The present invention relates to the field of leak detection systems and methods for checking the tightness of an object, more particularly based on the measurement of a physical quantity relating to a level of leak.
There are various systems and methods for detecting leaks, but in this case, the invention relates more particularly to leak detection by pressure variation. When it is desired to detect a leak by pressure variation, the object to be tested, so whose level of tightness is to be checked, undergoes a controlled pressure variation, that is, a known pressure variation is applied to an internal space of the object (called the direct method) or to a closed space surrounding said object (called the indirect method). Then, after a certain time, the pressure in the space that has undergone said pressure variation is measured again. If the object has a leak, then the measured pressure is different from the initial pressure.
A pressure variation is generally measured for a given time to allow the determination of a level of leak relating to the object. Indeed, the pressure variation per unit of time can be related to a level of leak by the following mathematical relationship:
in which, F is the leak generally expressed in cubic centimetres per minute (or cm3/min), ΔP is the pressure variation in Pascal (Pa) measured in the space, Δt is the time interval (in seconds) of the measured pressure variation ΔP, V is the relevant space to be considered (for example the internal space of the object) generally expressed in cubic centimetres (cm3), and k is a multiplying constant (in Pa−1).
Thus, regardless of the object or a sub-element of the object, it is possible to check the latter for leaks and determine its level of tightness.
The object to be tested may be an electronic device, a package, a container, etc. The tolerances on the level of tightness can therefore be highly variable with regard to the object to be tested, its space, its shape, its function, etc.
However, when the level of leak to be determined is relatively small compared to the space of the object to be tested, the environmental parameters can make it difficult to measure the pressure variation and/or its repeatability.
Indeed, the value of the pressure variation relating to the leak then has an order of magnitude close to the pressure variations of the environment (generally atmospheric pressure), and it is therefore particularly difficult to obtain reliable leak measurements and to distinguish a pressure variation related to a leak from a variation related to the environment.
This problem is all the more pronounced when leak detection is performed in a factory, that is, in an industrial environment where temperature and pressure may vary locally and/or over time depending on the operations carried out on the objects to be tested or in the vicinity of said leak detection system.
The present invention finds advantageous application in the field of leak detection for electric batteries for automobile electric vehicles, but also for any object with similar problems.
Indeed, an automotive electric battery is thus generally comprised of several modules housed in a casing which is equipped with a cooling system, an electronic management card, etc.
This type of battery can have a large space, in the order of 100 to 150 litres (or cubic decimetres), and has to meet strict tightness criteria, as the presence of water in such an object can be catastrophic. The level of leak of a battery therefore has to be small and checking of such leaks is therefore performed in an order of magnitude close to the temperature variations and/or pressure of the battery's environment. In addition, batteries are electrically and mechanically tested before they are installed in a vehicle. Batteries therefore undergo thermal and mechanical stresses that can affect a subsequent tightness checking.
Research and tests have therefore been carried out by the patent holder to provide a leak detection method and system with improved sensitivity and enabling better repeatability in leak detection, while improving the level of detectability of said leaks.
The invention is thus a new leak detection system for checking the tightness of an object, said system comprising:
According to a possible characteristic, the pressure variations ΔP in said space are corrected according to the pressure variations ΔPext of the environment. The correction of the pressure variations of said space make it possible to obtain a leak value that approaches the real value of the leak of the tested object.
According to another possible characteristic, the first and/or second pressure sensors are differential pressure sensors.
The use of differential pressure sensors has the advantages of being able to measure smaller pressure variations and to eliminate measurement errors related to the mechanical and/or thermal behaviour of the tested object.
According to another possible characteristic, the electronic entity and said first and second sensors make it possible to generate, over the test time interval ttest:
According to another possible characteristic, the electronic entity (15) determines the level of leak F′ of the tested object based on a corrected pressure variation ΔP′, said corrected pressure variation ΔP′ being calculated as follows:
F′=C
1
ΔP′=C1(ΔP−kSΔPext)
where kS is a normalisation coefficient specific to the first and second sensors and C1 is a constant depending on the time and space of the tested object.
