WO1999011924A1 - System for producing high pressure - Google Patents

Abstract

The invention relates to a system for producing high pressure, comprising a high-pressure pump (8) and a pressure control valve (14) on the pressure side of said pump. When a threshold pressure is reached, said pressure control valve (14) opens so that the quantity conveyed by the high-pressure pump (8) can be evacuated via a return system (16). The invention is characterised in that the return system (16) of the pressure control valve (14) interacts with a closing system (22) in such a way that the quantity conveyed by the high-pressure pump (8) is reduced as the return quantity increases.

Description

 High pressure system

State of the art

The invention relates to a system for high pressure generation as e.g. can be used for generating high fuel pressure in a fuel injection system of an internal combustion engine, in particular in a common rail injection system, with a high pressure pump and with a

Pressure control valve on the delivery side of the high-pressure pump, which opens when a threshold pressure is reached, so that the quantity delivered by the high-pressure pump is drained off via a return line.

In the case of a system for generating high-pressure fuel, a high-pressure pump directly driven by the engine delivers fuel depending on the engine speed, regardless of how much fuel is currently required or is to be injected by the engine. The excess fuel that is not required is drained into the tank via the pressure control valve via a return line.

In order to ensure the proper operation of the internal combustion engine, the high-pressure pump must be designed in such a way that it can operate even under the most unfavorable conditions, i.e. at low Speed, high requested injection quantity, exceptionally high or low temperatures can provide the desired pressure and the desired volume flow. Under normal conditions, the volume flow of the pump is too high, ie the amount of fuel delivered per unit of time is too high.

If, in extreme cases, the "gas" is removed at high speeds and the vehicle runs in overrun as a result of its kinetic energy, the entire drive power of the high-pressure pump, which can amount to approximately 3 KW, is converted into heat. This increases the fuel temperature below to over 100 ° C. This in turn poses problems when using plastic

Fuel return lines or a plastic tank. Furthermore, there is a deterioration in the electrical data of injectors and the pressure control valve.

With DE 195 49 108 AI it has already been proposed to limit the delivery rate of the high pressure pump by limiting the feed rate by means of a between a low pressure pump and the

To control the high pressure pump provided flow control valve. However, regulating the delivery rate is only possible with great effort; For example, an additional sensor for flow rate measurement at the output of the pressure control valve and a measurement input on a control unit are required.

It would also be possible to reduce the delivery rate by means of a control valve on the pump inlet side of the high-pressure pump without using a pressure control valve on the delivery side, but a pressure sensor on the delivery side of the pump, for example, is then absolutely necessary for pressure control. In addition, a reduction in the pressure in a pressure accumulator connected to the delivery side of the pump is only possible by taking a quantity (for example by injecting fuel into the engine). It is not possible to quickly reduce the pressure to a new lower setpoint (eg in the event of rapid load changes). When using a pressure control valve that opens at an adjustable threshold pressure, pressure control (within the production tolerances of the pressure control valve) is also possible without additional control loops (e.g. with a pressure sensor on the delivery side of the pump) and therefore it is not necessary to switch off the engine if this sensor fails . A pressure reduction in a pressure accumulator connected on the delivery side of the high pressure pump is easily possible by setting a lower set pressure on the pressure control valve (the pressure control valve then opens automatically until the set pressure is reached).

A delivery rate reduction by switching off a pump element leads to high pressure fluctuations and is therefore also not a viable option.

Proceeding from this, the object of the present invention is to counteract the problems described at the outset and to improve a system for high-pressure generation of the type described at the outset in such a way that in

Normal operation or in low load operation, the delivery rate of the high pressure pump can be reduced in a simple manner.

This object is achieved according to the invention in a system of the type described in the introduction in that the return flow of the pressure control valve interacts with a blocking or throttling device in such a way that the delivery volume of the high-pressure pump is reduced by the pressure control valve as the quantity discharged increases.

In this way, an automatic flow control of the high-pressure pump is implemented without the need for complex, electronically controlled control processes.

