RMS-DC Converter 20	200	W₀= 50, LFD = 10 volts = 100%
RMS-DC Converter 24	500	W₁= 20, HFD = 10 volts = 100%
DC Converter
34	7	W₂= 1.414, CFD = 10 volts =
(ratio)		100%
DC Converter 40	50	W₃= 0.2, KFD = 10 volts = 100%
(ratio)
RMS-DC Converter 48	167	W₄= 60, EDD = 10 volts = 100%

As shown in FIG. 3, the discriminants HFD, CFD, KFD and EDD, stored in[0090]

memories

26,36,42 and50, are applied to an arithmetical unit53, which may be an adder or multiplier to provide BDF Sum (=BDFS) as shown in equation (5) or BDF Product (=BDFP) as shown in equation (6).

For BDFS, the sum of the four discriminants are modified by a factor, W[0091]₇, equal to ten times the reciprocal of the number n of discriminants summed (2.5 as shown) in unit53 or multiplied or by a factor W₈, which is {fraction (1/10)}n if the discriminants are multiplied as shown in equation (6), where n is the number of discriminants. The mounting factor W₅is a factor in both of equations (5) and (6). The result, in either mode of calculation in unit53, is applied to adisplay54 and/or55. These discriminants are combined as shown by either or both of equations (5) and (6) indexed to provide a zero to 100% display.

BDF(Sum)=100−[W1×HFD+W2×CFD+W3×KFD+W4×EDD][W5×W7] (5)

BDF(Product)=100−[(W1×HFD)(W2×CFD)(W3×KFD)(W4×EDD)][W5×W8] (6)

Where W[0092]₁-W₄are the weights assigned to voltage outputs of the converters by the

scalers

21,25,35,41 and49 as shown in Table I. W₅is the mounting coefficient. The mounting coefficient W₅has a range of 1.5 to 1.7 in increments of 0.1. If the machine mounting is rigid, W₅=1.5 TO 1.7 (default 1.6). The International Standards Organization states in ISO 10816-3:1998 that “The general effect on measured vibration levels for rigid vs. flexible supports for small to large size machines, pumps with multi-vane impellers, ranges from 0.6 to 0.64. That is measured vibration level for a given rigidly mounted machine may increase by a factor of 1.56 to 1.67 flexibly mounted.”

Both resulting BDF factors (sum and product) are scaled to BDF=100% for convenience in indexing 100-BDF from zero to 100 as shown in equations (5) and (6).[0093]

In Table I, the coefficient W[0094]₀is shown at a value (50) that occurs when W₆is zero.

Scalers

27 and21 are inversely related as shown by the broken line27a. Since it is chosen to have an output of ten volts at LFD for the worst case condition, the scaling coefficient W₀is decreased as W₆increases in accordance with the relation W₀=50-50(W₆). Thus, for a default value of 0.2 for W₆, W₀will be forty (40).

The bearing degradation factor as determined by equations (5) and (6) may be signified in several ways to indicate the condition of a bearing. It is preferred to provide an indication on a scale of 0-100%, where 80 to 100% indicates an optimum condition, 40 to 80% indicates a maintenance alert, 0 to 40% indicates probable failure is imminent and maintenance correction required.[0095]

Determination of and combining of the weighted discriminants to determine BDF provides a new and more accurate analysis of bearing condition with a significantly reduced probability of missing a call on a defective bearing.[0096]

In tests on thirty bearings known to have “moderate” (lightly scored) damage to the rolling elements or the inner or outer race, the following results were produced using each discriminant independently, and the BDF(sum) composite degradation factor to detect the fault.[0097]

HFD Eighty three percent (83%) showed abnormal readings[0098]

CFD Seventy eight percent (78%) showed abnormal ratio readings[0099]

KFD Seventy eight percent (78%) showed abnormal ratio readings[0100]

EDD Eighty three percent (83%) showed abnormal readings[0101]

In these tests, the probability of catching a fault, based on a single discriminant, varied from 0.78 to 0.83. Therefore the probability of missing a call on a moderately scored bearing, using only one discriminant, varies from seventeen to twenty two percent.[0102]

Using the multiple discriminant approach of the present invention BDF, and four discriminants, the mathematical probability of missing a call on a moderately scored bearing decreases to [0.17×0.22×0.22×0.17=0.0014] or 0.14%.[0103]

