EP0166995A2 - Fuel injection pump for internal-combustion engines - Google Patents

Abstract

A fuel injection pump of the distributor injection pump type is proposed, in which the injection quantity control is controlled by controlling the first outlet cross section D of a first relief line (15) and the stroke-offset outlet C of a second relief line (3) of the pump work chamber (5) of the fuel injection pump by means of a load and / or speed adjustable control edge (25). A connection (A-37-B) is provided between the relief lines (15, 33) in order to achieve non-delivery within the intended delivery stroke of the pump piston at idle and low partial load. The connection exists only for the duration of a certain lifting section (he) and is additionally controlled by the control of the downstream outlet (C) of the second relief line (33) depending on the load and / or speed, so that from a certain upper load range to full load operation entire fuel quantity delivered by pump pistons via the effective delivery stroke also reaches the injection.

Description

State of the art

The invention is based on a fuel injection pump according to the preamble of the main claim. Such a fuel injection pump known from DE-OS 23 53 737 is based on the task of postponing the start of injection with a decreasing load. The design of the control cross-sections in the known injection pump is such that an influence on the start of injection is achieved by making it possible at low load that a part of the fuel delivered can flow out before the actual injection begins. In the extreme case, this drainage can take place up to a certain piston stroke and is controlled within this condition by the fact that the point in time related to the stroke of the pump piston, at which the exit of the second relief channel is triggered, is still determined by the position of a quantity adjusting member. which is designed as a ring slide which is displaceable on the pump piston depending on the load or speed. The measure taken for this in the known fuel injection pump is that in the idling range and in part of the partial load range the piston stroke is established over its duration, the connection between the first and the second relief channel is fully utilized for the relief becomes. As the load continues to increase, this possible relief quantity is limited by subsequently opening the outlet of the second relief channel. In this load range, this effectively results in an early start of spraying, and in full-load operation or in upper part-load operation, relief of the pump work space is completely prevented, so that the pump piston can bring its full, full-load injection quantity to the injection and that here too, the start of spraying is no longer delayed .

Advantages of the invention

The fuel injection pump according to the invention with the characterizing features of the main claim has the advantage that the fuel injection is interrupted or reduced over a constant piston stroke at idle up to a part of the partial load range and there is no change in the start of injection, since in the solution according to the invention in an advantageous manner the relief takes place over a predetermined Eub section of the pump piston after a part of the delivery stroke of the same. Here, too, the relief is advantageously switched off by the load-dependent control of the exit of the second relief channel at higher loads or at full load. A real interruption of normal fuel injection at low load is thus achieved after a pre-injection stroke. This results in an increase in the spraying duration, which produces a quiet running of the internal combustion engine, in particular when idling. This device can advantageously be implemented both for quantity control by controlling the start of injection and for quantity control by controlling the end of injection.

The measures listed in the subclaims characterize advantageous embodiments of the invention with regard to the production of the connection between the first relief channel and the second relief channel via the predetermined lifting section.

drawing

Six exemplary embodiments of the invention are shown in the drawing and are explained in more detail in the description below. 1 shows a first exemplary embodiment with control of the end of the effective injection and control of the connection of the two relief lines to one another via an annular groove, FIG. 2 shows a control diagram for the exemplary embodiment according to FIG. 1, FIG. 3 shows a second exemplary embodiment in a modification of the exemplary embodiment according to FIG Ring groove of a defined lifting height and a slot-like inlet cross-section of the second relief line, which extends in the circumferential direction, FIG. 4 shows a third embodiment with a slot-like ring groove and an inlet cross-section of the second relief line of a defined lifting height, FIG. 5 shows a fourth embodiment with an essentially axially extending bypass channel in the Wall of the cylinder for controlling the connection of the first relief line to the second relief line, Figure 6 shows a fifth embodiment in a modification of the embodiment of Figure 5, in which the down FIG. 7 shows a sixth exemplary embodiment of the invention with a fuel injection pump, which is designed to control the start of injection for metering fuel quantity, and FIG. 8 shows a control diagram for the exemplary embodiment according to FIG. 7.

description

In a housing 1 of a fuel injection pump, a pump piston 4 is arranged in a cylinder 2 of a cylinder liner 3 inserted into the pump housing, which is set into a reciprocating and at the same time rotating movement by means not shown. The pump piston encloses a pump working chamber 5 on its one end face and partially protrudes out of the cylinder 2 into a pump suction chamber 7. It is also driven at this end of the pump piston.

