Bio-Based Polyurethane Foams from Kraft Lignin with Improved Fire Resistance
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[1] D. Evtuguin,et al. Development of Rigid Polyurethane Foams Based on Kraft Lignin Polyol Obtained by Oxyalkylation Using Propylene Carbonate , 2022, ChemEngineering.
[2] S. Magina,et al. Polyurethane Adhesives Based on Oxyalkylated Kraft Lignin , 2022, Polymers.
[3] Qinqin Zhang,et al. Effect of bio-based polyols and chain extender on the microphase separation structure, mechanical properties and morphology of rigid polyurethane foams , 2022, European Polymer Journal.
[4] A. Sabnis,et al. Polyurethane foams from vegetable oil-based polyols: a review , 2022, Polymer Bulletin.
[5] D. Evtuguin,et al. Oxyalkylation of Lignoboost™ Kraft Lignin with Propylene Carbonate: Design of Experiments towards Synthesis Optimization , 2022, Materials.
[6] Wei Wu,et al. A review of microphase separation of polyurethane: Characterization and applications , 2022, Polymer Testing.
[7] M. Garrido,et al. Mechanical behaviour in shear and compression of polyurethane foam at elevated temperature , 2021, Journal of Sandwich Structures & Materials.
[8] X. Qiu,et al. Pristine lignin as a flame retardant in flexible PU foam , 2021, Green Chemistry.
[9] L. Avérous,et al. Structure-properties relationships of cellular materials from biobased polyurethane foams , 2021, Materials Science and Engineering: R: Reports.
[10] A. Rodrigues,et al. Valorization of Lignin Side-Streams into Polyols and Rigid Polyurethane Foams—A Contribution to the Pulp and Paper Industry Biorefinery , 2021, Energies.
[11] Darren J. Martin,et al. Dispersion Methodology for Technical Lignin into Polyester Polyol for High-Performance Polyurethane Insulation Foam , 2021 .
[12] J. Firmo,et al. Mechanical behaviour in shear and compression at elevated temperature of polyethylene terephthalate (PET) foam , 2021 .
[13] R. Frischer,et al. Case Study on Fire Resistance of Sandwiches for Means of Transport , 2021, Coatings.
[14] Shan Jiang,et al. Biobased foams for thermal insulation: material selection, processing, modelling, and performance , 2021, RSC advances.
[15] Ming He,et al. Highly Efficient, Environmentally Friendly Lignin-Based Flame Retardant Used in Epoxy Resin , 2020, ACS omega.
[16] L. Lucia,et al. Insights into the Potential of Hardwood Kraft Lignin to Be a Green Platform Material for Emergence of the Biorefinery , 2020, Polymers.
[17] L. Avérous,et al. Biobased Polyurethane Foams Based on New Polyol Architectures from Microalgae Oil , 2020, ACS Sustainable Chemistry & Engineering.
[18] D. Evtuguin,et al. Effect of different catalysts on the oxyalkylation of eucalyptus Lignoboost® kraft lignin , 2020 .
[19] Wenjing Guo,et al. Effect of incorporation of lignin as bio-polyol on the performance of rigid lightweight wood–polyurethane composite foams , 2020, Journal of Wood Science.
[20] U. Cabulis,et al. High Functionality Bio-Polyols from Tall Oil and Rigid Polyurethane Foams Formulated Solely Using Bio-Polyols , 2020, Materials.
[21] G. Mir Mohamad Sadeghi,et al. Soundproofing flexible polyurethane foams: Effect of chemical structure of chain extenders on micro-phase separation and acoustic damping , 2020, Journal of Cellular Plastics.
[22] A. Białkowska,et al. Physical blowing agents for polyurethanes , 2020, Polimery.
[23] Xuefeng Zhang,et al. Rigid polyurethane foams containing lignin oxyalkylated with ethylene carbonate and polyethylene glycol , 2019, Industrial Crops and Products.
[24] S. Bajwa,et al. A concise review of current lignin production, applications, products and their environmental impact , 2019, Industrial Crops and Products.
