The global market for artificial intelligence (AI) in the energy and utilities sector was valued at $10,56-billion in 2023 and is projected to surge to $45,78-billion by 2030, signalling the critical role AI will play in reshaping the future of power systems.
By Satyajit Dwivedi, regional director: EMEAP for energy utilities, mining & metals, public sector at SAS
At the same time, African cities are at a pivotal point in their energy transformation journey.
With nearly 600-million people across the continent still lacking access to electricity, the goal of building inclusive and sustainable smart cities remains out of reach without first modernising the foundational grid infrastructure. As efforts intensify to upgrade ageing assets and extend electricity access to underserved communities, AI is fast emerging as a catalyst for this transformation.
Africa’s evolving energy landscape — driven by rising demand, the growth of decentralised renewable generation, and rapid digitalisation — highlights the urgent need for smarter, more responsive grid systems. AI will be central to this shift, offering the intelligence, agility, and real time decision-making capabilities required to manage increasingly complex and dynamic electricity networks.
The urgent need for smarter grids in Africa
Traditional power grids were built for a simpler, one-directional world — where electricity flowed from centralised power plants to passive consumers. That linear model, which served the industry for over a century, is no longer sufficient. Today, the power network has become inherently multi-directional.
Urban centres are witnessing a surge in prosumers — consumers who also generate energy, such as households or businesses with rooftop solar panels feeding electricity back into the grid. Simultaneously, rising electrification, extreme weather events, ageing infrastructure, and the integration of renewable energy sources are making the grid more volatile and complex.
This dynamic environment requires more than just physical upgrades—it demands network intelligence. A modern smart grid is not defined solely by sensors and automation, but by its ability to interpret, adapt, and act on vast streams of real time data.
And that intelligence must be managed intelligently. This is where AI becomes indispensable: enabling predictive analytics, autonomous decision-making, and seamless coordination across a decentralised, digital, and multi-directional energy landscape.
AI: The intelligent engine of modern grids
When combined with the Internet of Things (IoT), AI effectively gives the electrical grid a functional brain — empowering it to sense, analyse, and act in real time. AI algorithms process enormous volumes of data from smart meters, grid sensors, weather feeds, and even social media to detect patterns and generate actionable insights far beyond the reach of manual systems. This evolution enables utilities to shift from reactive operations to predictive and proactive grid management.
For instance, AI-driven forecasting models leverage historical consumption patterns, weather forecasts, and live sensor inputs to accurately anticipate electricity demand. This foresight allows operators to optimise generation and storage planning, mitigating the risk of blackouts.
In countries like South Africa, where sudden demand spikes or generation shortfalls have historically led to severe load shedding, such predictive capabilities are game-changing—facilitating a shift from crisis response to long-term grid resilience.
Furthermore, smart meter data plays a crucial role in enhancing peak load management and operational efficiency. AI systems can analyse granular consumption data to identify high-demand periods, enabling the implementation of Time-of-Use (ToU) tariffs that incentivise off-peak usage and smooth demand curves. Integrated Demand Response Management (DRM) strategies can autonomously signal non-critical appliances — like air conditioners or water heaters — to cycle down during peak times, reducing strain on the grid without compromising user comfort. This real time coordination helps stabilise the grid and reduces the need for costly infrastructure upgrades.
AI also supports outage prediction and planning, using anomaly detection on grid parameters to forecast potential failures before they occur. In case of disruptions, intelligent systems can reroute electricity flows to minimise impact and accelerate restoration.
As African communities expand the use of distributed energy resources—such as rooftop solar, wind, and battery storage — AI plays a vital role in integrating these assets into a cohesive system. Machine learning models can dynamically determine the optimal mix of local and grid-supplied energy, ensuring efficient utilisation of renewables.
The result is a self-optimising, multi-directional smart grid that not only balances supply and demand in real time, but also adapts to an increasingly decentralised, data-rich, and consumer-driven energy landscape.
From reliability to sustainability
The promise of AI in smart grids is not abstract; it translates into very tangible benefits for utilities and citizens alike. Key AI-driven interventions for smart grids include several benefits.
Intelligent analytics can detect anomalies in equipment behaviour (like unusual vibrations in a transformer or voltage fluctuations) that often precede a failure. Utilities have begun installing IoT sensors on critical assets such as turbines, transformers, and transmission lines to enable this. AI systems analyse the sensor data in real time and can alert engineers to impending issues or even trigger automatic preventative actions. This predictive maintenance avoids catastrophic failures and widespread outages.
Power theft and non-payment are persistent challenges in many regions. In fact, utilities worldwide lose an estimated $89,3-billion every year due to customers who bypass meters or do not pay bills. Africa is no exception – electricity theft in Nigeria or illegal connections in South Africa’s townships directly affect utility finances and service quality.
AI can help here by analysing consumption patterns to flag suspicious anomalies. Advanced image recognition and drones equipped with AI can also patrol power lines to spot illegal taps or vandalism. By pinpointing where losses are occurring, utilities can take targeted action, improving revenue collection and reducing wastage.
This ultimately benefits honest consumers as well, by strengthening the utility’s ability to invest in better infrastructure instead of writing off losses.
Perhaps one of the most significant impacts of AI-driven smart grids is how they enable greater use of clean energy. Renewable sources like solar and wind are abundant across Africa, but they are intermittent by nature. AI comes to the rescue by forecasting renewable energy output (predicting a drop in solar generation when a storm is coming, for example) and balancing it with other sources or stored energy. Intelligent control systems can decide when to charge battery banks, when to draw from them, and how to smoothly blend renewable power with traditional generation to maintain a steady flow.
This means cities can reliably incorporate higher percentages of green energy without jeopardising stability. For a continent heavily impacted by climate change, the ability to build low-carbon, sustainable energy systems that are also reliable is a huge win. Smart grids with AI are thus not only about keeping the lights on – they are about doing so in a way that supports long-term sustainability and climate goals.
Towards a smarter, brighter future
The benefits of AI-driven grid modernisation extend to both urban and rural settings. In cities, a stable, responsive power grid underpins smart mobility, digital services, and industrial growth. In rural areas, AI-managed microgrids and mini-grids enable decentralised electrification using local renewable resources. These systems optimise every watt of available energy, ensuring reliable access in regions previously off the grid. The broader social impact is profound — improved healthcare, education, and economic opportunity through reliable electricity access.
As African nations invest in smart infrastructure, the electric grid becomes the critical enabler for all other smart city systems. To fully realise the potential of AI in smart grids, policymakers, regulators, and utility leaders must invest in digital infrastructure, advanced analytics platforms, cybersecurity protocols, and workforce reskilling. Strategic partnerships and regulatory alignment will be crucial to scale these innovations sustainably.
The transformation of African power systems through AI is not just a technological upgrade—it is a foundational step toward energy security, socio-economic development, and climate resilience. Smart grids empowered by AI offer a pathway to a future of fewer outages, better-managed resources, expanded energy access, and greener power generation.
By embedding intelligence into grid operations today, African nations can leapfrog into a new era of sustainable and inclusive energy systems.