The present invention relates to the field of systems for storing and pressurizing/supplying a fluid. In particular, such systems are used for various purposes in personal motor vehicles, heavy trucks, agricultural machines, or still in construction equipments and machines.
In particular, the invention concerns means for measuring a level of fluid in such systems, for example a level of an aqueous urea solution (a trade name of which is AdBlue®), in a storage system for catalytic converters of combustion engines.
The catalysts using the principle of selective catalytic reduction in order to reduce the emissions of nitrogen oxides (NOx), generally comprise a storage system adapted to contain a fluid mainly composed of urea and water (a trade name of which is AdBlue®). When the catalyst is in active operation, the fluid is brought into contact with the gases resulting from the combustion of fuel in the engine of the vehicle, so as to enable the transformation of the nitrogen oxides into nitrogen and water.
It is desirable to have reliable means for measuring a level of a fluid in the storage system, for example in order to provide the information necessary to a gauge capable of indicating the current fluid level in the pressurized storage system and generating an alert when this level turns out to be insufficient to guarantee the proper operation of the catalyst.
Various solutions are nowadays implemented in an attempt to provide measuring solutions. Thus, it is known to use mechanical devices, for example floats, introduced in the enclosure of the storage system containing the fluid. The reliability of the information produced by these mechanical measurement devices is limited by the sensitivity to dispersions of the fluid. Furthermore, in the case where the fluid has frozen—the aqueous urea solutions freeze at about −11° C.—, the mechanical devices are inoperative, because of the immobility imposed on the floats. Finally, the mechanical devices are generally bulky.
It is also known to use measuring devices including an ultrasonic source such as a ceramic capsule or a piezoelectric component. Nonetheless, besides the impossibility of obtaining a measurement of the fluid level in the case where the latter has frozen, the cost of this solution turns out to be high.
Another solution consists in using a level measuring device based on the measurement of the variations of the electrical capacitance. There are devices in contact with the fluid including a measuring circuit—typically an integrated circuit—, provided with a capacitive sensor, inserted in a protective sheath which is in turn plunged in the storage system. In order to ensure the capacitive coupling between the sensor and the liquid, throughout the sheath, a capacitive transmission element, for example a gel, is required. Hence, this solution turns out to be difficult to produce because, besides the complexity of the assembly, it is necessary that the walls of the sheath have a small thickness in order to enable the measurement of the capacitance, and made of a materiel adapted both to the immersion in an aqueous urea solution and to the measurement of the capacitance throughout said walls. Finally, these devices require arranging a sealing for separating the wet area from the dry area, at the interface between the tank and the measuring device.
Hence, there is still a need for alternative means for measuring a level of fluid, in a fluid storage system, which do not require the use of additional elements in contact with said fluid, while remaining reliable and inexpensive to produce and to implement.
One of the objects of the invention is to provide effective means for determining a level of fluid, in a fluid storage system, which do not require the use of additional elements in contact with said fluid, while remaining reliable and inexpensive to produce and to implement. Another object of the invention is to enable the determination of a level of fluid comprised in a container the walls of which are made from thermoplastics—for example, high-density polyethylene, polyethylene, polypropylene or polyoxymethylene—have a thickness substantially smaller than or equal to 5 mm, and throughout an air gap the thickness of which may reach substantially 3 mm. Another object of the invention is to enable the determination of a level of fluid comprised in a container, nonetheless without requiring the use of a conductivity gel between the wall of the container and the measuring means. Another object of the invention is to provide means which do not require the use of elements the manufacture and the assembly of which turn out to be complex, such as for example the sheaths used in the devices of the prior art for containing sensors. Another object of the invention is to provide means for measuring a level of fluid in a container adapted to be disposed out of said container, without any contact with the fluid, and without any contact with the container.
One or several of these objects is/are achieved by the level measuring device, the kits and the level measuring method according to the independent claims. The dependent claims further provide solutions to these objects and/or other advantages.
