EP1281860A2 - Injection System for an Internal Combustion Engine and Method for Operating the Same - Google Patents

Abstract

The fuel injection system has a fuel pump (5) for delivery of the fuel, at least one sensor (9,10,11,13), for monitoring a parameter of the fuel injection system or the engine and a control device (8) receiving the sensor signals, for corresponding control of the fuel feed rate of the pump, e.g. via a control valve. An Independent claim for an operating method for an internal combustion engine fuel injection system is also included.

Description

The invention relates to an injection system for an internal combustion engine according to the preamble of claim 1 and a Method of operating them according to claim 13.

Known injection systems for internal combustion engines usually have a low pressure pump, which is to be injected Sucks fuel from a fuel tank and on a high pressure pump forwards the in for injection the combustion chambers of the internal combustion engine required injection pressure generated. Between the low pressure pump and the High pressure pump a pressure regulator is usually arranged, that when a predetermined fuel pressure is exceeded in the low pressure area between the low pressure pump and the High pressure pump part of the pumped by the low pressure pump Branches off and into the fuel tank returns so that the fuel pressure in the low pressure area remains approximately constant. Is on the output side the high pressure pump with a pressure accumulator (English Common Rail) from which the individual combustion chambers of the Internal combustion engine-associated injectors with fuel be supplied. In addition, the accumulator is on Subordinate high pressure control valve that when a predetermined fuel pressure in the high pressure range Part of the fuel flow delivered by the high pressure pump branches off and into the fuel tank or into the low pressure area returns so that the fuel pressure in the Pressure accumulator is kept approximately constant.

A disadvantage of such known injection systems is that The fact that to control or regulate the fuel pressure in the high pressure area a separate high pressure control valve is required. Another disadvantage of those described above well-known injection system can be seen in that the high pressure pump regardless of the actual Always has a specified delivery rate, which depends on their speed. The high pressure pump therefore consumes in the partial load range of the internal combustion engine unnecessary mechanical drive power.

The invention is therefore based on the object at the outset to improve the known injection system described, that dispenses with a separate high pressure control valve can be and if possible no unnecessary mechanical Power for driving the high pressure pump is consumed.

The task is based on the one described above known injection system according to the preamble of the claim 1 and with regard to an associated operating method solved the features of claim 13.

The invention encompasses the general technical teaching that Fuel pressure in the high pressure area of the injection system on The high pressure pump does not exit through a separate high pressure control valve stop, but instead the funding the high pressure pump depending on the operating state the injection system or the internal combustion engine to control or regulate.

The injection system according to the invention therefore has one Fuel pump with a control input to control the Fuel delivery on, the control input with a Control device is connected, the at least one sensor to record a state variable of the injection system or queries the internal combustion engine and the fuel pump in dependence from the determined state variable with a corresponding one Control signal driven.

In the preferred embodiment of the invention this needs-based adjustment of the funding at High-pressure pump, however, the principle of the invention Demand-based control of the delivery rate of a fuel pump also or only applied to a low pressure pump become.

In the sensor for detecting a state variable of the injection system or the internal combustion engine, for example is a speed sensor that measures the speed the crankshaft or the camshaft of the internal combustion engine detected, so that the delivery rate of the fuel pump depends on the speed is set.

In addition to or instead of such a speed sensor a speed sensor, a temperature sensor can also be used which detects the fuel temperature so that the Control device the delivery rate of the fuel pump in Depends on the fuel temperature.

In addition, there is also the possibility of additional or alone to provide a pressure sensor that measures the fuel pressure recorded in the high pressure area and / or in the low pressure area, so that the delivery rate of the fuel pump is dependent is set by the fuel pressure.

In internal combustion engines with a camshaft adjustment furthermore the possibility of a rotation angle sensor to provide the twist angle between the camshaft and the crankshaft and the fuel pump accordingly controls. This is particularly important if the Setting the delivery rate of the fuel pump by Control valve takes place during the delivery stroke of the fuel pump a backflow of fuel into the low pressure area enables or blocks because the opening or Closing angle of such a control valve with the crankshaft position must be synchronized.

Finally, the fuel pump is preferably controlled also depending on the installation angle of the Fuel pump relative to the crank or Camshaft to set the desired phase position.

Another important factor in the generation of the control signal to control the fuel pump is the dead time the control valve of the fuel pump, i.e. the timespan between the application of a control signal to the control valve and the setting of the desired valve status.

Figur 1

eine erfindungsgemäße Einspritzanlage als Blockschaltbild,

Figuren 2a - 2c

die Hochdruckpumpe der in Figur 1 dargestellten Einspritzanlage in verschiedenen Betriebszuständen sowie

Figur 3

Zeitdiagramme zur Verdeutlichung der Funktion der in Figur 1 dargestellten Einspritzanlage.

