Degradation model and maintenance strategy of the electrolytic capacitors for electronics applications

Zhou, Yinggang; Ye, Xuerong; Zhai, Guofu

doi:10.1109/phm.2011.5939474

Cited by 12 publications

(1 citation statement)

References 6 publications

(7 reference statements)

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“…In the case of capacitors, it is found that the TCCDM is subject to the Arrhenius model between 339 K and 399 K (Figure 6 in [32]), is linear between 253 K and 333 K (Figure 12 in [33]), and exponential between 293 K and 353 K (Figure 7 in [34]). In other words, the Arrhenius model is only applicable within specific temperature ranges, whereas the relationship between the degradation parameter and temperature (i.e., the degradation rate) takes different shapes over different temperature ranges.…”

Section: Discussionmentioning

confidence: 99%

A Non-Arrhenius Model for Mechanism Consistency Checking in Accelerated Degradation Tests

You

Liang

et al. 2023

Actuators

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Degradation models are central to the lifetime prediction of electromagnetic relays. Coefficients of degradation models under accelerated degradation test (ADTs) can be obtained experimentally, and it is customary to map these coefficients back to those describing the actual degradation by the so-called Arrhenius model. However, for some components, such as springs in electromagnetic relays, the Arrhenius model is only appropriate over a certain ADT temperature range, which implies inaccurate mapping outside that range. On this point, an error function model (EFM) is proposed to overcome the shortcomings of the Arrhenius model. EFM is derived from the average vibration energy of the crystal, which is further related to temperature alongside some constants. The empirical part of the paper compares the proposed EFM to the Arrhenius model for the ADT of 28-V–2-A electromagnetic relays. The results show that EFM is superior in describing the temperature characteristics of coefficients in the degradation model. Through mechanism consistency checking, EFM is also shown to be a better option than the Arrhenius model. Moving beyond the case of electromagnetic relays, EFM is thought to have better applicability in the degradation models of capacitors and rubbers.

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Section: Discussionmentioning

confidence: 99%

A Non-Arrhenius Model for Mechanism Consistency Checking in Accelerated Degradation Tests

You

Liang

et al. 2023

Actuators

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A reliability prediction method considering degradation self-acceleration effect in DC-link electrolytic capacitor

Ye,

Sun,

Lin

et al. 2023

Quality Engineering

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A novel online ESR and C identification method for output capacitor of buck converter

Yao

Zhou

et al. 2014

2014 IEEE Energy Conversion Congress and Exposition (ECCE)

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As electrolytic capacitor is apt to fail in power circuits, it is very important to monitor its electrical parameters, mainly the equivalent series resistance (ESR) and capacitance (C). A novel non-invasive online monitoring method of capacitor's ESR and C for CCM buck converter is proposed in this paper. Based on the ac component of capacitor voltage, the calculation model is founded. By sampling the PWM signal and output voltage, the method needs no current sensor and is effective for the CCM buck converter operating at different conditions. Implementation of the monitoring system is presented. The experimental results validate the effectiveness of the method.

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Degradation model and maintenance strategy of the electrolytic capacitors for electronics applications

Cited by 12 publications

References 6 publications

A Non-Arrhenius Model for Mechanism Consistency Checking in Accelerated Degradation Tests

A Non-Arrhenius Model for Mechanism Consistency Checking in Accelerated Degradation Tests

A reliability prediction method considering degradation self-acceleration effect in DC-link electrolytic capacitor

A novel online ESR and C identification method for output capacitor of buck converter

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