Article
23 minute read 17 February 2021

Digital utility asset management

Building the backbone of the energy transition

Jim Thomson

Jim Thomson

United States

Brian Murrell

Brian Murrell

United States

Jian Wei

Jian Wei

United States

Kate Hardin

Kate Hardin

United States

Suzanna Sanborn

Suzanna Sanborn

United States

A framework to help electric power companies develop data-driven, risk-informed digital asset management strategies that balance risk, cost, and performance.

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  • Introduction

    The power industry is leading the way in the clean energy transition, with renewables at the center of many providers’ strategies. This translates into a newer, more diverse set of assets to manage and integrate with the rapidly aging set of existing assets, together worth about $1.2 trillion.1 At the same time, demand for affordable, clean, and uninterrupted power supplies is accelerating as businesses electrify and digitally transform their own operations and consumers increasingly work from home. Additional drivers, such as the COVID-19 pandemic and surging cyber risk, up the ante on the importance of managing assets by balancing cost, risk, and performance.

    But moving to cleaner power sources while boosting reliability, resilience, and security is a tall order. To achieve this, companies will likely need to move away from traditional asset management strategies and develop comprehensive digital strategies with robust data governance and cybersecurity at the core. Unfortunately, our research shows that most electricity providers are still only dabbling in digital, and not approaching digital transformation with the comprehensive, holistic view that could make it a game changer to unlock the full range of benefits.

    This report, the third in a series on digital transformation in the power, utilities, and renewables sector, presents Deloitte’s Digital Utility Asset Management Model—a framework that lays out the digital asset management journey through nine stages of evolution, with cybersecurity and data governance at its core. It explores where utilities and renewable providers are now in the journey and what steps they should consider taking to develop a data-driven, risk-informed, digital asset management strategy. Building a system for value-based decision-making can help electric power providers build tomorrow’s cleaner, more reliable, resilient, and secure grid—which will be the backbone of the energy transition in the power sector.

    Five disruptors and an expanding asset mix compel new asset management strategies

    Five intensifying challenges are prompting many electric power providers to seek new tools and processes for asset management (figure 1).

    At the same time, the slate of assets itself is expanding and becoming more complex. Until recently, asset management was typically compliance-driven, managed by different departments, and sometimes by individual employees who maintained their own reports based on bespoke data aggregation. Systems were often not fully connected or updated in real time—utilities often relied heavily on seasoned employees with decades of system knowledge and experience, who were difficult to replace as they retired. Risk management was not always informed by probability data. But the proliferation and complexity of assets is making this approach unsustainable.

    • Expanding number of assets: With the growth of renewables and distributed energy resources (DER), utilities are managing 10 times more assets than they were managing 20 years ago and assets will likely continue to grow.2 Unfortunately, utilities themselves do not own most of these DER, which increases the challenge in managing or controlling their impact on the grid. In addition, the more intermittent nature of wind and solar generation means additional solutions will likely be required to balance electricity load and supply. US DER capacity is projected to reach 387 gigawatts (GW) by 2025, driven by $110.3 billion in cumulative investment between 2020 and 2025.3
    • Increasing complexity of assets: Utility asset life cycles are becoming increasingly complex with the addition of renewables and the infrastructure required to integrate them smoothly into the grid. Moreover, with the convergence of information technology (IT) and operational technology (OT), or systems that control a utility’s physical infrastructure,4 many assets have electronic components with different life spans, depreciation rates, operating scenarios, and maintenance requirements. To help manage this evolving mix, providers are deploying new classes of assets, such as energy storage, smart meters, sensing devices, data, software, firmware, and hardware, which also increase the complexity of assets a utility has to manage.

    As power sector disrupters have accelerated and assets have become more numerous and complex, tools and technologies to manage them have also advanced. A proliferation of sensors provides a growing variety of metrics with greater frequency. New communications technologies enable faster data transfers from those sensors and cloud computing expands the scope and speed of data analysis. Artificial intelligence (AI) can help predict future behavior by learning from historical data. Such technological advances make new ways to manage assets possible. And improved asset management can help boost operational efficiencies, save costs, increase asset life expectancy, improve reliability, and enhance safety. But realizing these benefits through digital transformation requires a comprehensive framework, and like most good journeys, it begins with a road map.

