Plant Management Institute

Operational & Maintenance Best Practices for Thriving in the Thermal Power Generation Sector

As the thermal power generation industry navigates the complex transition to a cleaner energy future, plant operators face numerous challenges in maintaining operational efficiency and cost-effectiveness. This presentation will address critical issues and provide actionable insights into Operation & Maintenance (O&M) best practices that ensure gas-fired plants remain viable and profitable.
Top Mistakes in O&M: Identifying common pitfalls such as delaying vital repairs and their impact on plant performance and safety.
Cost-Saving Strategies: Five practical ways to reduce O&M expenses while enhancing total asset performance.
Crafting a Long-Term O&M Strategy: Developing a robust strategy to manage operations amid the uncertainties and evolving regulations in the global thermal power generation industry.
The Role of Gas-Fired Plants in the Energy Transition: Analyzing the current debate surrounding the future of fossil fuels, with insights into the controversial statement by the Aramco CEO on the "fantasy" of phasing out fossil fuels.

Data Center & AI Growth: Energy Challenges & Opportunities

The demand for energy to power data centers is skyrocketing, largely driven by the rapid expansion of AI. Data center owner/operators' business needs driving expansion create challenges for both energy supply and demand. Even so, these AI data centers have the potential to evolve beyond their traditional role as passive users of electricity. By aligning more closely with the electric grid, they can become dynamic assets that bolster grid reliability, resilience, and affordability for all electricity consumers. This can be realized through a concerted effort among data center stakeholders, utilities, market operators, technology innovators, and policymakers through changes in culture and standard taxonomies for flexible operation coupled with innovation in operating and business models.

AI and Energy: A New Horizon for Powering our Future

For energy companies, AI promises to be a boon. And it might be. AI brings new ways to improve efficiency and reliability in an environment where nearly every day more is demanded. But there are risks to AI as well. In this presentation, Ray Rasmussen, Managing Principal of rGen Consulting presents a quick overview of the likely impacts of AI on energy - but more importantly - he offers a no-regrets roadmap for leveraging AI and building skills internally within your organization. He uses a solution to one of the energy industry's most common problems to illustrate how energy companies can build the internal skills required to take advantage of this powerful and evolving technology while mitigating risk and limiting dependence on outside resources.

Nuclear Insurance and the ADVANCE Act

Brian's presentation will cover key highlights of the ADVANCE Act and its implications for the U.S. nuclear insurance landscape. He will also provide insights into the similarities between this legislation and the Price-Anderson Act, one of the most significant nuclear bills ever passed.

AI Adding Value and Improving Power Plant Performance

In many industries, machine learning (ML) and artificial intelligence (AI) have become catchphrases in a growing chorus of unproven claims. The power-generation industry is no exception; marketing references to ML and AI are trending upward with few proven, real-world results to help asset managers and front-line operators improve plant performance. Geared for key decision-makers in CCGT asset management, operation and maintenance roles, this presentation provides real-world results showing how large scale data processing combined with machine learning technology transforms management decisions, reliability and asset value .

Improving Alarm Management in the New Digital World

By coupling the use of Big Data Management with advanced alarm and plant process analytics, the concept of appropriately reducing plant alarms can be facilitated for more effective plant operations, and reduced workload on operations staff.

Siemens Energy is employing multiple layers of advanced alarming strategies coupled with automated analytics to make the process of plant alarm optimization a virtually automated process.

Hydrogen: The Ultimate Solution for Energy Storage and Transport?

Hydrogen, a versatile energy carrier, holds the potential to revolutionize various sectors and applications. This presentation dives into the process of generating, storing and using hydrogen as an energy storage solution. We provide a comparison of different storage technologies, focusing on their scalability, efficiency and the expected capital and operational costs.
We discuss methods and technologies used to produce hydrogen from renewable sources and increase its density through compression. We examine the optimal pressure levels and techniques for different applications, along with the benefits and drawbacks of these pressure levels.
In our exploration of using hydrogen as a fuel for power plants, we consider efficiency, emissions, safety and compatibility. We discuss the process of converting hydrogen into usable energy, the emissions that result from this process, and the safety measures that need to be in place when handling and storing hydrogen. We also look at how compatible hydrogen is with existing power plant infrastructure and what modifications may be needed.
We foster a complete understanding of hydrogen's role and dispel misconceptions while highlighting safety concerns associated with hydrogen use in our industry. We provide examples of how these concerns can be addressed to ensure a safe and effective use of hydrogen.
Through this presentation, we provide an overview of hydrogen's potential as an energy storage solution, stimulating discussion and further research. We dive into the future possibilities of hydrogen, discussing how its versatility and potential for clean energy production can play a pivotal role in our industry's future. We conclude with a call to action, encouraging further exploration and innovation in the field of hydrogen energy storage.

