Method for optimising a wetting current and adapted device for monitoring sensors with contact switches

The invention claimed is: 1. A method for optimizing a wetting current, intended to be implemented by a device for monitoring sensors with contact switches forming a circuit comprising a current source (A) supplied by a supply voltage, at least two assemblies including a contact switch (CT 1 , CT 2 ) and a resistor (R 1 , R 2 ) in series, said at least two assemblies (CT 1 /R 1 , CT 2 /R 2 ) being wired in parallel, and an analog-to-digital converter (CAN) having a saturation voltage, the method comprising the following steps: a first step in which the current source (A) supplies the circuit with a nominal current by means of a first control bus; a second step in which, if a voltage (Vm) measured across the terminals of said contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ) is greater than a predetermined threshold voltage (Vs), said threshold voltage (Vs) being selected so as to be lower than the supply voltage of the current source (A), then the current source is stopped and means for discharging the circuit are implemented by means of a second control bus; a third step in which, if the second step has brought about the stoppage of the current source (A) and the discharging of the circuit, then the current source (A) supplies the circuit again with a supply current equal to the nominal current reduced by a predetermined increment, wherein, at the end of the third step, the second step is implemented again until the voltage measured across the terminals of said two contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ) is lower than the threshold voltage (Vs). 2. The method for optimizing a wetting current as claimed in claim 1 , further comprising a fourth step in which a stabilization time delay (Tstable) is implemented, at the end of the third step, during which the voltage (Vm) across the terminals of the contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ) is measured in order to ensure that said voltage (Vm) remains lower than the threshold voltage (Vs), it being understood that if, during the stabilization time delay (Tstable), said voltage (Vm) across the terminals of the contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ) exceeds the threshold voltage (Vs), then the second step is implemented again. 3. The method for optimizing a wetting current as claimed in claim 2 , wherein, during the third step, the discharging is deemed to have finished once the voltage (Vm) measured across the terminals of said contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ) falls below a discharge threshold voltage (Vd), which is predetermined as being equal to the threshold voltage (Vs) reduced by a margin. 4. The method for optimizing a wetting current as claimed in claim 2 , wherein the threshold voltage (Vs) is selected so as to be lower than the saturation voltage of the analog-to-digital converter (CAN). 5. The method for optimizing a wetting current as claimed in claim 2 , wherein the threshold voltage (Vs) is configured in real time depending on the supply voltage of the current source (A). 6. The method for regulating a wetting current as claimed in claim 1 , further comprising a step of calculating the value of the equivalent resistance between the terminals of said contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ). 7. The method for optimizing a wetting current as claimed in claim 6 , wherein, during the third step, the discharging is deemed to have finished once the voltage (Vm) measured across the terminals of said contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ) falls below a discharge threshold voltage (Vd), which is predetermined as being equal to the threshold voltage (Vs) reduced by a margin. 8. The method for optimizing a wetting current as claimed in claim 6 , wherein the threshold voltage (Vs) is selected so as to be lower than the saturation voltage of the analog-to-digital converter (CAN). 9. The method for optimizing a wetting current as claimed in claim 6 , wherein the threshold voltage (Vs) is configured in real time depending on the supply voltage of the current source (A). 10. The method for optimizing a wetting current as claimed in claim 1 , wherein, during the third step, the discharging is deemed to have finished once the voltage (Vm) measured across the terminals of said contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ) falls below a discharge threshold voltage (Vd), which is predetermined as being equal to the threshold voltage (Vs) reduced by a margin. 11. The method for optimizing a wetting current as claimed in claim 10 , wherein the threshold voltage (Vs) is selected so as to be lower than the saturation voltage of the analog-to-digital converter (CAN). 12. The method for optimizing a wetting current as claimed in claim 10 , wherein the threshold voltage (Vs) is configured in real time depending on the supply voltage of the current source (A). 13. The method for optimizing a wetting current as claimed in claim 1 , wherein the threshold voltage (Vs) is selected so as to be lower than the saturation voltage of the analog-to-digital converter (CAN). 14. The method for optimizing a wetting current as claimed in claim 13 , wherein the threshold voltage (Vs) is configured in real time depending on the supply voltage of the current source (A). 15. The method for optimizing a wetting current as claimed in claim 1 , wherein the threshold voltage (Vs) is configured in real time depending on the supply voltage of the current source (A). 16. The method for optimizing a wetting current as claimed in claim 1 , wherein, after the calculation of the value of said equivalent resistance between the terminals of the contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ), corresponding to a first calculation, a second measurement of the voltage across the terminals of the contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ) is performed with a supply current that is lower than the supply current that enabled the first calculation, for the purpose of performing a differential calculation making it possible to determine the value of said equivalent resistance more precisely. 17. A device for monitoring sensors with contact switches forming a circuit intended to implement the method as claimed in claim 1 , said device comprising: at least two assemblies (CT 1 /R 1 , CT 2 /R 2 ) formed of a contact switch and of a resistor in series, said two assemblies being wired in parallel, a current source (A) supplied by a supply voltage, an analog-to-digital converter (CAN) having a saturation voltage, said device for monitoring sensors with contact switches further comprising: means for measuring the voltage across the terminals of said contact switch/resistor assemblies (CT 1 /R 1 , CT 2 /R 2 ), means (C 1 ) for comparing said measured voltage (Vm) with a predetermined threshold voltage (Vs) that is lower than the supply voltage of the current source (A), means for discharging the circuit, and wherein it is configured to implement the method as claimed in claim 1 . 18. The device as claimed in claim 17 , wherein the discharging means consist of a current source managed by a switch. 19. The device as claimed in claim 18 , further comprising second means (C 2 ) for comparing said measured voltage (Vm) with a predetermined discharge threshold voltage (Vd), said discharge threshold voltage (Vd) being equal to the threshold voltage (Vs) reduced by a margin. 20. The device as claimed in claim 17 , further comprising second means (C 2 ) for comparing