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學
生:符昌中
指導老師:王振乾 老師
Introduction
• Waterborne polyurethanes (WPUs) have excellent
mechanical properties and are environment-friendly.
• WPU resins have poor resistance against water and
chemicals compared with the crosslinked two-pack
solvent-based urethanes.
• A separate polymer could be incorporated to
polyurethane to form a multiphase structure in the
dispersions through various techniques such as
blending, seeded emulsion polymerization.
Introduction
• Using epoxy resin to modify WPU can combine the
advantages of both of these materials and results in
improved film performance.
• Epoxy resin and a blocked NCO prepolymer were mixed
to avoid the high viscosity of precrosslinked polyurethane and the difficulty of emulsification.
• In this work, we explored a novel postcrosslinking
method to form crosslinked polyurethane–epoxy
hybrid emulsion.
Materials
• 2,4-Toluene diisocyanate (TDI, 80/20)
• Polyether diol (PED) with a molecular weight
of 1000 Da(N210)
• Dimethylol propionic acid (DMPA)
• Epikote 1001 (hereinaftercalled type 1 epoxy)
Materials
•
•
•
•
•
•
1,4-Butanediol
Diethylene triamine
Acetone
1-methyl-2-pyrrolidone(NMP)
Isopropanol
Triethylamine (TEA)
Unmodified polyurethane dispersion
Blocking agent Isopropanol

70 ℃ 3 h
TDI, PED, 1,4-butanediol,and DMPA/NMP
40 ℃
 Ethylene diamine
 Triethylamine Neutralizing
Chain extension
The unmodified aqueous polyurethane
dispersion was thus obtained.
Epoxy resin-modified polyurethane dispersion
Precrossinking
 Type 1 epoxy /NMP
60-70 ℃ 2-3 h
TDI, PED,1,4-butanediol, and DMPA /NMP

70 ℃ 3 h
 Triethylamine Neutralizing
Isopropanol
Blocking agent

Primary diamines
Chain extension
An aqueous dispersion of polyurethane
ionomer was thus obtained.
Epoxy resin-modified polyurethane dispersion
Postcrossinking

Isopropanol Blocking agent
TDI, PED,1,4-butanediol, and DMPA /NMP

70 ℃ 3 h
30 ℃
 Triethylamine Neutralizing
Type 1 epoxy
/NMP
80 ℃ 2 h

Diethylene triamine
Chain extension
The crosslinked polyurethane–epoxy
hybrid emulsion was thus obtained.
Results and discussion
Fig. 2: IR spectra of emulsion before chain extension by
amine
N–H stretching of polyurethane was shifted
to 3294 cm-1.
The band at 1745 cm-1 was C=O stretching
of the urethane group.
The band at 1223–1267 cm-1 corresponded
to the stretching vibrations of C=O
combined with NH.
The bands at 1533–1539 cmO-1 correspond
to carbamate.
H
R
N
C
O
R
The absorption peaks of epoxy group and
free isocyanate group at 917 and 2277 cm-1
vanished after chain extension in, which
indicated that a chain extender reaction
occured between the isocyanate group,
epoxide groups, and amine chain extender.
Fig. 3: IR spectra of emulsion after chain extension by amine
Results and discussion
Fig. 4,5: DSC thermogram of PUPE1,2(before chain-extension)
There were two endothermic peaks at about 100 and 150 ℃, which represented the epoxide
group curing and the deblocking of isocyanate, respectively.
Results and discussion
Fig. 6: DSC thermogram of PUPE3(after chain extension)
Fig. 8: DSC thermogram of PUPE4 cured at 180℃ for 2 h
Fig. 7: DSC thermogram of PUPE4(after chain extension)
Results and discussion
Fig. 9: TEM images of (a) polyurethane emulsion, (b)emulsion prepared with precrosslinking, and (c) emulsion prepared
with postcrosslinking
Results and discussion
Since the crosslinking density of the films increased with an increase in epoxy content, the ratio
of the rigid segment in resin was enhanced.
Results and discussion
Conclusions
• The postcrosslinking method could improve the film
performance and the emulsion stability, and did not
result in increased viscosity of the prepolymer before
phase inversion because the epoxy resin did not react
with prepolymer.
• The type of amine chain extender significantly affected
the stability of emulsion.
• The molar ratio of NH/NCO at 1:1 showed the best film
performance, and the optimal reaction temperature of
amine extending chain was around 80℃.