The Hot Dip Galvanizers Association of Southern Africa (HDGASA) (Bedfordview, South Africa) plays an important role in supporting the energy value chain — which spans clean, renewable, and green energy — as it powers towards key sustainability targets, according to Executive Director Robin Clarke.
After a nine-year “teething period,” during which key energy sector stakeholders and local galvanizers found common ground, he says hot dip galvanizing is now the preferred corrosion control mechanism for this sector, enabling substantial return on investment for energy infrastructure projects and the industry as a whole.
“As an Association, we support the move to renewable energy,” says Clarke. “We are pleased that the sector has embraced hot dip galvanizing. What we do prolongs the life of the most essential element — steel.”
Part of the transition
According to the International Trade Association, 85%, or 42,000MW, of South Africa’s electricity is generated via coal-fired power stations. Coal will continue to provide most of the country's power for the next decade, although the share from renewables is expected to develop faster than the market.
Clarke says that the HDGASA has always fostered a close, constructive relationship with Eskom.
“As an Association, we have advised the parastatal regarding corrosion control of transmission lines and distribution equipment — and the relevant standards — over the past several decades,” he says. “We expect this to continue with the 14,000 kilometers of transmission lines due to be provided under Eskom’s strategic development program.”
The solar learning curve
This started with a rush to complete photovoltaic installations built according to generic European specifications in the Northern Cape.
Solar installations grew on the back of load shedding. “They were scattered across the length and breadth of the country,” Clarke explains. “We ran into headwinds related to corrosive environments that had not been factored into the original generic designs intended for the Northern Cape.”
It has taken time for stakeholders to replace generic specifications with site- and location-specific alternatives. This means pre-approving a quality plan before accepting a design to ensure that the corrosion control needed for each installation is correctly specified to meet the service life requirements. For example, a solar installation on the West Coast requires a different thought process and specification to an identical facility in Kakama in the Northern Cape.
“We began working very hard as an Association to interface with key players to ensure that this was done—and that a thorough environmental assessment was completed to ensure that the specifications for corrosion control and the selection of materials were correct,” Clarke says.
Although this initially applied to large solar farms, it soon extended to far smaller installations on the roofs of commercial buildings such as shopping malls.
“We have been advising commercial property groups to not only correctly determine the corrosion control specifications for individual solar installations, but also to assess the baseline corrosion condition of the roof and the roof sheeting — on top of which PV panel installations will be installed,” says Clarke. “These roofs are predominantly galvanized or duplex-coated galvanized substrates. As such, the roofs need to have a service life equal to — or exceeding — that of the renewable energy installation, to ensure acceptable projected return-on-investment and sustainability targets.”
Bridging the gap
The HDGASA’s role has included highlighting the parallels between standards used in South Africa and those applied internationally, including the Americas, Europe, India, Australia, and New Zealand. “We have provided solid proof to the renewables industry role players that our galvanizers can provide hot dip galvanizing equal to — or exceeding — the standards specified by designers of plants in Europe and America,” Clarke says.
The Association also advises on other ranges of galvanized materials used for corrosion control. For example, where some designers have resorted to using thinner steel sections protected by continuous galvanizing coatings, the HDGASA has found several instances showing the articles to be incongruent with the projected service life of the renewable plant
“Our advice has been to recommend that the designer specify batch dipping of fabricated steel elements,” Clarke says. This will inevitably provide greater service life from a substantially thicker coating, thereby providing greater durability and service life — with a marginal cost variance when compared to the overall projected cost.
Currently, he says that the HDGASA is working on two large remedial projects, resulting from poor storage and transportation.
“Bundling, nesting of pre-galvanized steel components, and strapping them together too tightly when importing such articles in a ship’s hold carries a disproportionate risk of damage to the corrosion control coating,” says Clarke. “Long periods when pregalvanized material is exposed to moisture and chlorides means that they have most likely begun to corrode at excessively high rates, by the time they arrive on site — affecting the service life of the renewable energy facility.”
The winds of change
Lessons learned from the solar sector will also assist with the wind power sector, which has, over the past 10 years, blown hot and cold, and only now seems to be gaining traction again as an alternative to the renewable energy arena.
Clarke says the HDGASA will continue to work closely both in-country and offshore with South African role players, championing the capacity and expertise of local galvanizers to supply the solar, wind, and developing renewable markets.
“The renewable energy sector provides a powerful growth opportunity for South Africa’s galvanizing fraternity and the HDGASA will do all we can to support and facilitate this,” Clarke says.
Source: HDGASA, www.hdgasa.org.za.