Powering the Next-Generation Home: Exploring Emerging Trends in Residential Electricity

The Electric Revolution: Embracing Electrification Across Sectors

The electric power industry is on the cusp of a transformative period, with electrification rapidly gaining momentum across the transportation, building, and industrial sectors. As the U.S. sets its sights on a carbon-free electricity grid by 2035, the demand for reliable, efficient, and sustainable power is skyrocketing.

Industry forecasts suggest that electricity demand could triple within the next two decades, driven by the accelerating adoption of electric vehicles (EVs), the transition to electric heating and cooling systems in homes and businesses, and the proliferation of energy-intensive applications like data centers and AI. This unprecedented increase in electricity consumption will require utilities to strategically upgrade and expand their grid infrastructure to ensure reliable power delivery.

“Electrification may also be accelerating in the building segment as residential and commercial buildings move to electric heat pumps and water heaters instead of fossil-fueled systems,” notes Suzanna, a senior research leader at the Deloitte Center for Energy Solutions. “By mid-2023, more than 125 U.S. cities and counties had adopted policies that require or encourage new and existing buildings to transition to electric heat pump systems.”

The transition towards electrification presents both challenges and opportunities for utility companies. On one hand, they must invest heavily in modernizing the grid, integrating distributed energy resources (DERs), and deploying advanced technologies to manage the increasing complexity of the system. On the other hand, the surge in electricity demand opens the door for innovative business models, new revenue streams, and the chance to lead the clean energy transformation.

Ensuring Grid Reliability and Resilience

As electrification accelerates, the electric power industry must address the evolving risks to grid reliability and resource adequacy. Extreme weather events, climate change-driven water scarcity, and the retirement of baseload fossil-fueled power plants are all putting strain on the system.

“NERC has warned that as much as two-thirds of North America could risk energy shortfalls during periods of extreme summer demand or peak winter conditions,” explains Kate Hardin, the executive director of Deloitte’s research team focused on the energy transition. “And we’ve seen that happen in both the rolling blackouts during California’s 2020 heatwave and Texas’s prolonged outages during winter storm Uri in 2021.”

To address these challenges, utilities are exploring a range of solutions, including:

1. Harnessing Distributed Energy Resources (DERs): The integration of DERs, such as rooftop solar, energy storage, and flexible loads, into virtual power plants (VPPs) can help balance the grid and provide reliable capacity during peak demand.

2. Improving Distribution System Planning (DSP): By enhancing DSP and integrating it with forward-looking, bulk system planning, utilities can more accurately forecast load and enable cost-effective solutions to address future capacity needs.

3. Maintaining Baseload Generation: While the industry continues to transition towards renewable energy, policies that help keep some baseload fossil-fueled and nuclear plants operational can provide critical stability to the grid during extreme weather events.

4. Expanding Generation Capacity: Strategic investments in new utility-scale renewable energy, energy storage, and flexible generation assets can bolster the system’s ability to meet growing demand.

These approaches, combined with innovative technologies like advanced analytics and AI, will be crucial in ensuring the electric grid can reliably and affordably power the next generation of homes and businesses.

Harnessing the Power of Smart Home Technology

As electricity demand rises, homeowners and businesses are increasingly turning to smart home devices and energy management solutions to optimize their energy use and reduce costs. From programmable thermostats and smart appliances to solar-plus-storage systems, these technologies are transforming the way we interact with and consume electricity.

“VPPs, which typically consist of distributed generation, storage, demand resources controlled by software, or all of them, appear well-suited to help meet electricity demand spikes,” says Suzanna. “A recent DOE study concluded that deploying 80 GW to 160 GW of VPPs by 2030 could support growing electrification, while redirecting grid spending to DER owners and reducing overall grid costs.”

Smart thermostats, for example, can automatically adjust a home’s temperature based on occupancy, weather, and energy pricing, helping to reduce HVAC energy consumption by up to 30%. And when paired with solar panels and battery storage, homeowners can maximize their renewable energy use, minimize their reliance on the grid, and potentially even earn income by participating in demand response programs.

“Green Mountain Power has submitted a plan to regulators that would allow it to buy and install batteries in customers’ homes rather than running more lines and paying additional storm recovery costs to repair damaged infrastructure,” notes Suzanna. “This could save time and money while enhancing reliability and resilience, the utility calculated.”

As the smart home ecosystem continues to evolve, innovative utility programs and policies that encourage customer participation will be crucial in unlocking the full potential of these technologies to support grid stability and energy efficiency.

Sustainable Energy Solutions: Harnessing the Earth’s Heat

While the electric power industry grapples with the challenges of rising electricity demand, advancements in geothermal energy technology offer a promising solution to diversify the nation’s energy mix and accelerate the clean energy transition.

The Department of Energy’s latest “Pathways to Commercial Liftoff” report highlights the immense potential of next-generation geothermal power, which could increase the U.S.’s geothermal energy production to 90 gigawatts or more by 2050 – a twentyfold increase.

“Next-generation geothermal energy represents a significant advancement in harnessing the Earth’s heat to generate power,” explains the report. “This innovative approach involves the use of nascent technologies and methods to access and convert geothermal resources into electricity more efficiently and sustainably than ever before.”

