EP1544447A2 - Method and device for controlling an internal combustion engine - Google Patents

Abstract

A combustion engine control process comprises adjusting the pressure in a low pressure circuit if the fuel flow is too low, with a high-pressure pump passing fuel into a reservoir with a value characteristic of the fuel temperature and with a maximum threshold temperature, when the low-pressure pump increases the transported mixture and raises the pressure. An independent claim is also included for a device for the above process.

Description

The invention relates to a method and a device for Controlling an internal combustion engine.

Known internal combustion engines have a fuel supply device with a low pressure circuit, which is a low pressure pump and a regulator comprising a predetermined pressure in the low pressure circuit when the flowing through it Flow rate of fuel is less than one Limit. Increasingly, internal combustion engines are also with a High-pressure pump equipped, which is coupled on the input side with the low-pressure circuit and the fuel into a fuel tank promotes. Injectors are with the fuel tank coupled and measure the fuel in the Combustion chambers of the cylinder of the internal combustion engine too. If the Temperature of the fuel in the low pressure circuit very high Values reached, there is a risk that there vapor bubbles form.

From EP 0 365 714 B1 a method for controlling a Internal combustion engine is known, in which checks whether a Operating state of the hot start is present in which an increased There is danger of formation of vapor bubbles. The operating state the hot start detected, so is the means of Injectors to be metered fuel mass increased in comparison to an operating state in which the probability a vapor bubble formation is low.

However, such a procedure is for internal combustion engines, which in addition to the low pressure circuit still have a high pressure pump, which promotes the fuel in the fuel storage unsuitable because vapor bubbles in the funded amount of fuel Prevent high pressure build up before the high pressure pump.

For internal combustion engines with a high pressure pump it is known the regulator should be designed to withstand the pressure in the Low pressure circuit sufficiently high, so that also ensured is when the temperature of the high pressure pump pumped fuel reaches a maximum value, that no vapor bubbles form. However, this has the disadvantage that in other operating conditions, in which the temperature the fuel is significantly lower, the low-pressure pump be driven with unnecessarily high power got to.

The object of the invention is a method and a device to provide for controlling the internal combustion engine, the or that is simple and reliable at the same time.

The task is solved by the characteristics of the independent ones Claims. Advantageous developments of the invention are characterized in the subclaims.

The invention is characterized by a method and a corresponding device for controlling an internal combustion engine with a fuel supply device with a low-pressure circuit, which includes a low pressure pump and a regulator. The regulator sets a predetermined pressure in the Low pressure circuit when the flow rate flowing through it of the fuel is less than a limit. Furthermore, the internal combustion engine has a high-pressure pump, the the input side is coupled to the low pressure circuit and the Promotes fuel into a fuel storage. One size is determined, which is characteristic of the temperature the fuel that the high pressure pump delivers. A given Condition is met if recognized by size is that the temperature of the fuel is a predetermined Threshold exceeded. If the given condition is satisfied, the low pressure pump is in the sense of Higher flow rate of the fuel is controlled, as if the Temperature of the fuel below the preset threshold is, with the higher flow rate specified is that a specifiable increase in pressure on the input side Pressure of the high pressure pump results.

The invention uses the knowledge that the flow rates / fuel pressure characteristic of the regulator from a certain Flow rate, which is the limit, to a significant increase in pressure leads. In addition, she uses the Realizing that the given threshold temperature of the fuel, as a rule, in operating states of the internal combustion engine is exceeded, in which only a small Fuel quantity by means of injection valves in the combustion chambers the cylinder of the internal combustion engine is metered.

