The U.S. electricity system is on the cusp of fundamental change, driven by rapidly improving cost-effectiveness of technologies that increase customers’ ability to efficiently manage, store, and generate electricity in homes and buildings. With growing adoption of these technologies, the electricity system is shifting toward a future in which the deployment and operation of distributed energy resources (DERs) will have far-reaching implications for grid operation, investment, and security. Yet, there is a looming disconnect between the rapidly evolving new world of distributed energy technologies and the old world of electricity pricing, where relatively little has changed since the early 20th century.
A new e–Lab report, Rate Design for the Distribution Edge: Electricity Pricing for a Distributed Resource Future, helps to bridge that gap. By changing electricity pricing to more fully reflect the benefits and costs of electricity services exchanged between customers and the grid, utilities and regulators can unleash new waves of innovation in distributed energy resource investment that will help to reduce costs while maintaining or increasing system resilience and reliability.
CAPTURING VALUE, OPTIMIZING INVESTMENT THROUGH GREATER RATE SOPHISTICATION
The stakes are high in getting this transition right. With or without pricing reform, distributed resources are likely to account for a growing share of total electricity system investments. DER developers and customers will optimize their investments and operations against the price signals provided by the utility, regardless of whether or not these prices are aligned to create the greatest value for society as a whole. The types of pricing structures most common today for residential and small commercial customers—bundled, volumetric block rates—provide little or no incentive for the deployment and operation of DERs at the times and places where they can create greatest overall benefit. The perpetuation of these pricing structures in the face of ongoing improvement in DER cost and performance and increased penetration of these technologies will result in lost opportunities for cost reduction and inefficient utilization of assets on the part of both customers and utilities.
Creating a clean, efficient, and secure 21st century electricity system will pivot, in part, on successfully integrating DERs into the design and operation of the electricity grid—and pricing provides the incentive structure needed to achieve this integration. More granular pricing, capable of reflecting marginal costs and benefits more accurately than today’s rates do, will provide better incentives to direct distributed resource investments, regardless of whether investments in and management of DERs are undertaken by customers, by utilities, or by third-party solution providers. Ultimately, prices could be adapted to fully reflect a two-way exchange of value and services between utilities and customers.
Making the transition to new pricing approaches, however, will undoubtedly pose challenges. In particular, it will require taking new approaches or making trade-offs against one of the hallmark principles of traditional rate design: simplicity. In addition, introducing new and more complex pricing structures could have disruptive effects on existing business models for DER developers. Developing and implementing new pricing structures will therefore require effective collaboration among utilities, regulators, technology developers, and customers. By creating a shared vision of the future trajectory for prices, however, these parties could create a pathway whereby DER technology and services can co-evolve with increasingly advanced price signals.
AN EVOLUTIONARY PATHWAY ALONG THREE PRICING CONTINUUMS
This e–Lab report discusses a pathway for deliberately and incrementally increasing rate sophistication along three continuums for residential and small commercial customers:
1. Attribute unbundling—shifting from fully bundled pricing to rate structures that break apart energy, capacity, ancillary services, and other components
2. Temporal granularity—shifting from flat or block rates to pricing structures that differentiate the time-based value of electricity generation and consumption (e.g., peak vs. off-peak, hourly pricing)
3. Locational granularity—shifting from pricing that treats all customers equally regardless of their location on the distribution system to pricing that provides geographically differentiated incentives for DERs.
A transition to more sophisticated pricing is attainable in the near-term for large portions of the country, but will require careful planning and customization to local circumstances. The introduction of more pricing options for customers—allowing customers to opt in to new rates that allow them to benefit from actions that reduce system costs—could allow the implementation of new approaches in stages, while providing an opportunity for customers and solution providers to experiment with new rates. For example, pricing options could include a default pricing option that gradually changes to become more differentiated over time, while providing alternative opt-in pricing structures that are more or less sophisticated than the default for customers who want or need such choices.
These evolutionary pricing options could include, individually or in combination:
Today’s bundled, volumetric block prices lack sophistication in each of the three continuums. However, a number of options exist—some achievable in the near term—for increasing sophistication to better capture value from, and direct the deployment of, distributed energy resources.
These more sophisticated pricing options need not introduce unnecessary complexity for customers—third-party aggregators, energy management software, smart thermostats, and other technologies can maintain a simple customer experience by optimizing performance behind the scenes even as greater differentiation gets built into the rate structures.
Transitioning to some of the new rate structures explored in this report is possible today or will be realistic in the next few years in some markets, especially where utilities have already transitioned to advanced metering infrastructure. In other cases, implementation of more advanced rate structures will take more time—and possibly even legislative and regulatory reform—to achieve. In any event, the conversation about how to adapt electricity pricing to meet the needs of a 21st century electricity system has begun. Bringing this transition to fruition will require participation, dialogue, and collaboration among stakeholders to deliver successful outcomes.
Source: RMI. Reproduced with permission.