More particularly, according to a first aspect, the invention relates to a measuring device intended to cooperate with a tank capable of containing a fluid. The device is adapted to determine a level n of the fluid, along a vertical axis NM of said tank. The device includes:
at least one sensor including a capacitive element electrically coupled to an oscillator configured to deliver a signal Si whose frequency FiPAD is a function of the capacitance of the capacitive element; said at least one sensor being intended to be disposed outside of the tank, so that the capacitance of the capacitive element varies based on the level n of the fluid, when said level is comprised between a first threshold hi-min and a second threshold hi-max;
a processing module, coupled to said at least one sensor, and configured to determine the level n of fluid in the tank based on the frequency of the signal Si.
The processing module may be configured to determine the level n of fluid in the tank based on the frequency of the signal Si and on a reference frequency FiVCO proper to said at least one sensor.
The processing module may be configured to determine the reference frequency FiVCO, in an initial calibration phase, and/or periodically—for example every week—, and/or upon the occurrence of an event, for example after identifying potential errors of measurement, and/or upon receipt of a command, for example from a user via a user interface or from another system. Furthermore, such an operation allows calibrating the measuring device, throughout its entire service life, in order to compensate the potential drift of the electronic components and the ageing/deformations of the tank. The reference frequency FiVCO may be equal to the frequency of the signal Si delivered by the oscillator of said at least one sensor when the level of the fluid is lower than the threshold hi-min.
In one embodiment, the processing module is coupled to an external module:
by a communication module, capable of enabling a transmission of the level n of fluid in the tank to the external module; and/or
by a power-supply module, capable of enabling a transmission of energy from the external module to said at least one sensor.
Typically the external module may be a motherboard.
In one embodiment, the processing module includes a diagnosis module configured:
when the fluid level n determined by the processing module is lower than the first threshold hi-min, to identify a dysfunction if the difference between the frequency FiPAD of the signal Si and a first reference frequency is substantially non-zero;
when the fluid level n determined by the processing module is higher than the second threshold hi-max, to identify a dysfunction if the difference between the frequency FiPAD of the signal Si and a second reference frequency is substantially non-zero.
The first reference frequency may be equal to the frequency of the signal Si delivered by the oscillator of said at least one sensor when the level of the fluid is lower than the threshold hi-min, for example when the tank is empty. The first reference frequency may be determined during a calibration phase by measuring the frequency of the signal Si or it may be predetermined. The second reference frequency may be equal to the frequency of the signal Si delivered by the oscillator of said at least one sensor when the level of the fluid is higher than the second threshold hi-max, for example when the tank is full of fluid. The second reference frequency may be determined during a calibration phase by measuring the frequency of the signal Si or it may be predetermined.
In one embodiment, the processing module includes:
a voltage-controlled reference oscillator configured to produce a signal whose frequency FiVCO varies based on a control signal;
a microprocessor configured to generate and deliver to the reference oscillator the control signal so that the frequency FiVCO of the signal produced by the reference oscillator substantially corresponds to the reference frequency proper to said at least one sensor;
a phase-locked loop configured to generate an output signal Δi based on the difference between the frequency FiPAD of the signal Si delivered by said at least one sensor and the reference frequency FiVCO;
an output filter, coupled to the output of the phase-locked loop, adapted to convert the phase-shift signal Δi into an output voltage Ui;
a conversion module configured to determine the level n based on the output voltage Ui.
The processing module may include a diagnosis module configured:
when the fluid level n determined by the conversion module is lower than the first threshold hi-min, to identify a dysfunction if the difference between the output voltage Ui and a first reference voltage UDEC is substantially non-zero;
when the fluid level n determined by the conversion module is higher than the second threshold hi-max, to identify a dysfunction if the difference between the output voltage Ui and a second reference voltage UREC is substantially non-zero.
The first reference voltage UDEC may be equal to the voltage Ui measured for the ith sensor when the fluid level n determined by the conversion module is lower than the first threshold hi-min, for example when the tank is empty. The first reference voltage UDEC may be determined during a calibration phase by measuring the voltage Ui for the ith sensor or it may be predetermined. The second reference voltage UREC may be equal to the voltage Ui measured for the ith sensor when the fluid level n determined by the conversion module is higher than the second threshold hi-max, for example when the tank is full. The second reference voltage UREC may be determined during a calibration phase by measuring the voltage U, for the ith sensor or it may be predetermined.