    The Digital Utility Asset Management Model helps map the digital transformation journey

    Digitally transforming asset management means decisions can be data-driven and risk-informed, rather than “acting on a hunch.” The Digital Utility Asset Management Model is a framework that describes the fundamental journey of digitally transforming and enabling assets (figure 2). This journey is backed by supporting technologies, with cybersecurity and data governance lying at its very core. Rather than being sequential, the journey instead requires the enterprise to identify its overarching vision and objectives, and construct an integrated solution with a customized road map that leads to specific business outcomes (see the section, “Next steps: Developing a digital asset management strategy”).

    The inner core of the Digital Utility Asset Management Model focuses on two critical dependencies: Data governance and cyberseurity, which we discuss further in the final section, “Next steps: Developing a digital asset management strategy.”

    The digital transformation journey traverses the utility value chain

    Efficiently managing an expanding portfolio of renewable assets is proving critical to electric power providers in leading the energy transition. The Digital Utility Asset Management Model can help them boost the reliability and resiliency of new and existing assets across the grid. Let’s consider how the industry is performing within the model across each segment of the value chain (generation, transmission and distribution, and grid edge) and what next digital steps it should take in the coming 2–3 years. As for the methodology for our mapping of each segment, we did extensive secondary research on latest solutions and technologies provided by major utilities, renewable energy companies, and OEMs, validating our conclusions through interviews with industry experts from major utilities.

    The generation segment is increasingly using digital innovation to manage renewable assets

    Starting with power plant design and siting and continuing through the plant’s entire life cycle, digital innovation is playing a key role in the transformation of asset management in the generation segment. It can be particularly valuable as the industry moves toward cleaner energy sources, including integrating intermittent wind and solar plants and harder-to-access offshore wind farms. Digital asset management can enhance performance by informing plant design and enabling health monitoring; reducing operations and maintenance (O&M) costs; and boosting reliability, availability, and profitability.

    CURRENT STATUS: The generation segment is largely in the Analyze and Visualize phases in the Digital Utility Asset Management Model.

    By using digital tools such as sensors, power generators can now access multiple data points, varying from fuel temperature and pressure to vibrations and humidity levels, depending on the type of plant. For example, gas turbines typically have hundreds of data points monitored while wind turbines may have over a hundred.5 Utilities have aggregated and analyzed this sensor data and developed dashboards to track plant-specific parameters, such as increased turbine pressure. Previously, technicians had to manually collect data from remote sites after issues arose, and determine the health of components often with little additional data for context.

    However, while sensor data combined with basic analytics and visualizations have improved plant monitoring and yielded maintenance cost savings and other benefits, only a small portion of the data collected is currently used to inform decision-making.6 This implies that the scope to implement digital solutions and reap the resulting benefits could be immense.

    DIGITAL LEAP: In the next two to three years, the generation segment will likely focus on advancing further into the Visualize and Augment phases.

    Asset managers have long used dashboards to display plant data. But many are just beginning to combine data, including real-time data, from diverse systems into those existing dashboards to enable continuous asset health monitoring and improve performance management. Some are combining real-time performance insights with historical trends and applying predictive or pattern-recognition algorithms to monitor equipment. This advanced asset health monitoring can enable plant technicians to walk through the plant and see “hot spots” in real time, or areas where advanced telemetry reveals anomalies that could lead to asset failure. They can also use this data to attenuate maintenance schedules and to create or upgrade existing digital twins.

    As renewable penetration increases, real-time generation data can become an important tool to maintain grid balance, given the intermittency associated with wind and solar power. In solar plants, the shift will likely be toward machine learning–based signature detection algorithms that automatically quantify and categorize the causes of production loss, providing insight to enable better plant maintenance strategies. Similar strategies are being used in wind plants (see sidebar, “Using digital innovation to boost renewable asset performance”).

    Using these predictive maintenance strategies to reduce O&M costs would be an enormous boon for the power generation segment, which has seen such costs soar. In just the past two decades, nonfuel power generation O&M costs rose 74%, according to an analysis of data from 2,500 US power plants.7 In one nuclear plant, for example, an asset performance management application reduced hours spent annually on preventive and corrective maintenance by 37%; helped reduce cost by 20% or $10 million annually; and improved the overall capacity factor while setting a record for power production.8 Analytics augmented with AI can also enhance scenario planning capabilities that are in growing demand as power providers increasingly focus on disaster preparedness plans.

