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Claims  |
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Having described the invention, what is claimed is:
1. A predictive vibration monitoring system for a machine, the system
comprising:
a machine to be monitored, the machine having at least one operational
state and at least one rotative element, each of the at least one rotative
elements adapted to generate a benchmark vibration signature for each of
the at least one machine operational states, and an operational vibration
signature for each of the at least one operational states of the machine;
a microcontroller;
at least one sensor operatively connected to the machine, the at least one
sensor being of the type which converts mechanical motion generated by the
at least one rotative element into a corresponding electrical signal, the
at least one sensor inputting the corresponding electrical signal to the
microcontroller;
communication means for enabling the microcontroller to communicate with
the monitored machine thereby enabling the microcontroller to correlate
the operational state of the monitored machine with the corresponding
electrical signal generated by the at least one sensor;
memory means, communicating with the microcontroller, for storing a
predetermined logic routine, at least one corresponding electrical signal,
each of the benchmark vibration signatures for each of the at least one
rotative elements; and at least one predetermined key frequency of the at
least one rotative element of the machine to be monitored; and
the microcontroller utilizing the predetermined logic routine to process
the corresponding electrical signal into a corresponding operational
vibration signature of the monitored machine, the microcontroller
comparing the corresponding operational vibration signature with both the
at least one predetermined key frequency and with the benchmark vibration
signature to predict the present and future condition of the at least one
rotative element.
2. A vibration monitoring system for a compressor, the system comprising:
a compressor to be monitored, the compressor having at least one rotative
element, and at least one operating state, each of the at least one
rotative elements adapted to generate a benchmark vibration signature for
each of the compressor operational states, and also to generate an
operational vibration signature for each of the at least one compressor
operational states;
a microcontroller;
at least one sensor operatively connected to the compressor, the at least
one sensor converting mechanical motion generated by the at least one
rotative element into a corresponding electrical signal, the at least one
sensor inputting the corresponding electrical signal to the
microcontroller;
memory means, communicating with the microcontroller, for storing a
predetermined logic routine, at least one corresponding electrical signal;
each of the benchmark vibration signatures for each of the at least one
rotative elements; and at least one predetermined key frequency of the at
least one rotative element of the compressor to be monitored; the
microcontroller utilizing the predetermined logic routine to process the
corresponding electrical signal into a corresponding operational vibration
signature of the monitored compressor, the microcontroller comparing the
corresponding operational vibration signature with the at least one
predetermined key frequency and the benchmark vibration signature to
predict the present and future condition of the at least one rotative
element.
3. A vibration monitoring system, as claimed in claim 2, further including
a communication means for enabling the microcontroller to communicate with
the monitored compressor thereby enabling the microcontroller to correlate
a predetermined operational state of the monitored compressor with a
corresponding electrical signal generated by the at least one sensor.
4. A vibration monitoring system, as claimed in claim 2, further including
a signal filter means, which communicates with the at least one sensor,
for preconditioning the corresponding electrical signal, and for
suppressing electrical and magnetic signals generated from outside the
vibration monitoring system.
5. A vibration monitoring system, as claimed in claim 2, and wherein the at
least one sensor is a proximity probe.
6. A vibration monitoring system, as claimed in claim 2, and wherein the at
least one sensor is an accelerometer.
7. A vibration monitoring system, as claimed in claim 6, further including
an analog amplifier connected to the accelerometer.
8. A vibration monitoring system, as claimed in claim 2, the
microcontroller processing the corresponding electrical signal into
corresponding vibration data by employing a fast Fourier transform
algorithm.
9. A vibration monitoring system, as claimed in claim 2, further including
a communication means for enabling the microcontroller to communicate the
corresponding vibration data to a predetermined location remote to the
vibration monitoring system.
10. A vibration monitoring system, as claimed in claim 2, further including
means for displaying the corresponding operational vibration signature.
11. A vibration monitoring system, as claimed in claim 2, further including
a means for inputting user selected data into the microcontroller.