[25] J. L. Ruiz-Herrero,et al. Long‐term thermal conductivity of cyclopentane–water blown rigid polyurethane foams reinforced with different types of fillers , 2019, Polymer International.
[26] S. Singh,et al. Lignin-Based Polyurethanes: Opportunities for Bio-Based Foams, Elastomers, Coatings and Adhesives , 2019, Polymers.
[27] E. Fosso-Kankeu,et al. Rigid polyurethane foams from unrefined crude glycerol and technical lignins , 2018, Polymers from Renewable Resources.
[28] Ana Barros-Timmons,et al. Polyurethane Foams: Past, Present, and Future , 2018, Materials.
[29] Mijung Cho,et al. Uniform Chemical Functionality of Technical Lignin Using Ethylene Carbonate for Hydroxyethylation and Subsequent Greener Esterification , 2018, ACS Sustainable Chemistry & Engineering.
[30] Rui F. Silva,et al. Enhancement of physical and reaction to fire properties of crude glycerol polyurethane foams filled with expanded graphite , 2018, Polymer Testing.
[31] A. Puszka. Thermal and Mechanical Behavior of New Transparent Thermoplastic Polyurethane Elastomers Derived from Cycloaliphatic Diisocyanate , 2018, Polymers.
[32] G. Malucelli,et al. An Overview on the Use of Lignin and Its Derivatives in Fire Retardant Polymer Systems , 2018 .
[33] A. Puszka,et al. The influence of soft segments on some properties of new transparent segmented polyurethanes , 2017 .
[34] Rui F. Silva,et al. Sound absorption properties of polyurethane foams derived from crude glycerol and liquefied coffee grounds polyol , 2017 .
[35] L. Avérous,et al. Cyclic Carbonates as Safe and Versatile Etherifying Reagents for the Functionalization of Lignins and Tannins , 2017 .
[36] P. Dubois,et al. Bio-based flame retardants: When nature meets fire protection , 2017 .
[37] Omar Y. Abdelaziz,et al. Physicochemical Characterisation of Technical Lignins for Their Potential Valorisation , 2017 .
[38] W. Tao,et al. Experimental study of the thermal conductivity of polyurethane foams , 2017 .
[39] Rui F. Silva,et al. Statistical evaluation of the effect of formulation on the properties of crude glycerol polyurethane foams , 2016 .
[40] L. Avérous,et al. Advanced biobased and rigid foams, based on urethane-modified isocyanurate from oxypropylated gambier tannin polyol , 2016 .
[41] T. R. Hull,et al. The fire toxicity of polyurethane foams , 2016 .
[42] Sanghamitra Sen,et al. Thermal properties of lignin in copolymers, blends, and composites: a review , 2015 .
[43] Xiaolan Luo,et al. Bio-based Polyols and Polyurethanes , 2015 .
[44] Rui F. Silva,et al. Bio-based polyurethane foams toward applications beyond thermal insulation , 2015 .
[45] B. Saake,et al. Synthesis of lignin polyols via oxyalkylation with propylene carbonate , 2015 .
[46] Darren J. Martin,et al. A systematic study substituting polyether polyol with palm kernel oil based polyester polyol in rigid polyurethane foam , 2015 .
[47] Thomas Keller,et al. Effects of elevated temperature on the shear response of PET and PUR foams used in composite sandwich panels , 2015 .
[48] A. Avots,et al. Rigid Polyurethane Foam Thermal Insulation Protected with Mineral Intumescent Mat , 2014 .
[49] N. Yan,et al. Polyurethane foams made from liquefied bark‐based polyols , 2014 .
[50] Gerald A. Tuskan,et al. Lignin Valorization: Improving Lignin Processing in the Biorefinery , 2014, Science.
[51] A. Rodrigues,et al. Lignin-based rigid polyurethane foams with improved biodegradation , 2014 .
[52] D. Argyropoulos,et al. Kraft lignin chain extension chemistry via propargylation, oxidative coupling, and Claisen rearrangement. , 2013, Biomacromolecules.
