Hydrogen-Steam Jet-Flame Facility and Experiments (NUREG/CR-3638, SAND84-0060)

On this page:

Download complete document

Publication Information

Manuscript Completed: October 1984
Date Published
: May 1985

Prepared by:
Joseph E. Shepherd
Fluid Mechanics and Heat Transfer
Division 1512
Sandia National Laboratories
Albuquerque. New Mexico 87185
Operated by Sandia Corporation
for the U.S. Department of Energy
Under Contract No. DE-AC04-76DP00789

Prepared for:
Division of Engineering Technology
and Division of Accident Evaluation
Office of Nuclear Regulatory Research
U.S. Nuclear Regulatory Commission
Washington. DC 20555-0001

Under Memorandum of Understanding DOE-40-550-75

NRC FIN A-1246, A-1336

Availability Notice


This report provides results from an in-depth analysis of twenty-one of the twenty-four premixed large-scale combustion experiments sponsored by the U. S. Nuclear Regulatory Commission (NRC) and the Electric Power Research Institute (EPRI) and conducted by EG&G at the Nevada Test Site (NTS). These experiments were performed in a 2048 cubic meter spherical vessel (hydrogen dewar) with mixtures of hydrogen, steam, and air ignited by glow plugs or heated resistance coils. Hydrogen concentrations ranged from 5 to 13% (by volume) and steam concentrations from 4 to 40%. Several tests also incorporated spray systems and/or fans which enhanced the combustion rate and significantly altered the postcombustion gas cooling.

In this work, data provided by EPRI from instrumentation designed to characterize the tlhermal environment in the dewar during and following combustion have been evaluated. The data reduction package SMOKE has been used to process data from thin-film gauges, Gardon and Schmidt-Boelter heat flux gauges, capacitance calorimeters, gas and wall thermocouples, and pressure sensors. Local measurements of the heat transfer are provided from the calorimetry, and global averages are inferred from the pressure. Instrumentation "goodness" for each test is assessed based on the raw data and on comparisons-of local and global results. Graphical and tabular results are provided for each test, and trends observed from the results are reported. This information should be useful for benchmarking existing computer codes used in modeling nuclear containment and associated safety-related equipment response to degraded-core accidents and for improving combustion and heat transfer models currently used in these computer simulations.

Page Last Reviewed/Updated Thursday, March 25, 2021