On-line oil condition sensor system for rotating and reciprocating machinery
First Claim
1. A method for optimizing the electrochemical measurement parameters of an impedance analysis technique for analyzing lubricants for thermal-oxidative breakdown, water contamination, or fuel dilution, or combinations thereof, comprising the steps of:
- bringing electrodes into contact with a sample of oil;
applying a direct current (DC) voltage bias to one of said electrodes;
applying an electrical potential to the sample to produce an electrical current therethrough;
applying a frequency variation as a sinusoidal frequency stimulus (f) of a first value to the sample to produce a frequency-dependent current response (I) therethrough;
varying said sinusoidal frequency stimulus (f) to the sample from the first value to a second value and continuing said frequency variation to a third and successive additional values to produce a frequency-dependent current response (I) therethrough;
measuring and recording a voltage response (E) from said electrical potential and sinusoidal frequency stimulus (f);
measuring and recording the frequency-dependent current response (I) during said frequency variation steps;
recording from said voltage response (E) and said frequency-dependent current response (I) the ratio of the real component (E) versus the real component (I) of said impedance analysis technique over frequency (f);
recording from said voltage response (E) and said frequency-dependent current response (I) the ratio of the imaginary component (E) versus the imaginary component (I) of said impedance analysis technique over frequency (f);
computing the sum of the square of said ratio of real component (E) versus real component (I) and said ratio of imaginary component (E) and imaginary component (I) all to the one-half power;
recording the magnitude of the impedance |Z| from said sum of the square of the ratio of real component (E) versus real component (I) and the ratio of imaginary component (E) and imaginary component (I) all to the one-half power;
recording the logarithm of said magnitude of the impedance |Z| versus the logarithm of frequency (f);
recording the phase angle (θ
) between the voltage response (E) and said frequency-dependent current response (I) versus the logarithm of frequency (f);
determining from said logarithm of the magnitude of the impedance |Z| versus the logarithm of frequency (f) the point of transition from a frequency-dependent impedance response to a frequency-independent impedance response;
identifying a stimulus frequency from the recorded logarithm of the magnitude of the impedance |Z| versus the logarithm of frequency (f) that is at least one order of magnitude less than said point of transition from said frequency-dependent impedance response to said frequency-independent impedance response;
verifying from said recording of the logarithm of the magnitude of the impedance |Z| versus the logarithm of frequency (f) that the shape of said frequency-independent impedance response is of a horizontal nature;
verifying from said recording of the phase angle (θ
) that said phase angle (θ
) is close to 0°
versus the frequency-independent impedance response recorded;
analyzing the recorded frequency-independent impedance responses for said magnitude of the impedance |Z| and said phase angle (θ
) to directly characterize said thermal-oxidative breakdown, water contamination, or fuel dilution conditions in said sample of oil;
comparing said frequency-independent magnitude of the impedance |Z| and phase angle (θ
) values with predetermined values corresponding to said characterized sample conditions; and
determining the quality and/or condition of the sample of oil as a function of the comparison.
1 Assignment
0 Petitions
Accused Products
Abstract
An on-line sensing system and method for monitoring in real-time thermal-oxidative breakdown, water contamination, and/or fuel dilution conditions in operational engine lubricating oils. The method of the invention includes an electrochemical impedance analysis technique specific to the particular oil to be monitored. Sensing devices having of at least two electrodes are configured for direct installation in an existing access port, or drain port, of a lubricating oil reservoir. An AC voltage waveform is applied to the sensing device (preferably less than 100 Hz) to produce voltage and current responses between the appropriate electrodes contacting the oil. The magnitude impedance |Z| and phase angle components of the complex impedance are used to characterize the quality and/or condition of the engine oil under test. The system also provides an electrical indication indicative of the percentage remaining useful life of the oil.
