Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
Shopping Cart: ( empty )
You are here: Home > Journals > WF > WF08128
RESEARCH ARTICLE
Contents Vol 18(6)

A model for calculating the temperature of aluminium particles ejected from overhead low-voltage lines owing to a short-circuit

E. G. Psarros A B , A. D. Polykrati A , C. G. Karagiannopoulos A and P. D. Bourkas A
+ Author Affiliations
- Author Affiliations

A Department of Electrical and Computer Engineering, Division of Electric Industrial Devices & Decision Systems, High Voltage and Electrical Measurements Laboratory, National Technical University of Athens, 9 Iroon Polytechneiou Str, Zografou, 15780 Athens, Greece.

B Corresponding author. Email: lpsarros@central.ntua.gr

International Journal of Wildland Fire 18(6) 722-726 https://doi.org/10.1071/WF08128
Submitted: 16 July 2008  Accepted: 26 September 2008   Published: 22 September 2009

Abstract

Wildfires, which are uncontrolled fires spreading readily over vast areas, are usually the result of human negligence, arson or lightning. There are cases of fires close to electrical distribution lines for which the network has been blamed. In the present paper, the risk of a wildfire breaking out owing to the temperature of molten metal particles that are possibly created on bare conductors of low-voltage networks in short-circuit faults (unless they are interrupted by the protection systems) is examined. Thus, a mathematical model is proposed for the estimated temperature rise of those molten metal particles ejected from bare conductors of low-voltage overhead lines. Moreover, this model can be applied to medium- or high-voltage networks. The model takes into account the weather conditions and particles’ height above the ground. Further, an arithmetic example for an incandescent particle ejected from aluminium conductors of a low-voltage network is given. According to this example, there is no risk of dead leaves or wood catching fire owing to this particle.


References


Bourkas PD (2004) ‘Applications of Industrial and Buildings Installations.’ (NTUA Editions: Athens)

Bourkas PD, Karagiannopoulos CG (2004) ‘Measurements on Industrial Apparatus and Materials.’ (NTUA Editions: Athens)

Bourkas PD, Karagiannopoulos CG, Tsarabaris PT (2008) Experimental investigation of short-circuit condition in low-voltage distribution networks. In ‘IASTED International Conference on Power & Energy Systems 8’, 23–25 June 2008. pp. 297–302. (IASTED ACTA Press: Anaheim, Calgary, AB, Canada)

K & K Associates (2000) ‘Thermal Network Modeling Handbook.’ (K & K Associates: Westminster, CO, USA)

Kreith F, Bohn MS (1965) ‘Principles of Heat Transfer.’ (International Textbook Company: Scranton, PA, USA)

Mills AF , Hang X (1984) Trajectories of sparks from arcing aluminium power cables. Fire Technology  20, 5–14.
Crossref | GoogleScholarGoogle Scholar | Naidu MS, Kamaraju V (1995) ‘High Voltage Engineering.’ (McGraw Hill: New York)

Public Power Corporation (1988) ‘Specification No. 22.’(Public Power Corporation: Athens)

Quintiere JG (1998) ‘Principles of Fire Behavior.’ (Delmar Publishers: New York)

Rallis CJ , Mangaya BM (2002) Ignition of veld grass by hot aluminium particles ejected from clashing overhead transmission lines. Fire Technology  38, 81–92.
Crossref | GoogleScholarGoogle Scholar | Towsend JS (1914) ‘Electricity in Gases.’ (Clarendon Press: Oxford, UK)