This invention relates generally to fluid analysis, and more particularly to a sensing system suitable for measuring the broadband impedance of oil, or other fluids used in or with equipment, machinery and the like. This measurement could be used, for example, to extract evidence or features for analyzing the condition or composition of such fluids.
Electrical and electrochemical properties, such as conductivity and dielectric constant, are often used to assess the condition of oil and other fluids. These measurements have traditionally limited the response of the measurement to specific frequencies only and therefore do not consider the overall spectrum response of the system. Additionally, the measurement is typically accomplished using one or more fixed-amplitude, single frequency tones. In most cases, the magnitude of the response is used as the sole gauge. The phase change of the response, which contains information needed to evaluate capacitance and inductance changes, is rarely used in field applications. For example, U.S. Pat. No. 4,646,070 (Yasuhara) and U.S. Pat. No. 6,028,433 (Cheiky-Zelina) disclose designs in which only one frequency tone is evaluated. U.S. Pat. No. 6,583,631 (Park) presents a method of determining only capacitance. Similarly, U.S. Pat. No. 6,535,001 presents a capacitive sensor that outputs a single DC voltage level, while U.S. Pat. No. 6,459,995 relies on a fixed frequency tone of an LC oscillator circuit to produce the interrogation signal. These designs provide little information about the full electrochemical response of the fluid. Furthermore, these methods neglect useful information that can be extracted from the fluid's broadband impedance. For those systems that do consider a multitude of frequencies, the fluid is repeatedly interrogated by a single frequency waveform, which results in full fluid characterization taking an extended time, up to 50 minutes (as disclosed in U.S. Pat. No. 6,577,112 by Lvovich). This approach is susceptible to very large errors due to environmental changes that can occur during the interrogation window. U.S. Pat. No. 5,889,200 describes a sensor that interrogates a fluid simultaneously using a multitude of frequencies in the form of a square wave. However, only one measurement (conductivity) is extracted and no effort is made to evaluate the fluid's broadband impedance. A square wave is also inferior to the interrogation signal presented by the current invention in the inability to control the signal's amplitude at specific frequencies. A similar design presented in U.S. Pat. No. 5,274,335, employs a triangle wave for interrogation, which suffers the same drawbacks as the square wave interrogation signal.
In most cases, the failure mechanism that dominates a mechanical system can be traced back to the fluid quality degradation or contamination of the system. It is precisely for this reason that on-line, in situ oil quality analysis is the key building block to effective diagnostics and prognostics for mechanical systems. The present invention directly addresses, this need in addition to the aforementioned technology shortcomings, with a novel sensor package to determine a fluid's broadband electrical impedance, which can be used to, among other things, predict quality and degradation in a range of fluid systems.
One aspect of the present invention is a measurement system comprising: a low-powered, broadband, interrogation signal; the analog circuitry needed to condition and facilitate acquisition of the interrogation (and response) signal(s); a data acquisition device for capturing these signals; and a processor and algorithms to control the interrogation and acquisition process as well as interpret the measurements to determine the impedance of the fluid.
In accordance with another aspect of the present invention, there is provided a method for measuring a fluid's impedance as a response to an interrogation, comprising: injecting a broadband signal containing a range of frequencies (range is dependent upon fluid type); and measuring the response to such signals through a fluid to determine impedance.
As part of this invention, a digital to analog converter is used to generate sensor interrogation waveforms comprising a composite of sinusoidal waveforms of varying frequency. A measurement circuit provides an analog to digital converter with inputs corresponding to the original interrogation signal and the sensor's response to that signal. A processor, in the form of a microcontroller, digital signal processor, a remote computer, etc. performs analysis of the response signals using a set of algorithms designed to calculate the impedance of the fluid based on magnitude and phase measurements extracted from the digitized input signals. In one embodiment, the sensor electrodes are constructed of two conductive plates that allow a representative fluid sample to pass between the plate surfaces. There is no intent to restrict the geometry of the electrodes to solely parallel plate designs; concentric rings, coaxial cylinders, and redundant (multiple version of a given design allowing a redundant measurement) electrodes should also be considered.
The measurement produced by this invention can be processed for the purpose of tracking specific electrochemical properties (conductance, capacitance, dielectric constant, inductance, and derived combinations), which have been demonstrated to be an effective method to sense changes in fluid quality, as indicated by Saba, C. S., and Wolf, J. D., “Tandem Technique for Fluid Testing”, Joint Oil Analysis Proceedings, 1998, pp. 81-90; Brown, R. W., et al., Novel Sensors for Portable Oil Analyzers, Joint Oil Analysis Proceedings, 1998, pp. 91-100; and Brown, R. W., and Cheng, Y., “Mathematical Physics Optimization of Electrical Sensors for Contaminant Detection”, 7th Annual Users Conference, Las Vegas, Nev., October 1996. However, there is no intent to limit the invention for use in determining oil quality and the application of impedance measurement to other fluids, liquid plastics, and other 2-phase or variance substance problems is implied.