The measuring device may further include at least one second sensor including a second capacitive element electrically coupled to a second oscillator configured to deliver a second signal whose frequency is a function of the capacitance of the second capacitive element. Said at least one second sensor is intended to be disposed outside of the tank, so that the capacitance of the second capacitive element varies based on the level n of the fluid, when said level is comprised between a third threshold hi-min and a fourth threshold hi-max. The processing module is coupled to said at least one second sensor, and is configured to determine the level n of fluid in the tank based on the frequency of the signal Si of said at least one first sensor and on the frequency of the signal Si of said at least one second sensor. In one embodiment, the range of values defined by the third threshold and the fourth threshold is disjoint from the range of values defined by the first threshold and the second threshold. Thus, it is possible to cover the case where it is necessary to know the level n only when the latter is close to some values, for example only when the level n is comprised between 0 and 5 cm and between 15 and 20 cm. The third threshold may be lower than the second threshold. When the third threshold is lower than the second threshold, the processing module may include a diagnosis module configured, when the fluid level n determined by the conversion module is comprised between the third threshold and the second threshold, to identify a dysfunction if the absolute value of the difference between, on the one hand, the fluid level n determined by the processing module from the signal Si of said at least one second sensor and, on the other hand, the fluid level n determined by the processing module from the signal Si of said at least one sensor is higher than a permissible deviation. For example, the permissible deviation may be chosen and/or configured based on the measurement accuracy, whether theoretical or measured during a calibration step, for each sensor.
According to a second aspect, the invention relates to a kit including a measuring device according to the first aspect and a tank intended to be assembled so that a space is arranged between the surface of the capacitive element of said at least one sensor and the wall of the tank. The kit may also include an aqueous urea solution intended to be contained in the tank. The tank may also be intended to contain other types of fluids, for example a fuel, a combustible, a coolant, a cleaning liquid, a lubricant, a heat-transfer liquid, etc.
According to a third aspect, the invention relates to a kit including a measuring device according to the first aspect, and an external module, for example a motherboard, configured to receive the level n of the fluid in the tank and/or to enable a transmission of energy to said at least one sensor.
According to a fourth aspect, the invention relates to a method for measuring a level n of fluid contained in a tank, along a vertical axis NM of said tank. The method is adapted in particular to be implemented by the device according to the first aspect. The method includes the following steps of:
collecting at least one signal Si delivered by a sensor, the sensor including a capacitive element electrically coupled to an oscillator configured to deliver a signal Si whose frequency FiPAD is a function of the capacitance of the capacitive element; said at least one sensor being intended to be disposed outside of the tank, so that the capacitance of the capacitive element varies based on the level n of the fluid, when said level is comprised between a first threshold hi-min and a second threshold hi-max;
calculating the difference between the frequency of the signal Si and a reference frequency FiVCO;
determining the level n of fluid in the tank based on the frequency of the signal Si.
The method may also include the following steps of:
when the determined fluid level n is lower than the first threshold hi-min, identifying a dysfunction if the difference between the frequency FiPAD of the signal Si and a first reference frequency is substantially non-zero;
when the determined fluid level n is higher than the second threshold hi-max, identifying a dysfunction if the difference between the frequency FiPAD of the signal Si and a second reference frequency is substantially non-zero.
In one embodiment, at least one second signal Si delivered by a second sensor is collected. The second sensor includes a capacitive element electrically coupled to an oscillator configured to deliver a second signal Si whose frequency FiPAD is a function of the capacitance of the capacitive element. Said at least one second sensor is intended to be disposed outside of the tank, so that the capacitance of the capacitive element varies based on the level n of the fluid, when said level is comprised between a third threshold hi-min and a fourth threshold hi-max. The third threshold is lower than the second threshold. The level n of fluid in the tank is determined based on the frequency of the signal Si of said at least one sensor and on the frequency of the signal Si of said at least one second sensor. When the fluid level n determined during the fluid level n determination step is comprised between the third threshold and the second threshold, the method further includes the following step of:
identifying a dysfunction if the absolute value of the difference between, on the one hand, the fluid level n determined from the signal S, of said at least one second sensor and, on the other hand, the fluid level n determined from the signal S, of said at least one sensor, is higher than a permissible deviation.