    Some electric power providers are already deploying advanced digital asset management technologies to extract the most value from their growing fleets of wind or solar plants (see sidebar, “Using digital innovation to boost renewable asset performance.”)

    The T&D segment is harnessing digital transformation to ensure reliability and resilience

    The US transmission and distribution (T&D) segment is being buffeted simultaneously by the five disrupters mentioned earlier. These intensifying phenomena could impact reliability and resiliency, which are among the top concerns for utilities. Right behind that is keeping costs in check. And with an estimated $1.1 trillion required to replace, expand, and upgrade the US electric grid through 2040 to maintain reliability and resiliency,9 the math is compelling. For example, if digital innovation could help avoid or defer even 3% of these expenditures, it would save a staggering $33 billion.

    CURRENT STATUS: The T&D segment is typically at the Integrate/Aggregate phase, though many rural utilities may still be in the Communicate phase as remote assets may  lack access to high speed communications.

    Because it traverses thousands of miles and reaches into each individual home and business, the T&D system is especially difficult to monitor and the stakes of missing something can be high. That may explain why the segment has a keen interest in advanced monitoring and inspection technologies to help ensure reliability, boost resilience, and reduce costs. In some cases, such as during the ever-lengthening wildfire season, automated remote monitoring could even help prevent fires if objects touching high voltage wires are detected and the condition can be more immediately addressed. In comparison, conventional inspection techniques typically involve on-foot visual inspections, which are expensive, labor-intensive, and can lack accuracy and compromise worker safety.

    Many US utilities have already installed sensors, smart meters, and other intelligent devices across their systems to measure and monitor a variety of events and conditions. Smart meters are becoming increasingly valuable for the data they provide, and with more than 60% penetration of customer sites, their value continues to increase.10 Utilities are also starting to deploy “sensing aerial solutions,” such as cameras mounted on drones, to inspect power lines, collect data on the condition of wires, poles, transmission towers, and other equipment, and to detect potential equipment failures.

    However, one of the biggest challenges has been gathering data from multiple networked asset components and providing a single repository source to monitor and analyze the data. Utilities often lack the cloud capabilities required to derive actionable insights in real time from the growing web of connected assets and the data they generate. Another challenge that has slowed T&D digitalization in some areas compared with the generation segment is communications. While a stationary power plant has the capability to connect through mechanisms including fiber cable or Wi-Fi, far-flung T&D systems traversing rural areas may currently be beyond the reach of high-speed communications networks.

    DIGITAL LEAP:  In the near term, the T&D segment will likely focus further on the Integrate/Aggregate phase while also progressing into the Analyze and Visualize phases.

    In the next 2–3 years, asset managers in the T&D segment will likely continue efforts to aggregate and standardize data from disparate systems into one repository source. This can help break down siloes, such as between operations, maintenance, and asset management, so operators can harvest insights by examining relationships among data sets to which they did not previously have access. Cloud storage and analytics solutions can generate actionable insights in real time and they compare favorably with on-premise solutions in terms of speed, scope, and depth of insights. Some regulated utilities have hesitated to adopt cloud solutions both for security reasons and because the expenditures have historically been treated as operating expenses rather than being included in capital assets, which can make it a challenge to earn a sufficient ROI. But that trend is starting to change and many utilities are deploying cloud solutions for scalability and flexibility.11 At the same time, a number of utilities have pursued private LTE/5G or fiber optics networks to upgrade communications latency and speed required by evolving IoT and data transmission needs.

    As they access and analyze more data, the T&D segment will also likely focus on creating more complex dashboards and visualizations to provide situational awareness. More utilities may deploy geospatial systems that not only integrate locational data with data from multiple systems as in a conventional geographic information system (GIS); they also enable collaboration and sharing of data, such as asset conditions, weather, and customer complaints, through multiple devices. In addition, as utilities begin to solve the challenges of accessing, updating, and ensuring the accuracy of critical data across the network, they will likely increasingly develop digital twins.

