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UC Won
You can invent alone, but you can’t innovate alone.
We focus on developing patent portfolios and to monetize that intellectual property in support of the Inventors and Stakeholders.
Mark Hauenstein
Partner
Can Solar Thermal close the Reliability Gap?
Mark Hauenstein – UCWON
In 2022, solar and wind as renewable energy sources account for about 13.1% of total U.S. energy consumption, with 3% solar and 10% wind respectively. Despite these small percentages, all our hopes of creating a clean grid are centered on massive adoption of a defective solution. Solar and wind, for all its clean benefits, is not a consistent and reliable energy source. Utilities are constantly fighting the biggest flaw in renewable adoption, the reliability gap. Today, wherever solar is deployed, natural gas fired plants are built to be ready when solar or wind fail to perform.
Closing the reliability gap could be fairly uncomplicated, using a system that couples abundant solar resources with geothermal power production. Clean and reliable, geothermal has long been an underappreciated workhorse developing carbon free energy. This session will explore the question: can stored solar energy be part of the solution? Can RenewGeo closes the reliability gap.
1-Minute Introductory Video
Mark Hauenstein
Can solar thermal close the reliability gap?
Information Request
F3
Solar PV | Siting | Regulations | Recycling
Feb 15 ( 1 pm – 3pm)
Dwight Clark
Solar Module Recycling at Utility Scale
Solar Module Recycling at Utility Scale
Dwight Clark – We Recycle Solar, Inc.
Summary of Presentation
The rapid growth of solar energy installations has resulted in an increased demand for efficient and sustainable solutions for solar module recycling. As the utility-scale solar industry expands, the need for a well-designed and effective recycling system becomes paramount to minimize environmental impact and maximize resource recovery. This presentation aims to provide an overview of a comprehensive solar module recycling system specifically tailored for utility-scale applications.The presentation will begin by highlighting the environmental challenges associated with the end-of-life management of solar modules, including the accumulation of electronic waste and the potential release of hazardous materials. It will emphasize the importance of implementing a circular economy approach to ensure the responsible and sustainable disposal of decommissioned solar modules.Next, the presentation will delve into the key components of an efficient utility-scale solar module recycling system. This will include discussions on collection and transportation logistics, sorting and dismantling processes, and the utilization of advanced technologies for material recovery. Furthermore, the presentation will explore strategies for handling and treating hazardous substances found in solar modules, such as lead and cadmium, in an environmentally friendly manner.Moreover, the economic aspects of solar module recycling at a utility scale will be addressed, highlighting the potential revenue streams and cost savings that can be derived from recycling valuable materials. The presentation will touch upon the importance of establishing partnerships and collaborations among stakeholders, including solar panel manufacturers, recycling companies, and policymakers, to create a robust and sustainable recycling infrastructure.Throughout the presentation, case studies and real-world examples will be provided to showcase successful utility-scale solar module recycling initiatives and the positive impact they have had on the environment and the renewable energy industry as a whole. The presentation will conclude by outlining the potential future developments and challenges in the field, encouraging ongoing research and innovation in solar module recycling technology.By attending this presentation, participants will gain a comprehensive understanding of the importance of solar module recycling in the context of utility-scale solar installations. They will be equipped with valuable insights into the design and implementation of an effective recycling system, as well as the economic and environmental benefits it can bring. This knowledge will enable participants to contribute to the sustainable growth of the solar industry while minimizing its ecological footprint.
Mark Hauenstein
Can solar thermal close the reliability gap?
Can Solar Thermal close the Reliability Gap?
Mark Hauenstein – UCWON
In 2022, solar and wind as renewable energy sources account for about 13.1% of total U.S. energy consumption, with 3% solar and 10% wind respectively. Despite these small percentages, all our hopes of creating a clean grid are centered on massive adoption of a defective solution. Solar and wind, for all its clean benefits, is not a consistent and reliable energy source. Utilities are constantly fighting the biggest flaw in renewable adoption, the reliability gap. Today, wherever solar is deployed, natural gas fired plants are built to be ready when solar or wind fail to perform.
Closing the reliability gap could be fairly uncomplicated, using a system that couples abundant solar resources with geothermal power production. Clean and reliable, geothermal has long been an underappreciated workhorse developing carbon free energy. This session will explore the question: can stored solar energy be part of the solution? Can RenewGeo closes the reliability gap.
Alison Wise
Innovation Infrastructure- Biomimicry and Resilience in Innovation
F3.2 Innovation Infrastructure- Biomicry and Resilience in Innovation
Alison Wise – Wise Strategies
Synergy and biomimicry- IIoT and Mycelium models for clean economic growth
How public-private partnerships can accelerate IIoT and innovation infrastructure build-out, and cutting edge technology to achieve climate goals
Role of private sector in innovation infrastructure build-out; i.e. clean energy/distributed finance/rapid transportation retrofits
Best practice for identifying clean, profitable energy investments for mitigating cryptocurrency hashing power usage.
Jared Strauss
Air Regulatory Considerations for Retrofitting Combustion Turbines for Hydrogen Co-firing
Air Regulatory Considerations for Retrofitting Combustion Turbines for Hydrogen Co-firing
Jared Strauss – TRINITY CONSULTANTS
With recent industry and regulatory developments involving the implementation of hydrogen as a potential fuel source, hydrogen fuel is becoming a primary component for reducing GHG emissions in the electricity generation sector. Potential regulatory requirements from the proposed ACE Rule Replacement could affect facilities with existing combustion turbines, but this may also present potential opportunities in the areas of ESG and energy diversity. For existing combustion turbines, retrofitting a turbine to utilize hydrogen as a fuel gas faces project design and execution challenges to demonstrate technological and economic feasibility. From a regulatory standpoint, federal and state regulations have not previously considered hydrogen fuel, which contributes to increased ambiguity in defining hydrogen fuel and fuel blends of hydrogen and natural gas. Further complications arise in evaluating the applicable emission standards and potential emissions for authorizing hydrogen co-firing. A hydrogen fuel retrofit project must also examine the potential compliance requirements including emissions monitoring adjustments and control technology updates. Additionally, considerations for the methodology of hydrogen generation and storage could consequently result in further regulatory requirements (i.e., Risk Management Plan) and potential infrastructure changes to accommodate hydrogen fuel. This presentation will address air regulatory considerations for a hydrogen fuel retrofit project and identify the areas of focus for permitting and compliance requirements. The presentation will also discuss the questions facilities should be reviewing when evaluating a retrofit project to use hydrogen as fuel gas.