2.1 Introduction:
When exposed outdoors to
weathering, the properties of polymers are subject to change. Primarily, the
effect is one of photo-oxidation brought about by incident wavelengths within
the ultraviolet range, although additional factors may contribute. In the case
of plastics, photo-oxidation may result in loss of impact strength, resistance
to slow crack growth, and thermal stability. This is a surface effect, and the
bulk polymer is not necessarily affected. Pigment fade may also be a consideration.
2.2 End-user
Requirements:
- Water (WSAA) and gas (AGA) industries require pipes to be
suitable for use after two years of outdoors exposure during storage.
- In the case of black pipes, WSAA allows permanent exposure for
above ground PE sewers. Other industries, such as mining, require up to 15
years of exposure during service.
2.3 Means of protection:
Protective additives such as
carbon black and hindered amine light stabilizers (HALS) are used in order to
minimize degradation. The use of carbon black optimizes UV stabilization and
thus black pipes dominate general usage.
For colored compounds,
stabilization has not been as effective as carbon black, but the introduction
of HALS (hindered amine light stabilizers) has enabled greatly improved UV resistance,
albeit still not to the level of carbon black.
2.4 Carbon Black
Carbon black confers excellent
long-term retention of properties, hence this additive shows predominant use
for PE pipes. For stabilization, the key attributes of the carbon black are
particle size and distribution, plus volatile content.
Although actual long-term performance is not well
documented quantitatively, there are sufficient data and long-term history of
use for black PE pipe grades to assume suitability.
Chevron Phillips Chemical
Company LP [7] have exposed black HDPE and MDPE pipe materials conforming to
AS/NZS 4131, plus materials with non-conforming carbon black, for over nine
years and seven years respectively in Singapore, where incident energy is about
80% of that in Nth. Queensland. These pipes, whilst exhibiting surface
oxidation, showed undiminished hydrostatic pressure resistance, even for
non-conforming carbon black (50 nm particle size) used for comparative
purposes.
Gaz De France Queensland
2.5 HALS
The development of HALS
stabilizers has resulted in significantly improved long-term resistance to the
effects of UV radiation on colored compounds. Such compounds are used as pipe
identification and may be used as co extrusions on pipes or for the pipes themselves.
The performance of HALS
stabilizers is well documented and acknowledged within AS/NZS 4130 by
acceptance of 0.2% of HALS as being adequate for exposure during storage.
According to Ciba Specialty
Chemicals, addition of 0.2% HALS Tinuvin 783 provides life of more than 16000
hrs, compared with less than 1000 hrs with nil stabilization, as measured by
carbonyl absorbance of the sample exposed to weathering in Weatherometer.
Based on Ciba
Specialty Chemicals data, 16000 hours in the Weatherometer is approximately
equivalent to 12.5 years. This approximates to more than 10 years of exposure
[9]. Notwithstanding the fact that artificial weathering cannot be accurately
correlated with natural exposure, it can be seen that 16000 hours provide a
large margin for two years exposure. Further, Cytec Industries Inc. have shown
that the addition of HALS additive UV-3346 at 0.2% provides in excess of 30
months to 50% of original elongation to break, compared with 6-9 months for
unstabilised material.
In pipe Standards, such as
AS/NZS 4130, AS/NZS 4131, and ISO 4437, it is usual to expose pipe specimens,
whereas in developmental work on polymers, small specimens are usually chosen,
so that the degraded area only is evaluated.
For long term use of colored
compounds in service, such as the use of white co extrusions for temperature
minimization, the dosage level of HALS should be increased to maximum
compatibility level. For example, Ciba Specialty Chemicals recommend inclusion
of 0.4% Tinuvin 783, plus at least 2% of TiO2 retile [10]. In
addition to providing the white color, TiO2 will impart improved UV
resistance, although its effect is not as pronounced as with PVC. This will
optimize performance for the 15 years required by the mining industry.
However, in order to quantify
performance, natural and/or artificial weathering tests should be conducted.
2.6 Synergistic effects
It is known that
stabilizers may act in combination with pigments and antioxidants to produce a
combined and otherwise unpredictable effect on UV resistance.
For example,
testing of HDPE by Chevron Phillips Chemical Company LP(3) has shown
that for certain yellow pigments, 2% dosage is superior to 1% dosage without
stabilization, but with stabilization the performance is reversed.
The synergistic
effect demands exposure testing, by natural exposure and/or Weather-Ometer. It
is recommended that in this context, Weather-Ometer testing be used only for
comparative purposes against data established from natural exposure plus
Weather-Ometer. In any case, all colored compounds should eventually be
assessed by natural exposure testing.
2.7 Exposure Testing:
Where neither carbon black nor
HALS is incorporated, compounds to AS/NZS 4130 and AS/NZS 4131 must be
subjected to natural exposure testing.
Due to the potential synergistic
effects, all colored pipe compounds should be evaluated by natural exposure
testing to a total incident energy level of 14 GJ/m2, but the time
period involved is likely to inhibit product development, so an interim
acknowledgement of conformance could be granted on the basis of compounds that
incorporate 0.2% min. of either Tinuvin 783 or Cytec UV-3346.
2.8 Means of Assessment
Following exposure, pipe specimens
are tested to assess effect on key properties: resistance to slow crack growth
(ESCR), impact strength, resistance to internal pressure, and thermal
stability.
Resistance to slow crack growth
and impact strength are usually assessed by some form of notched specimen
testing. However, as the notching removes the affected layer, these tests are
useless.
Fortunately, changes to both
resistance to slow crack growth and impact strength can be indirectly assessed
by one test, change in elongation to break. The general benchmark in
industry is an allowable reduction in elongation to break of 50% of original
and this is used for some of the data previously cited. AS/NZS 4131 and ISO
4437 require only that the elongation to break after exposure be 350%, rather than specify a change. An additionally, ISO
4437 requires the original elongation to break to be 350%.
Elongation to break of compounds
that meet all other requirements of the Standards is typically greater than
about 700%, so the requirement of 350% minimum is effectively 50% change.
As previously stated, the data
used as the basis is developed from small specimens and thus conservative
compared with exposure of pipes.
Resistance to internal pressure
is best evaluated by short term 80°C testing, as this simulates long-term
performance.
Thermal
stability is considered to be of little relevance. Although it relates to pipe
life and fusion welding,
the former is covered by the
tensile and pressure testing, and for the latter, welding techniques require
removal of the oxidized layer. Furthermore, it has been demonstrated that the
OIT method specified in AS/NZS 4130 and ISO4437 is not appropriate for HALS
stabilized materials after exposure and determination of carbonyl index should
be made.
2.9 Conclusions:
- Black pipes to AS/NZS 4130 satisfy end-user requirements for
both short and long-term use.
- Colored pipes, including co extrusions, to AS/NZS 4130 may be
considered suitable for two years storage under exposure provided
appropriate grades of HALS at dosage rate of 0.2% minimum are used.
Suitable grades
include Ciba Specialty Chemicals Tinuvin 783 and Cytec Industries UV-3346.
Confirmation by
natural exposure testing to a total energy level of 14 GJ/m2 should
be conducted.
- For longer periods, such as 15 years, optimum performance is
best obtained by incorporating HALS stabilizers up to polymer
compatibility level, plus at least 2% of retile titanium dioxide.
Further
quantification should be obtained by outdoors exposure testing.