    The segment will almost certainly hone its drone capabilities further in the next few years, and many look forward to being able to fly drones beyond the visual line of site (BVLOS). In the longer term, those using advanced communications technologies such as 5G would be able to combine it with BVLOS, which could be a game changer for the segment. Paired with cloud capabilities, these technologies could enable real-time streaming video from remote drones, providing enhanced visibility for assessing equipment and damage status. The drones could quickly process data using AI, potentially identifying structural defects in T&D infrastructure in near real time. This could be especially valuable in the wake of disasters and outages to speed data transfer to work crews so that they can restore power faster.

    Digital asset management provides more visibility and control at the grid edge

    The “grid edge” is not a segment of utility-owned assets, but rather an expanding array of DER and devices, many of which are customer or third party–owned and controlled. Digital asset management applications can help utilities gain more visibility and better understand DER impact on the whole asset ecosystem. As DER are proliferating, the three segments of the value chain are converging and the siloed approach to asset management by individual teams is becoming obsolete. The systems are joining to eventually become a single holistic, shared network, controlled centrally, and optimized for decision-making across the value chain.

    DER, such as rooftop solar systems, battery storage, EV chargers, and flexible load program capacity, may add up to nearly 24% of US generation capacity by 2025.12 And these resources can increasingly help balance the growing volume of intermittent renewables on the grid as the energy transition progresses. In fact, flexible load programs are expected to triple current US demand response program capabilities by 2030, reaching about 200 GW, or 20% of system peak.13

    For utilities, the goal is to help design and site these assets, where possible, and to gain visibility and control over their behavior to the degree possible. Digital applications, such as distributed energy resource management systems (DERMS), are helping utilities better understand load and manage these new assets at the grid edge.

    CURRENT STATUS: Assets at the grid edge typically range from the Create phase to the Integrate/Aggregate phase in their interaction with utility systems.

    Today many utilities are unable to detect and identify an EV-owning home on the distribution system. Rooftop solar systems are a different story, since utilities connect them to the grid, but many have little control over them after that. Analytics can be, and are, easily deployed to detect and identify the footprints of individual DER, such as EVs. And smart inverters and other software platforms can aggregate, control, and synchronize DER with grid operations, owner parameters, weather, and market conditions. But these solutions are unevenly deployed, as DER are a relatively recent addition to the grid, and rules and practices vary widely across utilities and jurisdictions. And in rural areas, network communication may also be a challenge.

    DIGITAL LEAP: In the next two to three years, utilities will likely advance further into the Integrate/Aggregate, Analyze, and Visualize phases as they integrate DER into the asset ecosystem.

    As utilities continue to more precisely map and plan their distribution systems with DER in mind, and move forward with developing DER rules and protocols, they will likely increasingly integrate these resources into system models and use analytics to assess and predict DER impact on the entire asset ecosystem. They’ll deploy more smart devices and distributed analytics at the grid edge to access more granular information in real time. And they’ll use the data to inform decisions and enhance operational efficiency, to help reduce stress on the system that could shorten the life cycle of equipment such as distribution transformers.

    Digitally enabling asset management across the utility value chain

    Figure 3 summarizes the current status and potential short- to medium-term digital leap in the Digital Utility Asset Management Model for each segment of the utility value chain.

    The three segments are progressing through the same phases, but at different rates largely due to differences in the nature of the assets. Generation plants are stationary and usually have access to high-speed communications, so progression through the loop may be faster and more widespread in this segment. In contrast, the transmission system traverses thousands of miles, sometimes through remote areas that lack high-speed communications capabilities. Distribution systems in rural areas may face the same challenge, including at the grid edge. In addition, since grid edge assets are often owned by customers or third parties, utilities may still lack the visibility to integrate and manage them optimally.

    While the three segments are progressing through the loop at different paces, planners across the value chain appear to be aiming for the Augment phase, in which AI can provide predictive insights to boost performance and save costs. This corresponds with results of a Deloitte survey in November 2020 that asked power industry respondents which technology was the most important for utilities right now (figure 4). More than half (55%) chose “Artificial intelligence/Machine learning.”

    Next steps: Developing a digital asset management strategy

    The most critical step in a digital asset management strategy is to formulate the organization’s vision and determine the desired business outcomes across the whole organization and asset ecosystem. The next step is to develop a comprehensive, integrated solution involving multiple technology components—a road map to success. This step is key because cherry-picking and experimenting with a few pilot projects in different phases of the framework without a comprehensive plan will likely not generate the expected benefits. Each project should be an integral part of a holistic digital strategy and road map, especially since the value chain is converging.