According to another possible characteristic, the normalisation coefficient kS is determined based on the curve of the pressure variations ΔP in said space and the curve of the pressure variations ΔPext of the environment, or prior to said measurement of the pressure variation ΔP in said space and the measurement of the pressure variation ΔPext of the environment, the value of the normalisation coefficient kS being stored in a memory of the electronic entity.
According to another possible characteristic, the system comprises a third pressure sensor configured to measure the pressure in the pressurised space. According to one aspect, the third sensor may for example be an absolute pressure sensor.
According to another possible characteristic, said electronic entity determines an average temperature variation per unit of time of the object via at least one sensor, said average temperature variation being also used to determine the leak so depending on the pressure variations in the pressurised space and the pressure variations of the environment.
Indeed, if the tested object is not in thermal equilibrium with its environment, the fact that it senses or transfers heat changes the temperature of the space and thus varies the pressure in said space.
According to another possible characteristic, the electronic entity is configured to determine, via the second or third sensor, the average temperature variation of the pressurised space and/or the tested object.
According to another possible characteristic, said electronic entity determines, via at least one sensor, a pressure variation ΔTP related to the average temperature variation of the object per unit of time, said pressure variation ΔTP being also used to determine the leak F″ of the tested object depending on the pressure variations ΔP in the pressurised space and the pressure variations ΔPext of the environment.
According to another possible characteristic, the electronic entity determines the level of leak F″ of the tested object depending on the following formula:
F″=C
1
ΔP″=C
1(ΔP−kSΔPext−ΔTP)
where ΔP″ is the corrected pressure variation of the tested object, ΔTP is the pressure variation depending on the average temperature variation of the tested object during the test time of said object, and C1 is a constant depending on the time and space of the tested object.
According to another possible characteristic, the system comprises a thermally insulated enclosure configured to accommodate the object to be tested.
According to another possible characteristic, the thermally insulated enclosure is made of a material having a thermal conductivity of less than 0.05 W·m−1·K−1 at 20° C., preferably less than 0.03 W·m−1·K−1 at 20° C., and even more advantageously less than 0.01 W·m−1·K−1 at 20° C.
According to another possible characteristic, said enclosure accommodating the object to be tested comprises one or more cavities capable of accommodating the object to be tested and a reference object.
According to another possible characteristic, the system comprises a ventilation device configured to stir the gas, preferably inert, or air of the internal space of the enclosure.
Said ventilation device makes it possible in particular to avoid the creation of hot spots and/or thermal bridges between the enclosure(s) and the outside of the detection device.
The invention also relates to a leak detection method for object tightness checking, said method being implemented within a leak detection system (1), and comprising the following steps:
The invention will be better understood, and further purposes, details, characteristics and advantages thereof will become clearer throughout the following description of particular embodiments of the invention, given by way of illustration only and not limitation, with reference to the appended drawings, in which:
Said system thus comprises:
The first and second pressure sensors 7 and 9 are preferably differential pressure sensors. Whereas the third sensor 17 is advantageously an absolute pressure sensor.
It will be noted that a differential pressure sensor is for example a sensor including a diaphragm where each face of the diaphragm is exposed to a pressure, the displacement of the diaphragm (measured for example by capacitive effect) enabling the pressure difference of each face of the diaphragm to be measured.
[
More particularly, the sensor 9 comprises a diaphragm 201 with each face located in a separate cavity 203, 205. Each of the cavities 203, 205 of the sensor 9 communicates with the outside (in this case the atmosphere), however one of the cavities 205 is configured to filter out rapid pressure variations that may occur in that environment, thus pressure values Pext and P′ext prevailing in each of the cavities 203, 206 can be defined, the difference of which provides pressure variations Pext of the environment.