12. A system for monitoring the vibration of at least one rotative element
of a machine to determine the present condition, and to predict the future
condition, of the at least one rotative element, the vibration monitoring
system comprising:
a microprocessor controlled machine to be monitored, the machine having at
least one rotative element, the machine having at least one operational
state and each of the at least one rotative elements adapted to generate a
benchmark vibration signature, and an operational vibration signature for
each of the machine operational states;
a microcontroller;
at least one sensor operatively connected to the machine, the at least one
sensor converting mechanical motion generated by the at least one rotative
element into a corresponding electrical signal, the at least one sensor
inputting the corresponding electrical signal to the microcontroller;
communication means for enabling the microcontroller to communicate with
the monitored machine thereby enabling the microcontroller to correlate a
predetermined operational state of the monitored machine with a
corresponding electrical signal generated by the at least one sensor;
memory means, communicating with the microcontroller, for storing a
predetermined logic routine, the benchmark vibration signatures; at least
one corresponding electrical signal and at least one predetermined key
frequency of the at least one rotative element of the machine to be
monitored; and
the microcontroller utilizing the predetermined logic routine to process
the corresponding electrical signal into a corresponding operational
vibration signature of the monitored machine, the microcontroller
comparing the corresponding operational vibration signature with the at
least one predetermined key frequency and with the benchmark vibration
signature to determine the present and to predict the future condition of
the at least one rotative element, the microcontroller interacting with
the microprocessor of the monitored machine such that the microcontroller
communicates predetermined operational commands to the monitored machine
in response to the determined present condition, and the predicted future
condition, of the at least one rotative element.
13. A vibration monitoring system, as claimed in claim 12, further
including a signal filter means, which communicates with the at least one
sensor, for preconditioning the predetermined electrical signal, and for
suppressing electrical and magnetic signals generated from outside the
vibration monitoring system.
14. A vibration monitoring system, as claimed in claim 12, and wherein the
at least one sensor is a proximity probe.
15. A vibration monitoring system, as claimed in claim 12, and wherein the
at least one sensor is an accelerometer.
16. A vibration monitoring system, as claimed in claim 15, further
including an analog amplifier connected to the accelerometer.
17. A vibration monitoring system, as claimed in claim 12, the
microcontroller processing the corresponding electrical signal into
corresponding vibration data by employing a fast Fourier transform
algorithm.
18. A vibration monitoring system, as claimed in claim 12, further
including a communication means for enabling the microcontroller to
communicate the corresponding operational vibration signature to a
predetermined location remote to the vibration monitoring system.
19. A vibration monitoring system, as claimed in claim 12, further
including a means for displaying the corresponding operational vibration
signature.
20. A vibration monitoring system, as claimed in claim 12, including a
means for inputting user selected data into the microcontroller.
21. A predictive vibration monitoring system comprising:
a compressor to be monitored, the compressor having at least one
operational state and at least one rotative element, each of the at least
one rotative elements adapted to generate a benchmark vibration signature
for each compressor operational state, and an operational vibration
signature;
a microcontroller;
at least one sensor operatively connected to the compressor, the at least
one sensor generating a signal corresponding to motion of the at least one
rotative element, the at least one sensor inputting the signal to the
microcontroller;
a signal filter means, which communicates with the at least one sensor, for
preconditioning the signal, and for suppressing signals generated from
outside the predictive vibration monitoring system;
communication means for enabling the microcontroller to correlate a
predetermined operational state of the monitored compressor with a signal
generated by the at least one sensor;
memory means, communicating with the microcontroller, for storing a
predetermined logic routine, at least one signal, each of the benchmark
signatures for each of the at least one rotative elements; and at least
one predetermined key frequency of the at least one rotative element of
the compressor to be monitored;
a means for inputting user selected data into the microcontroller;
the microcontroller utilizing the predetermined logic routine which
executes a fast Fourier transform algorithm to process the signal into a
corresponding operational vibration signature of the monitored compressor,
the microcontroller comparing the corresponding operational vibration
signature with both the benchmark vibration signature and at least one
predetermined key frequency to determine the present, and to predict the
future condition of the at least one rotative element, the microcontroller
interacting with the microprocessor of the monitored compressor such that
the microcontroller communicates predetermined operational commands to the
monitored compressor in response to the determined present condition, and
the predicted future condition, of the at least one rotative element; and
means for displaying the corresponding operational vibration signature. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention generally relates to a frequency vibration monitoring
system, and more particularly to a system for analyzing vibration
signatures to predict and to detect changes in machinery condition.