The pump working chamber 5 is supplied with fuel via longitudinal grooves 8 arranged in the lateral surface of the pump piston and a suction bore 9 running through the cylinder liner 3 in the housing 1, as long as the pump piston executes its suction stroke or assumes its bottom dead center position. The suction bore opens into the pump suction chamber 7 at its other end. The pump suction chamber is supplied with fuel from a fuel tank 12 via a feed pump 11. A pressure control valve 13 controls the pressure in the suction chamber in a known manner.

A longitudinal channel 15 leads from the working space 5 in the pump piston, which is designed as a blind bore and can be referred to as the first relief line. _. From this branches off a radial bore 16 which leads to a distributor opening 17 in the outer surface of the pump piston 4. In the working area of this distributor opening 2 feed lines 19 branch off in a radial plane of the cylinder, which are arranged distributed around the circumference of the cylinder in accordance with the number of cylinders to be supplied with fuel of the associated internal combustion engine. The Delivery lines 19 each lead via a valve 21, which is designed as a check valve or pressure relief valve in a known manner, to the fuel injection points, not shown.

At the end of the first relief line, a radial bore 22 branches off, which opens into an outlet cross section D in the lateral surface of the pump piston, specifically in the region of the part of the pump piston protruding into the pump suction chamber. In this area, a quantity adjustment element in the form of a ring slide 24 is arranged on the pump piston, which can be displaced tightly on the pump piston and forms a control edge 25 with its upper end face, through which the outlet cross section D is controlled. The axial position of the ring slide 2 ^L is determined in a known manner by a control lever 27 which can be pivoted about an axis 28 fixed to the housing and which is coupled to the ring slide via a ball head 29 at the end of its one lever arm. In a known manner, the ring slide is adjusted as a function of the load and / or speed by a controller (not shown further here). At the desired high fuel injection quantity, the ring slide 24 assumes an upper position near the pump working space, from which it is increasingly adjusted downwards as the load decreases. The available useful stroke h _n , which the pump piston or the outlet cross section D must cover from the bottom dead center of the pump piston, thus changes in order to be opened by the control edge 25 of the ring slide.

A third radial bore 31 branches off from the first relief line 15 and opens into a second outlet B on the lateral surface of the pump piston 4. Furthermore, a second relief line 33 is provided in the pump piston, which is constantly in the cylinder 2 located pump piston outer surface has an inlet A and has an outlet C in the working area of the ring slide 24. This is offset by a constant amount h from the first outlet D of the first relief channel to the pump working chamber, so that the outlet C from the control edge 25 is always opened first in the course of the pump piston stroke before the first outlet D is opened.

In the stroke area of the inlet A of the second relief line and the second outlet B of the first relief line, an annular groove 37 is arranged in the wall of the cylinder 2. The inlet A and the second outlet B are assigned to one another in such a way that if the inlet A just overlaps the bottom edge of the annular groove 37 during the pump stroke of the pump piston, the second outlet B of the first relief line already overlaps with the annular groove 37 is located and after an intended stroke of the pump piston h comes out of the overlap with the annular groove 27, a point where the inlet A of the second relief line 33 is still in overlap with the annular groove 37. In this way, a connection between the first relief line 15 and the second relief line 33 is established for the predetermined stroke section of size h.

The assignment of the cross sections and control edges mentioned can be seen from the diagram in FIG. 2. The assignment of the cross sections in the course of the pump piston stroke is plotted over the load or the position of the ring slide. LL means idle and VL means full load. In the case of the horizontally running line SB, spraying begins, for example with the start of the stroke of the pump piston from its bottom dead center. The pump working chamber 5 previously filled via the suction bore 9 and the longitudinal grooves 8 is then connected to one of the delivery lines 19 via the first relief line 15, the radial bore 16, the distributor groove 17, in accordance with the rotational position of the pump piston.

Line C represents the opening point of the outlet C of the second relief line 33. This line rises with increasing load in accordance with the position of the ring slide 24 which is adjustable with the load. D also shows the opening point D of the first discharge line 15. This line runs parallel to line C and indicates the possible useful stroke h. This useful stroke is indicated in FIG. 1 provided that the pump piston assumes its bottom dead center in the position shown. For the case shown, a broken position of the ring slide 24 was assumed.

