Techncial opportunities for improving PV modules and systems-Joshua Stein-Sandia National Laboratories

Sandia National Laboratories is a multimission laboratory managed and operated by National Technology and Engineering Solutions of Sandia, LLC, a wholly owned subsidiary of Honeywell International, Inc., for the U.S. Department of Energy’s National Nuclear Security Administration under contract DE-NA0003525. Opportunities for New and Innovative Photovoltaic Modules and Systems Joshua S. Stein Sandia National LaboratoriesSAND2018-1594 PE PV is a Disruptive Technology Steven Sinofsky defines four “Stages of Disruptive Technologies”1 . Disruption of Incumbent PV cells and modules offer “clean” and “free” energy but production costs are initially very high – Focus on small, off-grid systems first adopters. PV’s reliability “black eye” in the 1 9 7 0 ’s and early 1 9 8 0 ’s2 . Rapid Linear Evolution Efficiencies rise, reliability and durability increases, production costs fall. Modules treated as a commodity. 3 . Appealing Convergence PV is cheapest form of electricity Integration challenges remain e.g., energy storage, market structure, demand response, etc.4 . Complete Reimagination Solar roofing e.g., Tesla and BIPV Solar-driven cars Toyota is aiming for 7 0 of cars, 5 0 GW/yr. 8 GHG reduction Solar roads, vertical bifacial, internal tracking, adaptive shade response, conformable PV, etc. Future PV products will likely have many different characteristics from today’s modules.Sandia provides capabilities to characterize and model tomorrow’s PV technologies. Measuring and Modeling PV PerformanceFor the past 4 0 years Sandia National Laboratories has developed new methods for measuring and predicting PV performance. 3Factors that Affect PV Performance Irradiance intensity, uniformity, spectrum, variability, reflection, soiling, albedo Temperature uniformity, effects of air temp, irradiance, wind, RH, etc. IV Behavior LID, linearity, metastability, shading MPPT string-module-cell level, DC/AC1 System Performance over time degradation, variability In this talk I will show several examples of Sandia’s work aimed at better understanding the performance and reliability of new PV technologies. Strategies for Improving PV Performance Increase effective irradiance Reduce reflection losses Bifaciality Increase active area Shingled cells Manage electrical mismatch Module and Sub-module power optimizers Multi Use Deployments PV Roofing Increase lifetimes Hard to measure New hardware and software needs Future challenges 4 Reducing Reflections from PV e.g. Nishati Nishati makes rugged, glass-free solar panels designed for extreme environments e.g. military deployments. They are working with Sandia SBV Program to evaluate reflective properties of design variations of their modules. Initial results show that reflections are significantly reduced compare with conventional modules with glass top-sheets. 5 Nishati-us.com Such modules would be less visible and may be appropriate for installations near airports or in tactical environments. Can they last 2 0 yrs Bifacial Photovoltaics Bifacial PV offers a means to increasing the output of PV systems by 1 0 -2 0 with little additional costs. Sandia and NREL project goal is to build and validate bifacial PV performance models, generate performance data, and develop rating standards. Our approach has been to deploy test systems, measure performance backside irradiance, and develop prediction models. Backside irradiance is affected shadows from modules, racking, and other objects. Backside irradiance is spatially variable. Modeling has focused on ray-tracing and view factor approaches. Open-source models are available https//pvpmc.sandia.gov/pv-research/bifacial-pv-project/ Datasets will be made available at the end of the project. IEC rating standard TS6 0 9 0 4 Part 1 -2 will be released in January 2 0 1 9 . 