RU2000104841A - MANY RESISTIVE SENSORS FOR MASS FLOW METER WITH CORIOLIS EFFECT - Google Patents

Claims (16)

1. The Converter (20), made with the possibility of measuring compensated by the resistance of the state conductor for each of the n resistive sensors (109, 110) connected in series, in which said transducer has a means of measuring the resistance of the conductor for measuring the resistance of the conductor of wires connected between the said transducer and said n resistive sensors, measuring means indicating a state of resistance for measuring indicating a state of resistance at each and n of said resistive sensors (109, 110), and means (409) responsive to measuring said conductor resistance and measuring said state indicating resistance for determining a condition compensated by resistance of a conductor for each of said n resistive sensors (109, 110) from said state indicating resistance at each of said n resistive sensors (109, 110) and said conductor resistance, comprising n + 1 conductors (308 - 310) for connecting said n resistive sensors to mentioned transducer (20), the first of the mentioned n + 1 conductors (308) connected to the first (110) of the mentioned n resistive sensors (109, 110) at the first end of the mentioned n resistive sensors (109, 110) connected in series, n -1 of said n + 1 conductors (309) connected to said n resistive sensors connected in series between each of said n resistive sensors, the second of said n + 1 conductors (310) connected to the last of said n resistive sensors ( 110) at the second end of said n resistive of sensors connected in series, where said second conductor (310) connects said n resistive sensors to earth through a reference resistance, switching means (F ₀ ) connecting a supply voltage (5V) in said converter to said first conductor (308) to disconnect said supply voltages with said n resistive sensors in order to measure said conductor resistance with said conductor resistance measuring means (401, 406, 409) connected to said ne to the first conductor, and for connecting said supply voltage to said n resistive sensors connected in series to measure resistance indicating state on each of said n resistive sensors (109, 110) by said measuring means indicating resistance state (401, 406, 409) connected to said n-1 conductors (301). 2. The Converter (20) according to claim 1, wherein said means for measuring the resistance of the conductor includes synchronization means (501) for periodically opening said switching means in order to disconnect said voltage from said first end of said sequence of sensors, means (502) for measuring voltage across the conductor between said first end of said n resistive sensors (109, 110) and one of said n-1 conductors (309) connected between said n resistive sensors (109 , 110), in response to disconnecting said supply voltage (5V) from said n resistive sensors (109, 110) connected in series, means (R _ref ) for measuring a reference voltage at said reference resistance, and means for comparing said voltage across a conductor with said reference voltage to determine the resistance of said conductor.  3. The Converter according to claim 2, wherein said comparison means includes means for dividing said voltage across the conductor by said reference voltage to obtain a voltage ratio, and means for multiplying said voltage ratio by a reference value, wherein said reference value is a value in ohms of the referenced reference resistance.  4. The converter according to claim 3, wherein said reference value is 100 ohms.  5. The converter (20) according to claim 1, further includes one of said n-1 conductors (309) having a first end connected to said n resistive sensors (109, 110) connected in series between two of said n resistive sensors and at the second end of said transducer (20). 6. The Converter (20) according to claim 5, wherein said state indicating means includes a means (401) for measuring voltage on a first sensor between said first end of said n resistive sensors (109, 110) connected in series and said second end said one of said n-1 conductors (309), the means (U _0, U ₁₎ of the reference voltage at the reference resistor, and means (409) for comparing said voltage at the first sensor with said reference voltage to determine the con otivlenie said first sensor, wherein said first sensor resistance includes the resistance of the first of said n resistive sensors and the resistance of said first conductor.  7. The converter according to claim 6, wherein said means (409) for comparison includes means (409) for dividing said voltage on a first sensor by said reference voltage to obtain a first sensor voltage ratio, and means (409) for multiplying said first the ratio of the voltage of the sensor to a reference value in which said reference value is a value in ohms of said reference resistance.  8. The converter according to claim 7, wherein said reference value is 100 ohms.  9. The Converter according to claim 6, wherein said state indicating means includes means (409) for measuring voltage on a second sensor between said second end of said one of said n-1 conductors and said second conductor, means (409) for measuring a reference resistance on said reference resistance, and means (409) for comparing said voltage on the second sensor with said reference voltage to determine a resistance of said second sensor in which said The second resistance of the second sensor includes the resistance of the second of said n resistive sensors and the resistance of said second conductor.  10. The Converter according to claim 9, wherein said means of comparison includes means for dividing said voltage on the second sensor by said reference voltage to obtain a second voltage ratio of the sensor, and means for multiplying said second voltage ratio of the sensor by a reference value in which said the reference value is the value in ohms of the referenced reference resistance.  11. The converter according to claim 10, wherein said reference value is 100 ohms.  12. The Converter according to claim 9, wherein said determination means includes first subtracting means for subtracting said resistance of the conductor from said resistance of the first sensor to determine a compensated resistance of the first sensor, second subtracting means for subtracting said resistance of the conductor from said resistance of the second sensor to determine the compensated resistance of the second sensor, means for converting said compensated resistance of the first first sensor and said second sensor compensated resistance to a first state and a second state, respectively.  13. The Converter according to claim 1, wherein said comparison means includes synchronization means (501) for periodically opening said switching means to disconnect said supply voltage from said first end of said n resistive sensors connected in series, means for measuring a first voltage between said the second end of said one of the n-1 conductors and the second end of said second conductor in response to the disconnection of said n resistive sensors connected by therefore, from said supply voltage with said switching means, means for measuring a first reference voltage at said reference resistance in response to disconnecting said n resistive sensors connected in series from said supply voltage with said switching means, means for comparing said first voltage with said first reference voltage to determine the resistance of the first sensor, in which the mentioned resistance of the first sensor on there is the resistance of one of said n resistive sensors connected in series, the resistance of said one of said n-1 conductors, and the resistance of said second conductor, means for measuring a second voltage between said second end of said one of n-1 conductors and the second end of said second conductor in response to connecting said n resistive sensors to said supply voltage by said switching means, means for measuring a second reference voltage said reference resistance, when said sequence of sensors is connected to said supply voltage, means for comparing said second voltage with said second reference voltage to determine a resistance of a second sensor, wherein said resistance of a second sensor includes a resistance of said one of said n resistance sensors, connected in series, and the resistance of said second conductor, means responsive to said resistance ix first sensor and said second sensor resistance and said conductor resistance for calculating an average conductor resistance.  14. The Converter according to claim 13, wherein said computing means includes means for subtracting said resistance of the second sensor from said resistance of the first sensor to obtain an approximately calculated resistance of the conductor, means for adding said resistance of the conductor to said approximately calculated resistance of the conductor and dividing by two to get the mentioned average conductor resistance.  15. The converter according to claim 1, wherein one of said resistive sensors is a resistive temperature sensor, and said state is a temperature.  16. A method for measuring the resistance of a conductor of wires connected to n resistive sensors connected in series for use in determining a compensated resistance of a conductor state for each of said n sensors, said method comprising the steps of: disconnecting a conductor connected to the first of said n resistive sensors from the applied voltage, and measuring the voltage of the conductor on said conductor in response to the disconnection of said applied voltage .