By design, machinery having rotative elements, which are couplingly
connected, experience vibratory motion. This vibratory motion may be
generated by such rotative elements as the following: machine bearings,
such as bearing races, or defective ball bearings; misalignment of machine
assemblies, such as gears, motors, or shafts; and imbalance of machine
assemblies, such as motors, rotors, gears, pistons and fans. The vibratory
motion of such machine assemblies may be expressed in the form of a
vibration signature, vibration footprint or "footprint", which may be
graphically illustrated.
The present and future condition of machinery may be determined and
predicted by analyzing predetermined vibration signatures of individual
machinery. Determining the present and future condition of machinery is
essential for maintaining such machinery on line and capable of
contributing to an essential manufacturing process. The machinery to be
studied may include rotating type machinery, such as but not limited to
rotary screw type air compressors. Such rotary screw type air compressors
typically supply the entire pneumatic requirements for a manufacturing
facility. In such an example, if the rotary screw air compressors fail in
their essential function, production at the manufacturing facility will
most likely cease until such time as the fault condition is remedied or a
back up pneumatic supply is located. This, of course, may cause a great
loss of revenue for the affected manufacturing facility. Ideally, a
potential fault condition of a machine should be identified as early as
possible to permit a facility manager to schedule "down" time and machine
maintenance in a cost effective manner.
In an effort to avoid the loss of revenue caused by "down" equipment,
manufacturing facility managers have, in the past, employed independent
firms that specialize in the field of predictive vibration monitoring of
machinery. It is the purpose of such firms to supply personnel to a
manufacturing facility for the purpose of performing on-site vibration
monitoring. As is well known, in order to effectively perform predictive
vibration monitoring of machinery, the "normal" vibration signatures of
all the rotative components must be known before predictive vibration
monitoring is performed. These "normal" vibration signatures of the
rotative components serve as a benchmark from which to evaluate all other
vibration signatures. Notwithstanding the foregoing, typically such
independent firms performing predictive vibration monitoring do not know
the "normal" vibration signatures of the machines to be monitored. Without
the knowledge of such "normal" vibration signatures, predictive vibration
monitoring programs may produce extremely inaccurate results, which is a
problem presently plaguing this field. Such inaccurate results cause
unnecessary repair of machines that are otherwise in sound operating
condition, and cause the owners of such machines to file meritless
warranty claims against the manufacturer of such machines.
As may be appreciated by one skilled in the art, any collection of
vibration data for the purpose of predictive vibration monitoring must be
performed under equal machine conditions to achieve accurate results.
Present methods of collecting vibration data accomplish such data
collection absent any accurate correlation to the running state of the
monitored machine. For example, on a predetermined date, vibration data
may be collected for a compressor under compressor loaded conditions.
Thereafter vibration data may be collected for a compressor under
compressor unloaded conditions. Inaccuracy will occur if the dissimilar
collected vibration data is compared to predict the present and future
condition of the monitored machine.
In addition to the foregoing, present methods of vibration data collection
do not permit any integration between the vibration monitoring and a
microprocessor based control system of the monitored machine. This lack of
integration prevents any continuous logging of machine vibration data
which would permit a significantly more accurate analysis of any gathered
vibration data.
The foregoing illustrates limitations known to exist in present methods for
collecting vibration data for the purpose of predicting and detecting
changes in machinery condition. Thus, it is apparent that it would be
advantageous to provide an alternative directed to overcoming one or more
of the limitations set forth above. Accordingly, a suitable alternative is
provided including features more fully disclosed hereinafter.
