Theory of Quantity Value Traceability of Effective Apparent Power and Evaluation Method of Uncertainty

Theory of Quantity Value Traceability of Effective Apparent Power and Evaluation Method of Uncertainty

Apparent power and power factor are crucial metrics for evaluating the energy transmission efficiency and reactive power management in power systems. The increasing complexity of power load structures, driven by evolving energy production and consumption models, has intensified the nonlinear and unb...

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Hauptverfasser: Yi Luo, Jingfeng Yang, Fusheng Li, Bin Qian, Xiangyong Feng
Format: Artikel
Sprache:Englisch
Veröffentlicht: MDPI AG 2025-06-01
Schriftenreihe:Energies
Schlagworte:
effective apparent power
power factor
quantity value traceability
line loss
evaluation method of uncertainty
Online-Zugang:https://www.mdpi.com/1996-1073/18/12/3214
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Zusammenfassung:Apparent power and power factor are crucial metrics for evaluating the energy transmission efficiency and reactive power management in power systems. The increasing complexity of power load structures, driven by evolving energy production and consumption models, has intensified the nonlinear and unbalanced characteristics of circuits, presenting significant challenges to accurate apparent power measurement. The IEEE 1459-2010 standard introduces the concept of effective apparent power to enhance the assessment of energy transmission efficiency under non-sinusoidal and unbalanced conditions. However, the absence of a physical standard and a standardized traceability method for effective apparent power results in inconsistent measurement outcomes across instruments. This study proposes a novel method to trace effective apparent power measurements to the International System of Units (SI) benchmarks, based on the loss characteristics of transmission lines. The method includes a comprehensive analysis of measurement uncertainty. Simulation and experimental validation confirm that the proposed traceability circuit can achieve a measurement uncertainty of 0.0110% (coverage factor k = 2), satisfying the engineering requirement of expanded uncertainty <i>U</i> approximately 0.02% (k = 2). These results demonstrate the method’s practical suitability for engineering applications.
ISSN:1996-1073

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