Other advantageous developments of the invention are characterized in the subclaims or are explained in more detail below together with the description of the preferred exemplary embodiment of the invention with reference to the figures. Show it:

Figure 1

an injection system according to the invention as a block diagram,

Figures 2a - 2c

the high pressure pump of the injection system shown in Figure 1 in various operating states and

Figure 3

Time diagrams to illustrate the function of the injection system shown in Figure 1.

The injection system shown in Figure 1 is for a Internal combustion engine provided with four combustion chambers and has to deliver fuel from a fuel tank 1 a low pressure pump 2 by a, not shown Electric motor is driven. The drive of the low pressure pump However, 2 is also by a camshaft 3 Internal combustion engine possible.

The low-pressure pump 2 with a low-pressure regulator is on the output side 4 connected, which is exceeded when a predetermined Fuel pressure in the low pressure area at the outlet the low pressure pump 2 is part of the low pressure pump 2 delivered fuel flow branches and into the fuel tank 1 so that the fuel pressure in the low pressure range is kept approximately constant.

Furthermore, the low-pressure pump 2 is equipped with a High pressure pump 5 connected, the tappet from the Camshaft 3 is driven mechanically and for injection of the fuel into the combustion chambers of the internal combustion engine required injection pressure generated. The structure of the High-pressure pump 5 is shown schematically in FIGS. 2a-2c and will be explained in more detail.

The high-pressure pump 5 is on the output side via a check valve 6 connected to a pressure accumulator 7 (common rail), from which the the individual combustion chambers of the internal combustion engine assigned and shown here only schematically injectors remove the fuel to be injected.

Furthermore, the injection system according to the invention has a Control device 8, which has the task of the delivery rate to adjust the high pressure pump 5 as required that the fuel pressure in the pressure accumulator 7 within one predetermined bandwidth. This is the control device 8 connected with several sensors to state variables the injection system or the internal combustion engine and the delivery rate of the high-pressure pump 5 as required to be able to adjust.

So the control device 8 is on the input side with a Pressure sensor 9 connected to the fuel pressure P in the Pressure accumulator 7 detected.

Furthermore, the control device 8 is on the input side with a Temperature sensor 10 connected to the fuel temperature measures. However, the fuel temperature can also be due to other operating state variables can be calculated.

Furthermore, the control device 8 is connected on the input side to a rotation angle sensor 11 which detects the rotation angle ϕ _{KW of} the crankshaft of the internal combustion engine, since the angular position of the crankshaft forms a fixed reference system for controlling the high pressure pump 5.

On the output side, the rotation angle sensor 11 is connected to a computing unit 12, which determines the rotation speed n _{KW of} the crankshaft from the rotation angle ϕ _{KW of} the rotation angle sensor 11 and supplies it to the control device 8.

Furthermore, the injection system according to the invention has a rotation angle sensor 13 which determines the angular position ϕ _{NW of} the camshaft 3. This is important since the camshaft 3 rotates relative to the crankshaft when the camshaft is adjusted, so that the control of the high-pressure pump 5 must be adapted accordingly. A computing unit 14 is therefore provided, which is connected on the input side both to the rotation angle sensor 11 for the crankshaft and to the rotation angle sensor 13 for the camshaft and determines the rotation angle Δϕ _KW-NW between the crankshaft and the camshaft.

The two rotation angle sensors 11, 13 deliver in dependence from the respective position to the camshaft sensor wheel or Crankshaft encoder wheel each LOW and HIGH level, from which the camshaft angle or the crankshaft angle is calculated becomes.

The following is now based on the schematic representations the structure of the high-pressure pump 5 is described in FIGS. 2a-2c. So it is with the high pressure pump 5 Single cylinder piston pump with a piston 15, which in one Cylinder is oscillated by the camshaft. By doing On the one hand there is a pump housing with a low pressure connection for connecting the high pressure pump 5 to a low pressure area 16, between the low pressure pump 2 and the High pressure pump 5 is. On the other hand, the high pressure pump 5 a high-pressure connection 17 on which the high-pressure pump 5 connected to the check valve 6 and the pressure accumulator 7 is.

In the area of the low pressure connection of the high pressure pump 5 a control valve 18 is arranged which the flow connection between the pump housing and the low pressure region 16 enable or disable depending on a control signal can.

Finally, the high pressure pump 5 also has a check valve 19, which is arranged in the region of the high-pressure connection and a backflow of fuel from the downstream the high pressure pump 5 located high pressure area in the high pressure pump 5 prevented.

