KR20020089534A - Method for operating a fuel supply system for an internal combustion engine, especially in a motor vehicle - Google Patents

Abstract

The invention relates in particular to a fuel supply system 1 for an automobile engine. In this fuel supply system 1 fuel can be pumped from the pumps 6, 10 to the accumulator 2. The pressure prist in the accumulator 2 can be measured and the pressure prist in the accumulator 2 can be changed through the adjustment of the pressure control valve 4. The pressure control valve 4 can be fully opened via the control device 16, and the pressure measured in the accumulator 2 via the control device 16 can be compared with the expected pressure.

Description

How to operate fuel supply system, especially for car engines {METHOD FOR OPERATING A FUEL SUPPLY SYSTEM FOR AN INTERNAL COMBUSTION ENGINE, ESPECIALLY IN A MOTOR VEHICLE}

Automotive engines, for example, require a lot of power and at the same time demand a lot in terms of reducing fuel consumption and product emissions. To this end, modern engines are provided with a fuel supply system in which the supply of fuel to the combustion chamber of the engine is controlled and / or regulated electronically, in particular by a computer control device. It is possible here to inject fuel directly into the engine's air intake tube or into the combustion chamber of the engine.

In the above-mentioned type, in particular the so-called direct injection type, it is required that pressurized fuel is injected into the combustion chamber. For this purpose, an accumulator is provided in which fuel is pumped by the pump and set to high pressure. Thereafter, fuel is injected there from the combustion chamber of the engine via an injection valve.

Particularly with high pressures, parts of the fuel supply system can be changed, for example due to aging. Thus, the normal operability of the pressure control valve which can control and / or regulate the pressure in the accumulator can be changed slowly. In addition, the pressure control valve may be suddenly stopped by contamination. This change in function of the pressure control valve results in misfire or other engine malfunctions.

The invention relates in particular to a method of operating a fuel supply system for an automotive engine, in which fuel is pumped from the pump to the accumulator, the pressure in the accumulator is measured and the pressure in the accumulator can be changed through the adjustment of the pressure control valve. The invention also relates to a corresponding fuel supply system for an engine and a control device for such a fuel supply system.

1 is a schematic diagram of one embodiment of a fuel supply system according to the present invention.

2 is a schematic block diagram of one embodiment of a method of operation according to the invention of the fuel supply system of FIG.

It is an object of the present invention to provide a method of operating a fuel supply system for an engine that detects quickly and reliably a failure of a slowly occurring pressure control valve.

According to the invention, this object is solved by the pressure control valve being fully open in the method or fuel supply system of the type mentioned at the outset and the pressure measured in the accumulator compared to the expected pressure.

When the pressure control valve is fully open, this causes dynamic pressure to be generated in the pressure control valve. This dynamic pressure can be predetermined at an intakt pressure control valve without defects. The dynamic pressure here depends in particular on the parameters of the pressure control valve, for example the flow cross section. The measurement of the actual pressure in the accumulator after the full opening of the pressure control valve finally determines the dynamic pressure present at the pressure control valve. This measured dynamic pressure is then compared with the expected dynamic pressure, and from this comparison, the possibility of normal operation of the pressure control valve can then be deduced.

The method according to the invention can be quickly implemented without significant additional costs. In addition, the present invention can reliably detect whether the pressure control valve is intact or not. The method according to the invention here can also be carried out during operation of the engine, but in the area of inspection and the like, for example in a repair shop.

It is particularly advantageous if the pressure in the accumulator is measured immediately after the waiting time after the opening of the pressure control valve. Thus, it is ensured that the dynamic pressure at the pressure control valve is fully established.

In another advantageous embodiment of the invention, the expected pressure is determined in accordance with the parameters of the intact pressure control valve and / or the actual operating parameters of the engine.

The pressure control valve is then detected as contaminated when the measured pressure is greater than the expected pressure.

In an advantageous embodiment of the invention, the engine is in slide operation or idle operation. This operating state is the operating state of the engine which makes the method according to the invention particularly good.

Also advantageously, the temperature and / or rotational speed of the engine is within the allowable range. Thus, the reliability of the method according to the invention is further improved.

Other features, availability and advantages of the invention are provided from the following description of the embodiments of the invention, illustrated in the drawings. Here, all the features described and illustrated are formed by itself or in any combination of the subject matter of the present invention, in accordance with the core or its citations of the claims or according to its formation or illustration of the detailed description or the drawings.

