Determination of machine rotational speed based on vibration spectral plots

What is claimed is: 1. An apparatus for determining an estimated rotational speed of a rotating component of a machine in the absence of a reliable tachometer signal to indicate an actual rotational speed, the apparatus comprising: a vibration sensor attached to the machine that generates an analog vibration signal indicative of vibration of the machine; an analog-to-digital converter in electrical communication with the vibration sensor that converts the analog vibration signal to digital vibration data; an input device that receives input information from a user, the input information including a nominal speed value indicating a nominal rotational speed associated with the machine; a processor in electrical communication with the analog-to-digital converter and the input device that executes instructions to process the digital vibration data, including instructions to: (1) receive the nominal speed value from the input device; (2) generate a vibration spectrum based on the digital vibration data, the vibration spectrum comprising vibration amplitude values associated with frequency values; (3) identify a plurality of vibration peaks in the vibration spectrum, each of the vibration peaks having a peak amplitude value and a peak frequency value associated therewith; for j=1 to J: (4) determine a jth set of frequency values comprising: a jth candidate frequency value related to the nominal speed value; and a plurality of jth harmonic frequency values that are greater than the jth candidate frequency value and distributed incrementally across the vibration spectrum; (5) for each candidate and harmonic frequency value in the jth set, determine one of the vibration peaks identified in step (3) having a peak frequency value that is closest to the candidate or harmonic frequency value; (6) for each candidate and harmonic frequency value in the jth set, determine a frequency difference value indicating a difference between the candidate or harmonic frequency value and the peak frequency value that is closest; (7) generate a jth sum of the frequency difference values corresponding to the jth set of frequency values, and associate the jai sum with the candidate frequency value of the jth set of frequency values; (8) increment j by one and repeat steps (4) through (8) until j equals J; (9) determine a minimum sum of the J number of sums of the frequency difference values; (10) determine the estimated rotational speed of the machine based on the candidate frequency value associated with the minimum sum; and (11) analyze the digital vibration data using the estimated rotational speed of the machine to determine an operational characteristic of the machine. 2. The apparatus of claim 1 , wherein for j=1, the jth candidate frequency value corresponds to about half of the nominal rotational speed. 3. The apparatus of claim 1 , wherein for j=J, the jth candidate frequency value corresponds to about 1.5 times the nominal rotational speed. 4. The apparatus of claim 1 , wherein the nominal speed value is a nameplate rotational speed of the machine. 5. The apparatus of claim 1 , wherein J ranges from about 10 to about 100. 6. The apparatus of claim 1 , wherein the peak frequency value determined in step (5) is greater than or less than the closest candidate or harmonic frequency value. 7. The apparatus of claim 1 , wherein the jth set of frequency values includes eight harmonic frequency values. 8. The apparatus of claim 1 , wherein if it is determined that there are more than one minimum sum in the J number of sums of the frequency difference values, the processor executes instructions to: (12) for each of the J sets of frequency values, determine a sum of the peak amplitude values of the vibration peaks identified in step (3) that have peak frequency values closest to the candidate and harmonic frequency values; (13) determine a maximum sum of the J number of sums of the peak amplitude values determined in step (12); and (14) determine the estimated rotational speed of the machine based on the candidate frequency value associated with the maximum sum. 9. The apparatus of claim 1 , wherein the number of vibration peaks identified in step (3) is less than or equal to LOR/4, and wherein LOR is lines of resolution of the vibration spectrum. 10. An apparatus for determining an estimated rotational speed of a rotating component of a machine in the absence of a reliable tachometer signal to indicate an actual rotational speed, the apparatus comprising: a vibration sensor attached to the machine that generates an analog vibration signal indicative of vibration of the machine; an analog-to-digital converter in electrical communication with the vibration sensor that converts the analog vibration signal to digital vibration data; an input device that receives input information from a user, the input information including a percent accuracy value (% Accuracy) and a start frequency value (StartFreq) indicating a nominal rotational speed associated with the machine; a processor in electrical communication with the analog-to-digital converter and the input device that executes instructions to process the digital vibration data, including instructions to: (1) receive the percent accuracy value and the start frequency value from the input device; (2) generate a vibration spectrum based on the digital vibration data, the vibration spectrum comprising vibration amplitude values associated with frequency values; (3) identify K number of vibration peaks in the vibration spectrum, each of the vibration peaks having a peak amplitude value (AmplLocPeak(k)) and a peak frequency value (FreqLocPeak(k)) associated therewith; (4) for each of N number of harmonics of the start frequency value, determine candidate frequency values (FreqCandidate(j)) for which the following relationship is true: |FreqLocPeak( k )−( n ×StartFreq)|≤% Accuracy (5) for each of the candidate frequency values determined in step (4), determine a percentage difference value (PctDiff) according to: PctDiff = [ FreqLocPeak ⁢ ⁢ ( k ) - n × ( FreqCandidate ⁢ ⁢ ( j ) ) ] n × ( FreqCandidate ⁢ ⁢ ( j ) )