The function of the high-pressure pump 5 will now be described, initially on the one shown in FIG. 2a Suction phase is entered. Moved during this suction phase the piston 15 of the high pressure pump downwards, the Control valve 18 is open, allowing fuel from the low pressure area 16 is sucked into the pump housing, whereas the check valve 19 prevents fuel can flow back from the high pressure area.

The following is the one shown in FIGS. 2b and 2c Funding phase described, wherein Figure 2b shows a state shows the high pressure pump 5, in which no fuel is delivered should be and the high pressure pump 5 runs empty. In this state, the control valve 18 is still open, so that the piston 15 located in the pump housing Fuel on the upstroke back to the low pressure range 16 presses. It is important here that the resistance of the check valve 19 is so large that in the low pressure range 16 prevailing fuel pressure is not sufficient to the Open check valve 19.

In the state of the high-pressure pump 5 shown in FIG. 2c on the other hand, the control valve 18 is closed, so that the piston 15 does not return fuel during its upward stroke can press in the low pressure region 16. As a result, increases the fuel pressure in the pump housing of the high pressure pump 5 during the upward stroke of the piston 15 until the Fuel pressure is sufficient to open the check valve 19, whereupon the fuel enters the high pressure region 17 flows.

The delivery rate of the high pressure pump 5 is thus by Control valve 18 determines the delivery rate of the high pressure pump 5 is maximum when the control valve 18 during of the entire upward stroke of the piston 15 is closed, whereas the delivery rate of the high pressure pump 5 is minimal, if the control valve 18 during the entire upward stroke of the Piston 15 is opened.

The control of the control valve 18 of the high-pressure pump 5 will now be described below with reference to FIG. 3, the upper diagram in FIG. 3 showing the oscillating movement of the piston 15 of the high-pressure pump 5, while the middle diagram in FIG. 3 shows that generated by the control device 8 Control signal 20 for controlling the control valve 18 of the high pressure pump shows. A high level of the control signal 20 causes the control valve 18 to close, whereas a low level of the control signal 20 causes the control valve 18 of the high-pressure pump 5 to open. Finally, the lower diagram in FIG. 3 shows the actual state 21 of the control valve 18, it being recognizable that the control valve 18 only follows the control signal 20 with a delay due to mechanical inertia. The time delay between the control signal 20 and the actual state 21 of the control valve 18 is approximately 1 ms, the opening _{dead time} T _{tot, on} and the closing _{dead time} T _tot, not being identical.

From Figure 3 it can be seen that the control signal 20 towards the end the printing phase returns to a low level in time, that the control valve 19 at the beginning of the following suction phase is open again so that fuel from the low pressure area 16 can be sucked. The length of time for which the control valve 18 is closed during the printing phase, determines the delivery rate of the high pressure pump 5.

The closing time t _CLOSE and the opening time t _OPEN for the control signal 20 are calculated by the control device 8 in accordance with the following formulas as required: t ON = f 1 (φ Assembly , T dead , Δϕ KW-northwest , ϕ KW ) t TO = f 2 (F Should , T dead , t ON ) where F is the predefined fuel _requirement, which is predefined by the electronic engine control, which is not shown here for the sake of simplicity.

The above formulas only apply to a specific one Pump type, being between different pump types Variations are possible. But it is essential that the promoting fuel mass preferably a closing area of the control valve 18 during the printing phase.

The invention is not based on the embodiment described above limited. Rather, a variety of Variants and modifications conceivable, also based on the inventive concept Make use of and therefore in the protected area fall.

LIST OF REFERENCE NUMBERS

1

Fuel tank

2

Low pressure pump

3

camshaft

4

Low pressure regulator

5

high pressure pump

6

check valve

7

accumulator

8th

control device

9

pressure sensor

10

temperature sensor

11

Angle of rotation sensor (crankshaft sensor)

12

computer unit

13

Angle of rotation sensor (camshaft sensor)

14

computer unit

15

piston

16

Low pressure area

17

High pressure area

18

control valve

19

check valve

20

control signal

21

State of control valve 18

Claims (22)