1 shows a fuel supply system 1 provided for a vehicle engine. The fuel supply system 1 is in particular a so-called common rail system used for direct injection in the engine. Such common rail systems are known for diesel engines as well as gasoline engines.

The fuel supply system 1 comprises an accumulator 2 provided with a pressure sensor 3 and a pressure control valve 4. The accumulator 2 is connected to the high pressure pump 6 via a pressure tube 5. The high pressure pump 6 is connected to the pressure control valve 4 via a pressure tube 8. The pressure control valve 4 and the high pressure pump 6, through the pressure tube 9 and the filter, are also connected with the electric fuel pump 10, which is suitable for sucking fuel from the fuel tank 11.

The fuel supply system 1 comprises four injection valves 13 connected to the accumulator 2 via a pressure tube 14. The injection valve 13 is suitable for injecting fuel into the corresponding combustion chamber of the engine.

The pressure sensor 3 is connected to the control device 16 by a signal line 15, and a plurality of other signal lines are connected to the control device 16 as input lines. The fuel pump 10 is connected to the control device 16 by the signal line 17 and the control valve 4 is connected to the control device 16 via the signal line 18. The injection valve 13 is also connected to the control device 16 by a signal line 19.

The fuel is pumped from the fuel tank 11 to the high pressure pump 6 by the fuel pump 10. Pressure is generated in the accumulator 2 by the high pressure pump 6, which can be measured by the pressure sensor 3 and adjusted to a desired value through the corresponding operation of the pressure control valve 4. Thereafter, fuel is injected into the combustion chamber of the engine through the injection valve 13.

The pressure in the accumulator 2 is particularly important for setting the amount of fuel or fuel mass injected into the combustion chamber. The greater the pressure in the accumulator 2, the more fuel is injected into the combustion chamber during the same injection time. This pressure in the accumulator 2 can be regulated and adjusted by the control device 16.

To this end, the control device 16 controls the pressure control valve 4 in its connected state such that the high pressure pump 6 and the fuel pump 10 always generate different rising pressures in the accumulator 2. In contrast, the control device 16 controls the pressure control valve 4 in its open state such that fuel is discharged again from the accumulator 2 so that the pressure in the accumulator 2 is reduced again.

In the fully open state, dynamic pressure is generated in the pressure control valve 4. This dynamic pressure depends on the free flow cross section of the pressure control valve 4 and the amount of fuel flowing through. In addition, the fuel amount depends in particular on the number of revolutions of the engine, the amount of fuel transferred and the amount of fuel injected into the engine.

After a long operating time of the pressure control valve 4, the flow cross section of the pressure control valve 4 can be gradually narrowed by contamination or other deposition. This produces a gradual change in pressure in the accumulator 2 which is affected by the pressure control valve 4. In particular, if the flow cross section of the pressure control valve 4 is smaller, a pressure is generated in the accumulator 2 that is greater than the pressure that must exist. In extreme cases, a complete interruption of the flow cross section of the pressure control valve 4 will lead to a malfunction of the pressure control valve 4 and thus to a shutdown of the fuel supply system 1.

By the method according to FIG. 2, gradual contamination of the pressure control valve 4 is detected. The method according to FIG. 2 is executed by the control device 16.

In block 21, it is checked by the control device 16 whether the temperature of the engine is within an acceptable range. This is required in order for the method of FIG. 2 to be acceptable. If the temperature is not within the allowable range, the method of FIG. 2 is stopped and restarted at a later point in time.

If the temperature of the engine is within the allowable range, then in block 22, it is checked whether the engine is in a fuel cutoff state. In this state the engine is driven "outside". An example is a downward travel of a vehicle in which the driver does not activate either the accelerator pedal or the clutch pedal so that the vehicle does not have a large driving force but rolls down with the transmission connected. In this state, the engine is "slid" by a vehicle rolling down. For this reason the condition is also referred to as sliding operation (or coasting operation).

If the engine is not in coasting operation, the method of FIG. 2 is interrupted and repeated again later. However, if the engine is in coasting operation, the pressure control valve 4 (DSV) is fully opened by the control device 16 at block 23.