The blocking device is preferably provided on the suction side of the high-pressure pump, so that the pump inlet can be automatically closed by the blocking device as the return flow increases. In a very particularly advantageous development of the invention, the delivery rate control is achieved in that, with an increasing return amount, an increasing pressure is built up in a return line of the pressure control valve, which is applied to the blocking device and actuates the latter in such a way that the delivery rate of the high-pressure pump is reduced.

So if the demand for fuel is reduced at high engine speeds (going from gas), the pressure control valve on the delivery side of the high-pressure pump opens when a threshold pressure is reached and the pressure in the return line of the pressure valve is increased. This pressure increase in the return line now causes in the shut-off device that the fuel supply to the high-pressure pump is throttled or increasingly closed depending on the pressure in the return line. If a higher quantity of fuel is requested again, the pressure control valve closes, with the result that the pressure in the return line drops and thereby the

Shut-off device increasingly releases the fuel supply to the high-pressure pump.

The locking device for reducing the delivery rate of the high pressure pump is preferably integrated in the high pressure pump. The pressure control valve can also be integrated in the high-pressure pump.

It goes without saying that the system for high pressure generation according to the invention can be used in a particularly advantageous manner as a system for generating high fuel pressure in a preferably time-controlled fuel injection system of an internal combustion engine.

In a very particularly advantageous manner, the system according to the invention can be used in an injection system in which the fuel is injected into the cylinders by one injection valve each, the Injection valves are connected by a common fuel supply device in the form of a line or a high-pressure storage space which is under high pressure during operation and in which the injection can be triggered by an electrically actuated, if necessary hydraulically assisted device (e.g. common rail injection system).

If a safety valve is arranged between a low-pressure pump and the high-pressure pump, which, when the pressure falls below a predeterminable pre-pressure

If the fuel supply to the high-pressure pump is interrupted, then according to a preferred embodiment of the present invention the blocking device is formed by the safety valve. The safety valve is accordingly designed and connected to the return line, for example via a branch line, in such a way that an increase in pressure in the return line results in a reduction in the fuel supply to the high-pressure pump.

In a particularly simple and therefore advantageous manner, the return line in a further development of the invention opens on one side of a displaceable piston-like adjusting means of the shut-off device, the displacement of which causes an increasing opening or closing of a fuel supply opening to the high-pressure pump.

The displaceable piston-like actuating means is therefore preferably biased into an end position, so that when the pressure in the return line drops, the actuating means is automatically reset in a direction that clears the fuel supply opening.

If the shut-off device preferably comprises a second displaceable piston-like actuating means, which is acted upon on the one hand by the outlet of the low-pressure pump and on the other hand by a spring supported against the first displaceable piston-like actuating means, this is a particularly simple and functional self-regulating device System realized. When the amount of fuel delivered by the high-pressure pump is used for combustion, the first piston-like actuating means is in its end position and forms an abutment for the spring which is fixed to the housing. The second piston-like adjusting means is pretensioned by the spring force in such a way that it allows an unthrottled fuel supply between the low-pressure pump and the high-pressure pump above a threshold pressure required to operate the high-pressure pump, in that a fuel supply opening to the high-pressure pump is preferably largely opened. If the demand for fuel is reduced and the pressure control valve on the delivery side of the high-pressure pump opens as a result, so that the pressure in the return line rises, the first displaceable piston-like actuating means becomes displaceable from its end position in the direction of the second

Adjustment means moved. Here, the spring between the two piston-like adjusting means is further tensioned, which leads to a change in the balance of forces on the second piston-like adjusting means, with the result that the latter closes the fuel supply opening to the high-pressure pump

Direction is moved. As a result, however, the volume flow through the high-pressure pump that is conveyed per time or revolution is reduced. The system is self-regulating.