Assuming that only three discriminants (HFD, CFD and EDD) were utilized in determining BDF, the probability of missing a call is [0.17×0.22×0.17=0.00662] or 0.66%. This is still a significant improvement.[0104]

The test demonstrates that the probability of detecting a moderately damaged bearing has been improved significantly with the multiple discriminant approach without complex equipment, or need for a skilled practitioner.[0105]

Reference is made again to FIG. 3, which also illustrates the derivation of LEF from DFF and BDF. The DFF in[0106]

memory

28, which is shown in adisplay28a, is assigned a weight, W₉, in ascaler57 and the BDF, calculated in equation (5) or (6), is assigned a weight, W₁₀, in aselective scaler58.Scaler58 may select either BDFS or BDFP from unit53. The weighted values of DFF and BDF are summed in anarithmetical unit59 and the weighted sum is shown in adisplay60.

The LEF is the formulaic sum of the DFF and the BDF as follows:[0107]

LEF=[W₉×DFF+W₁₀×BDF] (7)

Where:[0108]

W[0109]₉=A weighting factor that apportions the contribution, and importance, of the DFF that may reduce expected life against the actual measure of bearing condition. A typical value might be in the range of 10 to 30%.

W[0110]₁₀=A weighting factor that balances the actual state of bearing degradation and need for possible prompt replacement action against the need for preventive life extending action. A typical value might be in the range of 70 to 90%.

The sum of W[0111]₉and W₁₀is always 1.0 or 100%. For most cases, at present time, the ratio of W₉=15% is preferred and is the default value for W₉.

Note that the value of LEF may be such that a value of 100% is optimum, and consistent with optimum displayed values of DFF and BDF. If DFF dropped to dangerously low levels, but the bearing had not begun to degrade, the LEF reading would decline modestly to perhaps 80%. A quick look at DFF and BDF would confirm that the cause was related to required balancing or alignment but no harm has yet been done to the bearing.[0112]

The LEF combines, in a formulaic manner, the DFF and BDF to provide a technically based assessment of the machine condition. When LEF is high (80 to 100%) the machine or facility is in optimum condition. When LEF drops to readings between 40 and 80% the next level DFF and BDF factors should be viewed.[0113]

The DFF and BDF provide “stand alone” reports on the status of those factors that contribute to shortened machine life and bearing operating condition state, respectively. The former provides guidance on inspection and maintenance action required for balancing or alignment or other such life affecting factors, and the latter, if heeded, provides highly reliable indicators of action required on bearing replacement. Mean, or distributive displays of this factor, may be used to informatively display the condition of a machine. Reference is now made to Table II, set forth below:[0114]

TABLE II


				ACTION	FAILURE
LEF	DFF	BDF	MEANING	REQUIRED	PROBABILTY

>80%	>80%	>80%	Equipment	None	Low
			Optimum
<80%	<80%	>80%	Minor Imbalance	Inspect	Slight Increase
<60%	<60%	>80%	Requires Balance/	Work Order	Slight Increase
			Align
<80%	>80%	<60%	Bearing	Lubrication	Moderate/
					Degrading
<40%	<40%	<40%	Bearing Near	Replace	High
			Failure	Bearing

Table II illustrates five different sample tests of the bearings on driven rotating machines utilizing the invention. In the first test, the LEF is above 80% indicating that both DFF and BDF are in an optimum range. No maintenance or service is required.[0115]

In the second test, a reading of less than 80% for LEF is observed. The practitioner then observes BDF and DFF and finds that DFF is less than the optimum range, that is <80%, while BDF is greater than 80%. In the case of a belt driven machine (assumed here for purposes of disclosure), this may indicate a minor imbalance or misalignment in the rotating drive. The practitioner will prepare a work order to inspect the drive and make whatever adjustment is necessary.[0116]

In the third test the LEF is found to be <60%, the DFF to be in the alert range of <60% while BDF is still in the optimum range of >80%. The low LEF indicates that immediate balance or alignment is necessary and a work order for repair will be prepared. In this case the BDF is still in the optimum range 80%, but the higher dynamic forces on the bearing indicate immediate attention to protect the LEF.[0117]

In the fourth test, the LEF is again low, upon further reference it is found that DFF is in the optimum range, >80%, but the BDF is low indicating that the bearing is degrading. The initial action will be to lubricate the bearing and recheck this machine at more frequent intervals.[0118]