Injection system for an internal combustion engine with a fuel pump (5) for delivering fuel, at least one sensor (9, 10, 11, 13) for detecting a state variable of the injection system or the internal combustion engine and one on the input side with the sensor (9, 10, 11, 13 ) connected control device (8) for controlling the fuel delivery as a function of the state variable,
characterized in that the fuel pump (5) has a control input for controlling the delivery rate,
the control device (8) is connected on the output side to the control input of the fuel pump (5),
so that the delivery rate of the fuel pump (5) depends on the control signal. Injection system according to claim 1,
characterized in that the fuel pump (5) has a control valve (18) which determines the delivery capacity of the fuel pump (5) and is controlled by the control signal. Injection system according to claim 2,
characterized in that the control valve (18) takes either an open position or a closed position depending on the control signal, the control signal being binary. Injection system according to claim 2 or 3,
characterized in that the fuel pump (5) has a low-pressure connection for drawing in fuel from a low-pressure area (16) and a high-pressure connection for delivering fuel into a high-pressure area (17) located downstream of the low-pressure area,
A check valve (15) is arranged in the area of the high-pressure connection (17) and prevents fuel from flowing back from the high-pressure area (17) into the low-pressure area (16).
while the control valve (18) is arranged in the region of the low pressure connection. Injection system according to at least one of the preceding claims,
marked by
a speed sensor (11, 12) for detecting the speed of a crankshaft or a camshaft of the internal combustion engine as a state variable of the internal combustion engine, the speed sensor (11, 12) being connected on the output side to the control device (8) so that the control signal for the fuel pump (5 ) depends on the speed. Injection system according to at least one of the preceding claims,
marked by
a temperature sensor (10) for detecting the temperature of the fuel as a state variable of the injection system, the temperature sensor (10) being connected on the output side to the control device (8), so that the control signal for the fuel pump (5) depends on the measured temperature. Injection system according to at least one of the preceding claims,
marked by
a pressure sensor (9) for detecting the fuel pressure as a state variable of the injection system, the pressure sensor (9) being connected on the output side to the control device (8) so that the control signal for the fuel pump (5) depends on the fuel pressure. Injection system according to at least one of the preceding claims,
marked by
a first angle of rotation sensor (11, 13, 14) for detecting the angle of rotation between the crankshaft and the camshaft as a state variable of the internal combustion engine, the first angle of rotation sensor (11, 13, 14) being connected on the output side to the control device (8), so that the control signal for the fuel pump (5) depends on the angle of rotation between the crankshaft and the camshaft. Injection system according to at least one of the preceding claims,
marked by
a second angle of rotation sensor (11) for detecting the angle of rotation of the crankshaft or the camshaft, the second angle of rotation sensor being connected on the output side to the control device (8), so that the control signal for the fuel pump (5) is synchronized with the angular position of the crankshaft or the camshaft , Injection system according to at least one of the preceding claims,
characterized in that the fuel pump (5) is a high pressure pump. Injection system according to at least one of the preceding claims,
characterized in that the fuel pump is a single cylinder pump. Injection system according to at least one of the preceding claims,
characterized in that the fuel pump is connected on the output side to a pressure accumulator (7). Method for operating an injection system according to one of the preceding claims, comprising the following steps: Detection of at least one state variable of the injection system or the internal combustion engine, Determination of a control signal depending on the state variable, Control of the fuel pump (5) with the control signal. A method according to claim 13,
characterized in that the installation angle of the fuel pump (5) is determined relative to the crankshaft or the camshaft and the control signal for the fuel pump (5) is determined as a function of the determined installation angle. A method according to claim 13 or 14,
characterized in that the dead time of the control valve of the fuel pump (5) is determined and the control signal for the fuel pump (5) is determined as a function of the dead time of the control valve (18). Method according to at least one of claims 13 to 15,
characterized in that the speed of the camshaft or the crankshaft is determined and the control signal is determined as a function of the determined speed. Method according to at least one of claims 13 to 16,
characterized in that the fuel temperature is determined and the control signal for the fuel pump (5) is determined as a function of the determined fuel temperature. Method according to at least one of claims 13 to 17,
characterized in that the fuel pressure is determined and the control signal for the fuel pump (5) is determined as a function of the determined fuel pressure. Method according to at least one of claims 13 to 18,
characterized in that the angle of rotation between the crankshaft and the camshaft is determined and the control signal for the fuel pump (5) is determined as a function of the determined angle of rotation. Method according to at least one of claims 13 to 16,
characterized in that the phase angle of the crankshaft or the camshaft is determined and the control signal for the fuel pump (5) is determined as a function of the determined phase position. Method according to at least one of claims 13 to 17,
characterized in that an opening angle for the control valve (18) as a function of the installation angle of the fuel pump (5) relative to the camshaft or the crankshaft, the dead time of the control valve (18), the angle of rotation between the crankshaft and the camshaft and / or the Angle of the crankshaft is set
that a closing angle for the control valve (18) is determined as a function of a predetermined desired fuel delivery, the dead time of the control valve (18) and / or the opening angle of the control valve (18),
that the control signal for the control valve (18) is determined as a function of the opening angle and the closing angle. Method according to at least one of the preceding claims,
characterized in that the battery voltage is determined and the control signal is determined as a function of the battery voltage.

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