Parallel to the line SB is a line A, which marks the opening point of the inlet A of the second relief line 33. The line B parallel thereto indicates the piston stroke at which the second outlet of the first relief line is closed. In the stroke range between A and B, the stroke h, there is a connection between the first relief line 15 and the second relief line 33. Only within this stroke range can the fuel delivered by the pump piston in this area or a part thereof flow out via the second relief line 33. However, this is only possible with a second condition if the outlet C of the second relief line is also open, that is to say that from the point of intersection Line C with line B no longer allows fuel to flow out. This point G is still before the full load point, so that the entire working capacity of the pump piston can be used for fuel delivery in the upper load range and at full load. At zero load, in the idling range or at low partial load, the relief range between lines A and B is within the range between C and D, so that a constant amount of fuel per delivery stroke of the pump piston is initially diverted over this range until line C leads to line A. intersects at point F. Between F and G, the amount of relief is increasingly smaller. The location of the area h and its usable height can be optimized with regard to a quiet combustion process at low load and without influencing the injection start control, which, for. B. can be done by a separate spray start adjuster of known design.

FIG. 3 shows another type of connection between the first relief line 15 and the second relief line 33 in a partial section of the piston. Here, the annular groove 37 has a defined height he ', the inlet A' of the second relief line 33 is widened in the stroke direction, so that it remains in constant communication with the annular groove 37 and the second outlet B 'of the first relief line 15 is designed in the form of a slot. During the delivery stroke of the pump piston 4, the second relief line 33 thus remains in constant connection with the annular groove 37. The duration of the connection between the first relief line 15 and the second relief line 33 is now determined by the slot-shaped second outlet B 'during the overlap h with the annular groove 37 determined.

This embodiment has the advantage that the control times of the overlap can be made more precise here, because of the slot-like design of the second outlet B ', a rapid opening takes place, as a result of which the influence of the speed on the discharge quantity is reduced. Due to the slot-like design, a throttle cross section can also advantageously be determined, which controls the degree of relief via the stroke h _e .

FIG. 4 shows an equivalent configuration to the exemplary embodiment according to FIG. 3. There, it is not the second outlet D but the annular groove 37 ′ which is slot-shaped and the width of the second outlet B of size h _{b determines} the duration of the overlap h _e .

A fourth exemplary embodiment of the connection between the first relief line 15 and the second relief line 33 is the solution according to FIG. 5. A bypass channel 39 is provided there in the cylinder liner 3 and extends parallel to the axis of the pump piston. The bypass channel opens into a first annular groove 41 on the pump work chamber side and at its other end in a second annular groove 42 located on the pump suction chamber side. The outlet position of the second outlet B of the first relief line 15 and the position of the inlet A of the second relief line 33 are assigned so that after that second outlet B has overlapped with the first annular groove 41, the inlet A is only over one stroke h _e in overlap with the second annular groove 42. The assignment can of course also be done in the opposite sense. It is only essential that the coverage area h _{e is} observed. The annular grooves 41 and 42 can also be provided in an equivalent manner on the pump piston. Instead of this solution, the embodiment according to FIG. 6 can also be carried out in such a way that the second outlet B 'of the first relief line 15 is again slot-shaped and the bypass channel 39' on the pump work chamber side is also realized in the form of a slot 44 of the same width. The other end of the bypass channel 39 'is connected to the second relief line 33 via the inlet A regardless of the pump piston stroke. In this embodiment, the width of the slot B 'or 44 determines the duration of the overlap h.

Using the sixth exemplary embodiment according to FIG. 7, it is shown that the device described above for generating a quiet running of the internal combustion engine at idling and in the partial load range can also be implemented if the ring slide 24 does not stop the pumping of the pump piston at an earlier or later point before OT controls, but the beginning of the pump piston after a more or less large stroke of the pump piston. The design of the fuel injection pump with pump piston 4 ', cylinder 2 and ring slide 24 is essentially the same as in the exemplary embodiment according to FIG. 1, except that the ring slide is actuated in reverse logic by the control lever 27. In a departure from the exemplary embodiment according to FIG. 1, the first outlet D "is arranged such that when the pump piston delivery stroke begins, it is first closed by the control edge 25" which is now below, before the control edge 25 "controls the subsequent outlet C" of the second relief channel 33 " constructive stroke difference is also called h in the same way as in the exemplary embodiment according to FIG. 1, the inlet A "of the second relief line 33" and the second outlet B "of the arranged first relief line 15 in the work area to the annular groove 37.