In contrast to the usual low flow of the Low-pressure pump in such operating conditions is the Flow rate of the low pressure pump adjusted so that a very high flow through the regulator results, the then the desired predetermined pressure increase of the input side Pressure of the high-pressure pump result. So can one very simple regulator can be used, for example only a spring-loaded check valve is with a Characteristic curve in which a large increase in pressure is dependent from the flow rate, and yet ensured be that a vapor bubble formation is avoided, when the temperature of the fuel, the high-pressure pump promotes, has exceeded the predetermined threshold. If the flow rate is not increased, the flow is by the regulator significantly lower and the pressure then approximately independent of the flow rate through the regulator. In addition, the regulator can be used for one be designed according to lower pressure, because of Increasing the pressure due to the increased flow rate. This then has an increase in the efficiency of the internal combustion engine Result and at the same time is the wear of the low pressure pump reduced.

In an advantageous embodiment of the invention is the given condition that a hot start operating state or the hot idling of the internal combustion engine occupied becomes. This has the advantage that this is the operating conditions the internal combustion engine, in which a vapor bubble formation can occur with high probability. Of the Operating condition of the internal combustion engine is also to anyway determined for other control purposes and so is then no additional Calculation effort necessary.

In a further advantageous embodiment of the invention is the low pressure pump for a predetermined period of time in Sensed the increased flow rate, if the predetermined Condition is met. This can be a suitable choice the predetermined period of time to ensure that a no vapor bubbles occur and on the other hand the burden is kept low for the low pressure pump.

The predefinable time duration is particularly advantageous from the integral of the metered fuel mass during the Control of the low pressure pump in terms of increased flow determined. The length of time within which a vapor bubble formation Probably, can be so very precise be estimated and the load of the low pressure pump can be kept so low.

In a further advantageous embodiment of the invention the control of the low-pressure pump takes place when the predetermined Condition is met, in the sense of an approximately maximum Flow rate of the low pressure pump. This results then a maximum pressure rise in the low-pressure circuit and Although the input side of the high-pressure pump. The regulator can work in In this case, then to a corresponding to the maximum pressure increase reduced pressure designed for normal operation and so can the efficiency of the internal combustion engine be further improved and also the wear of the low pressure pump be kept very low.

Furthermore, it is advantageous if the activation of the low-pressure pump, if the given condition is met, with Decreasing temperature of the fuel is reduced accordingly becomes. This can continue the wear of the low-pressure pump be reduced while ensuring that no vapor bubble formation occurs.

Figur 1

eine Brennkraftmaschine mit einer Steuereinrichtung,

Figur 2

ein Ablaufdiagramm eines ersten Programms zum Steuern der Brennkraftmaschine gemäß Figur 1 und

Figur 3

ein Ablaufdiagramm eines weiteren Programms zum Steuern der Brennkraftmaschine gemäß Figur 1.

Embodiments of the invention are explained below with reference to the schematic drawings. Show it:

FIG. 1

an internal combustion engine with a control device,

FIG. 2

a flowchart of a first program for controlling the internal combustion engine according to Figure 1 and

FIG. 3

a flowchart of another program for controlling the internal combustion engine according to Figure 1.

Elements of the same construction and function are cross-figurative provided with the same reference numerals.

An internal combustion engine (FIG. 1) comprises an intake tract 1, an engine block 2, a cylinder head 3 and an exhaust tract 4. The engine block 2 includes a plurality of cylinders, which Pistons and connecting rods have over them with a crankshaft 21 are coupled.

The cylinder head 3 comprises a valve train with an inlet valve, an exhaust valve and valve actuators. The cylinder head 3 further includes an injection valve 34 and a Spark plug.

Furthermore, a feed device 5 is provided for fuel. It comprises a fuel tank 50, which has a first Fuel line connected to a low pressure pump 51 is. The fuel line opens into a swirl pot 50a. The low pressure pump 51 includes a suction jet pump, the Fuel from the fuel tank 50 in the swirl pot 50a inflated. The suction jet pump is characterized by that of the low pressure pump 51 conveyed fuel driven.

On the output side, the low pressure pump 51 with an inlet 53 of a high-pressure pump 54 operatively connected. Further, too On the output side of the low-pressure pump 51, a mechanical regulator 52 provided, which on the output side via another Fuel line is connected to the fuel tank 50. The low-pressure pump 51, the mechanical regulator 52, the Fuel line, the other fuel line and the inlet 53 form a low pressure circuit.