Further features, details and advantages of the invention result from the attached patent claims as well as the graphic representation and the following description of a preferred embodiment of the system according to the invention. The drawing shows:

Figure 1 is a schematic representation of a system for high-pressure fuel generation according to the invention and

2 shows a further illustration of the system according to FIG

1 with a schematic representation of the shut-off device. The figures show a common rail injection system. From a fuel tank 2 carried in a motor vehicle, for example, a first intake line 4 leads to a low-pressure pump 6, which forms the backing pump to a high-pressure pump 8, by means of which fuel is pumped into a high-pressure storage space, the so-called rail, under a pressure of up to 2000 bar becomes. A safety valve 10 is provided between the low-pressure pump 6 and the high-pressure pump 8 and is designed such that it opens the fuel supply to the high-pressure fuel pump 8 when the one supplied by the low-pressure pump 6

Admission pressure is above about 1 bar. If this admission pressure drops below 1 bar, the safety valve 10 shuts off the fuel supply to the high pressure pump 8. A pressure control valve 14 is provided on the delivery side 12 (rail) of the high-pressure pump 8 and opens above a predetermined or predeterminable pressure on the delivery side 12. When the pressure control valve 14 is open, fuel which is not required or is not requested by the combustion process of the internal combustion engine is returned to the fuel tank 2 from the high pressure side 12 via a return line 17 which forms the return 16 and leads away from the pressure control valve 14 via a throttle opening 18 in the return line 17. The return line 17 communicates in the flow direction upstream of the throttle opening 18 with the safety valve 10 in such a way that the fuel supply to the high-pressure pump 8 is increasingly closed as the pressure in the return line rises. As a result, however, the volume flow through the high-pressure pump 8, which is conveyed to the delivery side 12, is reduced. A small part of the fuel is also discharged or used by the safety valve 10 for lubricating the high-pressure pump 8 via a branch line 20.

The structure of the safety valve 10, which forms a shut-off device 22 which communicates with the return line 17 and regulates the fuel supply to the high-pressure pump 8, is shown in a basic manner from the illustration according to FIG. The safety valve 10 or the shut-off device 22 comprises a first displaceable Piston 24 and a second displaceable piston 26, between which a compression spring 28 is provided, which biases the two pistons 24, 26 in opposite directions in their respective end positions.

The side of the piston 26 facing away from the spring 28 is acted upon by the fuel delivered by the low-pressure pump. In the piston 26, a throttle opening 30 is provided, which connects the inlet side of the safety valve 10 to the space 30 between the two pistons 24, 26 in which the spring 28 is arranged. The branch line 20 mentioned in FIG. 1 leads from this space 30 to the high-pressure pump 8 for the purpose of supplying lubricant.

One leads in a cylinder space 32, in which the pistons 24, 26 are arranged displaceably

Fuel supply line 34 radially to the piston longitudinal direction away to the high-pressure pump 8. The second piston 26 forms a control edge 36 such that, depending on the position of the piston 26 in the cylinder chamber 32, the supply line 34 is completely or only partially released and accordingly the fuel supply to the high-pressure pump is opened or throttled.

In the position shown in Figure 2, both pistons 24, 26 are in their respective end positions. If the

Low-pressure pump 6 delivers fuel and accordingly the pressure on the inlet side of the piston 26 rises, the piston 26 is pressed against the bias of the spring 28 in FIG. 2 to the right, that is to say in the direction of the first piston 24, so that the control edge 36 the fuel supply line 34 releases. The high pressure pump 8 now delivers fuel into the rail.

The return line 17 leading away from the pressure control valve 14 already mentioned opens into the

Shut-off device 22 on the side of the first piston 24 facing away from the compression spring 28. If more fuel than required is conveyed to the delivery side 12 and the pressure accordingly rises above a predetermined threshold pressure, the pressure control valve 14 opens. As a result of the throttle bore 18 which is arranged in the flow direction after communication with the first piston 24, the pressure rises the return line 17. As a result, the first piston 24 is moved counter to the spring force 28 in the direction of the second piston 26 in FIG. 2 to the left. However, this also changes the balance of forces on the second piston 26. The force of the spring 28 increases and causes the second piston 26 to be moved in the direction of its end position shown in FIG. 2, the control edge 36 passing over the outlet opening of the feed line 34 . The fuel supply to the high pressure pump 8 is increasingly closed. This reduces the delivery rate of the high pressure pump 8. The system is self-regulating. If, after the pressure control valve 14 closes, the pressure in the return line 17 decreases again, the first piston 24 is again moved into the end position shown in FIG 8 shift releasing direction.