Echogen's Pumped Thermal Energy Storage System design for the Alaska Railbelt

Innovations in Redox Flow Battery Technology for Long Duration Energy Storage

Kraftblock's Thermal Energy Storage System, Applications in Power and Industrial Heat

More than half of the world's energy is consumed in the form of heat, and as much as two-thirds in industry. The fossil fuels used to generate this heat account for 40% of global emissions, one of the biggest levers in the fight against climate change. Kraftblock is an engineering and manufacturing company that addresses this issue and decarbonizes heat in industry, district heating and power generation. At the heart of its technology is a unique proprietary thermal energy storage system using a newly invented sustainable material that can withstand temperatures of 1,300°C. This storage makes electrification more flexible and affordable and allows industrial waste heat or CSP to be shifted to times of demand. Kraftblock systems are solutions for thousands of heat processes, from food production to the chemical industry to steel and non-ferrous metals. Currently under construction is a 150 MWh electrification storage project for PepsiCo in the Netherlands and a waste heat project for a steel mill in India. Details of the application of this technology on these projects will be presented, in addition to execution status.

Propane Powers The EV Market

The Future of the Nuclear Energy Landscape

Nuclear technology can deliver carbon-free baseload power to support a world experiencing significant load growth. However, the modern nuclear market often invokes more questions than answers because potential owners/operators face an unclear path forward on technology selection, fuel availability, regulatory strategy, and project completion tricks. This presentation will address the latest news in the modern nuclear industry, differences in technologies, and timelines for new nuclear projects. Even if you consider nuclear projects as relegated to the distant future, there are some near-term activities that will effectively position your organization for long-term success, including siting studies and preparation for an early site
permit, which do not require significant commitments or capital spend. The time is now to get ahead!

Hit the Gas!

The market is seeing significant load growth for the first time in the last decade, increasing
reserve margin requirements to maintain system reliability, and continued coal retirements. The
result: an immediate need for additional dispatchable capacity. Natural gas will fill a role in
meeting at least some of this new capacity. We will discuss what we are seeing in the market
today and some of the common challenges generators are facing.
Developing a new generation facility in today's market is dramatically different than what it was
5 years ago. The Generation Interconnection process, major equipment lead times, permitting,
and construction labor shortages are driving development and execution timelines to take longer
than ever before. Are you planning far enough in advance?

Choosing an Electrolysis Technology for Clean Hydrogen Production

While clean hydrogen can be generated via several processes, electrolysis has become a focus for the production of hydrogen from various sources of electricity, including solar, hydro, wind, and nuclear power. The primary electrolysis technologies are Alkaline Water Electrolysis (AWE), Polymer Electrolyte Membrane (PEM), Anion Exchange Membrane (AEM), and Solid-Oxide Electrolysis Cells (SOEC). The primary differences among these technologies are the electrolyte material, specific consumption, efficiencies, acceptable water quality, operation temperature, ramp rates, and properties of the hydrogen product. They also differ in maturity of technology, packaging of product, footprint, and costs. Depending on the specific application of a project, any of the electrolyzer technologies may be the best fit for a project.

This presentation will discuss the major differences and design considerations of the widely available electrolysis technologies and the opportunities for new hydrogen production plants to be integrated with existing electrical power supplies and systems. It will include a case study that evaluates the major electrolysis technologies to determine the most technically feasible and cost-effective one to utilize at two separate existing power generation sites. The available electrical power, land availability, and opportunities for integration within these two power generation sites are some of the critical categories evaluated in this case study.

Accelerating Green Hydrogen Production with Advanced Membrane Design

This presentation will introduce PEM electrolysis as a viable pathway for green H2 production and explain how advanced membrane design can be leveraged to enable high-efficiency, scalability, and system integration while delivering lower levelized cost of hydrogen (LCOH). The speaker will present an offshore wind plant use case scenario model showing the impact of advanced PEM attributes on the overall system efficiency and LCOH. Attendees will walk away with an understanding of the challenges for green hydrogen production, how advanced PEM design and technology can break through existing performance barriers and reduce engineering trade-offs to enable high-efficiency, low total-cost-of-ownership WE systems.
Takeaway/Audience Participation (s):
• Introduce PEM electrolysis as a viable production pathway for green H2 production.
• Address efficiency, scalability, and system integration through advanced membrane design.
Present an offshore wind plant use case model

