- Our electrical systems are increasingly at the mercy of severe weather-related events.
- An 'active efficiency' approach can boost their resilience by reducing energy demand without shutting off the power.
- It involves deploying both passive and active measures across the full-spectrum of energy efficiency.
Recent events in Texas and elsewhere in the US are reminding us that our existing energy system infrastructure and operating structures are increasingly being challenged by severe weather-related events. In Texas, unprecedented freezing temperatures created a “perfect storm” of disruption, including dangerous conditions, decreased energy supply due to electric and gas infrastructure failures, and increased energy demand from building heating systems.
Excessive electrical heating demand in Texas required 6.5 GW of electrical curtailment, meaning that rolling blackouts had to be implemented to maintain grid integrity. These supply-side measures were under the control of grid operators who did their best to avert a complete grid shutdown, but these actions only addressed half the problem. In a crisis, it’s common to focus on fixing supply disruptions, but a growing suite of opportunities can make demand-side measures similarly impactful. With severe weather-related events increasing, we need to find solutions that will reduce energy demand without shutting off the power, and first among these should be an 'active efficiency' approach.
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Active Efficiency incorporates the entire spectrum of energy efficiency, from passive, component-based measures to dynamic, systems-level measures enabled by digital technology. Passive measures, such as increased building insulation, reflective surfaces (such as white or green roofs), natural ventilation, daylighting, shading and solar thermal heating are all effective measures to increase building resiliency as they help maintain comfortable indoor conditions during extended power outages in extreme hot or cold weather. Passive measures also reduce heating and cooling energy loads, reducing large electrical demand spikes, and help the system stay online or recover quickly under emergency conditions. Occupant behavior can also have a large impact on energy demand, including everything from turning off non-critical lights and plug loads, adjusting thermostats outside normal comfort settings, opening windows and modifying clothing levels.
In addition to passive measures, dynamic measures such as smart building controls and distributed energy resources (DERs) can deliver additional benefits to occupants and the grid, and respond to crises. Reopening guidance for COVID-19 suggests that building owners consider implementing special control sequences to adjust ventilation rates, and similar strategies have been implemented to temporarily shut down ventilation and reduce non-critical loads in response to wildfires, chemical spills, or other emergency situations. These types of preprogrammed control strategies, including the soft starting and sequencing of HVAC systems after a power failure, could result in significant demand reductions during emergencies as well as cost savings through demand. One of the goals of Beneficial Electrification is better grid management, a capability that can be delivered using Active Efficiency approaches.
Utilities and other companies are taking note. In the 2020 Energy Efficiency Indicator study, more than two-thirds of respondents rated increased energy security and facility resilience as an extremely or very important driver of investment. Notably, 63% plan to have one or more facilities able to operate off the grid in the next 10 years, an increase of 3% on the previous year. Additionally, 81% of US facility and energy executives said increasing the flexibility of facilities to quickly respond to a variety of emergency conditions was an extremely or very important driver of investment, second only to energy cost reduction. Over half of the respondents invested in building systems integration and a third replaced fossil-fuel space and water heating systems with electric heat pumps.
What is the World Economic Forum doing about making our electricity ecosystem cyber resilient?
Cyber resilience is a challenge for organizations globally, but particularly for the electricity industry. Power systems are among the most complex and critical of all infrastructures and act as the backbone of economic activity.
The unprecedented pace of technological change driven by the Fourth Industrial Revolution means that our systems of health, transport, communication, production and distribution will demand rapidly increasing energy resources to support global digitalization and advancement of interconnected devices.
Our Platforms for Shaping the Future of Cybersecurity and Digital Trust and Shaping the Future of Energy and Materials have pioneered a Systems of Cyber Resilience: Electricity Initiative, which brings together leaders from more than 50 businesses, governments, civil society and academia, each with their own perspective, to collaborate and develop a clear and coherent cybersecurity vision for the electricity industry.
Through the combination of passive and dynamic measures, DER integration and building-to-grid integration (often referred to as Grid-Interactive Efficient Buildings), Active Efficiency can maximize benefits to building occupants, communities and the grid. How can this be implemented? In the US, a particularly attractive near-term opportunity is to leverage federal stimulus funding for COVID-19-related health and safety improvements in mission critical public facilities with Energy Savings Performance Contracts or Energy as a Service projects, which are self-funded through guaranteed energy and operational savings. Up to a four-to-one leverage of federal funding would be possible, along with economies of scale, as the building system improvements would be integrated in a single project. Active Efficiency can not only help avoid another perfect storm of future weather-induced grid outages, but also deliver a trifecta of health, sustainability and resilience benefits.