FR3105427A1 - Real-time detection system of fuel injected into a fuel tank of a motor vehicle - Google Patents

Abstract

A fuel detection system (10) configured to detect the type of fuel injected into a fuel tank (13) of a motor vehicle, said system (10) comprising a laser unit (11) configured to emit at least one light beam , at least one reflection system (12) configured to receive the light beam from the laser unit (11) and to reflect it back to the fuel tank (13), an electronic detection and analysis module (14) fluorescence induced by the laser beam at the intersection of hydrocarbons present in the fuel present in the tank (13), an electronic control unit (15) configured to receive, analyze the information emitted by the detection module and electronic analysis (14) and to determine in real time the type of fuel present in said tank (13). Figure for the abstract: Fig 1

Description

System for the real-time detection of fuel injected into a fuel tank of a motor vehicle

The present invention relates to the field of motor vehicles, and in particular to the fuel supply of a heat engine of the vehicle.

When filling the fuel tank, it is essential not to use the wrong fuel, in which case the internal combustion engine would not be able to operate correctly. Any erroneous fuel present in the fuel tank will therefore have to be evacuated, which would cause a breakdown immobilizing the motor vehicle.

There is a need to be able to reliably detect the type of fuel necessary for the correct operation of the heat engine of the vehicle.

The object of the invention is therefore to overcome the aforementioned drawbacks and to propose a device for detecting the type of fuel necessary for the proper functioning of the heat engine of the vehicle.

The subject of the invention is a fuel detection system configured to detect the type of fuel injected into a fuel tank of a motor vehicle.

This system includes:

- a laser unit configured to emit at least one light beam,

- at least one reflection system configured to receive the light beam coming from the laser unit and to reflect it towards the fuel tank,

- a module for detection and electronic analysis of the fluorescence induced by the laser beam at the intersection of hydrocarbons present in the fuel present in the tank and

- an electronic control unit or computer configured to receive, analyze the information received by the analysis module of said induced fluorescence, and determine the type of fuel present in said tank in real time.

The control unit is configured to control the entire laser emission system and module for detecting and analyzing said induced fluorescence.

Thus, the system provides information on the presence, type and concentration of fuel injected into the fuel tank. Indeed, the spectral fluorescence signature characteristic of each type of fuel leads to its identification and characterization.

Advantageously, the system comprises an alert module configured to emit an audible and/or visual alert, for example comprising a light-emitting diode capable of lighting up, in the event of detection of the incorrect type of fuel.

The fuel sensing system is preferably located at the inlet of the vehicle's fuel tank filler pipe.

For example, the laser unit includes an excimer laser and/or a dye laser and/or a semiconductor laser.

According to one embodiment, the detection module comprises an optical system, in particular with a telescope of the detection module, configured to receive the fluorescence radiation emitted by the fuel and to direct it towards a spectral unit.

The spectral unit can correspond to the electronic detection and analysis module.

According to one embodiment, the system comprises a first mirror configured to receive the light beam coming from the laser unit and to reflect it towards a second mirror and towards the fuel, said light beam then being reflected towards an optical detection system, such as for example a photodetector.

For example, the second mirror is configured to reflect the light beam from the first mirror to an analysis container located in the fuel tank filler pipe. The radiation reflected by the second mirror is absorbed by the fuel present in the analysis container and the fluorescent components of said fuel emit fluorescence radiation.

Advantageously, the system further comprises a light-reflecting device, such as for example a reflector, located in the analysis container and configured to reflect the radiation emitted by the fuel and send it back to the fuel type detection module, by example located outside the reservoir.

According to one embodiment, the detection module comprises a telescope configured to receive the fluorescence radiation emitted by the fuel in order to direct it, via the two mirrors, towards the optical detection system.

For example, the system comprises a module for receiving and analyzing the signal emitted by the optical system and configured to transmit said signal to the electronic control unit.

According to a second aspect, the invention relates to a motor vehicle comprising a fuel tank and a fuel detection system as described above configured to detect the type of fuel injected into said tank.

