Jurgensen, L.
view article (5.871002)
Smoke and Toxic Gas Suppressants for Upholstered Polyurethane Foam.
CIBA-GEIGY Corp., Hawthorne, NY
Business Communications Co., Inc. (BCC). Recent Advances in Flame Retardancy of Polymeric Materials: Materials, Applications, Industry Developments, Markets. Volume 2. May 14-16, 1991,
Business Communications Co., Inc., Norwalk, CT,
Stamford, CT,
Lewin, M.; Kirshenbaum, G. S., Editors,
335-336 p.,
1991
Holzbauer, C. J.
view article (5.871002)
Process Specification: Application of Foam-In-Place Polyurethane to High Voltage Devices.
TRW Systems Group, Inc., Redondo Beach, CA
National Aeronautics and Space Administration, Lewis Research Center, Cleveland, OH,
NASA CR-72098; TRW 06378-6007-R225,
April 1967,
10 p.
Grand, A. F.; Switzer, W. G.
view article (5.871002)
Effect of Oxygen Concentration on the Evolution of Toxic Gases From Douglas Fir, Rigid Polyurethane Foam and PVC. Final Report.
Southwest Research Inst., San Antonio, TX
National Institute of Standards and Technology, Gaithersburg, MD,
SwRI Project 01-3764; Final Report,
November 1991,
91 p.
Modern Plastics
view article (5.871002)
Urethane Foams Meet Their Challenges: Combustibility, Toxicity, Supplies.
Modern Plastics,
Vol. 52,
No. 6,
72-75,
June 1974
Wilde, D. G.
view article (5.871002)
Combustion of Rigid Polyurethane Foam inVentilated Ducts.
Safety in Mines Research Establishment, Buxton, England
Fire Research Abstracts and Reviews,
208-210,
August 1968
Gottuk, D. T.
view article (5.871002)
Generation of Carbon Monoxide in Compartment Fires. Annual Report. September 1991-September 1, 1992.
Virginia Polytechnic Institute and State Univ., Blacksburg, VA
National Institute of Standards and Technology, Gaithersburg, MD,
NIST GCR 92-619,
December 1992,
265 p.
Levin, B. C.; Braun, E.; Paabo, M.; Harris, R. H., Jr.; Navarro, M.
view article (5.871002)
Reduction of Hydrogen Cyanide Concentrations and Acute Inhalation Toxicity From Flexible Polyurethane Foam Combustion Products by the Addition of Copper Compounds. Part 4. Effects of Combustion Conditions and Scaling on the Generation of Hydrogen cyanide and Toxicity From Flexible Polyurethane Foam With and Without Copper Compounds.
National Institute of Standards and Technology, Gaithersburg, MD
International Copper Assoc., Ltd., New York; Society of the Plastics Industry, Inc., New York,
NISTIR 4989,
December 1992,
114 p.
Gallagher, J. A.
view article (5.871002)
Interliner Effect on the Fire Performance of Upholstery Materials.
Polymer Technologies, Inc., Detroit, MI
Journal of Fire Sciences,
Vol. 11,
No. 1,
87-105,
January/February 1993
Kitano, M.; Nagano, M.
view article (5.871002)
Smoldering Combustion of Polyurethane Foam Under Natural Convection Conditions.
Tohoku Univ., Miyagi, Japan; Toyota Motor Co., Aichi, Japan
Bulletin of Japanese Association of Fire Science and Engineering,
Vol. 41,
No. 2,
11-18,
1993
Vanspeybroeck, R.; VanHees, P.; Vandevelde, P.
view article (5.871002)
Combustion Behavior of Polyurethane Flexible Foams Under Cone Calorimetry Test Conditions.
Urethanes Polymers Research and Development, Terneuzen, The Netherlands; State University of Ghent, Belgium
Fire and Materials,
Vol. 17,
No. 4,
155-166,
July/August 1993