Ghana must hasten electricity base-load switch to Nuclear

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Feature Nuclear Technology
Feature Nuclear Technology
Spining

… appropriate technology needed to deal with energy supply threat

A major concern that has been raised by many Energy experts and policymakers on the nation’s Electricity Supply Plan is the eminent electricity challenges and the need for an alternative sustainable baseload supply.

Energy experts studying the electricity supply plan over the years have indicated that beyond 2025, Akosombo and Kpong hydropower Plants, which currently serve 32 peer cent as the nation’s baseload supplier would have reduced drastically to about 25 per cent.

As a result, there have been persistent and urgent calls for alternative and diversified generations to support existing baseload plants.

Even though the report has not been specific on, which energy source would be prudent, indications are that Ghana is highly considering Nuclear as it guarantees the provision of sustainable, reliable, and affordable power to push the nation’s industrialisation agenda.

Energy Minister, Dr. Matthew Opoku Prempeh, during his Parliamentary vetting, confirmed the government’s desire to introduce Nuclear power into the country’s generation mix to help propel economic growth.

At the time, he noted that the selection of a Vendor – the country whose nuclear technology Ghana would want to partner with to construct the first Nuclear Power Plant – was a top priority as Cabinet had received the Nuclear Power Programme Comprehensive Report on the nation’s nuclear future and its prospects.

But the key question on the minds of many is, what kind of nuclear technology is Ghana going for?

A large reactor Nuclear Plant that would inject 1,000 megawatts and above into the national grid as a single unit or a Small Modular Reactors (SMRs) – which generally produce 300 megawatts equivalent or less, modular in nature and can be scaled up to meet growing demand.

Large Reactor Nuclear Power Plant

Major progress has been made towards achieving the case for the inclusion of Nuclear Power in Ghana’s generation mix.

However, the type of technology to be adopted hang in the balance.

Speaking to B&FT recently on the nation’s Transmission Grid safety and stability, Ing. Norbert Anku, a former Director at GridCo indicated that, the important role of the electric grid system to which the Nuclear Power Plant would be connected is a key determinant in the choice of a technology.

Ideally on a economy of scale, a single large reactor tends to be economical than a single SMR.

However, the technical issues of grid safety and reliability coupled with the levels of demand over time are critical.

A reliable, balanced and well-maintained electric grid is crucial for the adoption of a large reactor Nuclear Power Plant online and operating it cost-effectively and safely.

Ing. Anku cautioned that, considering the current electricity demand levels of over 3,500MW and the efforts to bring additional generation, preferably Nuclear, which is the way to go, a heavy injection which does not support the current state of the grid and the stability of the supply situation will be injurious; “should there be a situation where that Power Plant is knocked off the grid, it means you have lost 1000 megawatts and the grid can go into swings and crush.” he stressed.

He added that huge investment would be needed to manage the incident load structure of the nation’s grid and ensure that there would be no huge damages if such an instance occurred.

According to experts, a large reactor Nuclear Power Plant when connected to the grid will certainly be the largest single generating unit on the Ghana gid system.

This is significant because there is a practical limit to the size of generating unit that can be installed in an electrical power system if the system is to remain stable and secure, especially after unplanned disconnection of that generating unit.

A 1000 megawatts or higher Nuclear Power Plant injection as a single unit would mean the Nuclear Power Plant would be more than 10 percent of the total installed capacity even in 2030 when the Nuclear Plant is projected to come online.

Such a situation would likely pose technical and safety challenges on the Nuclear Power Plant and the transmission grid system at the same time unless substantial investment is made to upgrade the transmission grid infrastructure.

Without such investment, the grid system cannot reliably and safely be connected to the Nuclear Plant.

What does this mean?

The only option available to Ghana to connect large reactor Nuclear Power Plant to the current state of the transmission system is to invest hugely in

the grid infrastructure.

It is important to note that the current total installed capacity is around 5,000 megawatts. in terms of unit capacity, the largest on the grid currently is less than 200 megawatts.

Therefore, a 1000 or higher megawatts Nuclear Power Plant as a single unit on the grid would significantly impact on other generators should the Nuclear unit trips.

This technical complexity should not be overlooked notwithstanding the economy of scale for large reactors.

Small Modular Nuclear Reactors (SMRs)

SMRs are advanced nuclear reactors generally 300 megawatts equivalent or less. SMRs are “Small” – physically, a fraction of the size of large reactor Nuclear Power Plant and “Modular” – makes it possible for systems and components to be factory assembled and transported as a unit to the site for installation.

SMRs are simple design and has economy of scale associated to factory production and reduction in costs, can be installed module by module to meet growing demand, small power means countries with small and weaker electric grids can still connect SMR with very little or no investment on the grid, modules can be independently managed so that maintenance and refueling outage can be done while the other modules are still in operation.

The challenge is that, currently, there is none in operation. However, some countries are at advanced stages of connecting SMRs to their grid.

Would Ghana be First to operate an SMR?

Not really, just this month, the China National Nuclear Corporation (CNNC) announced the completion of the pouring of concrete for the foundation slab for the ACP100 multi-purpose Small Modular Reactor (SMR) demonstration project at the Changjiang nuclear power plant on China’s island province of Hainan according to World Nuclear News.

Construction of the multi-purpose 125MWe reactor officially started on July 13th 2021 following final approval for its construction by their country’s Regulator.

CNNC announced in July 2019 the launch of a project to construct an ACP100 SMR reactor at Changjiang. The site is already home to two operating CNP600 PWRs.

Under development since 2010, the ACP100 integrated PWR’s preliminary design was completed in 2014.

The major components of its primary coolant circuit are installed within the reactor pressure vessel.

In 2016, the design became the first SMR to pass a safety review by the International Atomic Energy Agency, the report noted.

Also reported by World Nuclear News is full scale production of NuScale SMR technology.

Under a newly signed agreement between NuScale Power (a USA Vendor) and Korean energy firm Doosan Enerbility, the Korean firm is to begin manufacture of main equipment for the NuScale Small Modular Reactors (SMRs).

“Under an agreement signed on 25 April, the Korean company could begin production of forging materials for the reactors this year, with full-scale equipment manufacturing expected to begin by the latter half of 2023. Specifically, Doosan will begin production of forging dies for the upper reactor pressure vessel.

These are expected to be used in the first commercial deployment of a NuScale VOYGR power plant for Utah Associated Municipal Power Systems’ (UAMPS) Carbon Free Power Project (CFPP) which is to be built at a site at the Idaho National Laboratory in the USA.”

The NuScale SMR is the first SMR design to receive approval from the US Nuclear Regulatory Commission. The NuScale Power Module with single unit generating 77 MWe comes in modules of 4 modules (308 MWe), 6 modules (462 MWe) and 12 modules (924 MWe).

Cleary from these two examples above, Ghana is unlikely to be the first SMR country should it decide to go for SMR technology because some countries are already at SMR integration.  

With the current energy quagmire the country is faced with, future energy plans need to be hastened but it must be done in a technically prudent manner to achieve optimal result.  

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