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Analytical Approaches to Evaluate Residual Cable Lifetime. Module 4. Dr. John H. Bickel Evergreen Safety & Reliability Technologies, LLC. Residual Cable Lifetime Assessment.
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Analytical Approaches to EvaluateResidual Cable Lifetime Module 4 Dr. John H. Bickel Evergreen Safety & Reliability Technologies, LLC
Residual Cable Lifetime Assessment • Objective is to conservatively demonstrate that should design bases accident occur at end of life conditions, critical equipment will function properly • Demonstration is based on Environmental Qualification program using qualification tests performed on “pre-aged” samples.
“Pre-Aging” • Environmental Qualification programs must simulate end of life aged components • Materials are “pre-aged” before running qualification tests (simulated LOCA tests) • Elevated temperature/irradiation burn-in tests used prior to qualification tests to simulate cable conditions at end of life.
Example EQ Qualification Test Envelope for US BWR Based on Design Basis LOCA
Cable Lifetime Assessments • Two predominant failure modes are typically considered: thermal, radiation • Arrhenius thermal aging model • Radiation aging via linear dose response model. • Both need to be considered.
Arrhenius Thermal Aging Model From probability theory, mean time to failure is given by: MTTF
Arrhenius Thermal Aging Model • Probability density function is assumed to be exponential: fτ(t) = 1/ τ exp (-t/ τ ) • With time to failure given by Arrhenius law: τ = k(T)-1 = [A exp (-Φ / kT)]-1 • Mean time to failure is simply: MTTF = τ = [A exp (-Φ / kT )]-1 k = 0.8617 x 10-4 eV / °K (Boltzmann’s constant) A, Φ = experimentally derived constants
Arrhenius Thermal Aging Model • Effects of aging in elevated temperature environment can be accelerated based on: MTTF1 = [A exp (-Φ / kT1 )]-1 MTTF2 = [A exp (-Φ / kT2 )]-1 • Computing the ratio of times to failure yields:
Arrhenius Thermal Aging Model • k = 0.8617 x 10-4 eV / °K (Boltzmann’s constant) • Φis an experimentally derived constant that can be obtained from tests of specific materials • Φis more commonly assumed at low value: 0.5eV when specific material test data is not available • Lower values of Φare conservative • Unjustified use of larger Φvalues can be major source of error
Comparison of Activation Energies • Plot below shows effect of Φ= 0.5 vs. 1.0 eV
Applications of Thermal Aging Model • It is desired to qualify electrical cable that will operate in a non-radiation environment at no hotter than 40°C (313.15 °K) for a 40 year lifetime (350,400 hours). • How long should a thermal qualification test run (at different temperatures) to demonstrate cable is qualified for such environment?
Applications of Thermal Aging Model • Based on operating experience temperatures have never exceeded 30°C (303.15 °K) • After 30 years of operation, it is desired to demonstrate that cable is capable of functioning for 30 more years (e.g. 60 years – or 525,600 hours) based on lower temperatures. • Is this justifiable?
Applications of Thermal Aging Model • MTTF2 = 350,400 hours at 40°C (313.15 °K) • Solving for MTTF1 at30°C (303.15 °K) yields: • MTTF1 = 645,700 hours vs. 525,600 hours • It is justifiable.
Radiation Aging Model • Linear Dose vs. Effects is assumed • Damage = Dose (Rads) x Time (hours) • Simulate effects of 40 year plant lifetime by use of higher qualification dose rates • t1 = (D2/D1) x t2 is used for scaling
Application of Radiation Aging Model • 40 year dose to equipment ~ 4.5 x 107 Rads ( or: 4.5 x 105 Gy) • To run accelerated aging test to cope with radiation effects, how large a dose is required?