A Rapid-Response SOC-based Energy Buffering System for Support of Renewables

Prompted by widespread electrification and the proliferation of high-demand distribution-side loads, there is an ever increasing need for energy storage. Buffering mechanisms allow electrical energy to be stored during periods of abundant electricity supply and later released to service periods of higher demand. Moreover, the coordination of distribution-side energy storage technologies is needed, allowing for rapid response to accommodate dynamic regional power requirements as determined by the system operator. Unfortunately, modern electrical power grids are not designed to store substantial amounts of energy and even excess electricity generated by renewable sources such as wind turbines or solar panel arrays must be often curtailed. The use of lithium-based battery technology is limited since the associated cost is prohibitive for even modest amounts of storage. Enter HELIOS(TM), an energy buffering solution comprising flexible and reversible solid oxide cell (SOC) technology, advanced controls and cost-effective storage in the form of hydrogen gas or hydrogen-carrier fuel. We provide a detailed description of each aspect of HELIOS(TM), covering the central SOC technology which incorporate metal-supported structures to deliver resilient operation, a smart-hydrogen hub (SH2) element providing rapid-response controls of the SOC as well as an interface to the system operator, and energy storage options ranging from the use of existing natural-gas infrastructure to the use of liquid carrier fuels. Simulation results of demonstrating rapid response to system operator requests are provided. In addition, a techno-economic analysis is given to assess the economic viability of HELIOS(TM) in relation to competing technologies.

Hydrogen-Hybrid Microgrid Features & Benefits

This hydrogen-powered, scalable power plant, capable of producing its own hydrogen on-site, has only recently introduced to the military and utility industry by RPW; it is designed for both "in front of the meter" and "behind-the-meter" applications. As a utility asset, it can provide low-cost spinning reserves (to counter-balance the effects of non-dispatchable assets) on utility distribution lines and has exceptional ramp-up speeds, behaving much like a diesel (but running on hydrogen - gray, blue or green). The hybrid configuration has been shown (in cyber-physical testing) to extend the life of a SOFC by better than seven times the typical useful life.

The HHM represents a break-through in hybrid technology for microgrid applications, in large measure due to its advanced power controls, its safety (producing its own hydrogen at 50 psi) and its being designed around a novel tightly coupled power production model, involving a pressurized Solid OxideFuel Cell (SOFC) and a modified NG turbine. It is capable of load-following, further enhancing its already high fuel efficiency. and providing low-cost spinning reserves. A demonstration model is now being built for further testing and refinement at the HyPer (Hybrid Performance) Lab at NETL in Morgantown, WV, due for completionby the Third Quarter.

Hydrogen-Hybrid Microgrid Features & Benefits

Case Study: Lessons Learned Through Implementing a Decommissioning and Demolition

Case study discussing the decommissioning and demolition of the former PowerSouth Lowman Power Plant. The presentation will discuss the planning and implementation of the retirement and demolition of the Lowman Power Plant. Upfront planning and coordination were conducted with utilities' stakeholders (operations, environmental, energy delivery, communications, security, safety, management, etc.) to develop a decommissioning plan that was executed by plant staff following plant shutdown. The presentation will also include a discussion on how a decommissioning effort can be successfully conducted by remaining plant staff and the advantages of documentation during the decommissioning process to facilitate demolition execution.
Following decommissioning of the plant, PowerSouth and Burns & McDonnell worked together to manage project expectations and minimize change orders by developing a clear technical scope of work. This presentation will also include a discussion of the collaboration efforts as the project was converted to an Engineering Procurement and Construction (EPC) project with Burns & McDonnell operating as the Prime Contractor. We will present the general steps involved in the demolition process and necessary planning for a safe and successful project. The presentation will also highlight lessons learned in the execution and implementation of the project.

Repurposing Power Plants - Opportunities and Incentives

Permitting Carbon Capture Projects

• Amy Gozdowiak, Senior Environmental Associate, Sargent & Lundy

Permitting a carbon capture project involves unique and often challenging regulatory considerations which require significant time and money to address. For example, assessing air permit applicability requires an understanding of changes in emissions due to the carbon capture project and whether the proposed project will be considered a modification to an existing source or a separate standalone facility. However, due to the novel nature of some carbon capture technologies, changes to air pollutant emissions can be difficult to quantify during early project planning. Additionally, carbon capture projects often trigger the requirements of the National Environmental Policy Act (NEPA), which can take years to complete. It is tempting to rush into such a long lead item, however, starting before a project is sufficiently mature can waste the time and attention of federal regulators. This presentation will discuss recent lessons learned from permitting a variety of carbon capture technologies and will identify what considerations need to be taken into account at the start of project planning.

Decarbonizing Hydrogen Production with Solid Fuels and Biofuels Chemical Looping

For the HydrogeNext Sessions

B&W's innovative low-carbon hydrogen production technology called BrightLoop chemical looping can directly process a wide range of feedstocks, including solid fuels such as biomass or coal, into hydrogen with a separated stream of CO2 for sequestration, beneficial use or further processing. BrightLoop is a chemical looping technology that uses an innovative oxygen-carrying metal oxide particle. In addition to detailing the process and progress of development, bioenergy production with carbon capture and sequestration (BECCS) technologies will also be discussed, which can provide carbon-negative CO2 and power for eFuels projects. The presentation will include a general discussion of how these technologies correlate to available financial incentives for reducing the carbon intensity of power and fuel production.

