FR2875544A1 - FUEL SUPPLY SYSTEM OF A MOTOR VEHICLE INTERNAL COMBUSTION ENGINE AND METHOD OF CONTROLLING THE FUEL SUPPLY PRESSURE OF SUCH ENGINE - Google Patents

Abstract

The system has a fuel pump driven by an electric motor (34), an electronic circuit board (24) to regulate electric motor supply current, and an electric motor supply current measuring unit (40). The regulating unit regulates rotating speed of the motor by regulating the motor supply current about a desired value of supply current representative of a fuel pressure level downstream the pump. An independent claim is also included for a method to regulate fuel supply pressure of an internal combustion engine.

Description

Fuel supply system for an internal combustion engine of

  motor vehicle and method of regulating the fuel supply pressure of such an engine.

  The present invention relates to a system for supplying fuel to an internal combustion engine of a motor vehicle. It also relates to a method for regulating the fuel supply pressure of such an engine.

  Many fuel systems exist and include a fuel tank and a fuel pump coupled to an electric motor. The electric motor, during all phases of operation of the engine of the vehicle, operates at a constant speed of rotation.

  Due to the need for high fuel flow at each start-up phase of the vehicle, the fuel pump coupled to the engine provides excess power during all other operating phases of the engine.

  This is the reason why in conventional fuel systems, an excess fuel return circuit is provided to redirect the excess fuel into the tank. This reinjection of excess fuel can be carried out either directly in the tank or in a holding tank used to maintain a fuel level always sufficient not to defuse the fuel pump, even when there is not much fuel in the tank. The electric motor therefore consumes energy unnecessarily because, apart from the start-up phases, it provides an excessive flow of fuel in relation to the needs of the heat engine.

  To overcome this drawback, it has been proposed in document US Pat. No. 4,756,291 to apply a voltage to the electric motor as a function of the desired fuel flow and, thus, to obtain a flow proportional to this voltage. However, such a solution requires to provide a number of sensors and therefore generates expensive adjustments.

  In documents EP-A-0 644 322 and WO 98/27333, it is proposed to regulate the fuel supply flow rate of a motor vehicle engine by controlling the fuel pump so as to maintain the supply flow rate at a minimum. sufficient level for the injectors to operate linearly, which also requires the use of various expensive sensors.

  Reference may also be made to US Pat. No. 6,609,501 and US Pat. No. 5,842,454, in which it is proposed to regulate the fuel supply pressure from a regulation of the motor supply current.

  In particular, the regulation implemented in document US Pat. No. 5,842,454 uses a measurement of the rotational speed of the engine, which is representative of the fuel flow rate, or a measurement of the voltage at the motor terminals, which is representative of the motor rotation speed. The regulation implemented in the document US 6,609,501 is based on a comparison between the fuel pressure and a target fuel pressure, a regulation of the motor supply current being implemented as soon as the supply pressure reaches or exceeds the target value. This technique therefore also requires the provision of a pressure sensor forming a switch.

  In view of the foregoing, the object of the invention is to overcome the disadvantages of the fuel supply systems according to the state of the art by limiting, in particular, the use of sensors to regulate the pressure of the fuel delivered by the system.

  According to the invention, it is therefore proposed a fuel supply system for an internal combustion engine of a motor vehicle, comprising a fuel tank, a pump driven by an electric motor and means for regulating the supply current. of the motor.

  This power system comprises means for measuring the motor supply current, the means for regulating the motor supply current being adapted to regulate the speed of rotation of the motor only by regulating the supply current of the motor. motor around a supply current setpoint representative of a fuel pressure level downstream of the pump.

  This supply system therefore requires only the use of a single sensor and therefore does not require any sensor to, in particular, measure the pressure and / or the flow of fuel downstream of the pump, or to measure the rotational speed motor, or to measure the voltage across the motor of the pump. In addition, this solution makes it possible to regulate the pressure downstream of the pump, by implementing a simple regulation of the motor supply current, a flow delivered by the pump, providing a given pressure level downstream. of it, being related to the level of motor power supply.

  According to another characteristic of the system according to the invention, means are provided for calculating the speed of rotation of the motor from a measurement of the motor supply current and for adapting the current setpoint value as a function of the speed. motor rotation.

  In one embodiment, in order to adapt the current set point value, the system comprises means for measuring the frequency of the motor supply current, means for converting the measured frequency into the speed of rotation of the motor and means comparing the rotational speed of the motor resulting from said comparison with at least one rotational speed reference value to adapt the current reference value.