SUMMARY OF THE INVENTION
In one aspect of the present invention, this is accomplished by providing a
predictive vibration monitoring system for a machine. The predictive
vibration monitoring system includes a microcontroller and a machine to be
monitored. The machine to be monitored includes at least one rotative
element. At least one sensor is operatively connected to the machine. The
at least one sensor is operable to convert mechanical motion generated by
the at least one rotative element into a corresponding electrical signal.
The at least one sensor inputs the corresponding electrical signal to the
microcontroller. A communication means is disposed between the
microcontroller and the monitored machine. The communication means enables
the microcontroller to correlate a predetermined operational state of the
monitored machine with a corresponding electrical signal generated by the
at least one sensor. A memory means communicates with the microcontroller
and stores a predetermined logic routine, at least one corresponding
electrical signal and at least one predetermined key frequency of the at
least one rotative element of the machine to be monitored. The
microcontroller utilizes the predetermined logic routine to process the
corresponding electrical signal into corresponding vibration data of the
monitored machine. The microcontroller compares the corresponding
vibration data with the at least one predetermined key frequency to
predict the present and future condition of the at least one rotative
element.
The foregoing and other aspects will become apparent from the following
detailed description of the invention when considered in conjunction with
the accompanying drawing figures.
BRIEF DESCRIPTION OF THE DRAWING FIGURES
FIG. 1 is a functional block diagram of a vibration monitoring system in
accordance with the teachings of the present invention.
FIG. 2 is a predetermined spectral display or vibration signature
(Frequency v. Velocity) for a machine.
FIG. 3 is a chart depicting operation logic employed by the system of the
present invention.
FIG. 3A is a chart highlighting the spectral analysis step 70 of FIG. 3.
DETAILED DESCRIPTION
Referring now to the drawings, wherein similar reference characters
designate corresponding parts throughout the several views, FIG. 1
illustrates a functional block diagram of a vibration monitoring system in
accordance with the teachings of the present invention. The vibration
monitoring system of the present invention may be used with any type
machine, such as but not limited to the following: gas compressors,
including centrifugal compressors and rotary screw air compressors; pumps;
blowers; turbines; engines or any other type machine having rotative
components which have some degree of vibratory motion which generate
characteristic vibration signatures.
Generally illustrated at 10 is a machine to be monitored, which in the
embodiment illustrated is a rotary screw type air compressor. One or more
sensors 12 communicate with the compressor 10. The sensors 12 are of the
type which convert mechanical motion or energy into electrical signals.
For example, the sensors 12 may be proximity probes, accelerometers or any
other type sensors which are used in industrial applications to measure
vibration. Each of the sensors 12 are attached to the compressor in
predetermined locations to be monitored. For example, the sensors 12 may
be attached to the compressor 10 in such a manner to analyze the vibratory
motion of machine bearings (e.g. bearing races, or defective ball
bearings), gears, motors, shafts, pistons or fans, for example. A
tachometer input is shown at 14 which is a magnetic type pickup, and which
is designed to determine rotational speed of a predetermined compressor
element. A power supply 16 supplies the requisite electrical power to the
vibration monitoring system. Signal filters are connected to the sensors
12 and the tachometer input 14 to precondition the electrical signals
which are generated therefrom, and to suppress noise or other electrical
magnetic interference. An optional analog amplifier is provided at 18
which is connected to the sensors 12, by way of the signal filter 17, and
to a microcontroller 20. Analog amplifier 18 is required only if the
signal generated by a sensor 12 is below a predetermined threshold
voltage, such as 0 volts, for example. Typically, accelerometers produce
such a voltage below 0 volts and require amplification.