Update & Implications of EPA's Electric Generating Unit's Greenhouse Gas Rule

The U.S. Environmental Protection Agency (EPA) recently drafted new greenhouse gas (GHG) standards and guidelines for electric generating units under the Clean Air Act Section 111. These rules target carbon dioxide emissions from both new and existing fossil-fired units, proposing the use of advanced technologies like carbon capture and hydrogen co-firing.
In this presentation, we dive into these rules, examining their requirements, objectives and potential impacts on the power industry. We employ a mixed-methods approach, combining regulatory analysis, stakeholder feedback and economic modeling to assess the feasibility, costs and benefits of compliance.

We compare these rules with other significant policy initiatives, like the Inflation Reduction Act and the Bipartisan Infrastructure Bill, providing a broader context for understanding the potential implications of the EPA's new rules.

Our findings suggest these rules could significantly reshape the U.S. energy landscape, presenting both challenges and opportunities for the power industry. We discuss potential implications for the future of the power sector and the environment, highlighting the potential for these rules to drive innovation in the sector, spur investment in clean energy technologies, and contribute to the fight against climate change.

Finally, we propose directions for further research, including more detailed studies on the technical feasibility and economic viability of the proposed technologies, as well as ongoing monitoring and evaluation of the rules' impacts. Our study lays a valuable foundation for these future research efforts and contributes to the ongoing dialogue on the future of the U.S. power sector.

DOE Financing Beyond the Regional Hydrogen Hubs

While DOE announced $7 billion to launch seven Regional Clean Hydrogen Hubs (H2Hubs) in October 2023 , there are additional plans for hydrogen hubs that were not selected. DOE's Loan Programs Office (LPO) is also available to support hydrogen projects through debt financing for Innovative Energy and Innovative Supply Chain Projects. LPO can support production, midstream infrastructure, and end-use projects, making it a flexible option.

The Economics of Small-Scale Hydrogen Pilot Projects: Challenges and Lessons Learned

Hydrogen is a promising energy carrier that can help decarbonize various sectors, but its deployment is still in the early stages, especially for small-scale projects. While hydrogen pilot projects can showcase the potential of the technology and generate valuable data, they often struggle to achieve financial viability. In this presentation, we will explore the economic challenges of small-scale hydrogen pilot projects and the reasons why they often to not proceed past the feasibility stage. We will discuss the high capital costs and technical complexities of hydrogen production, storage, and distribution, and how they affect the economics of small-scale projects. We will also examine the regulatory and policy barriers that impede the growth of the hydrogen market, including the lack of incentives and support for early-stage projects, and the uncertain regulatory framework for hydrogen. Furthermore, we will analyze some case studies of small-scale hydrogen pilot projects and highlight the key lessons learned. Ultimately, this presentation aims to provide insights into the economics of small-scale hydrogen pilot projects and to suggest possible solutions to overcome the challenges and accelerate the deployment of hydrogen at scale.

The Development of a Commercialized Hydrogen Campus will fuel adoption

Renewable energy sources will play an essential role in future energy strategies due to the increasing demand for energy and the need to energize a path to net zero. With a hydrogen economy valued at $130 billion and estimated to grow 9.2% annually, production costs will decrease by 50% through 2030.

Currently, advances in the hydrogen vertical are from large international players who are awarded government grants to create regional clean hydrogen hubs. While the multi-national players have been awarded 7 billion dollars in funding, it will be up to entrepreneurs and start-ups to finance new hydrogen technology and innovations not imagined by the big conglomerates.

Q Hydrogen is investing and opening the first Q Hydrogen commercial campus in the U.S. based on new proprietary technology. A hydrogen campus will boost hydrogen fuel adoption and meet growing industry infrastructure needs. Companies will run their electricity from hydrogen produced on the campus in Groveton, New Hampshire.

Innovative commercialized hydrogen hubs by start-ups will scale job opportunities, improve energy security, and provide a pathway for company adoption of a clean energy alternative.

The presentation will discuss the need for hydrogen investment, technology creativity, and the viability of commercialized hydrogen campuses. What will change the hydrogen landscape will be hydrogen hubs financed by well-capitalized and inventive start-ups bringing technical innovation to the vertical.

Hydrogen Purity for Fuel and Liquefaction BOP Requirements

For hydrogen to be liquified or to be used as fuel, it needs to comply with certain purity In order to comply with applicable ordinances worldwide. The degree of hydrogen purity affects the cost of BOP. Learn the factors that affect hydrogen purification (oxygen, nitrogen, water and/or residual ammonia, depending on source) and the relationship between purity requirements and purification cost that makes the selected systems more CAPEX or OPEX intensive.