FIG. 8 shows a diagram corresponding to FIG. 2 for this embodiment. The line D "runs according to the variable position of the ring slide 24 'inclined towards full load. In the same way, the line C", which marks the closing point of the outlet C ", runs with the distance h to the closing point line of the first outlet cross section D" . FE is a line running parallel to the abscissa, which indicates the constructive delivery end of the pump piston. Line A "and line B" are also shown in the diagram as lines parallel to line FE. A "denotes the point at which the inlet A" comes into contact with the annular groove 37, where at the same time the connection between the second outlet B "and the annular groove 37 still exists and the line B" denotes the point at which the. second outlet B "is closed and the connection between the first relief line 15 and the second relief line 33 is prevented. A reduction of the resulting injection rate at idle and low load by temporarily interrupted or reduced delivery also results in this embodiment of a fuel injection pump The exemplary embodiment according to FIG. 1, however, the pre-injection quantity before the discharge is dependent on the load.

In the exemplary embodiments, the control-effective pump delivery strokes are controlled with control edges and cross sections which are oriented in radial planes to the pump piston axis. However, since the pump piston has a fixed assignment of the rotary position to the stroke position during its drive, it can also be arranged by axially oriented control edges, for. B. implement the control with longitudinal grooves.

Claims (9)

1.Fuel injection pump for internal combustion engines with a reciprocating in a cylinder (2) and at the same time rotatingly driven and serving as a distributor pump piston (4), which includes a pump work chamber (5) in the cylinder (2), which is constantly connected to a first Relief line (15) is connected, which can be opened and closed at a load and / or speed-dependent point (25) of the pump piston stroke, with a second relief line (33) which is arranged in the pump piston and has an inlet (A) and has an outlet (C) on the pump piston outer surface, a connection between the inlet (A) of the second relief line (33) and the first relief line (15) being interrupted or established from a first, defined stroke of the pump piston and the outlet (C) the second relief line (33) is opened or closed by the pump piston movement when passing over a control edge (25), d he closing a constant, fixed partial stroke (h) of the pump piston (4) after the adjustable point of the pump piston stroke or opening a fixed partial stroke (h) of the pump piston before the adjustable point of the pump piston stroke, characterized in that the inlet (A) the second relief line (33) over a predetermined stroke section (h) of the pump piston Conveying stroke is connected to the first relief line (15) after a part of the conveying stroke thereof. 2. Fuel injection pump according to claim 1, characterized in that the predetermined stroke section (h) is smaller than the predetermined partial stroke (h) and the predetermined stroke section is placed such that in the upper load area the outlet (C) of the second relief line (33) only is opened after the connection between the first relief line (15) and the second relief line (33) is interrupted or the outlet (C ") of the second relief line (33") is already closed before the connection between the first relief line (15 ") and the second relief line (33") is produced. 3. Fuel injection pump according to one of claims 1 or 2, characterized in that the first relief line (15) and the second relief line (33) in the pump piston (4) extend that the first relief line (15) a first at the load and / or speed-adjustable point (25) controllable outlet (D) and a second outlet (B) axially offset from the inlet (A) of the second relief line (33) in the effective area of the cylinder (2) and the connection between the two relief lines ( 15, 33) via a channel (37) in the wall of the cylinder (2) surrounding the pump piston. 4. Fuel injection pump according to claim 3, characterized in that the channel is an annular groove (37). 5. Fuel injection pump according to claim 3, characterized in that the second outlet (B) of the first Relief line (15) or the inlet (A) of the second relief line (33) has a stroke-independent connection to the channel (37, 39) and the width in the axial direction of the inlet (A) of the second relief line (33) or the second outlet (B ) of the first relief line and / or the annular groove (37) as the element determining the predetermined lifting section (h) is reduced compared to the width of the other elements mentioned. 6. Fuel injection pump according to claim 3, characterized in that the channel (37) is designed as an axially extending bypass channel (39, 39 '). 7. Fuel injection pump according to claim 6, characterized in that the openings of the second outlet (B) of the first relief line (15) or the inlet (A) of the second relief line (33) in stroke-independent connection with one of the ends of the bypass channel (39, 39 ') and the width in the axial direction at the openings of the inlet (A) of the second relief line or the second outlet (B) of the first relief line (15) and / or the width in the axial direction of the outlet of the other end of the two ends of the bypass channel (39) are reduced in the cylinder as the element determining the predetermined lifting section (h) compared to the width of the other openings. 8. Fuel injection pump according to one of the preceding claims, characterized in that the outlet (C) of the second relief line (33) and the first outlet (D) of the first relief line (15) on an out of the cylinder (2) end of the pump piston ( 4) open and controlled there by a control edge (25) are arranged on a valve member (24) which can be displaced in a load-dependent and / or speed-dependent manner on the pump piston in order to adjust the said adjustable point of the pump piston stroke. 9. Fuel injection pump according to one of the preceding claims, characterized in that a throttle cross section B 'is effective when the connection between the first relief line and the second relief line is open.

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