Revealing the inner secrets of intumescence: Advanced standard time temperature oven (STT Mufu+)—μ‐computed tomography approach (English)
- New search for: Morys, Michael
- New search for: Morys, Michael
- New search for: Illerhaus, Bernhard
- New search for: Sturm, Heinz
- New search for: Schartel, Bernhard
In:
Fire and materials
;
41
, 8
; 927-939
;
2017
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ISSN:
- Article (Journal) / Print
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Title:Revealing the inner secrets of intumescence: Advanced standard time temperature oven (STT Mufu+)—μ‐computed tomography approach
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Contributors:
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Published in:Fire and materials ; 41, 8 ; 927-939
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Publisher:
- New search for: Heyden
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Place of publication:London
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Publication date:2017
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ISSN:
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ZDBID:
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DOI:
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Type of media:Article (Journal)
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Type of material:Print
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Language:English
- New search for: 51.00 / 56.55 / 56.55 / 51.00
- Further information on Basic classification
- New search for: 275/6650
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Keywords:Tomography , Coatings , residue analysis , Computer aided tomography , Steel , Furnaces , Scanning electron microscopy , Computation , standard time temperature furnace , Endoscopes , computed tomography , Case studies , Protective coatings , Foaming , Mechanical testing , Intumescent , Flammability , Electron microscopy , intumescence , Test procedures , Temperature effects , Reproducibility , Thermal insulation , Fire protection , Mechanical properties , bench‐scale fire testing , fire resistance , Computed tomography
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Classification:
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Source:
Table of contents – Volume 41, Issue 8
The tables of contents are generated automatically and are based on the data records of the individual contributions available in the index of the TIB portal. The display of the Tables of Contents may therefore be incomplete.
- 925
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Issue information| 2017
- 927
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Revealing the inner secrets of intumescence: Advanced standard time temperature oven (STT Mufu+)—μ‐computed tomography approachMorys, Michael et al. | 2017
- 940
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Development of a screening test based on isothermal calorimetry for determination of self‐heating potential of biomass pelletsLarsson, Ida et al. | 2017
- 953
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An exploration of enhancing thermal protective clothing performance by incorporating aerogel and phase change materialsZhang, Hui et al. | 2017
- 964
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Improvement of the flame retardancy of plasticized poly(lactic acid) by means of phosphorus‐based flame retardant fillersYemisci, Fatma et al. | 2017
- 973
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Preparation and studies of new phosphorus‐containing diols as potential flame retardantsWang, Kui et al. | 2017
- 983
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Study of using aluminum hypophosphite as a flame retardant for low‐density polyethyleneTian, Shenghui et al. | 2017
- 993
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Poly(vinyl chloride) and its fire propertiesHirschler, Marcelo M et al. | 2017
- 1007
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Measurement of self‐heating potential of biomass pellets with isothermal calorimetryLarsson, Ida et al. | 2017
- 1016
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Crack evolution process of window glass under radiant heatingChen, Haodong et al. | 2017
- 1027
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Study on different finite difference methods at skin interface for burn prediction in protective clothing evaluationZhai, L et al. | 2017
- 1040
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Tensile properties of plant fibre‐polymer composites in fireBhat, T et al. | 2017
- 1051
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Thermal degradation and fire performance of wood treated with PMUF resin and boron compoundsWang, Fei et al. | 2017
- 1058
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Procedures for development and revision of codes and standards associated with fire safety in the USAHirschler, Marcelo M et al. | 2017
- 1072
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Characterization of arc beads on energized conductors exposed to radiant heatIwashita, Tomoyasu et al. | 2017