The mechanical regulator 52 is preferably a simple one spring-loaded valve in the manner of a check valve, wherein the spring constant is chosen so that in the inlet 53 a predetermined low pressure of, for example, 3000 bis 6000 hPa is not exceeded. The regulator can do the Pressure within a given flow range by him to the predetermined pressure, e.g. Set 4000 hPa, if the flow rate is e.g. less than 100 1 / h. If the flow rate through the regulator is higher, The regulator can no longer set the pressure to the specified level Adjust pressure and pressure increases with increasing flow rate in the low-pressure circuit.

The low-pressure pump 51 is preferably designed so that they always during the operation of the internal combustion engine provides a sufficiently high fuel quantity, which ensures that the predetermined low pressure is not exceeded. For example, the maximum amount of fuel to be metered through the injectors 200 1 / h and the Low pressure pump maximum 280 1 / h promote.

The inlet 53 is guided to the high-pressure pump 54, which on the output side the fuel to a fuel tank 55 promotes. The high pressure pump 54 is usually driven by the camshaft and thus promotes constant Speed N of the crankshaft a constant fuel volume in the fuel storage 55.

The injection valves 34 are connected to the fuel reservoir 55 operatively connected. The fuel thus becomes the injectors 34 supplied via the fuel tank 55.

In the flow of the high pressure pump 54, that is upstream the high-pressure pump 54, is a volume flow control valve 56th provided by means of which the flow rate can be adjusted can, which is supplied to the high-pressure pump. By a corresponding control of the volume flow control valve 56th can be ensured that in the fuel tank 55 always the desired fuel pressure prevails without a electromagnetic regulator on the output side of the fuel accumulator 54 with a corresponding return line in the Low pressure circuit must be provided.

Alternatively, however, the internal combustion engine with a electromagnetic regulator output side of the fuel tank 54 and with a corresponding return line in be provided the low pressure circuit. Alternatively, that too Volume flow control valve integrated into the high-pressure pump 54 be.

Furthermore, the internal combustion engine is a control device 6 assigned, which in turn are assigned sensors that different Measurements record and in each case the measured value of the Determine measured quantity. The control device 6 determines dependent of at least one of the measured variables manipulated variables, which then in corresponding control signals for controlling actuators be implemented by means of appropriate actuators.

The sensors are a pedal position transmitter, which the position an accelerator pedal detected, a crankshaft angle sensor, which detects a crankshaft angle and which then a Speed N is assigned, an air mass meter, which detects the air mass flow, a pressure sensor 58, which the Fuel pressure in the fuel reservoir 55 detects, a first temperature sensor, which the temperature T_IM the intake air detected in the intake tract, a second temperature sensor, which detects a temperature TCO of a coolant, preferably the cooling water, and a third temperature sensor, which detects the temperature TCO of the engine oil. Depending on the embodiment The invention may be any subset of Sensors or additional sensors may be present.

The actuators are for example as intake or exhaust valves, the injection valves 34, a spark plug, a Throttle, the low pressure pump 51 or the flow control valve 56 trained.

Preferably, the internal combustion engine also has other cylinders, which then corresponding actuators are assigned.

A program for controlling the internal combustion engine is in one Step S1 (Figure 2) started, in which optionally variables be initialized.

In a step S4, a control signal SG for driving the Low-pressure pump 51 preferably depends on a zuzumessenden Fuel mass MFF and the speed N determined. The zuzumessende Fuel mass is from another control function, which is processed in the control device 6, depending determined by the internal combustion engine load. The actuating signal is determined in step S4 so that the Flow rate of the fuel through the low pressure pump 51 safely sufficient to the predetermined pressure in the low-pressure circuit on the other hand it is ensured that the flow rate through the regulator 52 is less than the limit, from which he sets the pressure in the low-pressure circuit can not adjust to the specified pressure.

