Method and apparatus for monitoring and analyzing vibrations in rotary machines

The invention claimed is: 1. A method of monitoring vibration amplitude and frequency in a rotary machine, comprising: receiving measurements of vibration amplitude and rotation speed of the machine from at least one sensor; recording as a data point each amplitude measurement as a function of vibration frequency and rotational speed; storing a plurality of different amplitude thresholds each representing a noise floor for a respective one of a first set of sub-ranges of vibration frequency and rotational speed, wherein each sub-range includes a sub-range of speeds and a sub-range of frequencies, wherein the different amplitude thresholds are set in a training process using training data points comprising vibration data from a run of the rotary machine deemed to be normal, and wherein the different amplitude thresholds are set by fitting an amplitude distribution to the training data points in each sub-range of vibration frequency and rotational speed; comparing each amplitude measurement to the amplitude threshold for a corresponding sub-range of vibration frequency and rotational speed for the data points within which the amplitude measurement falls; determining the amplitude measurement to represent noise if it falls below the amplitude threshold and as significant spectral content if it is above the amplitude threshold; using the amplitude measurement determined to be significant spectral content, assessing abnormalities of at least a component of the rotary machine; and when an abnormality is assessed, generating a signal configured to indicate the abnormality of at least a component of the rotary machine. 2. A method according to claim 1 wherein the different amplitude thresholds each representing a noise floor for a respective one of the first set of sub-ranges of vibration frequency and rotational speed are further set by calculating an extreme value distribution for said amplitude distribution and setting as said amplitude threshold an amplitude value representing a preset probability of being a maximum amplitude value that would be obtained for noise. 3. A method according to claim 2 wherein the preset probability is a probability above 0.99. 4. A method according to claim 2 wherein the amplitude distribution is a Gamma distribution. 5. A method according to claim 2 wherein the amplitude distribution is fitted after excluding training data points not representing background noise from the data in each sub-range of vibration frequency and rotational speed. 6. A method according to claim 2 further comprising: comparing each amplitude measurement to the extreme value distribution obtained from the training data points to read-off a probability value for that amplitude measurement; calculating from the probability value a novelty value as: novelty value=−log 10 {1−P e (x)}, where P e (x) is the extreme value distribution as a function of amplitude x; and outputting the novelty value. 7. A method according to claim 1 further comprising: among a second set of sub-ranges of vibration frequency and rotational speed, determining which ones of the sub-ranges of the second set contained, during a training process using vibration data from a run of the rotary machine deemed to be normal, more than a preset number of training data points whose amplitude measurement was above the noise floor, and defining these ones of the sub-ranges of the second set of sub-ranges of vibration frequency and rotational speed as containing known significant spectral content; and for each amplitude measurement determined to represent significant spectral content, determining the amplitude measurement to represent known significant spectral content when the amplitude measurement is within a sub-range of the second set of sub-ranges of vibration frequency and rotational speed that contains known significant spectral content and to represent novel significant spectral content when the amplitude measurement is within a sub-range of the second set of sub-ranges that does not contain known significant spectral content. 8. A method according to claim 7 wherein the first set and the second set of sub-ranges of vibration frequency and rotational speed are the same. 9. A method according to claim 7 wherein an alarm condition is triggered if a threshold number of amplitude measurements representing novel significant spectral content are found or if amplitude measurements representing novel significant spectral content persist for a predetermined time. 10. A method according to claim 1 wherein the frequency range is divided into 30 to 120 sub-ranges and the rotational speed range is divided into 5 to 40 sub-ranges. 11. A method according to claim 1 wherein the frequency range is divided into 50 to 100 sub-ranges and the rotational speed range is divided into 10 to 30 sub-ranges. 12. Apparatus for monitoring vibration amplitude and frequency in a rotary machine, comprising inputs for receiving vibration measurements from a vibration sensor and measurements of the rotation speed of the machine from a tachometer, and a data processing system adapted to execute the method of claim 1 . 13. A control system for a rotary machine comprising apparatus according to claim 12 . 14. A method of monitoring vibration amplitude and frequency in a rotary machine, comprising the steps of: receiving measurements of the vibration amplitude and the rotation speed of the machine from a run of the rotary machine from at least one sensor; recording as a data point each amplitude measurement as a function of vibration frequency and rotational speed; comparing each amplitude measurement to an amplitude threshold for a sub-range of vibration frequency and rotational speed for the data points within which the amplitude measurement falls, wherein the amplitude threshold represents a noise floor for the sub-range of vibration frequency and rotational speed, wherein the sub-range includes a sub-range of speeds and a sub-range of frequencies, wherein the amplitude threshold is set in a training process using training data points comprising vibration data from a run of the rotary machine deemed to be normal, and wherein the amplitude threshold is set by fitting an amplitude distribution to the training data points in the sub-range of vibration frequency and rotational speed; determining a set of sub-ranges in which the amplitude measurement is above the amplitude threshold; defining sub-ranges from the set of sub-ranges as known significant spectral content if more than a preset number of data points have an amplitude measurement above the amplitude threshold; defining sub-ranges from the set of sub-ranges as novel significant spectral content if there is less than a preset number of data points having an amplitude measurement above the amplitude threshold; using the sub-ranges defined to be novel significant spectral content, assessing abnormalities of at least a component of the rotary machine; and when an abnormality is assessed, generating a signal configured to indicate the abnormality of at least a component of the rotary machine.