Method and apparatus for determining the health and remaining service life of austenitic steel reformer tubes and the like

We claim: 1. A probe for testing an austenitic steel reformer tube comprising: a first sinusoidal current generator connected to a first transmitter coil; a second sinusoidal current generator connected to a second transmitter coil, the first and second current generators driving a magnetic field through the first and second transmitter coils, respectively, the first and second transmitter coils transmitting two sinusoidal electromagnetic signals, each signal having a different frequency F 1 and F 2 , respectively, into a test position on an austenitic steel reformer tube; a receiver coil positioned in a region of the magnetic field receiving a response signal from the test position; and a microprocessor analyzing said received response signal's fundamental and intermodulation frequencies to determine a state of the austenitic steel reformer tube at said test position. 2. The probe of claim 1 , further comprising an analog to digital converter converting the response signal into digital samples. 3. The probe of claim 1 , further comprising a clock connected to the first and second sinusoidal current generators. 4. The probe of claim 1 , further comprising a transportation device so the probe can move with respect to the austenitic steel reformer tube. 5. The probe of claim 4 , wherein the transportation device is a crawler. 6. The probe of claim 1 , wherein the transportation device includes a measuring device for measuring a position of the probe with respect to the austenitic steel reformer tube. 7. The probe of claim 1 , wherein transmitting two sinusoidal electromagnetic signals further includes choosing the two frequencies F1 and F2 such that: F 1 =N×F 0 ; F 2 =P×F 0 ; where N and P are integers with N not equal to P, and N and P are chosen such that none of the intermodulation frequencies, F(Q,R)=Q×F 1 +R×F 2 are equal to an integral multiple of F 1 or F 2 for small, non-zero, integer values of Q and R. 8. The probe of claim 1 , wherein the first and second transmitter coils have a larger diameter than a thickness of the austenitic steel reformer tube to be tested. 9. The probe of claim 1 , wherein the first and second transmitter coils are arranged coaxially. 10. The probe of claim 1 , wherein the first or second current generator includes a digital-to-analog signal generator. 11. The probe of claim 1 , wherein analyzing the received response signal's fundamental and intermodulation frequencies includes analyzing the first order fundamental and the third order intermodulation frequencies of said received response signal. 12. The probe of claim 11 , wherein the fundamental frequency is F 2 and said third order intermodulation frequencies are 2F 1 +F 2 and F 1 +2F 2 . 13. The probe of claim 11 , wherein analyzing the third order intermodulation frequencies includes converting the amplitude of the third order intermodulation frequencies into decibels dB relative to an amplitude of the fundamental. 14. The probe of claim 13 , wherein a strength of the third order intermodulation frequencies which have been converted into decibels dB is compared to a same measurement of brand new and end of service life austenitic steel reformer tubes, said comparison providing a qualitative measure of the health of said austenitic steel reformer tube. 15. The probe of claim 14 , wherein the microprocessor estimates a remaining service life of said austenitic steel reformer tube as a fraction of present service life of said austenitic steel reformer tube by the following formulas: fractional life remaining L r =|S e −S n |/|S e −S 0 |; and estimated lifetime remaining T r =( L r /(1− L r ))× T n where: L r is an estimated percentage of life remaining; S e is a third order intermodulation frequencies signal strength converted into decibels dB of an austenitic steel reformer tube at the end of service life; S n is a third order intermodulation frequencies signal strength converted into decibels dB of the test sample now; S 0 is either a third order intermodulation frequencies signal strength when there is no tube present under the probe, or the third order intermodulation frequencies signal strength of a new tube that has been heated to operating temperature for a few hours, whichever is higher; T r is an estimated service lifetime remaining for the test sample; and T n is a present service life of the test sample. 16. A probe for testing an austenitic steel reformer tube comprising: at least one sinusoidal current generator connected to at least one transmitter coil, the at least one current generator driving a magnetic field through the at least one transmitter coil, the at least one transmitter coil transmitting two sinusoidal electromagnetic signals, each signal having a different frequency F 1 and F 2 , respectively, into a test position on an austenitic steel reformer tube; a receiver coil positioned in a region of the magnetic field receiving a response signal from the test position; and a microprocessor analyzing said received response signal's fundamental and intermodulation frequencies to determine a state of the austenitic steel reformer tube at said test position.