Method for detecting a leak in a tire of a stationary vehicle

Abstract

A method of detecting a leak from a tire of a vehicle, the tire including a member for measuring the pressure and the temperature having a driving operating mode and a stationary operating mode, comprising determining that the vehicle is stationary; and then launching the stationary operating mode to detect when the vehicle is stationary the presence or the absence of a leak of inflating gas from the tire.

Claims

1. A method for detecting a leak from a tire of a vehicle, the tire including a member for surveillance of the tire with sensors for measuring pressure and temperature and having a driving operating mode and a stationary operating mode, and the method comprising: determining that the vehicle is stationary; then launching the stationary operating mode to detect, when the vehicle is stationary, a presence or an absence of a leak of inflating gas from the tire; after launching the stationary operating mode of the member, periodically measuring the pressure pg and the temperature θ of the inflating gas in an internal cavity of the tire; storing a series of pressure and temperature values and measurement times in a non-volatile memory; converting the measured pressure pg values to absolute pressure P values and the measured temperature θ values to absolute temperature T values and calculating a ratio P/T to obtain a series of values; and if the series of values decreases by an amount above a given threshold, triggering an alert.

2. The method according to claim 1, wherein a measurement period is constant and between 30 minutes and 60 minutes inclusive.

3. The method according to claim 1, wherein a measurement period increases continuously during at least a given number of measurements.

4. The method according to claim 3, wherein the measurement period increases after each measurement by a factor between 1.5 and 4 inclusive.

5. The method according to claim 3, wherein the measurement period is constant if it exceeds a given threshold.

6. The method according to claim 1, wherein the threshold is between 2 and 7% inclusive of the ratio P/T.

7. The method according to claim 1, wherein the threshold corresponds to a variation between 50 and 200 mbar inclusive of the pressure of the inflating gas from the internal cavity of the tire.

8. The method according to claim 6, wherein the last measurement or measurements of pressure and of temperature obtained in the driving operating mode of the member are taken as a reference for the ratio P/T.

9. The method according to claim 6, wherein the last measurement or measurements of pressure and of temperature obtained in the stationary operating mode of the member are taken as a reference for the ratio P/T.

10. The method according to claim 1, wherein, upon triggering the alert, an alert message is sent to at least one pre-identified addressee.

11. The method according to claim 10, wherein, the vehicle including a central unit for surveillance of the tires of the vehicle, upon triggering the alert, the member of the tire transmits the alert message to at least one pre-identified recipient via the surveillance central unit.

12. The method according to claim 1, wherein the vehicle includes a circuit for powering up a dashboard, and wherein determining that the vehicle is stationary is determined when the power up circuit is open.

13. The method according to claim 1, wherein determining that the vehicle is stationary is determined by virtue of an absence of weight on a seat of a driver.

14. The method according to claim 1, wherein the member includes an accelerometer for detecting a movement of rotation of the tire, and wherein determining that the vehicle is stationary is determined by an absence of any signal linked to movement in rotation of the tire for a time above a given threshold.

15. The method according to claim 14, wherein determining that the vehicle is stationary is determined after between 15 and 60 minutes inclusive.

16. The method according to claim 1, wherein the stationary operating mode switches to the driving operating mode if it is identified that the vehicle is no longer stationary.

17. The method according to claim 1, wherein the tire includes on at least a part of its interior wall a layer of a self-blocking product.

18. The method according to claim 1, wherein the vehicle has an autonomous driving mode.

Description

DESCRIPTION OF THE FIGURE

(1) The appended FIG. 1 is a schematic of the stationary operating mode of a surveillance member.

DETAILED DESCRIPTION

(2) FIG. 1 shows a diagram of the main steps of the stationary operating mode of a surveillance member according to one of the objects of the invention.

(3) The surveillance member in question is disposed in the internal cavity of a tyre of a vehicle and is equipped in particular with a pressure sensor, a temperature sensor, a microprocessor, a non-volatile memory, a clock. The member is able to transmit and to receive radio signals. The member has a vehicle driving operating mode and a vehicle stationary operating mode.

