WO2020007517A1 - Method for analysing a fluid of a motor vehicle using an optical sensor - Google Patents

Abstract

The present invention concerns a method for analysing a fluid of a motor vehicle, using an optical sensor (100) comprising a Fabry-Pérot interferometer (10) for performing spectral analysis of a light beam, a voltage generator (20) and power storage units (31, 32, 33). The method comprises successive steps of charging the storage units (31, 32, 33), by the generator (20), and supplying power to the interferometer (10), by the storage units (31, 32, 33).

Description

 Method for analyzing a motor vehicle fluid from an optical sensor

 The present invention relates to the automotive field and relates more particularly to the analysis of the fuel of a motor vehicle.

 A motor vehicle conventionally comprises an engine supplied with fuel, such as a liquid hydrocarbon or natural gas.

 In order to optimize engine operation, the fuel is analyzed before being injected into the engine to determine its composition and quality. For this purpose, it is known to mount an optical sensor in the vehicle.

 As illustrated in FIG. 1, such an optical sensor 1 comprises a light source 2 emitting a light beam F and a spectrometer 3 analyzing the light beam F emitted by the light source 2. The fuel C to be analyzed circulates between the source of light 2 and the spectrometer 3 so that the light beam F crosses the fuel C and thus the spectrometer 3 analyzes the composition of the fuel C from the spectrometric study of the light beam F.

 The spectrometer 3 comprises a Fabry-Pérot interferometer 4 made up of two semi-reflecting mirrors 4 ’placed opposite one another. Such an interferometer 4 makes it possible to analyze only one wavelength of the light beam F at a time, this wavelength depending on the distance between the two mirrors 4 ’. In order to analyze the whole spectrum, it is known to modify the distance between these 4 ’mirrors. For this purpose, the supply voltage of the interferometer 4 is varied, which has the effect of varying the distance between the mirrors 4 ’. With reference to FIG. 2, the interferometer 4 is voltage-controlled by a microcontroller 5.

 However, such a sensor has drawbacks. In order to determine the composition and the quality of the fuel, a large number of wavelengths must be analyzed, which requires a large number of measurements and therefore turns out to be time-consuming. In known manner, the measurements are carried out for 76 wavelengths, which requires a delay of approximately 5 or 6 seconds. An obvious solution would be to limit the number of measurements, however, this would limit the results of such a fuel analysis.

In addition, to obtain precise measurements, the variation in electrical voltage supplying the interferometer 4 must be fine. For this purpose, still with reference to FIG. 2, a low-pass filter 6 is placed between the microcontroller 5 and the interferometer 4. This low-pass filter 6 makes it possible to store the electrical energy delivered by the microcontroller 5 and d 'supply the interferometer 4 when a sufficient quantity of energy has been stored, thus making it possible to deliver the desired voltage to the interferometer 4 with precision. However, the prior storage of electrical energy before each measurement in the low-pass filter 6 increases the time necessary to carry out a measurement and therefore the time necessary for the analysis of the fuel.

 There is therefore a need for a solution which makes it possible to remedy these drawbacks at least in part, and in particular a method making it possible to carry out spectrometric measurements on the fuel of a motor vehicle in a fast, reliable and efficient manner.

 To this end, the subject of the invention is a method for analyzing a fluid in a motor vehicle from an optical sensor, said optical sensor comprising:

 - a measurement cell capable of being traversed by the fluid to be analyzed,

 a light source capable of emitting a light beam through said measurement cell,

 a Fabry-Pérot interferometer capable of measuring at least one parameter of a light beam having passed through the measurement cell to perform the spectral analysis and thus determine the composition and / or the quality of the fluid,

 - a voltage generator,

 the method being remarkable in that, the optical sensor comprising at least a first electrical energy storage unit and a second electrical energy storage unit, it comprises:

 - a step of charging the first storage unit by the generator,

 - a step of charging the second storage unit by the generator,

 a step of supplying electrical power to the interferometer by the first storage unit at a first voltage in order to carry out a first analysis of the fluid at a first wavelength,

 a step of interrupting the electrical energy supply to the interferometer by the first storage unit, and

 a step of supplying electrical power to the interferometer by the second storage unit at a second voltage in order to carry out a second analysis of the fluid at a second wavelength.