In a step S6, the current operating state BZ is the Internal combustion engine depending on the temperature TCO of the coolant, and / or the temperature T_IM of the intake air in the Intake tract 1 and / or the temperature TOIL of the engine oil and / or the speed and possibly other operating variables the internal combustion engine determined.

An operating state of the HS of the hot start becomes, for example taken when the temperature of the fuel that the High-pressure pump delivers, exceeded a predetermined threshold Has. The threshold can be, for example, at 80 ° C lie. The operating state of the hot start occurs, for example on when the internal combustion engine after a longer Operating time is turned off and shortly thereafter again is started when the engine block is still a high temperature Has. In this case, then the fuel that is in the Low pressure circuit is heated to the high temperature.

The same applies to an operating state HIS of the hot idling, in which by means of the injection valves 34 only a small Fuel quantity is metered and so in the Heat the low-pressure circuit fuel accordingly high can. The operating state of the hot-idling HIS becomes based on the usual conditions for an idle, so based the speed N and possibly other sizes recognized and further depending on the temperature TCO of the coolant, and / or the temperature T_IM of the intake air temperature and / or the temperature TOIL of the engine oil.

In a step S8, it is then checked whether the current Operating state BZ the operating state HS of the hot start or the operating state of the HIS is the hot idle. is does not satisfy the condition of step S8, the processing becomes continued in a step S14. Is the condition on the other hand, step S8 is satisfied, then in one step S10 a corrected control signal SG_COR depending on the Control signal SG, the current operating state BZ and preferably the time T_BZ since taking the current operating state BZ and preferably the fuel mass to be metered MFF determined.

The corrected actuating signal SG_COR is determined in the manner that by driving the low-pressure pump 51st Such an increased flow rate results in a predetermined Pressure increase, e.g. around 1000 hPa of the input side Pressure of the high pressure pump 54 in comparison to a control with the control signal SG results. The corrected actuating signal SG_COR is then preferably determined by means of a characteristic field.

Particularly simply, alternatively, according to the step S10 'be equalized the corrected control signal SG_COR a maximum control signal SG_MAX. This simply makes the maximum pressure rise can be achieved.

In a step S12, a time T_COR is increased Flow rate of the low pressure pump 51 determined. This can be in fixed in a simple configuration, e.g. between 30 seconds and 3 minutes, or depending from the time T_BZ since taking the current operating state BZ and the fuel mass MFF to be metered be determined. This is preferably done by integrating the fuel mass MFF to be metered. This can be a very good estimation of the time duration T_COR of the increased flow rate be achieved because the integral of the Fuel mass is characteristic of the course of the temperature T_F of the fuel in the low-pressure circuit.

In a step S14, the low-pressure pump 51 then becomes corresponding with the control signal SG or with the corrected Control signal SG_COR activated. The actuating signal is preferred a pulse width modulated signal. The control of the low-pressure pump with the corrected control signal SG_COR preferably for the time T_COR the increased flow, which was determined in step S12. Of course is the corrected control signal SG_COR in the step S14 then with a changing metering fuel mass MFF according to step S4 and optionally with increasing time T_BZ since taking the current operating state BZ adjusted.

Subsequent to step S14, the program remains in the Step S16 for a predetermined waiting period T_W before the processing in step S4 is continued again.

A second embodiment of a program for controlling the internal combustion engine is started in a step S18 (Figure 3). In a step S20, according to the step S4 determines the control signal SG. In a step S22 becomes the fuel temperature T_F of the fuel, the high-pressure pump 54 promotes, depending on the temperature TCO of the Coolant and / or the temperature T_IM the intake air in the intake tract 1 and / or the temperature TOIL of the engine oil and / or the speed and / or the fuel mass to be metered MFF determined. This is preferably done by means of a appropriate observer or by means of maps.

In a step S24, it is then checked whether the fuel temperature T_F is greater than a threshold T_F_THR. If this is not the case, then the processing is in one Step S30 continues.

If the condition of step S24 is fulfilled, then in a step S26, the corrected control signal SG_COR determined. This is preferably done depending on the fuel temperature T_F and optionally from the control signal SG and optionally of the fuel mass MFF to be metered.