(4) The driving operating mode usually enables the driver of the vehicle to be alerted in the event of loss of pressure in the tyre, in particular if the pressure decreases by more than 20% of the nominal relative pressure value when cold specified by the manufacturer of the vehicle.

(5) This surveillance member forms part of a surveillance system for the tyres of the vehicle made up of four surveillance members, one for each tyre, and a central unit or UC. In driving operating mode the UC periodically receives measurements taken by the members, processes them and transmits for the attention of the driver or of any other pre-identified addressee messages appropriate to the state of the tyres.

(6) In the step 100 the surveillance member is in driving operating mode. The vehicle is either moving or stationary but without the criteria for detection of stopping being satisfied.

(7) In the step 110 the member tests the detection of stopping. That detection may be linked to the opening of the circuit for powering the dashboard, absence of the signal linked to rotation of the tyre for a duration of greater than 15 or 20 minutes, or any other agreed test.

(8) If the criterion or the criteria for detection of stopping are not satisfied, the driving mode continues (loop 102).

(9) Otherwise, the operating mode of the surveillance member switches to the stationary operating mode (loop 104).

(10) At the moment of switching to the stationary operating mode, at to, the member takes a measurement of at least the relative inflation pressure p.sub.0 and the temperature θ.sub.0 of the gas in the internal cavity of the tyre (step 130).

(11) The member calculates the absolute inflation pressure P.sub.0 from the relative pressure and the absolute temperature in Kelvins:
P.sub.0=p.sub.0+p.sub.atm, where p.sub.atm, is atmospheric pressure; and
T.sub.0=θ.sub.0+273.16

(12) The member then calculates the ratio P.sub.0/T.sub.0 (step 140).

(13) Thereafter the member measures periodically the relative pressure and the temperature of the gas in the internal cavity of the tyre.

(14) By way of example, at t=t+Δt, it measures p.sub.t and θ.sub.t (step 150).

(15) The member then obtains the absolute pressures and the absolute temperatures and calculates the ratio: P.sub.t/T.sub.t (step 160).

(16) In the step 170, the member tests the value of the ratio P.sub.t/T.sub.t relative to the initial ratio taken as the reference:
P.sub.0/T.sub.0−P.sub.t/P.sub.tØS

(17) If the difference is below the threshold S (loop 172), the member tests whether or not the vehicle is still stationary (step 180). In the embodiment from FIG. 1, it is tested whether or not starting of rotation of the tyre has been detected, for example using an accelerometer of the surveillance member.

(18) If the two tests 170 and 180 are negative, the measurement step 150 is repeated after a period Δt greater than or equal to the previous one (loop 172).

(19) If the test 170 is positive, that is to say the difference between the two values, initial value and value at t, is greater the threshold S, the member concludes in the step 190 that there is a leak of gas from the internal cavity of the tyre. The member then sends a start-up and alert signal to the central unit UC of the surveillance system for the tyres of the vehicle (step 200). The UC then transmits to at least one pre-identified addressee an alert message warning of leak from the corresponding tyre.

(20) Optionally, after starting up the UC, the member may transmit to the UC all of the measurements carried out in the stationary operating mode (step 220).

(21) This optional step has the advantage of enabling the UC to validate or invalidate the leak diagnosis and to adapt the message sent to the pre-identified addressee as a function of the intensity of the leak detected: if the leakage rate is for example less than 0.05 or 0.10 bar per month, these are natural inflation losses and no message is of any use if the inflation pressure is correct; if the leakage rate is greater than 0.10 bar/month and less than 1 bar per week, this is an abnormal leak and it is necessary to alert the pre-identified addressee and to advise them to have the tyre concerned inspected; if the leakage rate is greater than 1 bar per week, this is a rapid leak and the message may be inspect the tyre concerned as soon as possible and prohibit driving if the inflation pressure is close to or below 1.5 bar.

(22) Of course, the messages sent may be adapted as a function of the measured relative inflation pressure of the tyre.

(23) Finally, if the test 180 is positive, the surveillance member switches from the stationary operating mode to the driving operating mode (loop 182) until the next time the vehicle stops.

(24) To implement the method of the invention, there may be used a surveillance device as described in the applicant's patent EP1354219 B1.