The method according to the invention makes it possible to limit the time necessary for the analysis of the fluid by using a plurality of storage units delivering successively (ie one after the other) a voltage to the interferometer in order to perform the analysis of the fluid at several wavelengths. Thus, it is no longer necessary to wait for the reloading of a single storage unit between two successive measurements, as is the case in the prior art. The analysis of the fluid can thus be carried out continuously as long as at least one storage unit is capable of supplying the interferometer. Preferably, the fluid is a liquid fuel or a gas, for example natural gas.

 Preferably, all of the storage units are electrically charged prior to the supply of the interferometer by the first storage unit.

 The charge of the first storage unit corresponds to the storage of a first electrical charge in the first storage unit. Similarly, the charge of the second storage unit corresponds to the storage of a second electrical charge in the second storage unit.

 In a preferred embodiment, the first storage unit being, on the one hand, electrically connected to the generator by a first storage switching unit and, on the other hand, connected to the interferometer by a first switching unit d power supply, and the second storage unit being, on the one hand, electrically connected to the generator by a second storage switching unit and, on the other hand, connected to the interferometer by a second power switching unit, each of said first storage switch unit, said first power switch unit, said second storage switch unit, said second power switch unit being adapted to switch between an open state and a closed state , the method comprises:

 the second storage switching unit being in the open state, a substep for switching the first storage switching unit in the closed state in order to store a first electrical charge in the first storage unit,

 a substep for switching the first storage switching unit in the open state and switching the second storage switching unit in the closed state in order to store a second electrical charge in the second storage unit,

 the second power switching unit being in the open state, a substep for switching the first power switching unit in the closed state in order to deliver the first voltage to the interferometer, and

 o a substep of switching the first switching power supply unit in the open state and switching the second switching power supply unit in the closed state in order to deliver the second voltage to the interferometer.

Advantageously, the charging steps can be carried out prior to the start of the measurement phase in order to save the charging time, during a phase vehicle dead, preferably when switching on the light source or when switching on the sensor.

 Advantageously, the charging of the first storage unit can be carried out when the second storage unit supplies the interferometer so as to be able to carry out another measurement once the second storage unit is discharged.

 The number of storage units can be greater than two in order to increase the measurement rate and / or limit the analysis time of the fluid. For example, each storage unit may in particular correspond to each of the wavelengths at which a measurement must be made.

 Preferably, the electric generator is a voltage generator, preferably adapted to generate a pulse-modulated signal.

 The interferometer, in particular a tunable interferometer, is thus voltage-controlled by said pulse-modulated signal.

 Preferably, the pulse-modulated signal is of the PWM type in order to easily modify the voltage generated.

 The electrical charge stored in the first storage unit can be different from the electrical charge stored in the second storage unit in order to deliver different voltages to the interferometer, allowing analyzes of the fluid at different wavelengths.

 Preferably, the first storage unit and the second storage unit are each in the form of a capacitor. Such a capacitor thus fulfills the dual function of storing an electrical charge and filtering the PWM signal.

 More preferably, the first storage switching unit, the first power switching unit, the second storage switching unit and the second power switching unit are each in the form of a switch, which allows easy management of the charges and discharges of the first storage unit and the second storage unit.

 Advantageously, the charging step comprises substeps for switching each storage switching unit to the open state when the electrical charge is stored in each storage unit.

 Advantageously again, the supply step comprises substeps for switching each supply switching unit in the open state when the electrical charge has been delivered to the interferometer.