The present invention will be described in connection with a preferred embodiment, however, it will be understood that there is no intent to limit the invention to the embodiment described. On the contrary, the intent is to cover all alternatives, modifications, and equivalents as may be included within the spirit and scope of the appended claims.
For a general understanding of the present invention, reference is made to the drawings. In the drawings, like reference numerals have been used throughout to designate identical elements.
As opposed to the single tone techniques described above, the concept for taking broadband electrical impedance measurements of a fluid system builds upon AC Voltammetry techniques used in the laboratory for characterization of electrochemical reactions. The basis of this concept involves injecting an alternating current (AC) signal into a system and measuring the system's response at the frequency of the injected signal. The impedance of the system can then be determined by comparing the differences between the interrogation (excitation) signal and the response signal. In the case of a fluid system, measurable levels of current are not possible and a voltage interrogation must therefore be used (as discussed below).
As illustrated in
The broadband interrogation signal depicted in
Frequencies are selected such that they are logarithmically spaced over the selected range of frequencies. By logarithmically spacing the frequency points used in the interrogation signal, the frequency range can be maximized while the number of discrete tones used is minimized. Equation 1 is used for generating a series of logarithmically spaced frequency values for a given decade defined by D.
where N is the desired number of frequency points and D is the desired decade the frequencies should span. The importance of using logarithmically spaced points is illustrated in
Due to the nature of capacitive sensor measurements, high frequency interrogation signals generate a stronger signal response than low frequency signals. A method was therefore designed to insure optimum data acquisition system resolution across the entire frequency band. During signal creation, one interrogation signal is created for each decade spanned by the frequency range of interest. The response of the system is assessed for each decade independently and then re-assembled during post-processing. Similar methods such as splitting the waveform by octaves could also be used depending on data acquisition requirements. By substituting Equation 1 into the formula for generating the interrogation signal, wD(t), based on decades becomes
where A is a scaling value used to obtain the desired magnitude (i.e. voltage), D defines the decade of frequencies spanned by wD(t) and N is the number of log-spaced tones. The scaling value, A, is selected such that the full dynamic range of the digital to analog converter, which outputs the interrogation signal, is utilized. This will ensure that the bit resolution of the sampled signal is adequate for performing impedance calculations. As mentioned, D specifies the desired waveform decade; for example, a fluid found to have an optimal interrogation range spanning 1 Hz to 100 Hz would be sampled by 2 waveforms, one including frequencies from 1Hz to 10 Hz (D=0) and one for 10 Hz to 100 Hz (D=1). This allows the gain settings of the data acquisition system to be adjusted between interrogation signals to achieve high resolution for all frequencies within the composite signals. The length of the time vector, t, is set so that multiple cycles of each tone are injected into to sensor. The total number of cycles needed is determined from the lowest frequency in the decade and the frequency resolution needed to accurately resolve all of the tones in the interrogation waveform when evaluated in the frequency domain.
The general equation for the relationship between impedance, voltage, and current is
Fluid is a very high impedance medium and, unless special measurement circuitry is applied, measurable levels of current are only achievable at moderate to very high-powered signals.
Referring to
The configuration shown in
A digital to analog converter (DAC) is used to generate the composite waveforms that are injected into the oil sample. Such a DAC is included in a multipurpose microcontroller sold as part number C8051F040, by Silicon Laboratories. A deglitching/reconstruction filter 301 is used to smooth errors in the output of the digital to analog converter, providing a more accurate representation of the intended interrogation waveform and removing high frequency errors.
Due to the very high impedance of oil, selection of R2 (302) and the instrumentation amplifiers 303 is critical to the operation of the circuit. R2 is selected to have high resistance, known frequency response, and a low temperature coefficient. The value of R2 should preferably match the average resistance of the fluid to be measured over the frequency range of interest. In some fluids this value will be very high, necessitating the use of a smaller resistor and a gain stage in the instrumentation amplifier to prevent unacceptable noise levels. The instrumentation amplifiers must have extremely low (preferably less than 100 fA) input bias currents and very high input impedance (preferably greater than 1 GΩ) to avoid large measurement errors. The error that can be created by low input resistance can be calculated by:
Note, that RMEASURE, for the purposes of this disclosure, is equivalent to R2 in
In a typical highly resistive fluid like oil, currents through the sensor 304 would be measured in nanoamps. Typical instrumentation amplifiers also have bias currents measured in nanoamps. This can result in measurement errors overwhelming the actual measurement. To counteract this effect, a specialized ultra-low bias current instrumentation amplifier, such as the INA116 manufactured by Texas Instruments, is used in addition to guard rings implemented on the PCB layout to reduce leakage. Guard drivers 305 are also implemented to further reduce leakage currents caused by cable capacitance. By selecting the correct amplifier, and implementing guarding techniques, leakage currents can be reduced to femto-amps.