-
Citations
40 Claims
-
1. A method for optimizing the electrochemical measurement parameters of an impedance analysis technique for analyzing lubricants for thermal-oxidative breakdown, water contamination, or fuel dilution, or combinations thereof, comprising the steps of:
-
bringing electrodes into contact with a sample of oil; applying a direct current (DC) voltage bias to one of said electrodes; applying an electrical potential to the sample to produce an electrical current therethrough; applying a frequency variation as a sinusoidal frequency stimulus (f) of a first value to the sample to produce a frequency-dependent current response (I) therethrough; varying said sinusoidal frequency stimulus (f) to the sample from the first value to a second value and continuing said frequency variation to a third and successive additional values to produce a frequency-dependent current response (I) therethrough; measuring and recording a voltage response (E) from said electrical potential and sinusoidal frequency stimulus (f); measuring and recording the frequency-dependent current response (I) during said frequency variation steps; recording from said voltage response (E) and said frequency-dependent current response (I) the ratio of the real component (E) versus the real component (I) of said impedance analysis technique over frequency (f); recording from said voltage response (E) and said frequency-dependent current response (I) the ratio of the imaginary component (E) versus the imaginary component (I) of said impedance analysis technique over frequency (f); computing the sum of the square of said ratio of real component (E) versus real component (I) and said ratio of imaginary component (E) and imaginary component (I) all to the one-half power; recording the magnitude of the impedance |Z| from said sum of the square of the ratio of real component (E) versus real component (I) and the ratio of imaginary component (E) and imaginary component (I) all to the one-half power; recording the logarithm of said magnitude of the impedance |Z| versus the logarithm of frequency (f); recording the phase angle (θ
) between the voltage response (E) and said frequency-dependent current response (I) versus the logarithm of frequency (f);determining from said logarithm of the magnitude of the impedance |Z| versus the logarithm of frequency (f) the point of transition from a frequency-dependent impedance response to a frequency-independent impedance response; identifying a stimulus frequency from the recorded logarithm of the magnitude of the impedance |Z| versus the logarithm of frequency (f) that is at least one order of magnitude less than said point of transition from said frequency-dependent impedance response to said frequency-independent impedance response; verifying from said recording of the logarithm of the magnitude of the impedance |Z| versus the logarithm of frequency (f) that the shape of said frequency-independent impedance response is of a horizontal nature; verifying from said recording of the phase angle (θ
) that said phase angle (θ
) is close to 0°
versus the frequency-independent impedance response recorded;analyzing the recorded frequency-independent impedance responses for said magnitude of the impedance |Z| and said phase angle (θ
) to directly characterize said thermal-oxidative breakdown, water contamination, or fuel dilution conditions in said sample of oil;comparing said frequency-independent magnitude of the impedance |Z| and phase angle (θ
) values with predetermined values corresponding to said characterized sample conditions; anddetermining the quality and/or condition of the sample of oil as a function of the comparison. - View Dependent Claims (2, 3, 4, 5)
-
-
6. An on-line method of analyzing lubricants in real-time for thermal-oxidative breakdown, water contamination, or fuel dilution, or combinations thereof, comprising the steps of:
-
bringing electrodes into contact with a sample of oil; applying a direct current (DC) voltage bias to one of said electrodes; applying an electrical potential to the sample to produce an electrical current therethrough; applying a sinusoidal frequency stimulus (f) to the sample to produce a frequency-dependent current response (I) therethrough; measuring and recording a voltage response (E) from said electrical potential and sinusoidal frequency stimulus (f); measuring and recording the frequency-dependent current response (I) during said sinusoidal frequency stimulus (f); recording from said voltage response (E) and said frequency-dependent current response (I) the ratio of the real component (E) versus the real component (I) of said method at frequency (f); recording from said voltage response (E) and said frequency-dependent current response (I) the ratio of the imaginary component (E) versus the imaginary component (I) of said method at frequency (f); computing the sum of the square of said ratio of real component (E) versus real component (I) and said ratio of imaginary component (E) and imaginary component (I) all to the one-half power; recording the magnitude of the impedance |Z| from said sum of the square of the ratio of the real component (E) versus the real component (I) and the ratio of imaginary component (E) and imaginary component (I) all to the one-half power; recording the phase angle (θ
) between said voltage response (E) and current response (I) analyzing the recorded mathematical values for said magnitude of the impedance |Z| and said phase angle (θ
) to directly characterize said thermal-oxidative breakdown, water contamination, or fuel dilution conditions in said sample of oil under test;comparing said magnitude of the impedance |Z| and phase angle (θ
) values with predetermined values corresponding to said characterized sample conditions;determining the quality and/or condition of the sample of oil as a function of the comparison; and providing an electrical indication indicative of said quality and/or condition of the sample of oil. - View Dependent Claims (7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19)
-
-
20. An in-situ, on-line system for monitoring lubricants for thermal-oxidative breakdown, water contamination, or fuel dilution, or combinations thereof, in a lubricating oil reservoir, comprising:
-
a. electronic power supply connected to an available 12V–
72V power bus;b. electronic instrument means connected to said power supply for generating an excitation stimulus comprised of a DC voltage bias, an electrical potential, and an alternating current (AC) drive signal, said electronic instrument means further comprising; (i) measuring and recording means to produce a voltage response (E) from application of said excitation stimulus; (ii) measuring and recording means to produce a frequency-dependent current response (I) from application of said excitation stimulus; (iii) processing means for computing from said voltage response (E) and said frequency-dependent current response (I) the ratio of the real component (E) versus the real component (I); (iv) processing means for computing from said voltage response (E) and current response (I) the ratio of the imaginary component (E) versus the imaginary component (I); (v) processing means for computing the sum of the squares of said ratio of real component (E) versus real component (I) and said ratio of imaginary component (E) and imaginary component (I) all to the one-half power, said processing means thus enabling the determination of the magnitude of the impedance |Z|; (vi) processing means for computing the phase angle (θ