The invention also relates to an optical sensor for analyzing a fluid, said optical sensor comprising a measurement cell capable of being traversed by the fluid to be analyzed, a light source capable of emitting a light beam passing through said measurement cell , a Fabry-Pérot interferometer able to measure at least one parameter a light beam having passed through the measuring cell, a voltage generator, at least first and second electrical energy storage units, said optical sensor being able to control:

 - the charge of the first storage unit by the generator,

 - the load of the second storage unit by the generator

 the supply of electrical energy to the interferometer by the first storage unit at a first voltage in order to carry out a first analysis of the fluid at a first wavelength,

 the interruption of the electrical power supply to the interferometer by the first storage unit, and

 the electrical power supply to the interferometer by the second storage unit at a second voltage in order to carry out a second analysis of the fluid at a second wavelength.

 In a preferred embodiment, the first storage unit being, on the one hand, electrically connected to the generator by a first storage switching unit and, on the other hand, connected to the interferometer by a first switching unit d power supply, and the second storage unit being, on the one hand, electrically connected to the generator by a second storage switching unit and, on the other hand, connected to the interferometer by a second power switching unit, each of said first storage switch unit, said first power switch unit, said second storage switch unit, said second power switch unit being adapted to switch between an open state and a closed state .

 Preferably, the fluid is a gas, for example natural gas, or a liquid fuel.

 The invention further relates to a motor vehicle comprising an engine powered by a fluid, said vehicle comprising an optical sensor as presented above, for the analysis of said fluid.

 Other characteristics and advantages of the invention will become apparent from the following description given with reference to the appended figures given by way of nonlimiting examples and in which identical references are given to similar objects.

 FIG. 1 schematically represents an optical sensor according to the prior art (described above).

Figure 2 shows schematically the power supply of the interferometer of the sensor of Figure 1 (also described above). FIG. 3 schematically represents a partial embodiment of an optical sensor according to the invention.

 FIG. 4 schematically illustrates an analysis method from the sensor of FIG. 3.

 The method according to the invention is presented mainly for implementation in a motor vehicle. However, any implementation in a different context, in particular in any type of vehicle supplied with liquid or gaseous fuel is targeted by the invention.

 Referring to Figure 3, there is shown an optical sensor 100 for analyzing the fuel for supplying the engine of a motor vehicle.

 This optical sensor 100 includes a light source (not shown) configured to emit a light beam, a Fabry-Pérot interferometer 10 configured to perform the spectral analysis of the light beam, and a measurement cell (not shown) configured to be crossed by the fluid to be analyzed. The measurement cell is placed between the light source and the Fabry-Pérot interferometer 10 so that the light beam is able to pass through the fluid to be analyzed, in this case fuel. The fuel can be in gaseous form, in particular in the case of natural gas, or liquid, in particular in the case of diesel or gasoline. Fuel changes the spectral density of the light beam passing through it. Thus, the spectral analysis of the light beam makes it possible to determine different characteristics of the fuel, such as its composition, its quality, or its calorific value. These characteristics make it possible to optimize the settings for the operation of the engine and the pollution control system.

 The Fabry-Pérot interferometer 10 includes two semi-reflecting mirrors (not shown) placed opposite one another. The two mirrors are placed at a distance determined according to the wavelength to be analyzed. When using the optical sensor 100, the distance between the mirrors varies in order to analyze different wavelengths and thus determine the composition and quality of the fuel. Such an interferometer is designated a tunable interferometer, that is to say adaptable to a particular wavelength by modifying the distance between the two mirrors.

The interferometer 10 is configured to be supplied electrically at variable voltage in order to modify the distance between the mirrors. In other words, a given voltage value corresponding to a given distance between the mirrors, supplying the interferometer 10 with different voltage values makes it possible to carry out parameter measurements of the light beam at different distances from the mirrors and therefore at different lengths wave. As illustrated in FIG. 3, the optical sensor 100 further comprises a voltage generator 20 as well as a first storage unit 31, a second storage unit 32 and a third storage unit 33.