In the fifth test it is found that the LEF is very low, <40%, indicating that both DFF and BDF are low. It is noted that DFF is less than 40% and BDF is less than 40%. This indicates that the bearing is in a condition having a high probability of failure and the dynamic forces on the bearing are contributing to bearing degradation. The machine will be taken out of service for bearing replacement and upon bearing replacement the drive for the machine will be balanced, realigned and otherwise serviced to minimize the dynamic forces and optimize life expectancy on the new bearing.[0119]

The indicia for determining DFF and BDF have been shown on a scale 0 to 100%. However, any other acceptable indicia for indicating these conditions may be utilized. A scale of 1 to 10 where the optimum condition is 0 to 2 may be utilized. In such case arithmetic unit[0120]53 would not be programmed to subtract the discriminants from one hundred as shown in equation (5).

Also as an illuminated bar graph that displayed a scale of 0 to 10 or 0 to 100%, where 100% represents optimum condition may be used for DFF, BDF and LEF. A simple color-coded bar graph with green, yellow and red to indicate Optimum, Reduced, or Action status may be utilized to indicate each of the factors.[0121]

FIGS. 5[0122]athrough5eillustrate sample touch screen displays of a possible handheld PC implementation of the instrument.

A user of the invention may utilize the LEF to determine the decline in expected bearing life and to predict the probability of a bearing failure. The optimum expected life of a bearing under given operating conditions is usually available from the bearing manufacturer or may be calculated from equation (3). The probability of failure, F(T), for a selected time period may be determined by the Weibull probability equation:[0123]

F(T)=[1−e−(t/θ)k] (8)

Where[0124]

t=the time evaluation period over which the probability of failure is to be estimated[0125]

θ=the estimated mean time between failure L[0126]₅₀=LEF when new Example: 100% LEF=50,000 hours=MTBF

K=2, generally used by bearing manufacturers[0127]

The reliability R(T) of a bearing may be determined by the companion (Weibull Survival) equation[0128]

R(T)=e−(t/θ)k (9)

where the terms have the same meaning as equation (8).[0129]

Assume that t=one year=8760 hours.[0130]

Then the probability of failure, at the time of installation, in the first year of operation is[0131]

F(T)=1−e^{−(8760/50000)2}=0.03 or 3% andR(T)=97% (10)

Assume that after one year of operation, LEF has dropped to 50% indicating that the manufacturer's expected life has been reduced to 50% of optimum or 25000 hours, and the probability of failure is sought within the next six months, then[0132]

F=1−e^{−(4380/25000)2}=0.03 or still 3% andR(T)=97% (11)

If the probability of failure after one year of operation and in the next year of operation is sought and there has been a decrease in LEF of 50%, then[0133]

F(T)=1−e^{−(8760/2500)2}=0.115 or 11.5% andR(T)=88.5% (12)

As hereinafter explained, the practitioner or user need only enter the information on the bearing manufacturer's optimum life expectancy and the time period under consideration into a system embodying the invention for the monitored machine. The processor of FIG. 4 performs the calculation of equations (8) or (9) and will display the F(T) or R(T) on a display screen.[0134]

A system embodying the invention includes a Weibull equation calculator[0135]63 for solving equation (8). Referring to FIG. 4, calculator63 receives a practitioner entered input indicated as t, the LEF fromunit59, FIG. 3, and will show ondisplay64 the probability of failure F or reliability R. Calculator63 will also display the remaining expected life LEF of the bearing under test if the practitioner inputs the expected life of the bearing into processor63.

A system embodying the invention may be embodied in a hand held multiple discriminant detector, analyzing and processing unit, referred to hereinafter as a processor, using a touch screen for display and entry of commands as will hereinafter be described.[0136]

The[0137]

system

10 will initially be constructed with certain coefficients preset in view of the specifications of the accelerometer and the number of discriminants to be derived for determining BDF. In the example set forth herein the

scalers

21,25,35,41 and49 will be manufacturer preset for the accelerometer as exemplified in Table I for the coefficients W₃-W₅. The coefficient W₆is set at the preferred or default value of 0.20 but the practitioner may vary this from zero (0) to one (1.0). W₉is set at a default value of 0.15 but the practitioner may vary this within the range previously stated. W₁₀is 1.00-W₉.

