EP0290797B1 - Fuel injection pump - Google Patents

Description

State of the art

The invention is based on a fuel injection pump according to the preamble of the main claim. In a fuel injection pump known from US-A 44 49 504, the controlling member is designed as a cylindrical evasive piston which is tightly guided in a cylinder bore open to the pump work space. The spring chamber, which always remains separate from the pump work chamber, is opened when the internal combustion engine is idling through an electrically pneumatically actuated valve to the relief line, so that the evasive piston can be adjusted by a path determined by a stop through the pressure prevailing in the pump work chamber when pumping the piston. This reduces the delivery rate of the pump piston when the engine is idling, but never stops the fuel injection. Such devices serve to make the combustion process softer in fuel injection pumps with low speeds. The relief line of the spring chamber is either permanently open when idling, or permanently closed at partial load or full load.

A fuel injection pump of the generic type is known from EP-A2 0 116 168. There, the relief space is delimited by the controlling member in the form of a piston, which at the same time represents a sliding wall for changing the volume of the relief space. The controlling member is moved against the force of a first and a second spring, both by one in one Cylinder bore tightly guided spring plate are separated. The position of this spring plate and thus the resetting characteristic of the spring arrangement is determined by a control pressure which is introduced into the space receiving the spring directly acting on the controlling member. The controlling member is thus moved against this control pressure and also against the spring clamped in this space. The control pressure is changed in one embodiment by a pressure-dependent pressure of the pressure source and in the other case by clocked relief of the spring-receiving space, which is now decoupled from the pressure source by means of a throttle. With such a device, the pressure curve of the high-pressure delivery stroke of the fuel injection pump is to be subdivided into a pre-injection and a main injection, with the aid of the removal space and the controlled member, the injection pause between the pre-injection and the main injection and thus the amount of the fuel pre-injection is controlled. In the embodiment with a clocked solenoid valve, the control pressure can be changed as a function of speed, temperature and load, so that depending on these parameters, a differently large extraction volume per delivery stroke of the pump piston is provided. In this known device, the high-pressure delivery phase of the pump piston is controlled independently of the control of the relief space by controlling a separate relief channel of the pump work space. The point of use of the main injection or the end of the pre-injection depends on the dynamic behavior of the controlling member and the spring arrangement loading it in connection with the controlling control pressure. At different speeds, there may be deviations in the control times between the pilot injection quantity and the main injection quantity.

From US-A-4 549 749 a fuel injection pump is also known, in which the fuel injection quantity takes place with the aid of a servo valve. The relief line of the pump work space is again controlled to control the fuel injection quantity by means of a flat seat valve which consists of a piston which can be displaced in a cylinder and which opens the connection of the relief line to a relief space from a certain displacement path. On the rear side, this piston encloses a volume which can also be connected to the relief chamber by means of a second relief line which is controlled by a solenoid valve. When the solenoid valve is closed, the volume behind the piston is locked in and prevents the piston from evading and thus opening of the relief line when the pump piston delivery stroke begins. Only when the solenoid valve opens does the piston evade and suddenly open the relief line of the pump work space. This controls the end of high-pressure fuel injection. With this device, however, it is not possible to effect a divided fuel injection per pump piston delivery stroke, since when the piston has opened the relief line, reclosing the solenoid valve does not bring the piston back into its closed position, so that the pump working space remains relieved.

Finally, US-A-4 590 908 discloses a fuel injection pump in which the pump work space can also be connected to a relief space via a relief line controlled by a servo valve in order to control the fuel injection quantity. The servo valve also consists here, as in the foregoing, of a piston sliding in a cylinder, the front edge of which, after lifting off a flat valve seat, opens the connection of the relief line to the relief chamber. The piston is held in the closed position by a spring, which is on the pump working space attacks the rear of the piston. This back of the piston in turn encloses in the cylinder receiving the piston a pressure chamber which can be relieved via a second relief line which is controlled by a solenoid valve. In this case, however, the pump work space is constantly connected to the rear of the piston via a throttle connection. In this way, this pressure is also effective on the rear of the piston when the pump working chamber pressure rises, so that the piston can be held in the closed position by the return spring without great difficulty. If the space on the back of the piston is relieved via the second relief line when the solenoid valve is opened, more fuel flows out there than can flow in via the throttle, so that the pump working chamber pressure brings the piston into the open position against the spring. This servo valve arrangement is provided in the known fuel injection pump for controlling the start of injection and the end of injection. The start of injection in the course of the delivery stroke of the pump piston is controlled by closing the solenoid valve, the return spring bringing the piston into the closed position, which is then held as a result of the pump working space pressure which continues to rise and is also effective in the rear space of the piston. When the solenoid valve opens, the fuel injection is ended, which also determines the fuel injection quantity. A pre-injection is not provided in this known pump.