 In order to control the interferometer 10 at different voltage values, the optical sensor 100 also comprises a first storage switching unit 41, a second storage switching unit 42, a third storage switching unit 43, a first storage unit power switching 51, a second power switching unit 52 and a third power switching unit 53

 The voltage generator 20 is an electrical generator configured to deliver an electrical control voltage for the interferometer 10. According to one embodiment according to the invention, the voltage generator 20 is configured to deliver a width-modulated signal. impulse, PWM type for Puise Width Modulation in English. Such a signal makes it possible to vary the voltage delivered. The voltage variation is obtained after filtering the PWM signal in a low-pass filter of the optical sensor 100. Since such a voltage variation is known, it will not be described in more detail.

 The first storage unit 31, the second storage unit 32 and the third storage unit 33 are configured to store an electric charge in order to subsequently supply the interferometer 10 with voltage, the value of said voltage depending on the value of said electrical charge.

 In the embodiment illustrated in Figure 3, the first storage unit 31, the second storage unit 32 and the third storage unit 33 are each in the form of a capacitor. Such a capacitor also makes it possible to filter the PWM signal delivered by the generator 20.

 However, it goes without saying that the first storage unit 31, the second storage unit 32 and the third storage unit 33 could be in any other form making it possible to store an electric charge, in particular a filter, a battery, etc.

 The first storage unit 31, the second storage unit 32 and the third storage unit 33 are connected in parallel so that they can be controlled independently of each other. This makes it possible to store a different electrical charge in each of the first storage unit 31, of the second storage unit 32 and of the third storage unit 33 in order to power the interferometer 10 according to different voltage values and thus carry out measurements for different wavelengths.

In the embodiment illustrated in FIG. 3, three storage units are shown, however, it goes without saying that the optical sensor 100 could include two or more than three. For example, the optical sensor 100 could include as many storage units as there are wavelengths for which a measurement is to be made.

 The first storage unit 31 is electrically connected, on the one hand, to the generator 20 by the first storage switching unit 41 and, on the other hand, to the interferometer 10 by a first power switching unit 51.

 The second storage unit 32 is electrically connected, on the one hand, to the generator 20 by the second storage switching unit 42 and, on the other hand, to the interferometer 10 by the second power switching unit 52.

 The third storage unit 33 is electrically connected, on the one hand, to the generator 20 by the third storage switching unit 43 and, on the other hand, to the interferometer 10 by the third power switching unit 53.

 Each of said first storage switching unit 41, said first power switching unit 51, said second storage switching unit 42, said second power switching unit 52, said third power switching unit storage 43 and said third power switching unit 53 in the form of a switch able to switch between an open state and a closed state.

 With reference to FIG. 3, the optical sensor 100 can also comprise an impedance adapter 60 electrically connected to the interferometer 10 and to the power switching units 51, 52, 53. This adapter 60 makes it possible to avoid leaks current through the interferometer 10 so that the storage units 31, 32, 33 do not discharge. The electric charge stored in a storage unit 31, 32, 33 does not vary over time, which makes it possible to precisely deliver the desired voltage during a measurement. In the illustrated embodiment, the adapter 60 comprises an operational amplifier, preferably in follower mounting.

 An embodiment of the method according to the invention for analysis using an optical sensor will now be presented with reference to FIG. 4.

 During a dead phase of the vehicle, in particular when the light source is switched on or when the optical sensor 100 is energized, electrical charges are stored in turn in the first storage unit 31, the second storage unit 32 and the third storage unit 33.

During this storage step E1, the second storage switching unit 42 and the third storage switching unit 43 being in the open state, the first storage switching unit 41 is firstly switched to the state closed during a substep E1 1. The voltage generator 20 supplies the first storage unit 31 so as to store a first electrical charge in the first storage unit 31. When the load has been stored, the first storage switching unit 41 switches to the open state during a sub-step E12. The first storage unit 31 is thus isolated from the generator 20, which makes it possible to maintain the stored charge.