Other particularities and advantages of the present invention will appear, in the description of embodiments hereinafter, with reference to the appended drawings, in which:
Referring to
The measuring device includes a detection circuit 10—typically an electronic board—on which a number of sensors 12 is arranged. The number nc is chosen based on the variations of the level n which are likely to be measured as well as on the desired accuracy. In the example illustrated in
In one embodiment, illustrated in
The ranges do not necessarily cover all the possible level values, but may cover only a critical area. For example, it may be provided to measure the value of the level only if the latter is higher than or equal to 10 cm.
Alternatively, each sensor 12 may be disposed so that the ranges Pi are substantially adjacent.
Alternatively, each sensor 12 may also be disposed so that the ranges Pi are disjoint, in particular if it is not necessary to measure the value of the level n for some ranges of values. For example, this case may be encountered when it is necessary to know the level n only when the latter is close to some values, for example, only when the level n is comprised between 0 and 5 cm and between 15 and 20 cm.
The detection circuit 10 further includes a processing module 14, coupled to the sensors 12, and configured to collect the signals Si. The detection circuit 10, and in particular the processing module 14 thereof, are adapted to be coupled to a motherboard 16 via a communication module 18. The motherboard 16 is external to the measuring device, and may be for example shared with other external devices. In particular, the communication module 18 is configured to establish a data link between the motherboard 16 and the processing module 14 of the detection circuit 10. It is then possible to transmit the value of the level n and/or the nc levels ni as measured by each sensor 12 and determined by the processing module 14 to the motherboard 16. The detection circuit 10 also includes a power-supply module 20 configured to receive energy from the motherboard 16 and power the components of the detection circuit 10. The power-supply module 20 may include wired means for transmitting the energy.
In an advantageous embodiment, represented in
As illustrated in
In one embodiment, each oscillator 40 is formed by an inverting logic gate with a Schmitt trigger input, thereby allowing producing a signal Si whose frequency presents a good stability, whose variation is typically lower than 0.05% Hz/° C. In the present application, each oscillator 40 presents an input capacitance whose value is substantially lower than or equal to 5 pF and a bandwidth substantially higher than 5 MHz. Depending on the cost of the electronic components and the available space, it is possible to choose the components of the oscillator 40 among the following non-exhaustive list: transistor(s) oscillators, operational Amplifier oscillators, Colpitts oscillators, Clapp oscillators, Hartley oscillators, Quartz oscillators, Wien bridge oscillators, logic gate oscillators. Typically, the components chosen for the oscillators 40 present the following characteristics: a high immunity to noise, a very low input capacitance, a high input resistance. Hence, the sensors 12 may be assembled using very low-cost components.
As represented in
A space 1 between the surface of the sensors 12 and the wall of the tank 2 facing the sensors is arranged, so as to form an air gap. For an optimum operation, in the case of a tank whose walls are made of a thermoplastic material—for example, high-density polyethylene, polyethylene, polypropylene or polyoxymethylene—and whose thickness e is substantially smaller than or equal to 5 mm, the space 1 of the air gap should be substantially smaller than or equal to 3 mm.
Referring in particular to
Referring to
The processing module 14 includes a phase-locked loop 58, generally referred to by the acronym “PLL” standing for “Phase-Locked Loop”, activated by the microprocessor 50. The microprocessor 50 is provided with a selector module 52. The selector module 52 allows coupling, successively, the output of the oscillator 40 of each of the different sensors 12 to the phase-locked loop 58. In the following description, the signal Si, selected at a given instant t, by the selector module 52 is referred to as SiPAD. The frequency of the signal Si selected at a given instant t, by the selector module 52 is referred to as FiPAD.
