The benefits of using HDPE pipe in civil and infrastructure projects
From potable water and wastewater systems, to gas and telecommunications — even underground beer transportation in Belgium — HDPE pipes are now the preferred pipe material in many civil infrastructure applications across the globe.
In Australia, plastic pipes are standard in telecommunications, sewage reticulation, irrigation, and gas transmission, and, according to the Intelligent Water Decisions Research Group at the University of Adelaide, make up around 85 per cent of the water services-related infrastructure in Australia’s cities.
PE100 is also the standard in the City of London. Between 2005 and 2010, the City of London had renovated or replaced approximately 17,000 km of water mains using PE100.
Their popularity in municipalities is thanks to a range of benefits that far outstrip almost any other pipe available.
PE100 pipe has a 100+ year life expectancy
According to Quenos, one of the world’s leading polyethylene manufacturers, the latest generation PE100 materials have a lifetime of well over 100 years, if they are installed correctly and normal service conditions are adhered to.
However, you may have noticed that manufacturers claim the life expectancy to be far lower.
This is because they can only advertise a 50-year lifetime, due to a design standard from the PE100 Association.
This standard specifies a 50-year Minimum Required Stress of 10 MPa. The actual strength of the material is therefore far in excess of this minimum, when it is being used under normal conditions.
By advertising just the standards, manufacturers know that they are compliant and can prove it, by virtue of accepted testing.
Research currently being conducted by the University of Adelaide’s engineering school also qualifies the long average life expectancy of plastic pipes, and verifies that if a plastic pipe is to fail, it isn’t because of its age.
According to one researcher, the typical causes for premature failures in plastic pipes are improper installation practices, manufacturing defects, rock impingement and excessive bending at fittings.
PE100 pipe is resilient, especially in earthquake zones
PE100 pipe is far more resilient than PVC and concrete, especially in earthquake zones.
In 2010-11, after each of the six major earthquakes in Christchurch, New Zealand, a team of researchers assessed the extent of damage to infrastructure and buildings as a result of liquefaction and displacement.
They discovered that the wastewater pipe network was so badly damaged, they predicted it would take three years to fully recover the system.
The potable water system, in contrast, was quickly restored.
Why?
Almost half of the pipes that failed in Christchurch were constructed from asbestos cement (AC), with the remainder constructed from PVC. The sub-mains network predominantly consisted of polyethylene (PE) pipes and galvanised iron (GI).
Analysis showed that PE and PVC pipes suffered significantly less damage than AC, steel, GI or other types of materials.
“…a significant difference in the performance of different pipe materials was found, with the PE and PVC pipes showing much better performance than pipes of other materials.”1
Back in Australia, polyethylene slurry pipes are used in Western Australia because of their high abrasion resistance when compared to all other pipe materials. Even where steel pipes are used — such as in high pressure pipelines — the pipes are lined with PE.
And in Perth, PE100 with high stress-crack resistance was specified by the Water Corporation for the construction of a recent recharge pipeline, to maximise the lifetime of the asset.
Additional benefits of PE100 pipe
In addition to its resilience and long life expectancy, PE100 pipe offers a range of additional benefits.
Its flexibility and toughness make it particularly well suited for horizontal directional drilling, which is why it was chosen for the Perth pipeline.
Its welds are completely sealed, which means that PE100 joints don’t suffer the leakage problems commonly found in concrete and rubber ring-jointed systems.
It does not corrode, which is why it is used to line pipes constructed from other materials, such as galvanised iron or steel.
It is ideal for trenchless technologies, which contribute to increased efficiency, and reduced costs and disruptions that are commonly found in installation, replacement, or rehabilitation processes.
It is lightweight and it reduces the number of joints needed, which also reduces installation time and labour requirements.
Since undertaking a major makeover of their municipal water system by switching to PE Pipe, the town of Aberdeen, a small community of 2000 people in Idaho, USA, has experienced the benefits HDPE pipe offers, first hand.
In 2003, more than 12 miles of PE pipe were used to replace aging, corroded cast iron and ductile iron pipes in a residential setting. In total, Aberdeen had 60,000 feet of PE installed.
“We found that the process of installing PE was less time consuming than installation of PVC or metal pipe,” said Cliff Cox, the main installer.
“If all conditions are the same, we can install 1000 feet of PE in one hour versus seven hours for PVC or concrete pipe,” he added.
PE pipe is fused together at the joints, creating a strong and flexible pipe that is virtually leak proof.
“When installed correctly, PE is leak free and the best solution for conserving water,” said Cliff.
If you need advice about the best type of pipe for your civil or infrastructure project, speak to Advanced Piping Systems today.
We measure our success in keeping your efficiency high, and your costs down.
References
1: Cubrinovski, Misko, Duncan Henderson, and B. A. Bradley. “Liquefaction impacts in residential areas in the 2010-2011 Christchurch earthquakes.” (2012).