In the embodiment of the vibration monitoring system described herein, the
microcontroller 20 is a 16 bit unit. The microcontroller 20 should be of a
type which is able to perform, at a minimum, the following functions:
collect data quickly; analyze data quickly by employing a signal analysis
algorithm, such as a fast Fourier transform algorithm (FFT algorithm);
quickly store and move data between memory locations; and perform floating
point calculations. A microcontroller which is known to be capable of
performing these functions is an Intel.RTM. 80C196 series microcontroller.
Signals from the sensors 12 are inputted to the microcontroller 20 through
an A/D converter 22, such as a 10-bit type A/D converter, for example. The
A/D converter operates to convert the real world analog signals which are
generated by the sensors 12 to a digital format to be processed by the
microcontroller 20. Signals from the tachometer input 14 are inputted to
the microcontroller 20 through a high speed input 24.
The microcontroller outputs to an address data bus 26, input/out ports 28
and a serial port 30. The address data bus 26 is required to permit the
microcontroller to communicate to peripherals, such as but not limited to
a data memory 38, program memory 40, display interface 42, machine status
input 44, and a user input 46, all of which will be described in further
detail hereinafter. Input/output port 28 typically comprises digital
inputs or outputs which may control such hardware functions as controlling
a backlight on a display interface, or controlling light emitting diodes,
for example. Serial port 30 permits the microcontroller 20 to communicate
with another central processing unit or microcontroller, such as a
microcontroller which may control operating functions of the compressor
10.
By way of the serial port 30, a microprocessor controlled machine, such as
a microprocessor controlled compressor 10, may be integrated with the
vibration monitoring system of the present invention. Such integration
permits the vibration monitoring system to precisely correlate the state
of the operating machine with the vibration data collected. Also, it is
contemplated by the teachings herein that action commands may be generated
by the microcontroller 20 and outputted through serial port 30 to the a
monitored machine. For example, if the analyzed vibration signature would
indicate an impending fault condition, a command signal may be outputted
to the monitored machine by the microcontroller 20. This command signal
may be of the type to control operations of the monitored machine or to
cause alarm information to be displayed by the monitored machine. More
than one serial port 30 may be included in the vibration monitoring
system, if for example, the system is to be employed at a remote site. In
such an embodiment of the present invention, a serial port 30 would be
dedicated to the monitored machine and a second serial port would be
employed to provide for communications between a remote field monitor 36
and the vibration monitoring system. Communications with the remote field
monitor 36 would be accomplished via a modem which would permit data
transfer to a remote site by way of cellular communications, radio
frequency communications or telephone communications, for example.
The microcontroller 20 communicates with a system clock 32. A serial
communications port 34 communicates with the one or more serial ports 30.
The serial communications port may be either a RS485 or RS232 type
communication port, however, an RS485 type serial communications port is
preferred due to being more robust in an industrial environment. The
serial communications port 34 is linked with a machine to be monitored,
such as the compressor 10, and a remote field monitor 36.
The data memory 38 is a random access type memory (RAM) having both a
volatile and a non-volatile memory component. Stored in non-volatile RAM
is a digitized footprint or vibration signature of the machine to be
monitored (e.g. FIG. 2). This footprint may be obtained initially at the
facility at which the monitored machine is assembled, and/or the footprint
may be obtained upon installation of the machine at a predetermined
manufacturing site, as will be explained in further detail hereinafter.
Also, stored in non-volatile RAM are predetermined values for all the key
frequencies of the rotative elements of the machine to be monitored. These
key frequency values will serve as a benchmark against which the
microcontroller 20 will compare collected vibration signatures. By using
an actual footprint of the machine to be monitored, and actual key
frequencies of rotative elements, extremely accurate predictive vibration
monitoring may be achieved.
The program memory 40, such as an erasable programmable read only memory
(EPROM), stores the program for controlling a fast Fourier transform
algorithm. The display interface 42 may include a liquid crystal display,
a printer, cathode ray tube, or any other similar suitable display
apparatus for visually depicting a vibration signature, such as the
vibration signature illustrated in FIG. 2. The machine status input 44
provides for an interface which permits the microcontroller 20 to
correlate the state of the machine to be monitored with collected
predetermined vibration signatures from a machine which is not equipped
with a microprocessor based controller. More particularly, in such a
machine which is not equipped with a microprocessor based controller, the
microcontroller 20 is unable to correlate collected vibration signatures
with a predetermined machine state. For example, a rotary screw compressor
may be operating in such states as "loaded", "unloaded", or "modulating".
