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Automated control of a cooling system cooling at least one electronic component is provided. The control includes monitoring over a period of time variation of an operational variable of the cooling system or of the at least one electronic component, and based, at least in part, on variation of the

Automated control of a cooling system cooling at least one electronic component is provided. The control includes monitoring over a period of time variation of an operational variable of the cooling system or of the at least one electronic component, and based, at least in part, on variation of the operational variable over the period of time, automatically determining whether to adjust control of the cooling system to limit variation of the operational variable. In one implementation, depending on the variation of the operational variable, and whether control of the cooling system has been previously adjusted, the method may further include automatically determining a probability of fail or an expected residual life of the cooling system, and responsive to the predicted probability of fail exceeding a first acceptable threshold or the expected residual life being below a second acceptable threshold, automatically scheduling for a cooling system repair or replacement.

대표청구항 ▼

1. A method of operating a cooling system cooling at least one component, the method comprising; monitoring over a period of time variation of an operational variable of the cooling system or of the at least one component cooled by the cooling system;based, at least in part, on the variation of the

1. A method of operating a cooling system cooling at least one component, the method comprising; monitoring over a period of time variation of an operational variable of the cooling system or of the at least one component cooled by the cooling system;based, at least in part, on the variation of the operational variable over the period of time, determining whether to adjust control of the cooling system to limit the variation of the operational variable; anddetermining, from the variation of the operational variable over the period of time, an oscillation metric representative of the variation of the operational variable over the period of time, and wherein the determining whether to adjust control of the cooling system comprises determining whether the oscillation metric exceeds a set threshold, and based on the oscillation metric exceeding the set threshold, the method further comprises adjusting at least one control parameter of the cooling system to, at least in part, reduce the oscillation metric. 2. The method of claim 1, wherein the monitoring comprises obtaining a set of data representative of the variation of the operational variable over the period of time, and determining the oscillation metric comprises, at least in part, summing multiple operational variable changes within the set of data to obtain a time-period-based metric representative of the variation of the operational variable over the period of time, and further deriving from multiple time-period-based metrics the oscillation metric. 3. The method of claim 1, wherein the cooling system comprises a proportional-integral-derivative control and the adjusting at least one control parameter comprises automatically adjusting at least one of a proportional gain, an integral gain, or a derivative gain of the proportional-integral-derivative control to, at least in part, reduce the oscillation metric. 4. A method of operating a cooling system cooling at least one component, the method comprising; monitoring over a period of time variation of an operational variable of the cooling system or of the at least one component cooled by the cooling system;based, at least in part, on the variation of the operational variable over the period of time, determining whether to adjust control of the cooling system to limit the variation of the operational variable; andwherein the cooling system cools multiple components, and comprises multiple cooling loops, each cooling loop of the multiple cooling loops cooling at least one respective component of the multiple components, and wherein the monitoring comprises, for each cooling loop, monitoring over the period of time variation of the operational variable associated with that cooling loop or the at least one respective component cooled by that cooling loop, and based, at least in part, on the variation of the operational variable over the period of time, determining for each cooling loop whether to adjust control of that cooling loop to limit the variation of the operational variable. 5. The method of claim 4, wherein the cooling system comprises a refrigeration unit, and the operational variable comprises an operational temperature associated with the cooling loop or the at least one respective component cooled by that cooling loop, and wherein the method further comprises adjusting control of the refrigeration unit to, at least in part, limit the variation of the operational variable, the adjusting control comprising automatically adjusting control of an electronic expansion valve of the refrigeration unit. 6. The method of claim 1, wherein the determining further comprises ascertaining that variation of the operational variable over the period of time is excessive, and that control of the cooling system has been previously adjusted to limit the variation of the operational variable over the period of time, and based thereon, determining a probability of fail for at least one element of the cooling system or an expected residual life of at least one element of the cooling system, and depending on the probability of fail exceeding a first acceptable threshold or the expected residual life being below a second acceptable threshold, automatically signaling for a repair or replacement of at least a portion of the cooling system. 7. A method of operating a cooling system cooling at least one component, the method comprising: monitoring over a period of time variation of an operational variable of the cooling system or of the at least one component cooled by the cooling system;based, at least in part, on the variation of the operational variable over the period of time, determining whether to adjust control of the cooling system to limit the variation of the operational variable; andpredicting probability of fail of at least one element of the cooling system or determining an expected residual life of at least one element of the cooling system, and responsive to the predicted probability of fail exceeding a first acceptable threshold, or the expected residual life being below a second acceptable threshold, automatically signaling for repair or replacement of at least a portion of the cooling system. 8. The method of claim 7, wherein the cooling system comprises a refrigeration unit and the predicting probability of fail or determining expected residual life comprises performing at least one of Weibull analysis on a compressor of the refrigeration unit or log-normal analysis on an electronic expansion valve of the refrigeration unit. 9. The method of claim 8, wherein setting T to be life of the refrigeration unit, and the underlying distribution to be log-normal with covariates, then the predicting probability of fail after an extra δT is determined by: P⁡(X≤T+δ⁢⁢T❘X>T)=1-Φ(-ln⁡(T+δ⁢⁢T)+(μ+∑i=1n⁢αi⁢γi)σ)Φ(-ln⁢⁢T+(μ+∑i=1n⁢αi⁢γi)σ), where: Φ is the normal cumulative distribution function;μ is the location parameter;σ is the scale parameter; andγi and αi, i=1 . . . n are covariates and their covariates coefficients, respectively. 10. The method of claim 8, wherein setting T to be life of the refrigeration unit and the underlying distribution to be Weibull with covariates, then predicting probability of fail employs: P⁡(X≤T+δ⁢⁢T❘X>T)=1-exp⁡(-{(T+δ⁢⁢Tβ*)c-(Tβ*)c}), where: c is the shape parameter;β is the scale parameter;β=βexp(Σi=1nαiγi); andγi and αi, r=1 . . . n are covariates and their covariates coefficients, respectively. 11. The method of claim 8, wherein setting the refrigeration unit to be of age, T, and the underlying distribution to be log-normal with covariates, then determining the expected residual life is determined by: E⁡(X❘T)=exp⁡(μ+∑i=1n⁢∝i⁢yi+σ22)⁢Φ(-ln⁢⁢T+(μ+∑i=1n⁢∝i⁢yi)+σ2σ)Φ(-ln⁢⁢T+(μ+∑i=1n⁢∝i⁢yi)σ)-T, where: Φ is the normal cumulative distribution function;μ is the location parameter;σ is the scale parameter; andγi and ∝i, i=1 . . . n are covariates and their covariates coefficients, respectively. 12. The method of claim 8, wherein setting T to be the age of the refrigeration unit, and the underlying distribution to be Weibull with covariates, then determining the expected residual life employs: E⁡(X❘T)=β*⁢Γ⁡[1c+1]⁢exp⁡((Tβ*)c)⁢(1-FGamma⁡(1c+1,1)⁡[(Tβ*)c])-T, where: c is the shape parameter;β is the scale parameter;β*=βexp(Σi=1nαiγi);Γ is the Gamma function;γi and αi, i=1 . . . n are covariates and their covariates coefficients, respectively; andF is the cdf of Gamma distribution with α=1c+1 and β=1.