    Two elements that should be at the core of any digital asset management strategy are data governance and cybersecurity. As the foundation for all analytics, data may well be a company’s most valuable asset. Without rigorous management of the collection, cleansing, standardization, storage, and curation of data, digitalization and the insights it generates could have little value. Consider starting by designing the data architecture and the governance to maintain it. This is important because the architecture will likely evolve over time with changes in technology, security threats, business needs, and customer preferences. Individual project plans should demonstrate how the business processes, data objects, and architecture will work together, what the data quality standards should be, and how they’ll be achieved.

    Equally as important is cyber risk management. With the increased connectivity that digital transformation brings, cybersecurity threats now extend into the cloud, across third-party networks, and through connected assets and devices. Perils prowl across industrial control systems, such as SCADA, and extend into all of the components of the industrial internet of things (IIoT), including sensors, mobile apps, capital equipment, software, firmware, hardware, operating systems, databases, ports, and more (figure 5). The North American Electric Reliability Corporation’s Critical Infrastructure Protection (NERC CIP) standards that address cybersecurity of the bulk electric power system continue to evolve, and should be considered as a floor from which to build.

    Other issues to consider when developing a digital strategy include the implications of adopting technologies such as 5G or cloud computing and how to spread the impact of capital costs and O&M expenses to net maximum benefit for both the organization and customers. And finally, it’s important to review the strategy periodically because as technologies advance, costs typically fall, implementation timelines can compress, and projects that had not been feasible yesterday may be possible today. While there are many issues to consider, the potential rewards will likely make the journey worthwhile.

    1. Companies database, S&P Global Market Intelligence, accessed January 2021.View in Article
    2. Jason Price, “Digital asset performance management—Taking utility asset management to the next level ,” EnergyCentral, October 12, 2020.View in Article
    3. Wood Mackenzie, “United States distributed energy resources outlook: DER installations and forecasts 2016-2025E ,” June 15, 2020. View in Article
    4. OT refers to the hardware and software used to change, monitor, or control physical devices, processes, and events, while IT refers to anything related to computer technology, including hardware and software. The main difference is that OT devices control the physical world, while IT systems manage data. Source: “Operational Technology vs. Information Technology: Differences, Similarities, & How the Intermix With Industrial Control Systems,” virtualamour.com, November 15, 2019.View in Article
    5. Steve Hanawalt, “Article 7: The top 4 solar asset monitoring challenges—and what you can do about them ,” Power Factors, October 8, 2020.View in Article
    6. Utilities need to exploit the deluge of data set to grow in 2020 as smart device sales soar ,” GlobalData , February 18, 2020.View in Article
    7. Uptake APM performed the analysis based on data from the US Federal Energy Regulatory Commission, as noted in Darrell Proctor, “Making the connection: Digitization ramps up optimization ,” Power , February 1, 2019. View in Article
    8. Ibid.View in Article
    9. US Department of Energy, “Chapter 3: Enabling modernization of the electric power system ,” Quadrennial Technology Review , 2015. View in Article
    10. U.S. Energy Information Administration, Annual electric power industry report, Form EIA-861 detailed data files , October 6, 2020; Deloitte analysis. View in Article
    11. Bill Graf, Katie Pavlovsky, and Dave Yankee, The power of Cloud: Are you truly a “digital utility ”? , Deloitte, July 2020. View in Article
    12. Historical and future power plant capacity database, S&P Global Market Intelligence, accessed January 2021, and Wood Mackenzie, United States distributed energy resources outlook: DER installations and forecasts 2016–2025E , June 18, 2020; Deloitte analysis.View in Article
    13. Ryan Hledik et al., The national potential for load flexibility: Value and market potential through 2030 , The Brattle Group, June 2019.View in Article

    The authors would like to extend special thanks to Jaya Nagdeo and Utham Ganesh for the research and insights they contributed to this article. They would also like to thank Sandy Jones, Christian Grant, Craig Rizzo, Mat Rommel, Adrienne Himmelberger, Sharene Williams, and Rupsha Champati for sharing their perspectives and Kavita Saini and Soy Lee for their editorial and production support.

    Cover image by: Gordon Studer

    Transforming Power, Utilities and Renewables

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    Jim Thomson

    Jim Thomson

    US Power, Utilities & Renewables leader

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