Winter Preparation/EOP-012

Exploring Fuel Oil as an Alternative During Winter Peaks

In the United States, winter storms Uri (2021) and Elliot (2022) interrupted natural gas production by more than 15 billion cubic feet per day according to S&P Global Commodity Insights. These interruptions led to reduced natural gas availability across multiple regions nationwide, while record cold weather caused a surge in gas and electric demand.
During these winter storms, electric generation set or nearly set peak winter demands. Some generating units struggled to maintain operation due to restricted natural gas supply. Others were forced to shut down or purchase expensive natural gas during the supply restriction. One solution to mitigate a generating unit's exposure to natural gas supply and increased electric demand is to equip existing or new gas turbines with fuel oil burning equipment. Fuel oil can serve as a contingency fuel when natural gas supply is limited, or when the cost of natural gas surpasses the cost of using fuel oil.
In our presentation, we discuss the benefits of a collaborative project approach for fuel oil installations. This approach involves working together to develop the engineering design that will be used by the owner for the procurement of equipment and construction services. Attendees will gain insight into main drivers for installing fuel oil burning equipment, major equipment, key design concepts, the role of Geotech, communication strategies, action items tracking, supply chain impacts and more. This collaborative approach ensures a comprehensive understanding of the project, leading to efficient execution and successful outcomes.

Exploring Fuel Oil as an Alternative During Winter Peaks

Keeping the Power Going: Conquering the Risks of Single Point of Vulnerability with Reliable Maintenance

Understanding single points of vulnerability (SPVs) in power plants is crucial. These SPVs are components that, if they fail, can cause a plant or turbine to trip, leading to plant shutdowns. Once identified, it's essential to implement maintenance and reliability strategies to mitigate their impact. This breakout session will define SPVs, discuss strategies, and share real life examples of successful mitigation efforts.

Guidelines and Best Practices for Explosion Venting in Energy Storage Systems

• Andreas Brandl, Chief Technology Officer, IEP Technologies
• Andreas Kerbl, Head of R&D Explosion Protection, HOERBIGER Wien GmbH

The potential hazards associated with battery energy storage system (BESS) containers have gained significant attention due to the risk of explosion that can result from the failure of a single battery cell. NFPA 855 acknowledges this risk and mandates the implementation of explosion protection systems in BESS containers. However, existing standards for designing explosion vents do not adequately address the unique geometries and battery module layouts in typical BESS containers. The dense arrangement of battery modules within these containers can exacerbate turbulence and explosion propagation rates, while also obstructing flow through traditional explosion vents. Consequently, there is a risk of explosion overpressures surpassing the container strength, even with venting systems in place.

The specific challenges of BESS systems, such as obstructions in the flame path, sub-volumes that are partially isolated and obstructed vent panel areas will be addressed by applying an engineering model to simulate explosion dynamics in a typical BESS container layout. The feasibility of utilizing established standards like NFPA 68 and EN 14991 to specify venting areas will be assessed by comparing model predictions with the design equations of these standards. Validation of the engineering models will be considered using data from experiments and/or detailed simulations. The results of the analysis will inform practical guidelines for designing explosion venting systems to effectively mitigate explosion effects and ensure safety. A best practice approach for explosion vent layout that introduces additional checks to NFPA 68 or EN 14991 will be suggested.

By addressing the limitations of current standards and leveraging modeling techniques, this presentation aims to enhance the understanding of explosion risks in BESS containers and provide valuable insights for designing robust explosion venting systems.

Diversifying Energy Storage Technology for the Energy Transition

BASF Stationary Energy Storage

Fail-Safe Energy Storage Systems

The future is now: A new era of visualization in energy

Staying ahead: Mastering regulatory demands in energy innovation

Taming the wild west: Controlling data and building the industrial metaverse

Innovating for Tomorrow: Harnessing Advanced IT/OT Integration to Drive Digital Transformation

Explore the cutting edge of industrial innovation, where the integration of IT and OT is key to driving digital transformation and achieving sustainability goals. This discussion focuses on the pivotal role of comprehensive digital twins in uniting the physical and digital worlds, enabling enhanced efficiency, profitability, and progress toward a greener future. Discover how these advanced technologies are not just transforming operations but are also essential for meeting the challenges of tomorrow's industrial landscape.

Building on real-world examples, this session will also highlight the strategic advantages of IT/OT integration, such as improved decision-making, reduced operational risks, and accelerated time-to-market. By leveraging the power of digital twins, companies can simulate, optimize, and implement changes with unprecedented precision, ensuring that their operations are not only more resilient but also more adaptable to the ever-evolving demands of the global market. This session offers a roadmap for organizations aiming to stay ahead of the curve in an increasingly digital and interconnected world.