In block 24, the control device 16 waits for a waiting time until dynamic pressure builds up in the pressure control valve 4. This waiting time can be predetermined and stored in the control device 16 according to the pressure control valve 4.

After elapse of waiting time, the pressure in the accumulator 2 is measured by the pressure sensor 3 in block 25. This measurement is instructed and executed by the control device 16. Due to the fully open pressure control valve 4, the measured pressure is the dynamic pressure of the pressure control valve 4.

In the next block 26, the comparison value for the dynamic pressure is calculated by the control device 16. The comparison is the expected pressure to be adjusted in the intact pressure control valve 4. The comparison depends on the current operating state of the engine, i.e. on the current operating variables such as its speed, engine temperature and the like. The comparison value also depends on the variable of the pressure control valve 4 stored in the characteristic straight line or characteristic region in the control device 16. The so-called variables here can be determined in advance in the pressure control valve 4, in particular associated with the intact pressure control valve 4 and of particular value, and then stored in the control device 16.

In the next block 27, it is again checked by the control device 16 whether the engine is still in the fuel cutoff state. If no longer, the method of FIG. 2 is interrupted and repeated at a later point in time.

If the engine is still in coasting operation, the control device 16 compares the measured dynamic pressure with the comparison value (maximum value) at block 28. If the measured dynamic pressure is less than the comparison value, then the intact pressure control valve 4 is inferred by the control device 16 at block 29.

However, if the measured dynamic pressure is greater than the calculated comparison value, contamination of the flow cross section of the pressure control valve 4 at the block 30 is inferred by the control device 16.

In the method described above, it is possible that the idling operation of the engine instead of the coasting operation is selected for the execution of the method. In addition to the condition that the temperature of the engine should be within the allowable range, it is also possible that the engine speed should be within the allowable range as another condition for the execution of the method of FIG.

The method described above can be executed during operation of the engine. It is also possible to allow the repair shop to carry out the method by means of a corresponding inspection device.

The variables of the so-called intact pressure control valve 4 are common for the determined engine type, but are individually determined and stored for each engine. Upon replacement of the pressure control valve 4 a new parameter can be determined and entered into the control device 16.

Claims (10)

Fuel is pumped from the pumps 6, 10 to the accumulator 2, the pressure in the accumulator 2 is measured, and the pressure in the accumulator 2 is controlled through the adjustment of the pressure control valve 4. In the method of operation of a fuel supply system, in particular for an automotive engine, The pressure control valve (4) is fully open and the pressure measured in the accumulator (2) is compared with the expected pressure. 2. The method according to claim 1, wherein the pressure in the accumulator is measured immediately after the waiting time after the opening of the pressure control valve. 4. Method according to claim 1 or 2, characterized in that the expected pressure is determined in accordance with the parameters of the intact pressure control valve (4). 4. A method according to any one of claims 1 to 3, wherein the expected pressure is determined in accordance with the actual operating parameters of the engine. The method of claim 1, wherein the pressure control valve is detected as contaminated when the measured pressure is greater than the expected pressure. 6. The method according to claim 1, wherein the engine is in sliding or idling operation. 7. The method according to any one of claims 1 to 6, characterized in that the temperature and / or rotational speed of the engine is within an acceptable range. Electrical control elements, in particular flashes, in particular for the control device 16 of the motor vehicle engine, which are executable on the computing device, in particular on a microprocessor and which store a program suitable for the execution of the method according to any one of the preceding claims. Memory or read-only memory. In the fuel supply system 1 fuel can be pumped from the pumps 6, 10 to the accumulator 2, the pressure in the accumulator 2 can be measured and the pressure in the accumulator 2 In particular in the control device for the fuel supply system 1 of an automobile engine, which can be changed through the adjustment of this pressure control valve 4, The control device characterized in that the pressure control valve 4 can be fully opened via the control device 16 and the pressure measured in the accumulator 2 via the control device 16 can be compared with the expected pressure. . Fuel can be pumped from the pumps 6, 10 to the accumulator 2, the pressure in the accumulator 2 can be measured and the pressure in the accumulator 2 being the pressure control valve 4. In the fuel supply system, in particular for an automotive engine, having a control device 16, A fuel supply system characterized in that the pressure control valve (4) can be fully opened via the control device (16), and the measured pressure in the accumulator (2) can be compared with the expected pressure via the control device (16).