Due to the unique composite interrogation signal used, which entails separate waveforms for each decade, specially designed anti-aliasing filters 306 are used to limit the bandwidth of the interrogation (VIN) and response (VOUT) signals. Typically, a single anti-aliasing filter is used for each channel of input, but due to the interrogation method used for this design, this would require the analog to digital converter (ADC) to greatly oversample the low frequency waveforms to prevent aliasing. To avoid this situation, multiple anti-aliasing filters are implemented on each channel (VIN and VOUT), and one filter is selected for each interrogation waveform via the digital I/O (DIO) lines of the controlling means 309. This implementation can be achieved by using multiple active/passive filter gain stages selectable through an analog switch device, or by using a variable cutoff frequency anti-aliasing filter. By limiting the bandwidth, the sampling rate required to avoid aliasing is reduced, thus reducing the amount of data required to perform accurate frequency spectrum analysis, and furthermore reducing post acquisition processing time.
The data acquisition system can be implemented locally, via an analog to digital converter module or multi-purpose microcontroller with integrated ADCs, or remotely, via a data acquisition system.
Line drivers 307 serve multiple purposes depending on the configuration of the data acquisition system. For A/D converters capable of bipolar inputs, the line driver acts as a simple buffer circuit to reduce the source impedance of the VOUT or VIN signal. For implementations utilizing a unipolar A/D converter, this circuit is used to scale and level-shift the voltages in addition to lowing the source impedance.
The measurement path for VIN and VOUT is design to be identical for each measurement. This allows for simple calibration routines to be implemented that can eliminate stray circuit effects such as cable capacitance and inductance, propagation delay, phase and magnitude distortions (from filters), and part tolerances. By shorting the conductive plates of the sensor and performing an impedance calculation these effects can be quantified and removed from future measurements. This measurement will be identified as ZSENSOR in the following equations.
An algorithm has been developed to translate simple voltage measurements, VIN and VOUT, into complex impedances. The impedance of the sample fluid can be calculated by an equation, derived from equation 3, as follows:
where R is equal to R2 from
As implied by Equation 6, impedance is calculated by determining the change in phase and magnitude of the two signals at each of the frequencies in the excitation waveform. The phase and magnitude of each signal is found by applying a Blackman windowing algorithm, taking the Fast Fourier Transform (FFT) of the two signals, and autonomously locating and extracting magnitude and phase information for frequencies included in the interrogation waveform, f=ω/2π. The phase and magnitude signals of the input and output voltages are then converted into complex values, and the impedance of the fluid sample is calculated using Equation 6. This process is also depicted in
As indicated, the impedance of the fluid sample can be represented on a Nyquist plot, the x and y values of which correspond to the real and imaginary impedance values (respectively) that are obtained by expressing the impedance in rectangular form. By applying Euler's relation, the calculated values can be converted from polar to rectangular form according to Equation 7.
ZOIL(ω)=Zejø=Z(cos ø+j sin ø)=Z{re}+jZ{im} (7)
Plotting the imaginary impedance versus the real impedance of a diesel oil sample results in a curve similar to that shown in
Once an impedance curve is calculated its structure can provide features that are indicative of oil quality.
To reduce EMI, a specially designed PCB and enclosure was created for the purposes of this invention. The circuit board is designed with an isolated power supply, sensitive components placed on a single side of the board, and unused portions of the board filled with grounded copper. Due to the small size of this board it can be placed within inches of the sensor electrodes, further reducing the possible effects of EMI.
The claims, as originally presented and as they may be amended, encompass variations, alternatives, modifications, improvements, equivalents, and substantial equivalents of the embodiments and teachings disclosed herein, including those that are presently unforeseen or unappreciated, and that, for example, may arise from applicants/patentees and others.
Priority is claimed from Provisional Application No. 60/520,521, for a “Smart Oil Sensor System And Method For Use Thereof,” filed Nov. 14, 2003, and assigned to Impact Technologies, LLC, which is also hereby incorporated by reference in its entirety.
Aspects of this invention were made with Government support under SBIR Contract Number: N00014-02-M-0178, awarded by the Office of Naval Research. The U.S. Government may have certain license rights in aspects of this invention.
Number | Date | Country | |
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60520521 | Nov 2003 | US |