In a simpler embodiment can also in a Step S26 'alternatively the corrected control signal SG_COR be equated the maximum control signal SG_MAX.

In a step S28, the time period T_COR is then increased Flow rate preferably by integrating the zuzessessenden Determined fuel mass. The time duration T_COR of the increased Flow rate can also be fixed.

In step S30, the low-pressure pump 51 then either with the control signal SG or accordingly with the corrected Control signal SG_COR activated. Preference is given respectively to rechecked for a predetermined period of time whether the fuel temperature T_F continues to be larger than the given one Threshold T_F_THR and only then the fuel pump 51 is controlled with the corrected actuating signal SG_COR, if this is still the case. The corrected actuating signal SG_COR as well as the control signal SG is changing to a MFF to be metered according to the Step S20 adapted respectively.

In addition, it is advantageous if the corrected Actuating signal for driving the low-pressure pump 51 also accordingly the calculation rule of step S26 changing fuel temperature T_F adapted in the way is that the delivery of the low pressure pump at decreasing fuel temperature T_F is reduced.

In a step S32, the program then stops for a predetermined waiting time before processing again in the step S20 is continued.

Claims (7)

A method of controlling an internal combustion engine having a fuel supply device (5) with a low pressure circuit comprising a low pressure pump (51) and a regulator (52) which sets a predetermined pressure in the low pressure circuit when the flow rate of the fuel flowing therethrough is less than one Limit value, and with a high-pressure pump (54), the input side coupled to the low-pressure circuit and the fuel in a fuel reservoir (55) promotes, in which determining a quantity which is characteristic of the temperature (T_F) of the fuel which the high-pressure pump (54) delivers, a predetermined condition is met when it is detected by the magnitude that the temperature (TF) of the fuel has exceeded a predetermined threshold (T_F_THR), and if the predetermined condition is met, the low-pressure pump (51) is driven in terms of a higher flow rate of the fuel, as if the temperature (T_F) of the fuel below the predetermined threshold (T_F_THR), wherein the higher flow rate is set so that a predeterminable pressure rise of the input-side pressure of the high-pressure pump (54) results. The method of claim 1, wherein the predetermined condition is that an operating state (BZ) of the hot start (HS) or the hot idle (HIS) of the internal combustion engine occupied becomes. Method according to one of the preceding claims, in which the low pressure pump (51) for a predetermined period of time (T_COR) is driven in the sense of increased flow. Method according to Claim 3, in which time duration (T_COR) depends of the integral of the weight of fuel (MFF) during the activation of the low-pressure pump (51) in the sense an increased flow rate. Method according to one of the preceding claims, in which the control of the low pressure pump (51) in the sense of an increased Flow rate in terms of an approximately maximum flow the low pressure pump (51) takes place. Method according to one of the preceding claims, in which the control of the low pressure pump (51) in the sense of an increased Flow rate with decreasing temperature (T_F) of the fuel is reduced. An apparatus for controlling an internal combustion engine having a fuel supply device (5) with a low pressure circuit comprising a low pressure pump (51) and a regulator (52) which sets a predetermined pressure in the low pressure circuit when the flow rate of the fuel flowing therethrough is less than one Limit value, and with a high pressure pump (54), which is the input side coupled to the low pressure circuit and the fuel in a fuel reservoir (55) promotes, with means that determine a quantity that is characteristic of the temperature (T_F) of the fuel that the high pressure pump (54) delivers, Checking whether a predetermined condition is met, which is satisfied when it is detected by the size that the temperature (T_F) of the fuel has exceeded a predetermined threshold (T_F_THR), and which control the low-pressure pump (51) in terms of a higher flow rate of the fuel when the predetermined condition is satisfied, as if the temperature (T_F) of the fuel below the predetermined threshold value (T_F_THR), wherein the higher flow rate is set so that a predeterminable pressure rise of the input-side pressure of the high-pressure pump (54) results.

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