[53] D. Argyropoulos,et al. Toward Thermoplastic Lignin Polymers; Part II: Thermal & Polymer Characteristics of Kraft Lignin & Derivatives , 2013 .
[54] Youmin Yu,et al. Functionalized lignin by grafting phosphorus-nitrogen improves the thermal stability and flame retardancy of polypropylene , 2012 .
[55] C. Macosko,et al. Rigid polyurethane foams from a soybean oil-based Polyol , 2011 .
[56] Fabrice Saint-Michel,et al. Mechanical properties of high density polyurethane foams: I. Effect of the density , 2006 .
[57] T. Hatakeyama,et al. Bio-based polyurethane composite foams with inorganic fillers studied by thermogravimetry , 2005 .
[58] Shau‐Tarng Lee,et al. Polymeric Foams : Mechanisms and Materials , 2004 .
[59] W. Kim,et al. Properties of Rigid Polyurethane Foams with Blowing Agents and Catalysts , 2004 .
[60] Hyunchul Jung,et al. Mechanical, morphological, and thermal properties of rigid polyurethane foams blown by distilled water , 2003 .
[61] Hyunchul Jung,et al. Properties of rigid polyurethane foams blown by HCFC 141B and distilled water , 2001 .
[62] D. Evtuguin,et al. Polyurethanes based on oxygen-organosolv lignin , 1998 .
[63] S. Goods,et al. Mechanical properties of a structural polyurethane foam and the effect of particulate loading , 1998 .
[64] ガブリエリ,フランコ,et al. Rigid polyurethane foam , 1997 .
[65] Hong-Ru Lin,et al. The structure and property relationships of commercial foamed plastics , 1997 .
[66] J. Grimminger,et al. Silicone Surfactants for Pentane Blown Rigid Foam , 1993 .
[67] S. Gustafsson. Transient plane source techniques for thermal conductivity and thermal diffusivity measurements of solid materials , 1991 .
[68] E. Barrett,et al. The Determination of Pore Volume and Area Distributions in Porous Substances. II. Comparison between Nitrogen Isotherm and Mercury Porosimeter Methods , 1951 .
[69] L. Avérous,et al. Scalable single-step synthesis of lignin-based liquid polyols with ethylene carbonate for polyurethane foams , 2022, Materials Today Chemistry.
[70] M. Barreiro,et al. Synthesis of thermal insulating polyurethane foams from lignin and rapeseed based polyols: A comparative study , 2020 .
[71] Kushairi Mohd Salleh,et al. Polyols and rigid polyurethane foams derived from liquefied lignocellulosic and cellulosic biomass , 2019, Cellulose.
[72] S. Amornraksa,et al. Development of Rigid Polyurethane Foam (RPUF) for Imitation Wood Blown by Distilled Water and Cyclopentane (CP) , 2018 .
[73] A. Hejna,et al. The influence of crude glycerol and castor oil-based polyol on the structure and performance of rigid polyurethane-polyisocyanurate foams , 2017 .
[74] Xiaolan Luo,et al. Lignocellulosic Biomass-Based Polyols for Polyurethane Applications , 2015 .
[75] S. Choi,et al. Effects of silicone surfactant on the cell size and thermal conductivity of rigid polyurethane foams by environmentally friendly blowing agents , 2009 .
[76] P. Chini,et al. Flame retardants for polypropylene based on lignin , 2003 .
[77] H. Stone,et al. Blowing Agents for Polyurethane Foams , 2002 .
[78] Zhenlun Song,et al. Effects of viscosity on cellular structure of foamed aluminum in foaming process , 2000 .
[79] E. Barrett,et al. (CONTRIBUTION FROM THE MULTIPLE FELLOWSHIP OF BAUGH AND SONS COMPANY, MELLOX INSTITUTE) The Determination of Pore Volume and Area Distributions in Porous Substances. I. Computations from Nitrogen Isotherms , 1951 .