Other aims, characteristics and advantages of the invention will appear on reading the following description, given solely by way of non-limiting example, and made with reference to the appended drawings in which:

very schematically illustrates a system for detecting fuel injected into a fuel tank of a motor vehicle according to a first embodiment of the invention; And

illustrates a system for detecting fuel injected into a fuel tank of a motor vehicle according to a second embodiment of the invention.

In Figure 1 is shown a first example of a fuel detection system 10 configured to detect the type of fuel injected into a fuel tank 13 of a motor vehicle (not shown), during the fuel supply of said tank .

The fuel detection system 10 is located at the inlet of the filler pipe (not shown) of the fuel tank 13 of the vehicle.

As illustrated, the fuel detection system 10 comprises a laser unit 11 configured to emit at least one light beam, a mirror 12 configured to receive the light beam from the laser unit 11 and to reflect it towards the fuel tank at fuel 13.

Without limitation, the laser unit 11 may comprise an excimer laser and/or a dye laser and/or a semiconductor laser.

Laser radiation is capable of ionizing neutral, resonant or non-resonant atoms or molecules. The atoms of each element have a unique set of excitation states allowing electrons to pass from the ground state by the absorption of one or more photons of close frequencies, provided that the corresponding selection rules are satisfied. . An excited atom decays to the ground state in an average time of about 10ns.

Lasers are sources of incident radiation on the fuel. The radiation is modified by diffusion as it passes through the fuel. When the fuel intercepts the laser beam from the laser unit 11, it generates a ray by reflection. The reflected signal is specifically specific and the reflected wavelength is different from the emitted beam. The reflected signal therefore contains information on the fuel, which allows remote physical and chemical analysis.

The fuel detection system 10 is configured to detect fluorescence induced by the laser beam at the intersection of hydrocarbons present in the fuel.

Thus, the system 10 makes it possible to obtain information on the presence, the type and the concentration of the fuel injected into the fuel tank.

Indeed, the spectral fluorescence signature characteristic of each type of fuel leads to its identification and characterization.

The radiation reflected by the mirror 12 is absorbed by the fuel and the fluorescent components of said fuel emit fluorescence radiation.

The fuel detection system 10 further comprises a detection module 14 of the type of fuel present in the tank.

The detection module 14 comprises an optical system 14a configured to receive the fluorescence radiation emitted by the fuel and to direct it towards a spectral unit 14b, a telescope corresponding to a part of the optical system 14a and a corresponding electronic detection and analysis module to the spectral unit 14b of the detection module 14.

The fuel detection system 10 further comprises an electronic control unit ECU 15 or computer configured to receive and analyze the information coming from the detection module 14 and an alert module 16 configured to emit an audible and/or visual alert. , for example comprising a light-emitting diode able to light up, in the event of detection of the wrong type of fuel.

In FIG. 2 is represented a second example of a fuel detection system 20 configured to detect the type of fuel injected into a supply pipe SA of a fuel tank of a motor vehicle (not represented), during fuel supply to said tank.

The fuel detection system 20 is located at the inlet of the filler pipe SA of the vehicle's fuel tank.

As shown, the fuel detection system 20 is configured to detect fluorescence induced by the laser beam at the intersection of hydrocarbons present in the fuel.

The fuel detection system 20 comprises a laser unit 21 configured to emit at least one light beam, a first mirror O1 configured to receive the light beam coming from the laser unit 21 and to reflect it towards a second mirror O2 and towards a optical detection system 22, such as for example a photodetector.

The second mirror O2 makes it possible to reflect the light beam towards the fuel tank, and in particular towards an analysis container RA located in the filling pipe SA of the fuel tank.

Without limitation, the laser unit 21 may comprise an excimer laser and/or a dye laser and/or a semiconductor laser.

The radiation reflected by the second mirror O2 is absorbed by the fuel present in the analysis vessel RA and the fluorescent components of said fuel emit fluorescence radiation.

