Gas flow analysis in low energy arc puffer interrupters

Gas flow analysis in low energy arc puffer interrupters

Puffer interrupters, which use the gas blast produced by relative movement of a piston and a cylinder, are widely used due to their compact size, simple structure and excellent interruption properties. For puffer technology, the interruption capability depends on the interaction between arc, gas flo...

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Bibliographic Details
Published in:22nd International Conference and Exhibition on Electricity Distribution (CIRED 2013) p. 0410
Main Authors: Attar, E, Stoller, P, Schwinne, M, Skryten, P, Ranjan, N, Wuethrich, B, Bjørtuft, T.R, Granhaug, O
Format: Conference Proceeding
Language:English
Published: Stevenage, UK IET 2013
Subjects:
Applied fluid mechanics
Fluid mechanics and aerodynamics (mechanical engineering)
General fluid dynamics theory, simulation and other computational methods
Nozzles
Power and plant engineering (mechanical engineering)
Reliability
Switchgear
interruption properties
compact size
reliability
gas blast
current interruption
nozzle geometry
pressure build up
shapes (structures)
CFD simulations
interrupters
gas flow analysis
leakage rate
computational fluid dynamics
piston
arcing zone
CFD modeling
pistons
puffer technology
puffer breaker
nozzle material
puffer design
low-energy arc puffer interrupters
gas blast circuit breakers
cylinder
interruption capability
nozzles
medium-voltage load currents
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Summary:Puffer interrupters, which use the gas blast produced by relative movement of a piston and a cylinder, are widely used due to their compact size, simple structure and excellent interruption properties. For puffer technology, the interruption capability depends on the interaction between arc, gas flow, pressure build up, nozzle material and geometry. The interrupter is divided into two main compartments with the same initial pressure. During arc interruption, the gas in the arcing zone is heated resulting in higher pressure. The pressurized gas from the other compartment blasts into the arcing zone and helps to extinguish the arc. Puffer design plays an important role in determining puffer pressure build up. In this paper computational fluid dynamics (CFD) simulations are used in order to understand the complex phenomena inside puffer interrupters during switching of medium voltage load currents. Two different nozzle geometries have been investigated using CFD modeling. In order to validate the simulation results, experiments have been conducted in a high power laboratory and compared with simulation. Understanding the gas flow and pressure build up during current interruption helps to develop a puffer interrupter that provides higher performance with better reliability in a more compact size. Optimizing the nozzle geometry and controlling the leakage rate inside the puffer breaker result in higher pressure build up and better interruption performance. (4 pages)
ISBN:1849197326
9781849197328
DOI:10.1049/cp.2013.0717