) between said voltage response (E) and said frequency-dependent current response (I);(vii) recording means to store the mathematical values for said magnitude of the impedance |Z| and said phase angle (θ
);c. sensor means configured to be installed in an existing access port, or drain port, of the lubricating oil reservoir for applying said excitation stimulus to the lubricant contained therein, said sensor means having; (i) two closely-parallel, electrically-conductive electrodes extending into the lubricating oil reservoir, the two electrodes immersed in the lubricant therein and having the excitation stimulus applied thereto; (ii) a mechanical housing structurally supporting the physical extension of said sensor means into the lubricating oil reservoir, the mechanical housing further enabling the electrical connection, and disconnection, of said sensor means to and from said electronic instrument means for generating the excitation stimulus; (iii) a temperature-sensitive resistor in thermal contact with said lubricant in the lubricating oil reservoir and electrically isolated from said two electrodes, the resistor providing a voltage output for determining the temperature of said lubricant; (iv) an inner silicone O-ring fixtured within the inner cavity of said mechanical housing, the inner silicone O-ring providing a leak-proof seal to prevent said lubricant from contacting either the electrodes, or said temperature-sensitive resistor, within said inner cavity of the sensor means; d. threaded housing means for fixturing said sensor means to be installed in the existing access port, or drain port, of the lubricating oil reservoir, said threaded housing means having; (i) a first threaded section; (ii) a second threaded section; (ii) an outer silicone O-ring fixtured immediately forward said first threaded section of the threaded housing means, the outer silicone O-ring further corresponding with the outer perimeter of said inner cavity of the sensor means and providing additional sealing to prevent the lubricant from entering either one of said sensor means or threaded housing means; (iii) a threaded jam nut corresponding with the mechanical housing of said sensor means to securely tighten said sensor means to said first threaded section of the threaded housing means, the tightening of said threaded jam nut thus forcing both the inner and outer O-rings into a state of compression for an even further leak-proof design; (iv) a third silicone O-ring fixtured immediately aft said second threaded section of the threaded housing means, the third silicone O-ring providing an additional sealing barrier between the external surface of the existing access port, or drain port, of the lubricating oil reservoir and said threaded housing means; e. electronic potentiostat means electrically connected between the electronic instrument means and sensor means and mounted internally to said threaded housing means, said electronic potentiostat means having (i) a stimulus control amplifier to electronically buffer instantaneously and reproduce the excitation stimulus applied to said sensor means via said electronic instrument means; (ii) a voltage buffer to electronically monitor the electrical potential of said excitation stimulus and provide return electrical feedback signals to said stimulus control amplifier, said voltage buffer further transmitting the voltage response (E) as a first return voltage back to said electronic instrument means of the in-situ, on-line system; (iii) a current buffer to transform the resultant frequency-dependent current response (I) of said excitation stimulus into a second return voltage transmitted back to said electronic instrument means of the in-situ, on-line system; (iv) electronic temperature buffer means electrically connected to said temperature-sensitive resistor in thermal contact with the lubricant to current-bias the produced voltage from the temperature-sensitive resistor, said electronic temperature buffer means enabling an automatic correction of said magnitude of the impedance |Z| due to changes in the temperature of said lubricant in the lubricating oil reservoir, the electronic temperature buffer means thus providing third and fourth return voltages for the temperature-sensitive resistor and the electronic temperature buffer means respectively back to said electronic instrument means of the in-situ, on-line system; (v) an electrical interconnect component comprising a plurality of contacts for electrically connecting said sensor means with said electronic instrument means and the excitation stimulus therefrom, the electrical interconnect component enabling multiple cycles of engagement and disengagement of said sensor means by way of gold-over-nickel plating material; f. electrical cable means interposed between said electronic instrument means and electronic potentiostat means, said electrical cable means conducting the excitation stimulus to the electronic potentiostat means and transmitting individually the return voltages for the voltage response (E), the transformed current response (I), the temperature-sensitive resistor, and the electronic temperature buffer means back to said electronic instrument means for further processing and analysis; g. electronic analysis means for evaluating the processed mathematical values for said magnitude of the impedance |Z| and said phase angle (θ
), said electronic analysis means enabling a direct characterization of said thermal-oxidative breakdown, water contamination, or fuel dilution conditions in the lubricant under test;h. electronic comparison means for comparing the processed magnitude of the impedance |Z| and phase angle (θ
) values with predetermined values corresponding to said characterized lubricant conditions;
said electronic comparison means thus enabling a determination of the lubricant'"'"'s quality and/or condition as function of the comparison; andi. electrical indication means to provide an electrical signal indicative of said quality and/or condition of the lubricant. - View Dependent Claims (21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38)
-
-
39. A method for sensing in-situ the electrochemical impedance characteristics of engine oil while said oil is in use in an operating combustion engine to determine the relative electrochemical condition of said oil, comprising the steps of:
-
(a) placing at least two electrodes into contact with said oil; (b) applying a DC voltage bias to one of said electrodes; (c) applying an electrical potential to one of said electrodes in order to generate an electric current through said oil; (d) applying a sinusoidal generally constant frequency stimulus to one of said electrodes to produce a frequency-dependent response through said oil; and (e) measuring and recording with one of said at least two electrodes different than the first one electrode the frequency-dependent response during said step of applying the sinusoidal generally constant frequency stimulus to the impedance characteristics of said oil and thereby assess the in-situ condition of said oil as a function of an increase or decrease in said frequency-dependent response, or combinations thereof. - View Dependent Claims (40)
-
Specification