The return flow quantity in the equilibrium state through the pressure control valve 14, the return line 17 into the tank 2

"drained" can be adjusted by changing the diameter of the throttle bore 18. Thanks to the integrated control, the high-pressure pump only delivers as much fuel as is required or requested by the internal combustion engine. The drive power of the pump and thus the

Fuel temperatures are reduced to a minimum.

According to an alternative inventive concept, the return line could cooperate with a control device for the eccentric stroke of the high-pressure pump in such a way that, as the pressure in the return line increases, the eccentric stroke of the piston in the high-pressure pump is reduced so that the amount of fuel delivered per time is reduced. Also with This inventive idea enables an advantageous automatic flow rate control of the high-pressure pump to be achieved.

The type of delivery control described by limiting the supply amount to the high-pressure pump as a function of the return amount of the pressure control valve to the tank provided on the delivery side of the high-pressure pump can be integrated into the pump in a structurally simple manner, since the pressure control valve in most high-pressure pumps for common-rail injection systems is already attached directly to the pump. All that is required is a slight change to the safety valve or shut-off device and a slightly modified line routing.

Claims

Expectations

1. System for high-pressure generation with a high-pressure pump (8) and with a pressure control valve (14) on its delivery side, which opens when a threshold pressure is reached, so that the quantity delivered by the high-pressure pump is drained via a return line (16), characterized in that the Return (16) of the pressure control valve (14) cooperates with a locking device (22) in such a way that as the quantity discharged by the pressure control valve (14) increases, the delivery rate of the high-pressure pump (8) is reduced.

2. System according to claim 1, characterized in that the locking device (22) is provided on the suction side of the high-pressure pump (8), and increasingly automatically closes the pump inlet as the return flow increases.

3. System according to claim 1 or 2, characterized in that increasing the return flow leads to increasing pressure in the return (16) of the pressure control valve (14) which is placed on the locking device (22) and actuates it in such a way that the delivery rate of the high pressure pump ( 8) is reduced.

4. System according to claim 1, 2 or 3, characterized in that the locking device (22) for reducing the flow rate in the high pressure pump (8) is integrated.

5. System according to any one of the preceding claims, characterized in that the pressure control valve (14) is integrated in the high pressure pump (8).

6. System according to one of the preceding claims for fuel high pressure generation in a fuel injection system of an internal combustion engine.

7. System according to claim 6, characterized in that the fuel injection system is time-controlled.

8. The system according to claim 7, wherein the fuel is injected into the cylinders by means of one injection valve each, the injection valves being connected by a common fuel supply device which is under high pressure during operation and the injection, in particular hydraulically assisted, is triggered by an electrically operated device is.

9. System according to one of the preceding claims, characterized in that between a low-pressure pump (6) and the high-pressure pump (8) safety valve (10) is arranged, which interrupts the supply to the high-pressure pump (8) when the pressure falls below a pre-pressure, and that Locking device (22) is formed by the safety valve (10).

10. System according to any one of the preceding claims, characterized in that a return line (17) on one side of a displaceable piston-like adjusting means (24) of the shut-off device (22) opens, the displacement of which causes an increasing opening or closing of the supply opening to the high-pressure pump (8) .

11. System according to claim 10, characterized in that the displaceable piston-like adjusting means (24) is biased into an end position.

12. System according to claim 10 or 11, characterized in that the shut-off device (22) comprises a second displaceable piston-like actuating means (26) which on the one hand from the outlet of the low-pressure pump (6) and on the other hand from one against the first displaceable piston-like actuating means (24) supported spring (28) is acted upon.

13. System according to any one of the preceding claims, characterized in that in the return line (17) in

A throttle means (18) is provided downstream of the shut-off device (22).

14. System according to claim 13, characterized in that the throttle means (18) is adjustable.