DC arc flash calculations &amp;#x2014; Arc-in-open-air &amp;amp; arc-in-a-box &amp;#x2014; Using a simplified approach (Multiplication factor method)

Fontaine, Michael D.; Walsh, P. E. Peter

doi:10.1109/esw.2012.6165544

Cited by 16 publications

(2 citation statements)

References 6 publications

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“…Inspired by Ammerman's work, Fontaine [25] further extended Wilkins' iterative technique and more comprehensively presented the application of the Wilkins' a and k factors in determining the incident energy projected from enclosures. Wilkins' constants and the effective multipliers used to calculate the dc enclosure incident energy density E 1 from the dc open-air incident energy E s are provided in Table II for various worker distances. Wilkins used the 1584 data set (310 entries) and 37 additional tests performed at Ferraz Shawmut to develop formulas for predicting the ac arc current and incident energy density generated from a three-phase arcing fault.…”

Section: Ammerman's Work In DC Arc Modelingmentioning

confidence: 98%

A Review of Commonly Used DC Arc Models

Gammon¹,

Lee

Zhang

et al. 2015

IEEE Trans. on Ind. Applicat.

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The dc arc hazard is a great concern to industry. Quantitative arc hazard assessments are performed on dc systems to determine a nearby worker's potential incident energy exposure during an arcing event. Four viable dc assessment methods are reviewed in this paper. The most widely used model for predicting dc incident energy is based on Lee's theoretical arc model; the electrical arc power is determined from the maximum power transfer theorem, and the arc is depicted as a spherical radiant source with uniform heat transmission in all directions. Like Lee's model, Ammerman's model assumes complete conversion of electrical arc energy into thermal energy, but arc power is determined from an iterative technique constrained by arc power and circuit characteristics. Ammerman incorporates multiplying factors which account for the higher incident energies associated with arcing in enclosures. Based on dc arc testing, the applicability of an existing software package has been extended to dc systems through multiplying factors, and equations for dc rail and transit systems have also been developed. Model derivation is examined in this paper for suitability to arcing in general and dc specifically. Model performance is assessed using the available limited data (ac or dc). Example calculations are provided.Index Terms-Ammerman's model, arc flash hazard, dc arc model, dc transit systems, Ralph Lee model.

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Section: Ammerman's Work In DC Arc Modelingmentioning

confidence: 98%

A Review of Commonly Used DC Arc Models

Gammon¹,

Lee

Zhang

et al. 2015

IEEE Trans. on Ind. Applicat.

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“…To calculate the exposure from an arc flash (16), it is also assumed that all of the stored energy is converted to the radiant energy of the arc flash, and then spreads out over a spherical area…”

Section: Arc Flashmentioning

confidence: 99%

Safe Distances From a High-Energy Capacitor Bank for Ear and Lung Protection

Hammer¹,

Pearson²,

Porschet³

2014

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