Digital renaissance: Transforming legacy energy infrastructure into future-ready digital twins

DCS Logic Upgrades for Fuel Variability & Turndown

Variability in North Dakota lignite has long presented significant challenges for operations and NOx emissions compliance. In addition, successful operation in current power markets requires increasing operating flexibility, including operating at increasingly lower loads.
Standard DCS BTU compensation is often not adequate to address the inherent variability in coal, especially North Dakota lignite. BTU correction or compensation signals often vary with load, rather than with changes in coal heating value. This complicates operations for all coal-fired units. Cooling air or "tramp" air from burners or cyclones out of service becomes increasingly difficult as turndown increases. This results in higher combustion NOx and higher heat rates. Both of these issues are more difficult for cyclone units, where variation in fuel and air flows results in large variation in stoichiometric ratios in individual cyclones. The result is often increased cyclone slagging and poor cyclone slag tapping.
In this presentation, we will discuss improved BTU compensation and air flow logic that provides reliable cyclone SR control and improved emissions and efficiency at lower unit loads. The benefits are:
• Reduced operating issues and maintenance costs related to slagged up cyclones
• Reduced overall excess O2
• Reduced NOx emissions and urea or ammonia costs
• Lower stable minimum loads
• Increased boiler efficiency/reduced heat rates, especially at lower loads
We will explain the approach and present results based on case studies where these upgrades have been implemented.

Navigating Change: New EPA Rules for Power Generation and How a Utility is Approaching Effluent Limitations Guidelines (ELG)

Peak Performance: APS's Virtual Power Plant Saves Big During Brutal Heatwave

• Sarah Noll, Manager, VPP Innovation & Strategic Initiatives, Arizona Public Service Company [APS]

Advancing Green Building with Solar Energy Integration

Multifamily residents earn around 52% of the average salary in the United States and as a result, they face energy burdens three times higher than people living in standalone homes. And until recently, there was no way for multifamily residents to access clean, affordable energy from their rooftops. Allume Energy's Solshare, a world-first technology, is unlocking solar energy for multifamily buildings, providing a solution to energy inequity.

In this session Mel Bergsneider, Executive Account Manager at Allume Energy, will explore the energy equity challenges around multifamily buildings and apartment renters in particular and what the unique barriers are to obtaining rooftop solar in multifamily properties. We will then discuss how this new technology solves these challenges and what the opportunities and challenges have been of implementation in the US.

Leveraging BIM Technology for Industrial Power Project Execution

Join us as we explore the transformative power of emerging technologies in industrial power projects. These innovations serve as a gateway to unprecedented opportunities, streamlining software, scanning, and data workflows, enhancing data accessibility, and fostering collaboration among stakeholders. These opportunities ultimately result in faster execution, higher quality, and under budget projects.
In an era characterized by relentless technological innovation, industrial power professionals face the challenge of navigating a complex landscape of options. The variety of advanced tools and groundbreaking platforms can be overwhelming, leaving decision-makers uncertain about which technologies will drive success in their projects. Moreover, the implementation of new technologies often requires significant investments of time, resources, and expertise, further complicating decision-making processes. In this presentation we will explore these issues and discuss solutions to minimize uncertainty while adopting new technologies.
Amidst this uncertainty, recent practices have emerged as guiding lights, offering proven strategies and solutions to revolutionize efficiency, communication, and collaboration within industrial power projects. By embracing these practices, teams can confidently navigate even the most intricate projects, leveraging technology to achieve unparalleled outcomes.
Prepare to be captivated by groundbreaking integrations tailored to the unique challenges faced by industrial power professionals. These integrations facilitate seamless sharing of large data files, point cloud management, enhancing accessibility and collaboration, and ultimately driving a dramatic improvement in project quality, efficiency and stakeholder satisfaction.
Don't miss this opportunity to unlock the potential of emerging technologies and propel your projects to new heights. Join us on a journey of discovery and innovation as we uncover the keys to success in industrial power projects.

Cogenerating Solar: How Direct Use of Solar Power Provides Advantages for Industrial Facilities

Cogenerating Solar: How Direct Use of Solar Power Provides Advantages for Industrial Facilities

Microgrids: Increasing Grid Stability with Dispatchable On-site Generation for Commercial and Utility Customers

Microgrids: Increasing Grid Stability with Dispatchable On-site Generation for Commercial and Utility Customers