Compared to traditional geothermal systems, these next-gen technologies can access a wider range of geothermal resources, including those at greater depths and in more challenging geological conditions. By tapping into the Earth’s abundant, reliable, and carbon-free heat, geothermal power can play a vital role in achieving decarbonization goals while providing baseload electricity generation.

Moreover, the report notes that next-generation geothermal benefits from the long-standing use of geothermal as a power generation technology, as well as transferable technology, supply chains, and workforces from the oil and gas sector. This synergy can help accelerate the deployment and scaling of this renewable energy solution.

As the electric power industry continues to navigate the challenges of electrification and grid modernization, sustainable energy sources like geothermal can offer a valuable complement to the nation’s diversifying energy portfolio.

Investing in the Future: Navigating Funding Challenges

The electric power industry’s capital expenditures are reaching new heights, with S&P’s sample group of large energy utilities expected to spend nearly $171 billion in 2023 – an 18% increase from the previous year. This surge in investment is driven by the need to upgrade and modernize the grid, harden it against severe weather, prepare for rising demand, and source more renewable energy.

However, as utility companies face rising interest rates and inflation, passing the full costs on to customers may become increasingly challenging. “After a 25% average residential customer bill increase over the last five years, utility regulators may be more likely to challenge and limit rate increases,” notes the Deloitte report.

To address this dilemma, utilities are exploring a variety of funding sources, including:

1. Federal and State Grants, Loans, and Tax Credits: The Infrastructure Investment and Jobs Act (IIJA) and the Inflation Reduction Act (IRA) have allocated nearly $94 billion in funding to support the electric power sector’s goals, from grid modernization to clean energy deployment.

2. Operational Savings: Utilities are driving efficiencies through digital technologies, such as smart grid infrastructure and optimized outage management, and diverting the resulting savings into their capital spending programs.

3. Asset Sales: Some utilities are selling non-core assets, like commercial renewable energy projects, to free up funds for their grid investment plans.

4. Alternative Financing Structures: Utilities are also exploring innovative business models, such as selling minority equity interests or offering renewable energy and resilience services to corporate customers through green tariffs and power purchase agreements.

By leveraging a diverse range of funding sources and business model innovations, electric power companies can balance the need for essential infrastructure investments with the imperative to maintain affordable electricity rates for consumers.

The Power of Generative AI: Transforming the Electric Grid

As the electric power industry grapples with the challenges of rising electricity demand, grid modernization, and the clean energy transition, the emergence of generative artificial intelligence (AI) offers a promising solution to address these complex issues.

Generative AI, a subset of AI that can create new content in the form of text, code, images, and even processes, has the potential to transform the way utilities operate. At least 16% of the top 25 U.S. utilities are already in the initial stages of integrating generative AI into their operations, with applications ranging from improving asset management and maintenance to enhancing customer service and energy efficiency.

“In the short term, some are piloting generative AI’s capabilities in initial applications that include automating customer service, generating reports and analyses, and optimizing grid operations and maintenance,” explains the Deloitte report. “These applications have helped utilities trim operations and maintenance costs.”

Looking ahead, generative AI and other large language models (LLMs) are expected to expand the industry’s capabilities in areas such as complex data analysis, pattern recognition, forecasting, and optimization. This could unlock new solutions to address core challenges, including:

1. Resource Planning: Generative AI can help utilities more accurately forecast electricity demand and model the optimal mix of generation resources to meet future needs.

2. Grid Management: By analyzing vast amounts of data from sensors and control systems, generative AI can identify patterns and optimize the grid’s performance, enhancing reliability and resilience.

3. Cost Reduction: Generative AI can automate repetitive tasks, generate insights from unstructured data, and optimize maintenance schedules, helping utilities streamline operations and maintenance expenses.

However, as the electric power industry explores the potential of generative AI, it must also address concerns around data bias, privacy, safety, and governance. Regulators globally have stepped in to establish rules for AI development and deployment, reflecting the collective effort to harness the technology’s benefits while mitigating its risks.

Conclusion

The electric power industry stands at the cusp of a transformative era, driven by the accelerating pace of electrification, the imperative to ensure grid reliability and resilience, and the promise of emerging technologies like smart home devices and next-generation geothermal power.

As utilities navigate the complexities of modernizing the grid, meeting rising electricity demand, and achieving decarbonization goals, they must also grapple with the challenge of securing the necessary funding to power these ambitious initiatives. By leveraging a diverse range of financing sources and business model innovations, electric power companies can balance the need for essential infrastructure investments with the imperative to maintain affordable electricity rates.

At the same time, the rise of generative AI presents a unique opportunity to streamline operations, enhance grid management, and unlock innovative solutions to the industry’s most pressing challenges. By embracing this transformative technology while addressing the associated risks and regulatory concerns, the electric power industry can unlock new levels of efficiency, reliability, and sustainability.

As the electric revolution unfolds, the next-generation home will be a testament to the industry’s ability to harness emerging trends, technologies, and sustainable energy solutions to power a cleaner, more resilient, and more affordable energy future for all.