior (11) are connected in parallel such that they only in areas of the displacement movement of the damping piston (44) are open, in which free travel of the speed adjustment lever (32) occur. 3. Fuel injection pump according to claim 2, characterized in that the damping cylinder consists of a damper housing (41) fixed in the pump interior (11) and from a mutually closed damper housing bore (42) axially displaceable guide sleeve (43) in which the damping piston (44 ) that at least one flow path (67) has a control opening (60), which is arranged in the guide sleeve (43) and is released towards the pump interior (11) and which has a channel (44) leading to the damping chamber (45) in the damping cylinder (44) 62) for blocking and releasing the flow path (67) cooperates in that one end face of the guide sleeve (43) together with the damping piston (44) has a control chamber (50) connected to the pump interior (11) and the other one from a closure plate (52 ) covered front end of the guide sleeve (43) delimits a relief chamber (54) connected to a fuel return (56) and that in the relief chamber (54) ei ne on the closure plate (52) supporting compression spring (53) is arranged with preferably adjustable bias. 4. Fuel injection pump according to claim 3, characterized in that the channel (67) by a throttle (47) in the damping piston (44) bridging bypass bore (62) is formed, which is at a distance from the mouth of the throttle (47) on the circumference of the Damping piston (44) opens, and that the control opening (60) is so large in diameter that it can cover the openings of the throttle (47) and / or bypass bore (62). 5. Fuel injection pump according to claim 3 or 4, characterized in that a further flow path (68) of an annular groove (63) in the damping chamber (45) which according to one of the relative position of the guide sleeve (43) and Damping piston (44) dependent displacement path of the damping piston (44) with respect to the damping chamber (45) is completed or released again, by a radial bore (65) in the guide sleeve (43) released towards the pump interior (11) and by an axial groove (64) is formed in the damping piston (44), which connects the annular groove (63) over the entire displacement path of the damping piston (44) with the radial bore (65). 6. Fuel injection pump according to one of claims 1-5, characterized in that the further throttle (48) and the further check valve (49) are arranged in the damper housing (41). 7. Fuel injection pump according to one of claims 1-6, characterized in that a third unthrottled flow path (69) is provided directly between the damping chamber (45) and pump interior (11), the pressure valve (70) controlled by a pressure in the pump interior (11) ) is controlled in such a way that it is open in the pump interior (11) above a pressure value corresponding to a higher engine speed. 8. Fuel injection pump according to claim 7, characterized in that the pressure valve (70) is designed as a slide valve arranged in the damper housing (41), the valve connections of which are connected on the one hand to the damping chamber (45) and on the other hand to the pump interior (11) and whose hydraulic Control input on the pump interior (11) is connected. 9. Fuel injection pump according to claim 8, characterized in that in the damper housing (41) to the pump interior (11) open blind bore (71) is introduced, in which a control piston (73) against the action of a compression spring supported thereon and on the bag base (74) is guided axially displaceably, and that the control piston (73) carries a control groove (77), which has two radial control bores (75, 76) opening diametrically in the blind bore (71) for releasing or closing the third flow path (69 ) interacts, one of which communicates with the pump interior (11) and the other with the damping chamber (45). 10. Fuel injection pump according to claim 9, characterized in that the compression spring (74) receiving end portion of the blind bore (71) via a relief bore (72) with the relief chamber (54) in the damper housing (41).

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