The machine status input 44 permits the integration of non-microprocessor
controlled machines with the microcontroller 20 to provide for accurate
predictive vibration monitoring in those instances. User input setup 46 is
an apparatus for permitting a user to control the vibration monitoring
system. For example, the user input setup may be a membrane panel with
appropriate input type switches, or any other suitable type human/machine
interface type apparatuses.
FIG. 2 is an actual footprint or vibration signature which has been
obtained under a known machine state, and from an individual sensor 12,
having a known, predetermined location. Each sensor 12 provides vibration
data to produce a single vibration signature. Overlying each vibration
signature is an alarm level. The alarm level is employed by the vibration
monitoring system to indicate predetermine maximum levels above which
machine fault conditions may occur to the monitored machine.
The requisite operational steps employed by the vibration monitoring
apparatus of the present invention are detailed in FIG. 3. As should be
understood, the vibration monitoring system of the present invention may
be installed in a newly manufactured compressor as original equipment.
Alternatively, the vibration monitoring system may be supplied as a
retrofit assembly in compressors already existing at site locations. The
operational steps detailed in FIG. 3 are based upon an original equipment
type vibration monitoring system.
During the assembly of a newly manufactured machine, such as the rotary
screw air compressor 10, electrical power is applied to power supply 16 at
block 48. Thereafter, the microcontroller 20 is initialized at block 50.
During initialization, a predetermined logic routine is executed which
accomplishes such tasks as determining the software revision resident in
the program memory 40; identifying the machine to be monitored and the
rotative elements to be monitored; identifying the number of sensors
present within the vibration monitoring system; and determining the state
of the various sub-assemblies of the vibration monitoring system, such as
but not limited to, the data memory 38, the program memory 40, the display
interface 42, and the microcontroller 20. Upon completion of the
initialization at block 50, a calibration test is accomplished at block
52.
Calibration data and a predetermined calibration sub-routine are retrieved
by the microcontroller 20 from the data memory 38. If the calibration test
is passed, operational step 52 is advanced to step 54 where a start-up
production test is performed upon the machine to be monitored. If the
calibration test is failed, the microcontroller 20 returns the system
logic to the initialization step at 50. The calibration step employs a
predetermined calibration circuit containing a built in signal to simulate
signals generated by the sensors 12 to the microcontroller 20 for self
calibrating or zero offsetting purposes. The calibration step 52 also
includes the following: determination of the status of the power supply 16
and the excitation voltage to the sensors 12; determination of the status
of sensor connections to confirm the number of sensors employed by the
vibration monitoring system; and determination of the status of the
outputs of the vibration monitoring system.
At the manufacturing facility of the machine to be monitored, a start-up
production test is accomplished which is represented at block 54. The
start-up production test is performed during operation of the machine to
be monitored, during which initial vibration data is collected. It is the
purpose of the start-up production test to compile the initial vibration
data into various benchmark footprints for different operating states of
the machine to be monitored. For example, in the case of a rotary screw
compressor, a footprint is established for an "unloaded" state, a "loaded"
state, or a "modulating" type state, for example. The various footprints
are then digitized and stored within the data memory 38. At step 56 the
initial vibration data is compared to the key frequencies of the rotative
elements of the machine to be monitored, which have also been stored
within the data memory 38. The data analysis which is accomplished at step
56 determines whether the initial vibration footprints are within the
acceptable frequency ranges of the rotative elements of the machine to be
monitored. If the initial vibration footprints are within such acceptable
frequency ranges of the rotative elements, the machine is determined to be
suitable for shipment which is accomplished at block 58. Conversely, if
the initial vibration footprints are determined to be out of range, the
machine is determined to be unfit for shipment, and the machine is
inspected to locate the source of the fault condition.