"After a deadly derecho hit Houston with no warning in May, H-E-B's lights remained on. When Category 1 Hurricane Beryl barreled through the Gulf Coast region, H-E-B's lights remained on. For years in the face of Texas' increasingly frequent natural disasters, the beloved grocery chain's fastidious emergency preparedness has become the subject of widespread awe and praise, particularly when contrasted against the state's own aging infrastructure. " -Brooke Kushwawa, Houston Chronicle
When Hurricane Beryl ripped across the Texas Gulf Coast in July, Enchanted Rock provided outage protection for three greater Houston-area locations of beloved Texas grocery stalwart H-E-B, who has relied on Enchanted Rock to help keep stores operating through numerous severe weather events in Texas. Those three locations, serviced by Entergy Texas, Inc. and protected by Enchanted Rock as part of a long-term agreement to develop backup generation solutions for commercial and industrial customers, utilized 170 hours of backup power, with over 107 continuous hours of coverage at the Kingwood, TX location alone.
The system protecting those stores--Enchanted Rock's natural gas-powered microgrid--can run in two modes: synchronously with the grid, allowing surplus energy generated to be sold back to the grid in times of high demand, or in "island mode," providing utility-grade power for the host customer. This allows stores to stay open during grid outages, providing the community access to emergency supplies during significant weather events such as storms or hurricanes.
This partnership between Entergy Texas and Enchanted Rock highlights the use of distributed energy resources--in this case, dual-purpose natural gas-powered microgrids that are 100x cleaner than traditional tier 2 diesel in the same small footprint--as part of a comprehensive resiliency plan that enables businesses to stay operational during severe weather events. Enchanted Rock's performance during Hurricane Beryl is the latest example of how microgrids are transforming resiliency planning and emergency preparedness.

The DeBary Green Hydrogen Project: A Step Towards Decarbonized Gas Power

The DeBary Green Hydrogen Project is a first of a kind project that will use power directly from a neighboring Duke Energy solar PV facility to produce hydrogen via PEM electrolysis to be compressed and stored in gaseous form. This green hydrogen can then be blended with natural gas or fired at 100% in an existing, retrofitted GE Vernova 7E peaking gas turbine to produce decarbonized power. This power to power (P2P) project presents a unique opportunity for Duke Energy and other utilities to produce their own carbon-free fuel for later use in clean power generation. The project began planning and development in the middle of 2022, began construction in 2023, and estimated to be commissioned by the end of 2024. Once commissioned, this project is expected to be the first E-class turbine operating on 100% hydrogen.

Duke Energy will present their vision when developing the project and how the project fits into the future of their generating portfolio. The discussion will cover permitting, site selection, project development, selecting the team, and project execution. The presentation will also cover how Duke Energy plans to learn from the project once operational and the application of these learnings to future hydrogen endeavors.

Sargent & Lundy, performing the engineering for Duke Energy on the Project, will walk through the different systems on the project required to create a fully functional integrated system. S&L will share several engineering decisions and challenges that the project overcame and how the system will operate once commissioned.

The presentation will introduce specific opportunities and challenges that many hydrogen project developers are bound to encounter.

The DeBary Green Hydrogen Project: A Step Towards Decarbonized Gas Power

Mitigating Fossil-based Power Emissions Through Technology

Designing Data Center Systems to Meet Massive Energy Demand

• Sean Hughes, Business Development Manager, Wartsila North America, Inc.

Grid as an Ecosystem - Key Enabler for the Energy Transition

Notre Dame's Commitment to Carbon Neutrality

Space-Based Solar Power

This presentation will introduce the concept of Space-Based Solar Power (SBSP), which offers the promise of delivering clean, dispatchable, reliable, and clean power from outer space. If realized, this technology offers the ability to address some of the most pressing challenges facing the bulk power system, as well as providing unique capabilities no other power system can. This presentation will look at how this promising technology may come to be, and how it might help solve our most vexing energy issues.

Mitigating Risks in Geothermal Projects

• Geothermal wells have been around for more than 100 years and the challenges to harness the earth's natural heat into power have remained consistent: temperature and pressure. Oil and gas companies are helping to overcome these challenges by transferring oilfield technologies and best practices to geothermal well drilling and production to reduce risk while increasing successful outcomes and maximizing asset value. Learn how oilfield technology and techniques are powering next generation geothermal projects.

Comparison of Hydrogen Jet Fire Modelling Techniques

As the world starts its progression to net zero, hydrogen is seen as a form of energy that is both transportable and flexible and can replace traditional hydrocarbon fuels. Hydrogen has been used for many years across a number of industries and its characteristics as a flammable fluid are well known, although the heat load from impacting hydrogen jet fires is less well characterised.
The heat load from a hydrocarbon jet fire impacting onto a pipe or vessel 'target' is well understood and there have been a wide range of experiments undertaken which have help validate computer models. There are standard jet fire tests for hydrocarbon fuels primarily used to test passive fire protection systems. The total heat load on a target is made up of a contribution of the radiative and the convective heat flux. The convective heat load may be higher for hydrogen fires due to the greater adiabatic flame temperature of hydrogen and the increased storage pressure, and hence flow velocity, typically used for hydrogen. The radiative heat load will also differ as the combustion of hydrogen in air has emissions in the infrared range due to vibrationally excited water molecules and emissions in the ultraviolet range due to OH molecules. Hydrocarbon fires emit in the visible spectrum from the pyrolysis of carbon and in the ultraviolet range due to OH molecules.
This paper reports on a comparison of four large scale hydrogen jet fire releases impacting on a target, assessed using CFD modelling techniques. Two different CFD software packages were used to provide a comparison of the heat load on a target for the two modelling packages. The results were further compared to experimental data for the same releases for hydrocarbon jet fires allowing a direct comparison between hydrogen and hydrocarbon jet fires.

