Polythene (polyethylene):Properties, Production &
Uses |
Properties and Uses
| Property |
Low Density Polyethylene
(LDPE) |
High Density Polyethylene
(HDPE) |
| Melting Point |
~115oC |
~135oC |
|
| Crystallinity |
low crystallinity (50-60% crystalline)
Main chain
contains many side chains of 2-4 carbon atoms leading to
irregular packing and low crystallinity (amorphous) |
highly crystalline (>90% crystalline)
contains less
than 1 side chain per 200 carbon atoms in the main chain
leading to long linear chains that result in regular packing
and high crystallinity |
|
| Flexibility |
more flexible than HDPE due to lower crystallinity |
more rigid than LDPE due to higher crystallinity |
|
| Strength |
not as strong as HDPE due to irregular packing of polymer
chains |
strong as a result of regular packing of polymer
chains |
|
| Heat Resistance |
retains toughness & pliabilty over a wide temperature
range, but density drops off dramatically above room
temperature. |
useful above 100oC |
|
| Transparency |
good transparency since it is more amorphous (has
non-crystalline regions) than HDPE |
less transparent than LDPE because it is more
crystalline |
|
| Density |
0.91-0.94 g/cm3
lower density than HDPE |
0.95-0.97 g/cm3
higher density than
LDPE |
|
| Chemical Properties |
chemically inert
Insolvent at room temperature in most
solvents.
Good resistance to acids and alkalis.
Exposure
to light and oxygen results in loss of strength and loss of
tear resistance. |
chemically inert
|
|
| Schematic diagram |
 |
 |
|
| Uses |
sandwich bags, cling wrap, car covers, squeeze bottles,
liners for tanks and ponds, moisture barriers in
construction |
freezer bags, water pipes, wire and cable insulation,
extrusion coating |
Production of LDPE
Production of LDPE by addition
polymerization requires:
- temperature range of 100-300oC
- very high pressure 1500-3000 atmospheres
- oxygen or an organic peroxide such as dibutyl peroxide,
benzoyl peroxide or diethyl peroxide as initiator.
An
initiator is a substance which is added in small quantities and is
decomposed by light or heat to produce a free radical
(R.). A free radical is formed when a covalent
bond is broken and a bonding electron is left on each part of the
broken molecule. Since the O-O covalent bond is weak, free
radicals are easily formed from oxygen or peroxides.
- benzene or chlorobenzene used as the solvent since both
polymer (polythene) and monomer (ethene) dissolve
in these compounds at the temperature and pressure used.
Water
or other liquids may be added to dissipate the heat of reaction as
the polymerization reaction is highly exothermic.
CH2=CH2
ethene |
+ |
R.
initiator |
-----> |
.CH2-CH2-R |
| CH2=CH2 |
+ |
.CH2-CH2-R |
-----> |
.CH2-CH2-CH2-CH2-R |
| Process continues to form polythene
(polyethylene)
[-CH2-CH2-]n |
Production of HDPE
- Production of HDPE by addition
polymerization with a supported metal oxide catalyst requires:
- temperature ~300oC
- 1 atmosphere pressure (101.3kPa)
- aluminium-based metal oxide catalyst (metallocene catalyst)
The catalyst can be used in a variety of operating modes
including fixed-bed, moving-bed, fluid-bed or slurry processes
- The ethene
(ethylene) monomer is fed with a paraffin or cycloparaffin
diluent (diluting agent).
After polymerization the polymer
(polythene) is recovered by cooling or by solvent evaporation.
- Production of HDPE by coordination polymerization
requires:
- temperature 50-75oC
- slight pressure
- a coordination catalyst is prepared as a colloidal
suspension by reacting an aluminium alkyl and titanium chloride
(TiCl4) in a solvent such as heptane
(C7H16).
- The polymer (polythene) forms as a powder or granules which
are insoluble in the reaction mixture. When the polymerization
is completed, the catalyst is destroyed by adding water or
alcohol to the reaction mixture. The polymer (polythene) is then
filtered or centrifuged off, washed and dried.
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