Similarly, in the present example, the leak detection is done by means of a reference 13, but the latter can be:
More particularly, the device 5 comprises:
Generally, the device 5 and its elements 51, 57, the electronic entity 15, as well as the various sensors 7, 9 and 17 are arranged inside a casing 20. However, the various elements, such as the sensor 9, can be offset and arranged outside the casing 20.
Said electronic entity 15 is also connected to said valves 57, in order to control said valves 57 during the various steps necessary for checking the tightness of the object 10.
As for [
Thus, said system 1 furthermore comprises an enclosure 30 comprising a base 30a and a cover 30b. The base 30a is configured to accommodate the battery 10 and the cover 30b to cover said battery 10 in order to limit environmental influences when detecting leaks.
For this, said enclosure 30 may be made of a material having a thermal conductivity of less than 0.05 W·m−1·K−1 at 20° C., preferably less than 0.03 W·m−1·K−1 at 20° C., and even more advantageously less than 0.01 W·m−1·K−1 at 20° C.
In an alternative embodiment not represented, said enclosure 30 comprises one or more cavities capable of accommodating the object to be tested 10 and the reference 13.
In another alternative embodiment not represented, the system 1 comprises a ventilation device configured to stir the gas, preferably inert, or air of the internal space of the enclosure 30.
Thus, as illustrated in [
It will be noted that some of the steps of the method 100 are part of an aeraulic leak detection management method that can be divided into four phases, more particularly illustrated in [
The various steps and phases described below are controlled by the electronic entity 15 which manages the opening and closing of the various valves 57 accordingly.
Additionally, said electronic entity 15 is configured to determine a leak F′ and F″ depending on the pressure variations in the pressurised space ΔP and the pressure variations of the environment ϕPext, said variations ΔP, ϕPext being measured, over a predetermined time interval ttest, by the first and second sensors 7 and 9.
The electronic entity 15 is thus configured to correct the curve ΔP by the curve ΔPext, in order to obtain a corrected pressure variation ΔP′ which is no longer influenced by the environment (pressure and/or temperature variations from the environment).
More particularly, said corrected pressure variation ΔP′ is calculated as follows:
ΔP′=(ΔP−kSΔPext)
where kS is a normalisation coefficient specific to the sensors 7 and 9 allowing the values of each of the curves to be subtracted from each other.
An example of a corrected pressure curve ΔP′ based on the curves in [
Said normalisation coefficient kS is for example:
Thus, the electronic unit 15 determines the level of leak F′, also called corrected level of leak, from the corrected pressure variations ΔP′ according to the following formula:
where C1 is a constant depending on the time (for example the test time ttest) and the space V of the tested object (that is, the space of the object whose tightness is to be determined).
Depending on the value of the leak F′, and according to the required threshold, the electronic entity 15 indicates the compliance or not of the tested object.
In an alternative embodiment, said electronic entity 15 determines an average temperature variation per unit of time of the tested object, via at least one sensor, for example the second or third sensor 9, 17.
Said average temperature variation is then used to determine a corrected leak F″ depending on the pressure variations ΔP measured in the pressurised space and the pressure variations ΔPext of the environment.
More particularly, in a step prior to the test, the second 9 or third 17 sensor is configured to measure a pressure variation ΔTP (in Pa/s) depending on the average temperature variation of the object per unit of time.
This measurement can for example be carried out during a step prior to filling or during the stabilisation phase, but it is necessary that the object to be tested and/or the reference are isolated from the outside.
The electronic entity 15 then determines a corrected pressure variation in ΔP″ of the characteristic space of the tested object depending on the following formula:
ΔP″=ΔP−kSΔPext−ΔTP
Then, as previously, the electronic entity 15 calculates a corrected level of leak F″ based on ΔP″ according to the previous equation.
Number | Date | Country | Kind |
---|---|---|---|
2006778 | Jun 2020 | FR | national |
2008152 | Jul 2020 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2021/067770 | 6/29/2021 | WO |