A multiple discriminant detector and analyzer[0138]70 (hereinafter “processor”) which includes all of the circuitry shown in FIGS.1-4 in a casing orhousing71 is shown in FIG. 5aand thetouch screen72 thereof in various modes in FIGS. 5b-5d. The processor70 is similar in size to a hand held computer and has many features in common therewith. The analyzer is battery operated and receives inputs fromaccelerometer11 over a cable L as shown in FIGS. 1 and 2. The processor will also supply operating power toaccelerometer11. The processor70, as shown in FIG. 5a, includes aconventional touch screen72 and a computer-like stylus activatedkeyboard73 for data input. Analyzer70 includes an output port represented by thearrow74 and an input port represented byarrow75 to receive input from a bar code reader which reads point identification on machines to be tested. When apower button76 is initially touched, the system is powered-up and the touch screen shown in FIG. 5bappears.

Processor[0139]70 includes amemory102 which stores all discriminants and factors as shown, which are readily available for read-out upon command.

As shown in FIG. 5[0140]b, three modes of operation are offered, Set-Up, Data Display and Review Stored Data onscreen72 together with

selection indicia

77,78 and79, respectively. The Set-Up mode is first discussed. It will be assumed that the user will want to initially set system parameters different than previous settings. Upon selection of Set-UP thescreen72 displays a set-up menu as shown in FIG. 5c.

The user may enter the date on[0141]

indicia

81 by means of the stylus-activatedkeyboard73. The user will then touch POINT ID,indicia82 to read the bar code or other identifying indicia on the machine to be tested. If the machine to be inspected is not identified by a bar code, the user may enter identifying nomenclature on thekeyboard73.

Other selection indicia are[0142]

FLEXIBLE

83 for a flexibly mounted machine, RIGID84 for a rigidly mounted machine,RPM85 to set the upper limit offilter19,W₆86 to set the percentage of HFD to be included in DFF,W₉87 to determine the percentage of DFF in LEF,W₁₀89 to enter the BDF for LEF, EXPECTEDLIFE90 to enter the remaining expected life of the bearing under investigation, andTIME PERIOD91 to enter the time period for which the probability failure or reliability is sought. The

indicia

84,85,86,87,89 and90 include drop down arrows for the user to select parameters if the user does want to set-up the default values.

Under the heading[0143]

DISPLAY

91, the user will select ON or OFF for the data that is to be displayed. Then, the user will touch SAVE SET-UP92 and then NXT to advance to the display screen shown in FIG. 5d. The DISCRIMINANT selections on the set up screen are hereinafter discussed.

The user will initially select[0144]

COLLECT DATA

94 on the display screen of FIG. 5dto commence detecting the data fromaccelerometer11. When the accelerometer signal V_ais analyzed the various derived factors, DFF, LEF and BDF are shown as displays in

colored bar graphs

95,96 and97 and the percentage DFF, LEF and BDF in

windows

98,99 and100, both respectively.

For the particular machine being inspected it is noted that BDF is in the optimum range, LEF is just below optimum and DFF is indicating unacceptable dynamic loading. This notifies the user that steps should immediately be taken to correct the unacceptable dynamic loading on the bearing.[0145]

After the user has made observation of the display screen he or she may touch[0146]

STORE

101 to forward the collected data to theprocessor memory102 shown in FIG. 6.Memory102 will store data from all previous tests on all bearings by machine identification and date as shown in FIG. 6, which may be called up to review the history of previous inspections as shown in FIGS. 5eand5fand determine any trends in bearing condition or dynamic loading.

While the invention has been disclosed as being implemented by analog techniques, as embodied in prototype form, for purposes of disclosure, the invention may be practiced using all digital technology receiving the acceleration signal V[0147]_aor by any combination of analog and digital technology.

The invention provides a new, improved and simplified technique of determining and indicating the present condition of rolling element bearings and the life expectancy thereof. The bearing data is determined by known and effective techniques which normally require sophisticated equipment and highly skilled practitioners but is communicated in a highly informative but simplified manner for observation and use by other than highly skilled personnel. The bearings of rotating machines may be periodically inspected and the results stored for later reference to determine if there is any LEF or BDF trends for particular machines or particular types or models of machines.[0148]

It may thus be seen that the objects of the invention set forth above, as well as those made apparent are efficiently attained. While preferred embodiments of the invention have been set forth for purposes of disclosure other embodiments of the invention may occur to those skilled in the art. Accordingly the appended claims are intended to cover all embodiments of the invention and modifications thereto which do not depart from the spirit and scope of the invention.[0149]