Synthesis of waterborne polyurethane using snow as dispersant: Structures and properties controlled by polyols utilization

doi:10.1016/j.jmst.2019.03.017

Abstract

Abstract:

Waterborne polyurethane (WPU) dispersions have gained attention towards environmentally-friendly synthesis. In this article, a series of waterborne polyurethane emulsions was successfully synthesized and extensively characterized in terms of thermal, mechanical properties, hydrophilic behavior and morphology. Snow was chosen as dispersant instead of commonly used water. Preparation parameters such as intrinsic properties and molecular weight of polyols were discussed systematically. A chain structure was confirmed by Fourier transform infrared (FT-IR) spectroscopy. When comparing the nature of the polyols (PPG, PEG and PNA, 2000 g/mol) of this study, as-synthesized polyether waterborne polyurethane provided higher solid content, viscosity and water-resistance. However, polyester waterborne polyurethane performed differently and it exhibited higher thermal stability and crystallinity. When comparing the samples (WPU-N210, WPU-N220, WPU-N230 and WPU-N240) with different molecular weight of the same polyol (PPG) used as soft segment, the emulsion WPU-N220 with molecular weight of 2000 g/mol PPG provided the highest solid content and lowest viscosity. It was observed that particle size was uniform and highly dispersed for all samples from TEM images. Thermogravimetric, differential scanning calorimetry (DSC) and X-ray diffraction results demonstrated that the emulsion WPU-N230 with molecular weight of 3000 g/mol PPG possessed higher thermal stability and crystallinity than the other samples. The reason was that the T_g and thermal stability were increased with increasing molecular weight. When molecular weight increased, the arrangement of soft segment became more regular and so did the regularity of the molecular chains. This work demonstrated that different polyols as soft segment applied could lead to great differences in the structure and property of the resulting WPU.

Key words: Waterborne polyurethane (WPU), Snow, Soft segment, Polyester, Polyether

Changqing Fang, Shaofei Pan, Zhen Wang, Xing Zhou, Wanqing Lei, Youliang Cheng. Synthesis of waterborne polyurethane using snow as dispersant: Structures and properties controlled by polyols utilization[J]. J. Mater. Sci. Technol., 2019, 35(7): 1491-1498.

Figures/Tables 10

Table 1 Nomenclature of the WPU dispersions synthesized with different polyols.

Polyols	Molecular weight of the polyols (Mw) (g/mol)	Nomenclature of the WPU
Poly(propyleneoxide glycol)	1000	WPU-N210
Poly(propyleneoxide glycol)	2000	WPU-N220
Poly(propyleneoxide glycol)	3000	WPU-N230
Poly(propyleneoxide glycol)	4000	WPU-N240
Poly(ethylene glycol)	2000	WPU-PEG
Poly(neopentylglycol adipate)	2000	WPU-PNA

Fig. 1. (a) Solids content of the WPU samples. (b) Vicosity of the WPU samples. (c) and (d) Beginning and end of the solid content test, respectively.

Fig. 2. TEM images of WPU dispersions in synthesis of different polyols. (a) WPU-N210, (b) WPU-N220, (c) WPU-N230, (d) WPU-PNA.

Fig. 3. (a) FT-IR spectra of WPU-N210, WPU-N220, WPU-N230, WPU-N240. (b) FT-IR spectra of WPU-N220, WPU-PNA, WPU-PEG.

Table 2 Characteristic IR bans of the WPU.

Wavenumber (cm^-1)	Assignment
3581-3334	st N—H (bonded)
2974-2867	st C—H
2280-2260	st N=C=O
1737-1708	st C=O (urethane)
1666-1649	st C=O (urea)
1560-1554	st C—N + δN—H
1469-1460	δ CH₂
1450-1400	st sym (COOˉ)
1249-1236	st asym N—CO—O + (C—O—C)
1236	st (C—O)
1135-1099	st (C—O—C)

Table 3 Main decomposition of the samples.

Samples	Hard segments		Soft segments
Samples	T (°C)	Weight loss (%)	T (°C)	Weight loss (%)
N210	243.0	33.6	351.8	41.0
N220	255.8	26.6	342.4	57.3
N230	261.3	25.0	331.4	67.9
N240	262.8	17.1	331.4	52.1
PNA	278.2	30.7	351.4	43.0
PEG	263.2	27.6	344.2	62.6

Fig. 4. TG and DTG curves of WPU films. (a) and (c) WPU synthesized with different molecular weights of PPG. (b) and (d) WPU synthesized with PPG, PEG and PNA.

Fig. 5. DSC thermograms of WPU in synthesis of different polyols.

Fig. 6. X-ray diffractograms of the WPU films.

Fig. 7. (a-f) Water contact angles of all the samples. (g) Tendency for all the samples. (h) Cartoon of the water contact angles test.

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