The energy transition, marked by the shift from fossil fuels to cleaner, more sustainable energy sources, is reshaping the power landscape globally. At the heart of this transformation is the integration of digital technologies, particularly artificial intelligence (AI), which enables utilities organisations to enhance efficiency, reliability and sustainability.

AI's ability to process vast amounts of data, identify patterns and make real-time decisions has profound implications for critical areas like demand response program designs and predictive asset maintenance, creating new opportunities for utilities organisations on both continents.

The role of AI in the energy transition

As industries and transportation continue to electrify, utility organisations are central to this energy transition as they manage the infrastructure and resources that distribute electricity from increasingly renewable sources like wind, solar and hydropower. However, integrating intermittent renewable sources while maintaining grid stability presents significant challenges.

AI has emerged as a key technology to address these challenges, helping utilities organisations optimise grid operations, enhance customer engagement and improve asset management.

AI-driven response program designs

Demand response (DR) programs are critical tools for managing energy consumption, reducing peak demand and enhancing grid stability. These programs incentivise consumers to adjust their electricity usage during peak periods or in response to price signals. Traditionally, DR programs have been relatively static, relying on manual processes or predefined schedules. However, with the integration of AI, DR programs are becoming more dynamic, adaptive and customer centric.

1. Predictive demand forecasting

AI algorithms analyse historical consumption data, weather patterns and other external factors to predict demand spikes with high accuracy. AI-driven forecasting improves demand prediction, enabling utilities organisations to activate DR programs more efficiently and ensure customers are notified to reduce consumption during critical times. In regions where renewable energy is expanding rapidly, AI-driven forecasting is essential to balance supply and demand, especially when renewable generation is variable.

2. Customer segmentation and personalisation

AI enables the segmentation of customers based on their usage patterns, preferences and willingness to participate in DR programs. AI-powered personalised customer engagement strategies can significantly increase participation rates in DR programs. Machine learning models allow utilities organisations to design tailored DR incentives, maximising participation and program effectiveness by identifying which customers are more likely to respond to specific and even customised price offerings.

3. Real-time optimisation

AI-powered DR platforms can react in real time to grid conditions, automatically adjusting DR requests based on grid frequency, market prices and renewable energy output. Real-time AI solutions enable businesses to deploy DR measures dynamically, avoiding the need for costly peaking plants and enhancing grid stability. 

Predictive asset maintenance with AI

As utilities organisations modernise their infrastructure to accommodate the energy transition, asset management becomes increasingly complex. Traditional maintenance approaches are often reactive, leading to higher costs and unexpected outages. AI enables a shift towards predictive and proactive asset maintenance, helping businesses maintain grid reliability while reducing operational costs.

1. Proactive maintenance schedules

AI analyses sensor data from transformers, substations and other grid assets to predict when maintenance is needed before failures occur. AI-powered predictive maintenance can reduce maintenance costs significantly and prevent unplanned outages by detecting early signs of asset degradation and extending asset lifecycles.

Australian developed CGI Machine Vision, powered by generative AI, is helping utilities with remote asset monitoring, replacing periodic manual inspection with continuous automatic analysis, freeing up staff and increasing the rate of coverage by many times.

2. Improved resource allocation

Incorporating AI into asset maintenance allows utilities organisations to prioritise repairs and allocate resources more efficiently. AI models assess which assets are at the highest risk of failure and determine the potential impact on the grid. AI-driven asset management improves grid reliability and operational efficiency, ensuring critical assets are serviced promptly while minimizing unnecessary disruption of service.

3. Digital twins for real-time monitoring

Utilities organisations are deploying digital twins—virtual replicas of physical assets powered by AI and IoT sensors—to monitor grid infrastructure in real time. The use of digital twins will become increasingly common, providing a holistic view of asset performance and enabling real-time simulations of potential failure scenarios. This technology allows utilities organisations to implement preventative measures before issues arise, enhancing grid resilience.

AI innovation in numbers: CGI 2024 Voice of Clients insights

As cited by executives interviewed in CGI’s annual Voice of Our Clients global research, AI is the top innovation priority over the next 3 years — yet 50% of respondents also cite an increased focus on optimising investments and operations by both business and IT stakeholders.

This suggests that while utilities organisations are prioritising investments on AI initiatives, realizing the ROI from these investments is critical. Two key areas, AI-driven demand response program design and predictive asset maintenance with AI can provide significant ROI from their investment when powered by accurate, timely data.

The future of AI in the energy sector

As the energy sector navigates the complexities of its transition to sustainability, AI emerges as a pivotal force in enhancing operational efficiency and reliability for utilities organisations globally. By integrating AI into demand response programs and predictive maintenance strategies, businesses are not only adapting to real-time conditions but also preventing costly outages and optimising asset management. The evolution of smart grids and the proliferation of distributed energy resources (DERs) necessitate sophisticated orchestration capabilities that AI provides, simplifying the management of decentralised systems.

As utilities organisations continue to harness AI's potential, they are better positioned to confront the challenges of this multifaceted energy transition, ultimately paving the way for a cleaner, more resilient energy future that balances flexibility with sustainability.

Our team is here to provide guidance on developing AI strategy and governance, and on AI-powered technologies designed to fast-track operational efficiencies and business outcomes.