The fuel detection system 20 further comprises a light-reflecting device RR, such as for example a reflector, located in the analysis container RA and configured to reflect the radiation emitted by the fuel and send it back to a detection module 25 of the type of fuel present in the tank.

The detection module 25 comprises a telescope 26 configured to receive the fluorescence radiation emitted by the fuel to direct it, via the two mirrors O1, O2, towards the optical system 22, such as for example a photodetector.

The fuel detection system 20 further comprises a module 23 for receiving and analyzing the signal emitted by the optical system 22 and an electronic control unit ECU 24 or computer configured to analyze the signal coming from the module 23 for receiving and signal analysis.

The fuel detection system 20 further comprises an alert module 27 configured to emit an audible and/or visual alert, for example comprising a light-emitting diode capable of lighting up, in the event of detection of the incorrect type of fuel.

As shown, the RA analysis vessel includes an OS drain port allowing fuel to drain to the fuel tank.

Alternatively, a multimode optical fiber or a thin conduit of plastic or quartz material could be used to transmit the laser beam from the laser unit 21 to the supply pipe SA of the fuel tank and to the optical system 22.

Thanks to the fuel type detection system according to the invention, the concentration and the type of fuel injected and/or present in the fuel tank of the motor vehicle are analyzed in real time and a warning can be given in the event of an incorrect type of fuel. .

Such a system is moreover easily adapted to any vehicle and makes it possible to effectively protect the internal combustion engine of the vehicle against operation with an unsuitable fuel.

Claims (11)

A fuel detection system (10, 20) configured to detect the type of fuel injected into a fuel tank (13, SA) of a motor vehicle, said system (10, 20) comprising a laser unit (11, 21) configured to emit at least one light beam, at least one reflection system (12, O1, O2) configured to receive the light beam from the laser unit (11, 21) and to reflect it towards the fuel tank (13 , SA), a detection and electronic analysis module (14, 25) of the fluorescence induced by the laser beam at the intersection of hydrocarbons present in the fuel present in the tank (13, SA) and an electronic unit (15, 24) configured to receive, analyze said induced fluorescence and determine, in real time, the type of fuel present in said tank (13, SA). A system (10, 20) according to claim 1, comprising an alert module (16, 27) configured to emit an audible and/or visual alert upon detection of the wrong type of fuel. System (10, 20) according to Claim 1 or 2, in which the fuel detection system (10, 20) is located at the inlet of the filler pipe (SA) of the fuel tank (13) of the vehicle. A system (10, 20) according to any preceding claim, wherein the laser unit (11, 21) comprises an excimer laser and/or a dye laser and/or a semiconductor laser. A system (10) according to any preceding claim, wherein the sensing module (14) includes an optical system (14a) configured to receive fluorescence radiation emitted from the fuel and to direct it to a spectral unit. System (20) according to any one of claims 1 to 4, comprising a first mirror (O1) configured to receive the light beam from the laser unit (21) and to reflect it towards a second mirror (O2) and towards the fuel, then to an optical detection system (22). System (20) according to Claim 6, in which the second mirror (O2) is configured to reflect the light beam coming from the first mirror (O1) towards an analysis container (RA) located in the filling pipe (SA) of the fuel tank. System (20) according to claim 7, further comprising a light reflecting device (RR) located in the analysis vessel (RA) and configured to reflect the radiation emitted by the fuel and return it to the detection module (25) the type of fuel. A system (20) according to any one of claims 6 to 8, wherein the detection module (25) comprises a telescope (26) configured to receive the fluorescence radiation emitted by the fuel to direct it, via the two mirrors ( O1, O2), to the optical detection system (22). System (20) according to any one of claims 6 to 9, comprising a module (23) for receiving and analyzing the signal emitted by the optical system (22) and configured to transmit said signal to the electronic control unit (24). Motor vehicle comprising a fuel tank (13, SA) and a fuel detection system (10, 20) according to any one of the preceding claims configured to detect the type of fuel injected into said tank (13, SA).