6This project is a collaboration between Sandia, NREL and the Univ of Iowa Increase Active Area Shingled-cell PV Modules SunPower, Tesla, and others are making modules with shingled cells interconnected with conductive adhesives. Maximizes the active area in the module Eliminates solder bond cell-cell interconnections common point of failure These modules require certain changes to modeling assumptions, such as the angular response function, which is directional due to the cell stacking. Conductive adhesives can affect series resistance of cells too. 7 Reduce Electrical Mismatch e.g., Maxim Integrated Power optimizers allow modules or cell strings with different irradiance levels to be combined in series with minimal losses. Maxim Integrated is testing its optimizers at the Regional Test Centers Allows for closer row spacing higher GCRs Future applications may include bifacial modules that have significant backside irradiance variability 8 Multi Use PV Deployments PV modules that produce energy AND provide another value, such as Protect building from elements Roof, windows, faades Reduce evaporation on reservoirs Floating PV Allow more varied crops to be grown Value is more than energy Appearance, weight, physical properties are all important. We have worked with several PV roofing developers. Most recently, Tesla’s Solar Roof. Outdoor, large-scale testing capability is necessary Sandia’s outdoor 2 -axis trackers are able to run performance characterization on full-sized roof mockups. 9 Increase PV Lifetime Degradation rates and profiles affect LCOE. PV Lifetime Project Sandia and NREL are deploying representative PV systems 1 0 -1 5 kW in NM, CO, and FL. 1 0 0 module flash testing initially Annual retesting of samples Automated string-level IV tracing every 3 0 min. 7 8 0 modules currently in program 8 manufacturers 4 of the top 1 0 , 1 1 different module models Data from these modules and systems will be made available after analysis is complete. 1 0 Hanuwa Q-Cells mono and poly PERTCanadian Solar mono and polyJinko polyTrina polyNew Mexico SystemsColorado Systems New Monitoring HardwareSandia has helped to develop some new hardware solutions for monitoring PV performance. 1 4 0 A Series II 8 -3 2 Channel In-Line String-Level I-V Tracer Developed jointly by Pordis LLC and Sandia available for purchase from Pordis 2 0 units to be deployed in the field in NM, CO, and FL. Traces are triggered from ref cell, Modbus signals e.g. irradiance, temperature or by time. String is automatically disconnected from inverter, trace is scanned, and then reconnected. Extremely linear temperature response -1 0 to 5 0 C Irradiance Variability Datalogger Developed jointly by Pordis LLC and Sandia Measures and stores irradiance at 1 sec intervals Communicates via cellular modem, Wifi, or serial. Onboard leveling, GPS Records irradiance ramp rate distributions Parts cost 1 0 0 1 1 Open-Source Modeling ToolsOpen-source software allows the National Labs to share new methods with industry stakeholders. Some Examples. PVLIB Toolbox Matlab and Python – Set of over 5 0 functions that allow users to build their own sophisticated PV performance models. Sandia System Advisor Model SAM – Performance simulations for many RE technologies. Recently released as open source C NREL Bifacial_radiance – Ray-tracing software for bifacial NREL BifacialVF – 2 D view factor code Python for bifacial NREL GridPV Toolbox Matlab – Models and simulates the impacts of PV on the distribution grid. Sandia Wavelet Variability Model – Simulates geographic smoothing of irradiance variability over a PV plant footprint. Sandia 1 2 Collaboration is Very Important The PV Performance Modeling Collaborative PVPMC facilitates sharing of new methods, data, and information. Website https//pvpmc.sandia.gov over 1 0 k visits per month Open-Source Software PVLIB, and more International Workshops Next workshop the 1 2 th is in Albuquerque, NM May 1 4 -1 6 , 2 0 1 9 Sandia and NREL also collaborate internationally with IEA PVPS, PVQAT, and other groups. 1 3 From Germany to China In 2 0 0 9 , when I started in PV, Germany was the world leader in PV technology. US sent fact-finding missions China is now emerging as a world leader in PV and RE technologies 2 0 1 8 NSF Report China is world’s largest producer of scientific articles Chinese PV innovations are growing Increased technical engagement with China’s universities, labs, and PV industry is warranted. 1 4Data from EPIA, IEA, CPIA Wang Sicheng, 2017ChinaChina Final Thoughts PV is a disruptive technology and is starting to be completely reimagined. Early prototypes are always expensive but their multi-use value might be underestimated. Refocusing from cost to value may open up new innovation opportunities. 1 5Floating PV PV Along HighwaysPV in Agriculture PV on HillsidesPV Roads PV Airplane PV Roof Thank youUpcoming Events 2 0 1 9 PV Reliability Workshop, Lakewood, CO February 2 6 -2 8 , 2 0 1 9 PV Materials, Modules, and Systems Reliability 1 2 th PV Performance Modeling Workshop in Albuquerque, NM May 1 4 -1 6 , 2 0 1 9 PV Measurement, Modeling, Monitoring and Integration bifiPV Workshop 2 0 1 9 in Amsterdam, NL October 2 0 1 9 Bifacial cells, modules, systems, modeling, and characterization 1 6