Advantages of the invention

The fuel injection pump according to the invention has the advantage that a pre-injection is possible in the entire speed-load range and the distance pre-injection to main injection can be set variably. In fuel injection pumps of the type according to the invention, only one control device is required when using a plurality of injection nozzles. The control device can work with a single pressure valve or a constant pressure valve and is constructed in such a way that the pump piston drive is also prevented from jumping off the drive cam.

The measures listed in the remaining subclaims provide advantageous developments of the fuel injection pump according to the invention. They are explained with the aid of an exemplary embodiment with its advantages in the following description.

drawing

An embodiment of the invention is shown in the drawing and is explained in the following description. The figure shows a partial section through a fuel injection pump.

Description of the embodiments

The figure shows a part of a known distributor injection pump schematically in section. The figure discloses a pump piston 1, which slides in a cylinder 9 and is set in a reciprocating, pumping and rotating movement by a cam drive, not shown. The pump piston 1 delimits a pump work space 2. This pump work space 2 is filled via filling grooves 14 which come into contact with a suction line 5 during the suction stroke of the pump piston 1. The suction line 5 branches off from a suction space 6 which is filled with fuel which is subjected to speed-dependent pressure. In a known manner, the pump piston 1 of this fuel injection pump acts as a distributor during operation, fuel being conveyed from the pump working chamber 2 via an injection line 12 to the injection valve 41 via a longitudinal or distributor bore 48 in the pump piston 1. A relief line 4 leads away from the pump work space 2 and cooperates with a valve closing element 7 which controls the relief line 4. This valve closing member 7 is part of a pressure valve 50 and has a valve cone 35 on the underside, which cooperates with a valve seat 32 attached to the relief line 4. This valve closing member 7 slides back and forth with guide ribs 51 on its shaft in a cylinder 43 surrounding the pressure valve 50. On the circumference, this valve closing member 7 is provided with longitudinal grooves 52, which begin at the valve cone 35. On the side opposite the valve cone 35, the valve closing member 7 is acted upon by a return spring 8. The return spring 8 is placed in a relief chamber 10 under tension so that it presses the closing member 7 onto the valve seat 32. The return spring 8 is accommodated in the cylindrical space, in the relief space 10, from which a second relief line 22 with a valve seat 15 leads away. This valve seat 15 acts with a valve closing member 18 of an electrically controlled valve, here a solenoid valve 11 together. The valve closing member 18 is designed as an armature of the solenoid valve with a conical tip 44, which has a sealing surface 45, and comes to rest on the valve seat 15 of the second relief line 22. A return line 16 leads from the relief chamber 10 to the suction chamber 6 via the valve seat 15 and the second relief line 22. A spring 46, which cooperates with a part 47 connected to the armature, ensures that the armature of the solenoid valve 11 lifts off the valve seat 15 in the de-energized, non-activated state.

The organs described above work as follows:
If the pump piston 1 is moved downward by the cam drive, fuel is thereby conveyed into the pump work space via the feed line 5 and the filling grooves 14. During the subsequent delivery stroke of the pump piston, a pressure builds up in the pump work chamber 2, in the longitudinal bore 48 of the pump piston 1, the first relief line 4, the distributor groove 30, the delivery line 12 and on the valve needle 54 of the injection valve 41 loaded with a compression spring 53 until a Pressure is reached, which lifts the valve needle 54 against the force of the spring 53 from the valve seat 55, so that an injection takes place. Only when the pressure in the pump work chamber 2 increases further is the force of the return spring 8 of the valve closing member 7 overcome, and now the fuel can pass through the longitudinal grooves 52 of the valve closing member 7 to the relief chamber 10, the second relief line 22, which is open in the uncontrolled state, and the return line 16 flow to the suction space 6. With the opening process, the valve closing member 7 is suddenly loaded on a larger area by the pressure of the pump work space and quickly brought into the fully open position. With this backflow of the fuel into the suction chamber 6, the pressure in the pump working chamber 2 is reduced again, so that the pressure drops below the level that was present at the beginning in order to push the valve needle 54 away from the valve seat 55 and that led to the pre-injection. When the injection valve 41 is closed, the solenoid valve 11 is actuated at the same time, as a result of which the valve seat 45 on the armature 18 presses onto the valve seat 15 and closes the second relief line 22 Cam drive takes place, the above-mentioned pressurized parts are pressurized, and the valve closing member 7 is brought back into the closed position by the return spring 8. The fuel that continues to be delivered can now only flow to the injection valve 41 via the longitudinal bore 48 in the pump piston 1, the distributor groove 30, the delivery line 12. Therefore, the valve needle 54 of the injection valve 41 lifts off the valve seat 55 and the main injection occurs. The duration is determined by the time in which the solenoid valve 11 remains closed. If the solenoid valve 11 opens, the back of the valve closing member 7 is suddenly relieved and the valve closing member is opened immediately due to the high pressure in the pump work space, so that the pump work space is relieved and the injection is ended.