 Then, the first storage switching unit 41 and the third storage switching unit 43 being in the open state, the second storage switching unit 42 switches to the closed state during a substep E13. The generator 20 supplies the second storage unit 32 so as to store a second electrical charge in the second storage unit 32. When the charge has been stored, the second storage switching unit 42 switches to the open state when a sub-step E14. The second storage unit 32 is then also isolated from the generator 20, which makes it possible to maintain the stored charge.

 Then, the first storage switching unit 41 and the second storage switching unit 42 being in the open state, the third storage switching unit 43 switches to the closed state during a substep E15. The generator 20 supplies the third storage unit 33 so as to store a third electrical charge in the third storage unit 33. When the charge has been stored, the third storage switching unit 43 switches to the open state when a sub-step E16. The second storage unit 33 is then also isolated from the generator 20, which makes it possible to maintain the stored charge.

 These steps are carried out successively for each of the first storage unit 31, the second storage unit 32 and the third storage unit 33.

 When the first storage unit 31, the second storage unit 32 and the third storage unit 33 are electrically charged, it is then possible to carry out the measurements.

 The measurements can be carried out following the storage of the electrical charges or alternatively. The first storage unit 31, the second storage unit 32 and the third storage unit 33 thus make it possible to delay between the moment when the charges are stored and the moment when the measurements are carried out.

 To carry out the measurements, the interferometer 10 is supplied with electric voltage by the first storage unit 31, the second storage unit 32 and the third storage unit 33.

During this supply step E2, the first supply switching unit 51 switches to the closed state during a substep E21. The first storage unit 31 then delivers a first electrical voltage value, corresponding to the first electrical charge, in order to power the interferometer 10. The mirrors of the interferometer 10 move (if necessary) so that the distance between them separating corresponds to the value of the first electrical voltage delivered. An analytical measure fuel can then be produced for a first wavelength. When the measurement is made, the first power switching unit 51 switches to the open state during a substep E22. The first storage unit 31 is then discharged.

 Then, the second power switching unit 52 switches to the closed state during a substep E23. The second storage unit 32 then delivers a second value of electrical voltage, corresponding to the second electrical charge, in order to power the interferometer 10. The mirrors of the interferometer 10 move (if necessary) so that the distance between them separating corresponds to the value of the second electrical voltage delivered. A fuel analysis measurement can then be performed for a second wavelength. When the measurement is made, the second power switching unit 52 switches to the open state during a substep E24. The second storage unit 32 is then discharged.

 Then, the third power switching unit 53 switches to the closed state during a substep E25. The third storage unit 33 then delivers a third value of electrical voltage, corresponding to the third electrical charge, in order to power the interferometer 10. The mirrors of the interferometer 10 move (if necessary) so that the distance between them separating corresponds to the value of the third electrical voltage delivered. A fuel analysis measurement can then be performed for a third wavelength. When the measurement is made, the third power switching unit 53 switches to the open state during a substep E26. The third storage unit 33 is then discharged.

 These steps are carried out successively for each of the first storage unit 31, the second storage unit 32 and the third storage unit 33.

 The interferometer 10 is thus controlled according to different electrical voltages, which makes it possible to carry out measurements for different wavelengths. The time required to analyze the fuel according to the different wavelengths is thus optimized since it no longer depends on the loading time of a single storage unit as in the prior art.

 Advantageously, that or those of the first storage unit 31, the second storage unit 32 and the third storage unit 33 which are not in the process of supplying the interferometer 10 can be charged in turn by the generator 20 in order to optimize the measurement time at the different wavelengths.