  According to another characteristic of the system according to the invention, the latter further comprises a retention tank housed inside the tank, in which there is a conduit connected to the pump and constituting an excess fuel return circuit for maintain a substantially constant fuel level in the holding tank.

  In one embodiment, the fuel return circuit is equipped with a fuel filter. However, this filter may be arranged downstream of the pump.

  According to the invention, there is also provided a method for regulating the fuel supply flow rate of an internal combustion engine, according to which the supply current of an electric drive motor of a fuel pump is regulated. fuel.

  According to this method, the speed of rotation of the motor is regulated solely by regulating the motor supply current around a supply current setpoint value representative of a fuel pressure level downstream of the pump.

  Preferably, according to this method, the motor supply current is measured, the rotational speed of the motor is calculated from the measurement of the motor supply current and the current reference value is adapted according to the speed of rotation of the engine.

  In one embodiment of this method, the rotational speed of the motor is calculated by measuring the frequency of the motor supply current and converting the measured frequency into a corresponding rotational speed.

  Other objects, features and advantages of the invention will become apparent on reading the following description, given solely by way of nonlimiting example and with reference to the appended drawings, in which: FIG. 1 schematically illustrates the general structure of a fuel supply system of an internal combustion engine of a motor vehicle; FIG. 2 illustrates another embodiment of the system of FIG. 1; - Figure 3 and a block diagram illustrating the general structure of the regulating means of the feed system of Figure 1; and FIG. 4 illustrates the mode of regulating the speed of rotation of the motor.

  In Figure 1, there is shown a fuel supply system according to the invention, designated by the general numerical reference 10. This system is intended for supplying an internal combustion engine of a motor vehicle.

  This system essentially comprises a tank 12 of fuel, supplying an injection device 14 of a heat engine 16. The tank 12 is internally provided with a fuel retention tank 18 in which is practiced a small orifice 20, that is to say of negligible size relative to the bottom surface of the retention tank 18.

  The reservoir 12 is also provided with a fuel pump 22 controlled by an external control electronic card 24, or internal, to the tank. It ensures the aspiration of the fuel from the retention tank 18. For this purpose, a pipe 26 connected to the fuel pump 22 and equipped with a fuel filter 28 dives into the retention tank 18. A second pipe 29 extends between the injection system 14 and the pump 22. As visible in Figure 2, which is otherwise identical to Figure 1 and on which elements identical to those of Figure 1 are designated by the same reference numerals , the second pipe can be equipped with a fuel filter 31 instead of the filter in the retention tank. Finally, an optional pressure regulator 30, disposed downstream of the pump 22, regulates the fuel pressure delivered by the pump so as to maintain it at a substantially constant level. For this purpose, a fuel return line 32 is provided between the pressure regulator 30 and the retention tank 18 or, alternatively, as shown in dotted lines, directly in the remainder of the tank so as to reinject the excess fuel. This pipe makes it possible, by Venturi effect in the tank 20, to keep the level of fuel in the tank 18 substantially constant.

  The fuel pump 22 comprises an electric motor 34 controlled by the electronic control card 24 and a hydraulic pump 36 driven by the motor 34.

  In order to control the fuel pressure supplied by the pump 22, the motor supply current 34 is regulated by the control card 24. This card 24 controls the electric motor 34 of the fuel pump only by regulation. the motor supply current, which is always powered by a DC voltage, without the use of any sensors. In other words, the motor supply current is regulated around a set point capable of obtaining a rotational speed of the motor making it possible to obtain a target current pressure downstream of the pump, and this in function characteristics of the pump binding the pressure as a function of the fuel flow. In addition, the characteristics of the pump linking the pressure depending on the flow rate may vary depending on the fuel flow through the pump, the set value is developed or adapted depending on the flow. For this purpose, the value of the motor supply current, which translates the fuel flow through the pump, is used to correct the current setpoint.

  FIG. 3 shows the block diagram of the electronic control card 24 making it possible to regulate the pump 22.

  As can be seen in this figure, this card 24 comprises a DC voltage converter 38 receiving, as input, a supply voltage Ve delivered by the vehicle's on-board network R and delivering, as output, an output voltage Vs of supplying the motor 34 of the pump 22. Furthermore, in order to regulate the motor supply current, this card 24 is associated with a device 40 for measuring the motor supply current which, as indicated, previously, the pressure of the current downstream of the pump, according to the characteristics of the pump establishing a pressure level as a function of the flow delivered by the pump. The measured current delivered by the measuring member 40 is compared, after filtering by means of a suitable filtering member 42, with a current reference value CONS by means of a comparator 44: The error thus calculated is presented at the input of a regulator 46 and then at the input of a control stage 48 to produce a control signal S for the voltage converter 38.

