Transcript 下載/瀏覽

Teacher: Cheng-Ho Chen
南台化材
1
Outline
Introduction
Materials
Experimental
Results and discussion
Conclusions
南台化材
2
Introduction (1)
 During the last twenty years, not only in the academia but also in
the industry clay polymer nanocomposites (CPN) have attracted
significant interest.
 Nanocomposites provide a significant improvement in polymer
properties such as modulus,strength, and heat resistance, when
compared to conventional composites.
 Montmorillonite can significantly improve thermal stability and
mechanical properties when dispersed in a polymer matrix with
a low content. In general, there are two nanostructures in Mt/PP
nanocomposites.
南台化材
3
Introduction (2)
 They intercalated octadecyl amine ethoxylate ether (A), which
has two poly(ethylene oxide) segments, into the interlayer space
of Mt, and the modified Mt was used to prepare Mt/PP
nanocomposites by a melt blending technique with and without
maleic anhydride grafted polypropylene (PPg).
南台化材
4
Materials
 Polypropylene, PP
[-CH2CH(CH3)-]n
 Ca2+-montmorillonite , Ca2+-Mt
 Octadecyl trimethylammonium chloride
 Octadecyl amine ethoxylate ether
南台化材
5
Experimental (1)
The surfactant A (50 g) was first dissolved in water till a limpid solution was
obtained and then Ca2+-Mt (50 g) were added to this surfactant solution.
The AMt dispersion was heated at 60 °C under vigorous stirring.
The A/Ca2+-Mt (AMt) hybrids were dried in a 60 °C oven for several days and
then pulverized. The power was sieved by passing though a 200-mesh stainless
steel sifter.
A/OMt (AOMt) hybrids were prepared in the same way.
南台化材 6
Experimental (2)
AMt or AOMt hybrids were added with 1–5 parts per hundred parts of PP (phr)
by weight, then extruded by a general three-section twin-screw extruder (D=20
mm, L/D=40).
Screw speed was set at 200 rpm and the temperatures were 175 °C, 190 °C, and
190 °C for each section of the barrel and 185 °C for the die.
Before analysis by FTIR and TGA, all samples were extracted by boiling xylene
for 72 h in order to get rid of free octadecyl amine ethoxylate ether component.
南台化材
7
Results and discussion
南台化材 8
FT-IR
2923cm-1、2851cm-1
:C-H
南台化材
9
TGA
N-H…O
南台化材
10
XRD
南台化材
11
TEM
1.80nm
PP/AMt
(100/5)
1.80nm
PP/PPg/AMt
(90/10/5)
3.88nm
PP/AOMt
(100/5)
4.28nm
PP/PPg/AOMt
(90/10/5)
1.83nm
4.21nm
1.83nm
3.73nm
Fig. 4. TEM micrographs of Mt/PP nanocomposites: (a) and (b), PP/AMt (100/5); (c) and (d),
PP/PPg/AMt (90/10/5); (e) and (f), PP/AOMt (100/5); (g) and (h), PP/PPg/AOMt (90/10/5).
南台化材
12
Mechanical properties
南台化材
13
SEM
PP/AMt
(100/5)
PP/AOMt
(100/5)
PP/PPg/AMt
(90/10/5)
PP/PPg/AOMt
(90/10/5)
南台化材
14
XRD
南台化材
15
DSC
南台化材16
Crystallization
南台化材
17
Rheological behaviors
PP/AMt
PP/PPg/AMt
PP/AOMt
PP/PPg/AOMt
南台化材
18
Conclusions
 As observed by XRD and TEM analysis, Mt/PP nanocomposites
were successfully prepared by melt blending technique using
different contents of Mt modified by polyether with and without
compatibilizer PPg.
 The modified Mt polyether in PP matrix led to a significant
reduction of melt viscosity and enhancement in Izodnotched impact strength and elongation at break.
 The Izod-notched impact strength and elongation at break of
Mt/PP nanocomposites were 1.95 and 2.77 times as high as those
of pure PP. The tensile strength was also improved in the
南台化材
19
presence of PPg.
Thanks for your attention
南台化材
20