Another alternative embodiment is shown in dashed lines in the figure. In the valve closing member 7, a through hole 56 is made, into which a pressure spring-loaded ball valve 57 is introduced on one side, through which the relief chamber 10 can flow. In this embodiment, no feed line 5 from the suction chamber 6 to the pump work chamber 2 is required. Instead of introducing the ball valve 57 into the valve closing element 7, a line with a ball valve leading around the valve closing element 7 could also be installed.

By means of the devices explained above, the fuel could get from the suction chamber 6 via the return line 16, the second relief line 22, the through bore 56, the ball valve 57, the first relief bore 4 into the pump work chamber 2.

Another possible alternative is that by means of a two-stage solenoid valve, the coordination with the valve closing member 7 can take place in such a way that after opening the valve closing member 7, the first stage of the solenoid valve is opened and the pressure is not completely reduced, but the pressure is short Time is held at a certain level, in order to then release the pressure completely with the second stage to complete the main injection.

Otherwise, the fuel injection pump according to the invention can also be operated without pre-injection if the solenoid valve 11 remains closed from the beginning. At the beginning of the cam rotation, the pump piston 2 is moved upward, so that the fuel entering the pump work chamber 2 via a feed line 5 and a filling groove 14 begins to compress and the pressure in the pump work chamber 2 increases. The increase in pressure opens the injection valve 41. The valve closing member 7 is closed and the solenoid valve 11 is closed. The rotation of the cam continues, the pump piston 1 moves upward, compresses more and injects until the solenoid valve 11 opens. The pressure in the pump work chamber 2 is reduced via the return line 16 and the injection valve 41 closes. A new cycle can begin.

Claims (6)

1. Fuel injection pump for internal combustion engines having at least one pump piston (1) and a pump working space (2) which is delimited by the latter and which can be connected to a fuel injection valve (41) via a fuel injection line (12) during the delivery stroke of the pump piston (1) and via a first relief line (4) controlled by a controlling member (7) to a relief space (10), the controlling member (7) being loaded in the opening direction by the pressure in the pump working space on an area which is smaller in the closed position of the member than in the open position of the member in opposition to the force of a restoring spring (8) which is arranged in a spring space (10) which can be relieved via a second relief line (22) which contains an electrically controlled valve, characterised in that the spring space (10), in the closed position of the member (7), is a space which can only be relieved via the second relief line (22) and is otherwise closed and, in the open position of the member (7), the spring space (10) is connected via overflow cross sections (52) to the first relief line (4), the opening pressure of the controlling member (7) being higher than the opening pressure of the injection valve (41) when the second relief line (22) is open.
2. Fuel injection pump according to Claim 1, characterised in that the spring space (10) can be connected to the first relief line (4) via a return valve (57) opening in the direction of the pump working space (2).
3. Fuel injection pump according to Claim 1 or 2, characterised in that the member (7) is loaded with a restoring spring (8) which can be adjusted in dependence on operating characteristics of the internal combustion engine.
4. Fuel injection pump according to one of the preceding claims, characterised in that the flow cross section of the second relief line (22) can be changed in steps by the electrically controlled valve in the course of a fuel injection process.
5. Fuel injection pump according to one of the preceding claims, characterised in that the electrically controlled valve is opened in a first working area of the fuel injection pump for controlling a fuel preinjection volume at the beginning of the delivery stroke of the pump piston, is closed for controlling the beginning of the main injection from a particular pump piston delivery stroke and is opened again for ending the fuel injection and in that in a second working area the electrically controlled valve (11) is closed at the beginning of the delivery stroke of the pump piston and is opened for ending the fuel injection.
6. Fuel injection pump according to one of the preceding claims, characterised in that the fuel injection pump is constructed as a distributor injection pump.

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