Webinar on the SE 2050 Committing to Net-Zero Embodied Carbon
$100.00
Continuing Education Credits Available – 1.5 PDH Credits
Structural materials are a major contributor to a building’s embodied carbon footprint. Embodied carbon represents the greenhouse gas emissions associated with the manufacturing, construction and demolition of the building’s components. Therefore, structural engineers play a critical role in reducing the environmental impacts of a building or renovation.
The Structural Engineers 2050 (SE 2050) Commitment Program by the Structural Engineering Institute (SEI) of the American Society of Civil Engineers (ASCE) is a program created for structural engineers to become engaged in understanding, measuring and reducing embodied carbon in structural systems. This presentation will provide background on the program, what is required from a committed firm, what data is collected in the SE 2050 database, and resources and strategies available to structural engineers to begin reducing embodied carbon on their structural designs.
Presenters
Mark D. Webster, P.E., LEED AP BD+C, is a structural engineer at Simpson Gumpertz & Heger. He is a founder of the Structural Engineering Institute’s Sustainability Committee and recently completed a term as co-chair of the committee. He leads the SE 2050 Commitment Resources Working Group and contributes to the SEI Sustainability Committee’s Circular Economy Working Group. He edited and co-authored the Sustainability Committee’s technical report addressing the climate impacts of structural materials, “Structural Materials and Global Climate,” and the committee’s white paper entitled “Achieving Net Zero Embodied Carbon in Structural Materials by 2050.” His structural consulting practice encompasses new design, renovation and investigation work, with an emphasis on historic buildings.
Charlotte A. Sauer, LEED AP BD+C, is an associate and structural engineer in the Chicago office of CannonDesign with experience in the design of healthcare, corporate, and science & technology projects. She leads the CannonDesign structural engineering group’s sustainability efforts and is the Embodied Carbon Champion for the firm’s commitment to SE2050. Charlotte is a graduate of the Illinois Institute of Technology, with a Bachelor of Science degree in Civil Engineering and a Master of Engineering degree in Structural Engineering. She is an active member of the ASCE-SEI Sustainability Committee and the SE2050 Subcommittee focusing on resource development.
Chris Jeseritz, S.E., P.E., LEED AP BD+C, is a project manager at PCS Structural Solutions in Seattle, WA, a consulting structural engineering firm in the Pacific Northwest. At PCS, Chris manages a variety of project types and the company’s internal sustainability engineering team. He serves as chair of the Structural Engineers Association of Washington’s (SEAW) Sustainability Committee and is a member of the ASCE SEI Sustainability Committee and the SE 2050 Commitment Program.
In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically
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In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically
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In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically
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In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically
Webinar on Cold-Formed Steel Curtain Wall Design
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In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically
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In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically
Price: $100
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Continuing Education Credits Available – 1.5 PDH Credits
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In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically
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Continuing Education Credits Available – 1.5 PDH Credits
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Presenter: Reynald Serrette, Ph.D.,
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Reynaud Serrette, Ph.D. is a professor in the Department of Civil, Environmental and Sustainable Engineering at Santa Clara University in Santa Clara, California. He has been involved in cold-formed steel research and design since 1987.
In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically
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Continuing Education Credits Available – 1.5 PDH Credits
This webinar will focus on the ideation, development, analysis and experimental evaluation of an innovative lightweight modular floor system utilizing cold-formed steel. As part of a research project funded by the American Institute of Steel Construction (AISC), researchers at the University of Kansas developed a novel floor system composed primarily of cold-formed steel, intended for modular use in steel-framed buildings. The webinar will highlight the background and initial development of the floor system, including design and construction considerations and corresponding analyses. As rapid fabrication, vibration mitigation and diaphragm behavior were emphasized in the development of the floor system, experimental testing of the floor focused on the cyclic behavior of connectors in the cold-formed steel components, vibration serviceability of the floor, and cyclic diaphragm performance within a steel-framed structure. All aspects of system validation will be presented, including physical and analytical evaluations as well as recommendations for future implementation and other project.
Matthew F. Fadden, Ph.D., P.E., Wiss, Janney, Elstner Associates
Dr. Fadden joined WJE with 10 years of experience in structural engineering research and consulting. His primary areas of expertise include the design, analysis and evaluation of steel structures (hot-rolled and cold-formed) and reinforced concrete structures. Additionally, Dr. Fadden has expertise in structural evaluation using finite element modeling and structural testing. His experience also includes seismic design, structural vibrations, offshore structures and litigation support.
Prior to joining WJE, Dr. Fadden was a professor in the Department of Civil, Environmental, and Architectural Engineering at the University of Kansas. There, his research areas included modular systems and connections for steel buildings, bolted and welded connections, ancillary sign structures, structural vibrations, and additive manufacturing for civil infrastructure. Dr. Fadden has authored many technical publications in referenced journals and provided numerous conference presentations.
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William N. Collins, Ph.D., P.E., University of Kansas
Dr. Collins is the Chair’s Council Associate Professor of Civil, Environmental and Architectural Engineering at the University of Kansas.
Dr. Collins’ expertise is in structural engineering, with a particular focus on fracture and fatigue behavior and metallic infrastructure. He has been associated with numerous projects related to structural behavior, fabrication and inspection. He is active with numerous professional organizations, including TRB, ASTM International and the AASHTO/NSBA Collaboration. Dr. Collins is also engaged in a variety of educational initiatives at the University of Kansas, including the development and implementation of peer mentoring in structural engineering curricula, an effort that has spread to other groups and departments within the university. He was awarded the AISC Milek Fellowship in 2021.
Previously, he was a research engineer at Purdue University and a research/teaching assistant at Virginia Polytechnic Institute and State University (Virginia Tech). He was also a timberwright at Blue Ridge Timberwrights in Christiansburg, Virginia and a construction superintendent at Prospect Homes of Richmond.
Dr. Collins is a registered Professional Engineer in Kansas. He holds B.S., M.S., and Ph.D. degrees in Civil Engineering, Structural Engineering and Materials from Virginia Tech.
In order to receive credit for this course, you must complete the quiz at the end and pass with at least 80% for a certificate to be generated automatically