The processing module 14 includes a voltage-controlled oscillator 54, acting as a reference oscillator, capable of producing a signal at a variable frequency, based on a control signal generated by a generator 56. The voltage-controlled oscillator 54 is coupled to the phase-locked loop 58. The generator 56 may be a pulse width modulated signal generator—more generally referred to by the acronym “PWM” standing for (“Pulse Width Modulation”), driven by the microprocessor 50. The generator 56 may be a digital-to-analog converter, driven by the microprocessor 50, to produce the control signal. The control signal is then converted into a voltage by a RC filter 59. The frequency FiVCO of the signal produced by the voltage-controlled oscillator 54 is predetermined for each of the sensors 12, during a calibration phase, in the absence of fluid 1 in the tank 2. Thus, the microprocessor 50 is configured to drive the generator 56 so that the voltage-controlled oscillator 54 delivers a signal whose frequency FiVCO corresponds to the frequency FiCAL predetermined during the calibration phase for the oscillator 40 currently selected by the selector module 52.
The phase-locked loop 58 is configured to generate an output signal Δi, based on the difference between the frequency FiPAD of the signal SiPAD currently selected by the selector module 52 and the frequency FiVCO of the signal produced by the voltage-controlled oscillator 54. Hence, the output signal Δi is a function of the difference FiVCO−FiPAD. The two frequencies FiVCO, FiPAD being sufficiently close to each other, the output signal Δi corresponds to a phase-shift signal (a duty cycle, in the digital field), and may therefore be converted into a voltage Ui by an output RC filter 60 coupled to the output of the phase-locked phase 58. Afterwards, the voltage Ui is digitized by the microprocessor 50 using an analog-to-digital converter 62.
Using the selector module 52, the microprocessor 50 successively reads the value of the voltage Ui for each sensor 12 of the detection circuit 10 and stores the corresponding values.
The microprocessor 50 also includes a conversion module 63 adapted to convert voltages Ui collected for each sensor 12 into a level n of the fluid in the tank 2. An example of tables for converting the voltages Ui into a level n is given in the diagrams of
Referring now to
collecting S110 at least one signal Si delivered by a sensor, the sensor including a capacitive element electrically coupled to an oscillator configured to deliver a signal Si whose frequency FiPAD is a function of the capacitance of the capacitive element; said at least one sensor being intended to be disposed outside of the tank, so that the capacitance of the capacitive element varies based on the level n of the fluid, when said level is comprised between a first threshold hi-min and a second threshold hi-max;
calculating S120 the difference between the frequency of the signal Si and a reference signal FiVCO;
determining S130 the level n of fluid in the tank based on the frequency of the signal Si
Referring in particular to
In one embodiment, the processing module 14 includes at least one reference sensor 65, delivering a signal SREF, adapted to enable the detection of variations of the environment which are likely to affect the sensors 12. The reference sensor 65 may include for example the same elements as the other sensors 12, but will be disposed on the detection circuit 10 so that the variations of the level n do not affect its capacitive element. The microprocessor is then coupled to the reference sensor 65 so as to receive the signal SREF and is configured to correct the signals Si based on the variations of the frequency of the signal SREF, by acting on each FiVCO of each sensor 12.
In one embodiment, the processing module 14 includes at least one temperature sensor 66 adapted to deliver a voltage UTEMP based on the temperature of the environment of the sensors 12. The microprocessor 50 is then coupled to the temperature sensor 66 so as to receive the signal UTEMP and is configured to correct the signals Si based on the temperatures observed by the temperature sensor 66.
In one embodiment, the processing module 14 includes a diagnosis module 70. As illustrated in
Referring in particular to
The steps described hereinafter apply when the fluid 1 is in a liquid state in the tank 2: thus, the method may include an optional step (not represented in
During a first step S210, it is determined whether the level n, obtained upon completion of step S130, is comprised in one of the overlapping ranges Ri of two adjacent sensors 12.