Claims

 1. Method for analyzing a motor vehicle fluid from an optical sensor (100), said optical sensor (100) comprising:  - a measurement cell capable of being traversed by the fluid to be analyzed,  a light source capable of emitting a light beam through said measurement cell,  a Fabry-Pérot interferometer (10) capable of measuring at least one parameter of a light beam having passed through the measurement cell in order to carry out the spectral analysis and thus determine the composition and / or the quality of the fluid ,  - a voltage generator (20),  the method being characterized in that, the optical sensor (100) comprising at least a first storage unit (31) of electrical energy and a second storage unit (32) of electrical energy, it comprises:  a step (E1 1) of charging the first storage unit (31) by the generator (20)  - a step (E13) of charging the second storage unit (32) by the generator (20)  a step (E21) of supplying electrical energy to the interferometer (10) by the first storage unit (31) at a first voltage in order to carry out a first analysis of the fluid at a first wavelength,  a step (E22) of interrupting the supply of electrical energy to the interferometer (10) by the first storage unit (31), and  a step (E23) of supplying electrical energy to the interferometer (10) by the second storage unit (32) at a second voltage in order to carry out a second analysis of the fluid at a second wavelength.  2. Method according to claim 1, in which all of the storage units (31, 32, 33) are electrically charged prior to the supply of the interferometer (10) by the first storage unit (31). 3. Method according to one of the preceding claims, in which the first storage unit (31) being, on the one hand, electrically connected to the generator (20) by a first storage switching unit (41) and, d on the other hand, connected to the interferometer (10) by a first power switching unit (51), and the second storage unit (32) being, on the one hand, electrically connected to the generator (20) by a second storage switching unit (42) and, on the other hand, connected to the interferometer (10) by a second supply switching unit (52), each of said first storage unit storage switching (41), said first power switching unit (51), said second storage switching unit (42), said second power switching unit (52) being adapted to switch between a open state and closed state, the method comprises:  the second storage switching unit (42) being in the open state, a substep (E1 1) for switching the first storage switching unit (41) in the closed state in order to store a first charge electric in the first storage unit (31),  a substep (E12) of switching the first storage switching unit (41) to the open state and switching (E13) of the second storage switching unit (42) to the closed state in order to storing a second electrical charge in the second storage unit (32),  the second power switching unit (52) being in the open state, a substep (E21) of switching the first power switching unit (51) in the closed state in order to deliver the first voltage at the interferometer (10), and  a substep (E22) of switching the first power switching unit (51) to the open state and switching (E23) of the second power switching unit (52) to the closed state in order to deliver the second voltage to the interferometer (10).  4. Method according to one of the preceding claims, in which the electric generator (20) is a voltage generator, preferably adapted to generate a pulse-modulated signal.  5. Method according to one of the preceding claims, wherein the first storage unit (31) and the second storage unit (32) are each in the form of a capacitor.  6. Method according to one of the preceding claims, in which the first storage switching unit (41), the first power switching unit (51), the second storage switching unit (42) and the second unit switching switches (52) are each in the form of a switch. 7. Method according to one of the preceding claims, comprising sub-steps for switching (E12, E14, E16) of each storage switching unit (41, 42, 43) in the open state when the electric charge is stored. in each storage unit (31, 32, 33). 8. Method according to one of the preceding claims, comprising switching sub-steps (E22, E24, E26) of each supply switching unit (51, 52, 53) in the open state when the electric charge has was delivered to the interferometer (10). 9. An optical sensor (100) for analyzing a fluid, said optical sensor (100) comprising a measurement cell capable of being traversed by the fluid to be analyzed, a light source capable of emitting a light beam passing through said cell measurement, a Fabry-Pérot interferometer (10) capable of measuring at least one parameter of a light beam having passed through the measurement cell, a voltage generator (20), at least first and second storage units ( 31, 32) of electrical energy, said optical sensor (100) being able to control:  - the charge of the first storage unit (31) by the generator (20),  - the load of the second storage unit (32) by the generator (20),  the electrical energy supply to the interferometer (10) by the first storage unit (31) at a first voltage in order to carry out a first analysis of the fluid at a first wavelength,  the interruption of the electrical energy supply to the interferometer (10) by the first storage unit (31), and  the supply of electrical energy to the interferometer (10) by the second storage unit (32) at a second voltage in order to carry out a second analysis of the fluid at a second wavelength.  10. Motor vehicle comprising an engine powered by a fluid, said vehicle comprising an optical sensor (100) according to claim 9, for the analysis of said fluid.