  For example, the voltage converter 38 comprises a set of switching cells based on bipolar transistors, MOSFET transistors, ... driven by pulse width modulation by the control stage 48 so as to obtain a level of target current.

  As can be seen in FIG. 3, the card 24 is completed by a correction stage 50 adapted to correct the current setpoint as a function of the fuel flow, insofar as, as indicated above, the characteristics of the pump binding the pressure Depending on the flow of fuel passing through the pump, and depending on the supply current of the motor 34, the fuel consumption depends on the flow rate. This correction is also based on a measurement of the current delivered by the measuring element 40.

  The correction stage 50 comprises a stage 52 for measuring the frequency of the measured current connected to a stage 54 for converting frequency into rotational speed of the motor. This conversion is carried out according to the following relation: Q = f / 2p in which: Q denotes the speed of rotation of the engine in revolutions per second; f denotes the frequency of the supply current; and p denotes the number of pole pairs of the electric motor.

  Thus, as shown in FIG. 4, after measurement of the current I (step 56), the frequency detection stage 52 measures the frequency f of the supply current (step 58). The conversion stage 54 then calculates the rotation speed of the motor (step 60).

  The rotational speed of the motor is then compared to a reference speed VIT by means of a comparator 62. The difference thus calculated is then presented at the input of a corrector 64 to insert into the result of the comparison between the current measurement. filtered and the current setpoint, a correction component of the current setpoint as a function of the rotational speed of the motor. As indicated above, this compensation makes it possible to adapt the current setpoint to the speed of rotation of the motor and, in particular, to overcome the non-linearities of the fuel pump.

  In operation, when starting the heat engine, the voltage delivered by the vehicle battery, which is available on the vehicle's on-board system, is applied to the electronic control card. This card then starts the electric motor of the pump and a regulation of the supply current of this motor around a current setpoint representative of the nominal operating pressure of the fuel supply circuit.

  Note that the current setpoint value can be held fixed throughout the application of the voltage of the onboard network and, therefore, as long as the vehicle is in operation.

  Alternatively, it is also possible to vary this setpoint and / or the reference speed used to develop the correction component of this setpoint value.

  It will be noted finally that the control of the electric motor of the pump has been illustrated in an application according to which the motor is a DC electric motor with brush. For a brushless direct current electric motor, the same control principle applies as well. However, in this case, the direct current is polyphase and frequency-controlled. The rotational speed of the electric motor can therefore be directly deduced from the driving frequency. The current regulation described above applies in turn in parallel to all of the phase currents.

Claims (9)

  A fuel supply system for an internal combustion engine of a motor vehicle, comprising a fuel tank (12), a pump (36) driven by an electric motor (34) and means (24) for regulating the motor supply current, characterized in that it comprises means (40) for measuring the motor supply current, the means for regulating the motor supply current being adapted to regulate the speed of rotation of the motor only by regulating the motor supply current around a supply current setpoint (CONS) representative of a fuel pressure level downstream of the pump.   2. System according to claim 1, characterized in that it comprises means (52, 54, 62, 64) for calculating the rotational speed of the engine from a measurement of the motor supply current and to adapt the current setpoint as a function of the rotational speed of the motor.   3. System according to claim 2, characterized in that it comprises means (52) for measuring the frequency of the motor supply current, means (54) for converting the measured frequency into the rotational speed of the motor. and means (62) for comparing the rotational speed of the motor resulting from said comparison with at least one rotational speed reference value to adapt the current reference value.   4. System according to any one of claims 1 to 3, characterized in that it further comprises a retention tank (18) housed inside the tank, wherein there is a conduit connected to the pump and constituting an excess fuel return circuit for maintaining a substantially constant fuel level in the holding tank.   5. System according to claim 4, characterized in that the fuel return circuit is equipped with a fuel filter (28).   6. System according to any one of claims 1 to 5, characterized in that it further comprises a fuel filter (31) disposed downstream of the pump.   A method of regulating the fuel supply pressure of an internal combustion engine, which regulates the supply current of an electric motor (34) for driving a fuel pump, characterized in that regulating the motor rotation speed only by regulating the motor supply current around a supply current setpoint (CONS) representative of a fuel pressure level downstream of the pump.   8. Method according to claim 7, characterized in that the motor supply current is measured, the motor rotation speed is calculated from the measurement of the motor supply current and the current setpoint as a function of motor rotation speed.   9. Method according to claim 8, characterized in that the rotational speed of the motor is calculated by measuring the frequency of the motor supply current and converting the measured frequency into a corresponding rotational speed.