Babcock has come full circle at a major power station where it will be upgrading electrostatic precipitators (ESPs) on six boiler units that it designed and built in the 1980s.

Using technology not available at the time, Babcock will bring the boiler units into the 2020s, enabling the power station to comply with the latest emission regulations of below 50mg of dust per normal cubic metre (Nm3) of flue gas, essentially halving the impurities.

This power station has provided reliable power to the utility for more than four decades, ranking as the best-performing and lowest-cost generating station in the utility’s fleet. The boiler was designed to burn coal with a low calorific value and an ash content above 40%. Producing fly-ash with a low carbon content proved beneficial for the cement industry, which relies on these properties to improve water resistance in cement.

Three-part programme

To meet the latest emission regulations, a three-part programme is required to enhance the total precipitator capability in order to achieve levels of below 50mg: 

Babcock has been awarded the third portion of the programme and will refurbish four precipitator cases in each boiler beginning in 2023. 

Dave Brook, Technical Director at Babcock, explains that ESPs use an electric charge to remove impurities from air or gases through a series of collector and discharge electrodes. “Fly ash is a very fine dust found in hot flue gases from coal combustion. It travels through the heat transfer surfaces of the boiler and the air heater, and eventually emerges through the ducting and through electrostatic precipitators. After it is removed and deposited in the hoppers below, the fly ash is either removed or sold to the cement industry,” says Dave.

“The fine dust in the gas travels a torturous route in the boiler, resulting in areas where there is more dust, and others with less dust. In order for the ESPs to function optimally, the gas distribution should be as homogenous as possible.”  

Dust distribution

Dave explains that an ESP is a box with a series of electrodes or plates strung vertically inside of it. The dust particles are charged creating a flow to the collector electrodes upon which the dust is deposited and collected. When these plates get full, they are rapped (struck), and all the dust slides down into the hopper. 

Babcock will use computational fluid dynamics modelling, which was not available in the 1980s, to model the gases from the outlet of the boiler into the precipitator cases, to better understand and manage what is happening with the gases under different load conditions and improve dust distribution, thereby improving dust collection and removal. 

Electrode replacement

Also included in the scope of work is the replacement of the current wire-type discharge electrodes with modern and more reliable rigid discharge electrodes. After time, the 12-metre long weighted discharge electrode wires have started to perish, diminishing the electric, or corona field, causing the collector electrodes to lose efficiency and collect less dust. The new rigid discharge electrodes, which will be manufactured in South Africa, cannot break and will create a more stable corona field, thereby maximising efficiency of the ESPs. 

Babcock is the lead contractor responsible for all project management, integration, delivery and construction for the project, and will be working in partnership with USA-based Babcock & Wilcox (B&W). B&W owns the technology of the original design of the precipitators and will be undertaking the process and detailed engineering. 

Babcock has delivered solutions to many of the power stations in the country, and is present at several sites undertaking projects that include high-pressure piping, coal burner overhauls and mill maintenance.

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