If the level n is comprised in one of the overlapping ranges an error determination step S220 is implemented. Such case is illustrated by
DIFFTABLE=|U3-TABLE−U4-TABLE|
The expected value U3-TABLE and the expected value U4-TABLE may be determined by reading, for the level n, the value corresponding to each sensor in the same conversion tables used by the conversion module 63 to determine the level n. Thus, the difference DIFFTABLE corresponds to the expected deviation, for the level n, according to the conversion tables, between the voltages U3 and U4. In the example of
During step S220, there is determined the difference DIFFMES in absolute value between, on the one hand, the value of the voltage U3 measured for the 3rd sensor and, on the other hand, the value of the voltage U4 measured for the 4th sensor:
DIFFMES=|U3−U4|
Thus, the difference DIFFMES corresponds to the deviation actually measured by the measuring device, between the voltages U3 and U4.
During step S220, a permissible deviation 6 is determined or obtained. For example, the permissible deviation 6 may be chosen and/or configured to be substantially equal to the measurement accuracy, whether theoretical or measured during a calibration step, for each sensor 12. During step S220, there is then determined whether the absolute value of the difference between, on the one hand, the difference DIFFMES and, on the other hand, the difference DIFFTABLE, is lower than twice the permissible deviation, namely:
|DIFFMES−DIFFTABLE|<2.δ
If so, the measured level n is considered to be valid. If not, the measured level n is considered to be potentially unreliable, so that an alert may then be transmitted to the external module, for example the motherboard 16, to indicate a potential dysfunction of the measuring device.
If, during the first step S210, it has been determined that, the level n, obtained upon completion of step S130, is located outside of the overlapping ranges Ri of two adjacent sensors 12, an upstream error determination step S230 and a downstream error determination step S240 are implemented. Such a case is illustrated by
During the upstream error determination step S230, there is determined an expected voltage UDEC corresponding to the voltage Ui expected when the level n is lower than the lower bound hi-min of the corresponding range Pi. The expected voltage UDEC may be determined by reading, when the level n is lower than the lower bound hi-min of the range Pi, the corresponding value in the same conversion tables used by the conversion module 63 to determine the level n. The voltage UDEC may also be determined during a calibration step, in the absence of fluid 1 in the tank 2. In the example of
During step S230, for each sensor whose lower bound hi-min of the measuring range Pi is higher than the level n, the voltage Ui measured for each of said sensors is compared to the expected voltage UDEC. Thus, in the example of
If so, the signals Si of each sensor whose lower bound hi-min of the range Pi is higher than the level n, are considered to be valid. If not, the signals Si of the sensors whose lower bound hi-min of the range Pi is higher than the level n, and for which the difference between the voltage Ui and the expected voltage UDEC is substantially non-zero, are considered to be potentially unreliable, and an alert may then be transmitted to the external module, for example the motherboard 16, to indicate a potential dysfunction of the corresponding sensors.
During the downstream error determination step S240, there is determined the expected voltage UREC corresponding to the voltage Ui when the level n is higher than the upper bound hi-max of the corresponding range Pi. The expected voltage UREC may be determined by reading, when the level n is higher than the upper bound hi-max of the corresponding range Pi, the corresponding value in the same conversion tables used by the conversion module 63 to determine the level n. The voltage UREC may also be determined during a calibration step, the tank being completely filled with fluid 1. In the example of
If so, the signals Si of each sensor whose upper bound hi-max of the measuring range Pi is lower than the level n, are considered to be valid. If not, the signals Si of the sensors whose upper bound hi-max of the measuring range Pi is lower than the level n, and for which the difference between the voltage Ui and the expected voltage UREC is substantially non-zero, are considered to be potentially unreliable, and an alert may then be transmitted to the external module, for example the motherboard 16, to indicate a potential dysfunction of the corresponding sensors.
If, during steps S230 and S240, the signals Si of each sensor whose upper bound of the measuring range Pi is lower than the level n, and the signals Si of each sensor whose lower bound hi-min of the range Pi is higher than the level n, are considered to be valid, then the level n determined by the measuring device is considered to be valid. This information may be transmitted to the external module, for example the motherboard 16. Otherwise, the level n determined by the measuring device is considered to be potentially unreliable, and an alert may then be transmitted to the external module, for example the motherboard 16, to indicate a potential dysfunction of the measuring device.
Number | Date | Country | Kind |
---|---|---|---|
15/57947 | Aug 2015 | FR | national |