Unlocking The Power of Ammonia: A Safe & Energy-Dense Hydrogen Carrier

Ammonia is the second-most produced chemical in the world and is widely used as a fertilizer because one of its base elements - nitrogen - is a vital nutrient for plants. As a result, the world already knows how to safely transport, store and use ammonia, making it an efficient carrier for its other base element - hydrogen.

In fact, ammonia is a lower-cost and more energy dense solution than hydrogen and battery electrification. As a result, it's gaining traction as an alternative fuel to decarbonize hard-to-abate sectors such as shipping and power generation.

In this session, attendees will learn about the global infrastructure already in place to support using ammonia as a carbon-free fuel and the potential to expand ammonia supply and infrastructure to support growing use cases. They'll hear about the challenges and benefits of using ammonia compared to other alternative fuels, and successful demonstrations of how it can be used in real-world applications. One such example is the world's first ammonia-powered tugboat, which is creating a pathway towards decarbonizing the shipping industry. Each year, the global shipping industry emits close to 1 billion tons of greenhouse gasses, equivalent to the emissions of a G7 country like Germany or Japan. By demonstrating how existing vessels can be retrofitted, this initiative validates the vast potential ammonia holds for transforming the shipping industry and other hard-to-abate sectors. With our planet's natural ecosystems, biodiversity, climate stability, and air quality at stake, bold climate action requires inventive solutions.

Peak Performance: APS's Virtual Power Plant Saves Big During Brutal Heatwave

Implementing a Virtual Power Plant (VVP) Model to Improve Reliability and Performance: Lessons Learned

• Jim Finnerfrock, Sr Program Manager, Mitsubishi Power Americas, Inc.

The Digital Foundation for Delivering Energy as a Service with Microgrids and VPPs

Operationalizing DERs with Topline Demand Control, the Next Generation of VPPs

The Role of Life Cycle Assessments in GHG Emissions

Title: The Role of Life Cycle Assessments in GHG Emissions
Author: Timothy Eiden
Abstract:
The goal of the Life Cycle Analysis (LCA) is to model the global warming potential (GWP) associated with installing proposed full-scale integrated carbon dioxide (CO2) capture systems from cradle-to-delivered electricity or industrial product, often at existing power or industrial facilities. Emissions from energy inputs into the facility including fuels and electricity; combustion emissions at the facility; chemical production; construction of the facility and manufacturing impacts; transportation of all equipment, materials, chemicals, and fuels; carbon dioxide transport and saline aquifer storage; and, in the case of projects delivering electricity, electricity transmission and distribution emissions make up the scope of emissions studied for the LCA. The LCA model is typically developed in OpenLCA utilizing the pre-established National Energy Technology Laboratory (NETL) processes and supplemented by publicly available information. OpenLCA calculates GWP for each process in a product system and displays the results in kilograms (kg) of CO2 equivalent (CO2e) emissions. This presentation will cover a case study on developing a LCA for a CO2 capture system and how the inputs, such as fuel source, distribution, etc. impact the overall GWP of the project.

Bipartisan Infrastructure Law (BIL)/Infrastructure investments and Jobs Act (IIJA) IRA - Inflation Reduction Act

Acceleration of Gas-Fired Power to Reach Decarbonization Targets

As the nation transitions towards a decarbonized energy future, the integration of renewable energy sources, particularly solar and wind, has surged. This shift has led to significant changes in the operational dynamics of traditional power generation plants, and the needs of newly installed capacity. Regions with substantial renewable installations have experienced a growing demand for flexible power generation to complement intermittent renewable resources.
This presentation will explore the impact of increased renewable energy penetration on the power grid, focusing on regions with significant renewable installations. We will examine how existing power plants with different technology are adapting to these changes, and the increasing demand for flexible power. Data from recent RFPs and operational trends will illustrate the growing utilization of gas-fired reciprocating engines as a critical component of a decarbonized energy future. While these engines offer valuable flexibility, we will also discuss potential challenges and future trends in the industry.

Designing Data Center Systems to Meet Massive Energy Demand

Solar-Powered Crypto Mining: Innovation, Sustainability, and Profit

The integration of solar energy into cryptocurrency mining represents a paradigm shift, harnessing renewable energy for digital asset creation. This presentation will articulate the intersection of solar power and crypto mining, providing a blueprint for operators and project managers considering such projects in their portfolios. Participants will gain insights into the technological innovations that make solar-powered crypto mining viable and the strategic planning necessary to implement these solutions effectively. The talk will dissect case studies where solar energy has been successfully utilized for crypto mining, emphasizing lessons learned and best practices in operations and management. Attendees will benefit from a deep dive into the economic and environmental advantages of this synergy, focusing on the potential for cost reduction, increased profitability, and energy independence.