Upon arriving at an operational site, and after the machine to be monitored
is permanently installed, power is supplied to the machine and the machine
is calibrated at step 60. Thereafter, an installed start-up test is
performed at step 62. The installed start-up test is similar to the
start-up production test. The purpose of the installed start-up test is to
compile initial benchmark vibration data for the installed machine to be
monitored. As should be understood, when a machine, such as a rotary screw
air compressor is installed, floor mounting systems, absorption pads,
and/or vibration mounts may alter a machine's vibration signature.
Therefore, predictive vibration monitoring is based upon the vibration
data compiled by the installed start-up test. As with the start-up
production test, the vibration data for the installed start-up test is
digitized and stored within the data memory 38. Also at step 62, the
initial vibration data is compared to the key frequencies of the rotative
elements which were previously stored within the data memory. If the
vibration footprints for the installed machine are within the acceptable
frequency ranges of the rotative elements, the machine is determined to be
suitable for operation, which is represented at step 64. Conversely, if
the initial vibration footprints are determined to be out of range, the
machine is inspected to locate the source of the fault condition.
Vibration data is collected at user selected time intervals at step 66.
Throughout the collection of vibration data, the system microcontroller 20
interacts with a microcontroller of the compressor 10 to thereby correlate
the machine state with the vibration data collected. In the situation
where the machine to be monitored is not equipped with a microcontroller,
the microcontroller interacts with the machine status input 44 to
correlate machine state with the vibration data collected. The collected
vibration data is then stored at step 68 in the data memory 38 such that a
spectral analysis, step 70, may be performed thereupon. At predetermined
time intervals a calibration function is accomplished at step 74 similar
to the calibration function accomplished at step 52. Additionally, at
predetermined time intervals, an initialization function is accomplished
at 72 similar to step 50. Data obtained from the spectral analysis
performed at steps 56, 62 and 70 may be displayed at step 76 by way of the
display interface 42. Also, during operation of the monitored machine,
commands may be provided at step 76 to control the operation of the
monitored machine when the value of predetermined vibration data exceeds
the stored key frequency values. An override is provided at step 73 to
inhibit the transmission of alarm commands to the monitored machine during
predetermined user selected time periods.
The spectral analysis performed at steps 56, 62 and 70 employs a fast
Fourier transform algorithm to obtain a vibration signature from collected
vibration data generated by signals from the sensors 12 and 14. This is
accomplished by converting a real time domain signal and converting this
signal to a frequency domain to permit predictive vibration monitoring.
The fast Fourier transform algorithm is digitally controlled and permits
predetermined frequencies of the rotative elements of the monitored
machine to be isolated for analysis. In order to accurately perform
predictive vibration monitoring, the vibration signatures generated by the
fast Fourier transform algorithm are compared with the following: the
benchmark vibration signatures stored in the data memory 38; the key
frequency values for the rotative elements of the monitored machine which
are stored in the data memory; and previously obtained vibration
signatures. Turning to FIG. 3A, examples of the type of key frequencies
which are stored within the data memory 38 are outlined in block 80,
namely gas pulse frequencies and harmonics thereof, bearing frequencies,
and gear mesh frequencies, for example. The spectral analysis performed at
step 70 is utilized by the vibration monitoring system of the present
invention to perform fault detection at step 82. The fault detection is
accomplished by comparing the vibration signatures obtained during
operation of the monitored machine with any suitable output data, such as
that listed at step 84, or by comparing the vibration signatures with
severity trending at step 86. For example, if an unaccounted for frequency
rise occurs between two known gas pulse frequencies, a determination can
be made as to the cause of such a frequency rise, such as a failing
rotative component, for example.
While this invention has been illustrated and described in accordance with
a preferred embodiment, it is recognized that variations and changes may
be made therein without departing from the invention as set forth in the
following claims.
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