UNEP-2002 Report of the Rigid and Flexible Foams, Technical Options Committee, 2002, pp. A17–A112.
[2] Prociak A., Rokicki G., Ryszkowska J.: „Materiały poliuretanowe”, Wydawnictwo Naukowe PWN, Warszawa 2014.
[3] Brumner K., Schrock A.K.: “Technical Advances in the Elimination of Blowing Agents in Flexible Slabstock System”, Conference Proceedings, Utech ‘92, Dow Chemical Europe 1992, 92, 194.
[4] Kurańska M., Prociak A., Michałowski S. et al.: Polimery 2018, 63, 672.
Crossref
[5]
Crossref
[6]
Crossref
[7] Williams D., Bogdan M.: “Performance of HFC-245fa in Integral Skin Foam Application”, Conference Proceedings, Polyurethanes 2000, p. 250.
[8] Vollmer M.K., Reimann S., Folini D. et al.: Geophysical Research Letters 2006, 33 (20), L20806.
Crossref
[9] Stemmler K., Folini D., Ubl S. et al.: Environmental Science & Technology 2007, 41 (4), 1145.
Crossref
[10] UNEP-May 2018. Progress Report 2018, V3, pp. 5–9.
Crossref
[11] Regulation (EU) No 517/2014 of the European Parliament and of the Council of 16 April 2014 on Fluorinated Greenhouse Gases and Repealing Regulation (EC) No 842/2006.
Crossref
[12] Honeywell Solstice 1233zd(E), Honeywell 2013.
Crossref
[13] Fluorochemicals-Forane FBA 1233zd Blowing Agent- Technical Profile, Arkema Inc. 2017.
Crossref
[14] DuPont receives US EPA approval for Formacel 1100 foam expansion agent, 2014.
Crossref
[15] “Opteon 1100 Liquid blowing Agent”, PU Magazine International 2019, 06, 376.
[16] Diendorf J.: 4th Generation Blowing Agents: Chances and Challenges with HFOs Rigid Technical Seminar Evonik, 2018.
[17] Mayer O.: “CFC Free. Low Density. Soft Flexible Slabstock Foams”, Arco Chem. Europe Inc., Conference Proceedings, Polyurethanes 1992, 92, pp. 487—492.
[18] Treuling U., Horn P.: “CFC Replacement. Technical Applications for Microporous Materials”, Conference Proceedings Polyurethanes 1995, 95, pp. 196–203.
[19] Obata H., Utsumi H., Ohkubo K. et al.: “New All Water Blown MDI Based Flexible Moulded Foam System”, Conference Proceedings, Polyurethanes 1995, 95, pp. 406–412.
[20] Wada H., Fukuda H.: Journal of Cellular Plastics 2009, 45 (4), 293.
Crossref
[21] H2Foam Lite (LDC50)TM, The Evolution of Insulation, Icynene Europe 2018.
Crossref
[22] Jacobs L.J.M., Kemmere M.F., Keurenties J.T.F.: Green Chemistry 2008, 10 (7), 13.
Crossref
[23] PLASTINUM Polyurethane Foaming with CO2-Linde Gaz.
Crossref plastic_rubber_solutions/plastinum_foam_p.html
[24] Supercritcal CO2Technology for Polyurethane Spray Foam, UNDP Report 2013. 690 POLIMERY 2020, 65, nr 10 ht t p://mu lt i l at e ra l f u nd.or g /O u r Work /DemonProject/Document Library/7106a1 super C02 pu foam.pdf
[25] US Pat. 44 670 899 (1984).
[26] US Pat. 5 451 612 (1995).
[27] US Pat. 5 789 451A (1999).
[28] US Pat. 5 874 021 (1999).
[29] US Pat. 6 316 662 B (2001).
[30] US Pat. 6 326 412 B1 (2001).
[31] Da X., Liu C., Long Y. et al.: Applied Polymer Science 2019, 137, 48752.
Crossref
[32] Wianowski L., Białkowska A., Dobrowolski L. et al.: Polimery 2020, 65, 83.
Crossref
[33] PL Pat. 230 383B1 (2017).
[34] Long Y., Zheng L., Gu Y. et al.: Polymer 2014, 55, 6494.
Crossref
[35] Liu C., Long Y., Xie J., Xie X.: Polymer 2017, 116, 240.
Crossref
[36] Long Y., An J., Xie X.: Arabian Journal of Chemistry 2020, 13, 3226.
Crossref
Google Scholar