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Abstract

CO₂ adducts from hydrophobically-modified polyethylenimines (PEIs) in powder form are newly-developed environment-friendly blowing agents for polyurethanes (PUs). However, they are difficult to disperse into foaming systems that usually contain polyether polyols as the PU soft segments. Herein, we employ mixtures of di(propylene glycol) monomethyl ether-grafted polyethylenimines (DPG-PEIs) and poly(propylene glycol) (PPG) polyols to absorb CO₂, with in situ formation of the CO₂ adduct particles as PU blowing agents. Their CO₂ saturation degrees, revealed by thermogravimetry, scatter in the range of 93–98%. The DPG side chains tend to be exposed at the particle–matrix interface to stabilize the particles. In addition, some PPG oligomers in the matrix might entangle with the CO₂ adduct macromolecules during the in situ particle formation. The entangled PPG chains could further stabilize the suspending particles. The high grafting rate and high molecular weight of the PEI backbones could result in small particles, which largely thicken the foaming systems. The optimized blowing agents, with grafting rates between 5% and 8% and PEI backbone molecular weights not higher than 10k Da, show particle sizes from several hundreds of nanometers to ∼1 μm. The resultant foams demonstrate densities below 50 kg/m³ and compressive strengths over 200 kPa, comparable to the values from industrial foams. This in situ CO₂ adduction has potential as a universal method suitable for PU foaming at an industrial scale.

Keywords

polyethylenimine polyurethane blowing agent

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References

Kim

Shon

Nguyen

, et al. A review of major chlorofluorocarbons and their halocarbon alternatives in the air. Atmos Environ 2011; 45: 1369–1382.

Mcculloch

Life cycle inventory analysis of the production of a high-performance foam blowing agent HFC-245fa (1,1,1,3,3-Pentafluoropropane). J Cell Plast 2010; 46: 57–72.

Lee

Jang

Choi

, et al. Liquid-type nucleating agent for improving thermal insulating properties of rigid polyurethane foams by HFC-365mfc as a blowing agent. J Appl Polym Sci 2016; 133(25): 43557.

Ling

Williams

DJ.

Foams and articles made from foams containing 1-chloro-3,3,3-trifluoropropene (HFCO-1233zd). US Patent 2011/0303867 A1, 2011.

Hulse

Basu

Singh

, et al. Physical properties of HCFO-1233zd(E). J Chem Eng Data 2012; 57: 3581–3586.

Molés

Navarro-Esbrí

Peris

, et al. Low GWP alternatives to HFC-245fa in organic rankine cycles for low temperature heat recovery: HCFO-1233zd-E and HFO-1336mzz-Z. Appl Therm Eng 2014; 71: 204–212.

Vollmer

Reimann

Hill

, et al. First observations of the fourth generation synthetic halocarbons HFC-1234yf, HFC-1234ze(E), and HCFC-1233zd(E) in the atmosphere. Environ Sci Technol 2015; 49: 2703–2708.

Fouad

Vega

LF.

Next generation of low global warming potential refrigerants: thermodynamic properties molecular modeling. AIChE J 2018; 64: 250–262.

Papadimitriou

Talukdar

Portmann

, et al. CF₃CF=CH₂ and (Z)-CF₃CF=CHF: temperature dependent OH rate coefficients and global warming potentials. Phys Chem Chem Phys 2008; 10: 808–820.

10.

Russell

Hoogeweg

Webster

, et al. TFA from HFO-1234yf: accumulation and aquatic risk in terminal water bodies. Environ Toxicol Chem 2012; 31: 1957–1965.

11.

Maestrini

Callaioli

Rossi

, et al. Styrenics materials and cyclopentane: problems and perspectives. J Mater Sci 1996; 31: 3747–3761.

12.

Kalinowski

Keske

Matimba

, et al. Rigid foam compositions and method employing methyl formate as a blowing agent. US Patent 2004/006753357 B2, 2004.

13.

Murayama

Fukuda

Kimura

, et al. Water-blown polyurethane rigid foam modified with maleate. J Cell Plast 2005; 41: 373–387.

14.

Ito

Matsunaga

Tajima

, et al. Generation of microcellular polyurethane with supercritical carbon dioxide. J Appl Polym Sci 2007; 106: 3581–3586.

15.

Chu

Yeh

Peng

, et al. Preparation of microporous thermoplastic polyurethane by low-temperature supercritical CO₂ foaming. J Cell Plast 2017; 53: 135–150.

16.

Jiang

Zhao

Feng

, et al. Microcellular thermoplastic polyurethanes and their flexible properties prepared by mold foaming process with supercritical CO₂. J Cell Plast 2019; 55: 615–631.

17.

Long

Zheng

, et al. Carbon dioxide adduct from polypropylene glycol grafted polyethyleneimine as a climate-friendly blowing agent for polyurethane foams. Polymer 2014; 55: 6494–6503.

18.

Long

Sun

Liu

, et al. A family of polypropylene glycol-grafted polyethyleneimines reversibly absorb and release carbon dioxide to blow polyurethanes. RSC Adv 2016; 6: 23726–23736.

19.

Long

Sun

Liu

, et al. Climate-friendly polyurethane blowing agent based on a carbon dioxide adduct from palmitic acid grafted polyethyleneimine. J Appl Polym Sci 2016; 133(35): 43874.

20.

Liu

Long

Xie

, et al. Towards green polyurethane foams via renewable castor oil-derived polyol and carbon dioxide releasing blowing agents from alkylated polyethylenimines. Polymer 2017; 116: 240–250.

21.

Long

Yuan

Wang

, et al. Polyurethane foaming with engineered CO₂-releasing nanoparticles: from the thickening effect to the industrial applications of the blowing agents. Polymer 2018; 143: 69–78.

22.

Liu

Long

, et al. Polyurethane foaming with CO₂ adducts from C₈ alkyl grafted polyethyleneimines: optimization of the grafting rate and application of the blowing agents. J Appl Polym Sci 2020; 137(22): 48752.

23.

Long

Xie

CO₂-releasing blowing agents from modified polyethylenimines slightly consume isocyanate groups while foaming polyurethanes. Arab J Chem 2020; 13: 3226–3235.

24.

Lim

Kim

BK.

Polyurethane foams blown with various types of environmentally friendly blowing agents. Plast Rubber Compos 2010; 39: 364–369.

25.

Notario

Pinto

Solorzano

, et al. Experimental validation of the Knudsen effect in nanocellular polymeric foams. Polymer 2015; 56: 57–67.

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In situ synthesis of CO 2 adducts of modified polyethylenimines in polyether polyols for polyurethane foaming

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