$0.00
Functional Safety plays a critical role in the design and development of active control and safety systems across multiple industries, including automotive/EV, micromobility and stationary energy storage. This discussion outlines several of the core industry or regulatory requirements for functional safety as it applies to battery safety control systems. Specific areas of discussion are risk assessments, comparing various functional safety reference standards, and interpreting requirements across multiple certification schemes and standards.
This webinar will focus on the following key topics:
• Identifying key battery/ ESS standards
• Applying functional safety requirements to battery management systems
• Selecting appropriate Functional Safety standards
• Performing battery-specific risk assessment
Presenter
Rich Byczek – Global Technical Director at Intertek
Rich Byczek is the Global Technical Director at Intertek. He has 30 years of experience in product development and validation testing, with over 20 years at Intertek. Rich is experienced in the areas of energy storage, product validation, EMC and Quality Management. As Intertek’s Global Technical Lead for Electric Vehicle and Energy Storage, Rich sits on several standards technical committees and working groups. He holds a Bachelor of Science in Electrical Engineering from Lawrence Technological University and is based at the Intertek EV and Battery Center of Excellence located in Plymouth, Michigan.
Intertek is a proud sponsor of this event.
Related products
-
Key Trends, Recent Developments and ‘What’s Next’ for Energy Storage?
Billions of dollars have recently been invested into advanced energy storage systems initiatives globally. These include further development of R&D and manufacturing advancements in xEV batteries, stationary power systems, “beyond lithium” technologies, and more. NextEnergy will share some knowledge gained through its suite of venture support services, including access to funding opportunities, & in-depth value chain and market analyses, based on primary & secondary research.
This webinar will highlight some key market and R&D trends, key innovators in the energy storage space, and take a high-level look at other initiatives influencing “what’s next” in the field of advanced energy storage, with an emphasis on Li Ion batteries for automotive applications.
This webinar will focus on the following key topics:
• NextEnergy’s capabilities, and a sneak preview of NextEnergy’s Li Ion battery value chain. This work is primarily focused on automotive applications
• Key general trends in the energy storage sector, in terms of manufacturing, R&D, and market trends
• A brief review of select early stage companies offering innovative solutions to the energy storage community
• Select novel R&D initiatives in the Li Ion and “beyond lithium ion” spaces will be presented, at a high-level, and “what’s next” in energy storage systems will be addressedPresenter
Kelly Jezierski – Energy Storage Manager, NextEnergy
Kelly Jezierski has been with NextEnergy for over 7 years. NextEnergy is one of the nation’s leading accelerators of advanced energy technologies, businesses and industries. Kelly is leading a joint initiative funded by the US Department of Commerce and Michigan Economic Development Corporation (MEDC) to foster growth in the advanced energy storage cluster and fill gaps in the domestic supply chain. Kelly holds a Bachelor of Science degree in Chemical Engineering and a Master of Science degree in Alternative Energy Technologies degrees, both from Wayne State University.
Buy Now -
Battery Ageing – How Modeling is Used to Predict Battery Life
Battery modeling and simulation makes it possible to analyze multiple operating conditions and design parameters for batteries and other electrochemical systems and processes. By developing mathematical models you can begin to understand the interaction of electrochemical and chemical processes in the battery and how these processes affect the performance and life of the battery.
In this presentation, we will take a look at the benefits of modeling and simulation in the design, selection, and operation of a lithium-ion battery. We will especially take a look at how modeling can be used together with testing. These results provide manufacturers and application experts with the data to not only predict battery life but to analyze the implications of design parameters and operating conditions to better understand the limitation of the battery.
This webinar will focus on the following key topics:
• Benefits of modeling and simulations in the design, selection, and operation of a lithium-ion battery
• Implications of design parameters and operating conditions with respect to experimental observations of battery performance, aging, and battery safety
• How battery modeling can be used together with testingPresenter
Tom O’Hara – Global Business Manager, Intertek
Tom O’Hara is the global business manager / advisory services for Intertek’s energy storage programs. Aside from his consulting role, Tom supports U.S. and European marketing and sales efforts and APAC CTIA certification efforts. As a 30-year veteran of the battery technology field, Tom has worked in Energizer Battery’s R&D sector and consulted with several start-up battery companies. He is also the co-inventor of the world’s first successful mercury-free zinc air button cell and holds seven U.S. patents. He obtained both a B.S. and M.S. in chemistry from Wake Forest University in North Carolina.
Buy Now -
Understand and Prevent Battery Fires and Explosions – and Avoid Costly Failures Like the Samsung Note 7
Modern batteries (eg Li-Ion) contain hazardous chemicals & they heat up during use: this combination always has the potential to cause fires & explosions. This presentation will focus on improving the understanding of how these incidents occur, what can be done to avoid them & how the risk can be minimized during early stage design.
The Samsung Note 7 phone & Boeing Dreamliner airplane fires are very costly examples of how even large corporations fail to understand the potential fire risk of batteries.
The solution lies in knowledge of heat generation rate during normal use & information about safe boundaries such as temperature, discharge rate & overcharge, in realistic situations that represent actual use conditions. Data from commercial batteries of different types will be used to illustrate these points.
A relatively new technique will also be discussed with data, which allows total heat output during discharge to be measured on-line and this can be used both for design and battery modelling. Examples of the data will be provided.
This webinar will focus on the following key topics:
• Why battery fires & explosions occur
• How to design safer batteries though understanding of heat generation
• Video evidence of batteries under explosive conditions
• How better thermal management systems can be designed – based on heat measurement from isothermal calorimetry
• Laboratory instruments suitable for testing and data generationPresenter
Dr. Jasbir Singh – Managing Director at Hazard Evaluation LaboratoryJasbir is a chemical engineer specializing in thermal hazards and calorimetry, traditionally for the chemical industry but now increasingly involved in battery safety, especially Li-ion EV and related types.
A graduate of Imperial College (London), where he undertook PhD into combustion and explosions, his experience includes many years in process design for the chemical and petrochemical industries. He is currently developing test methods and instruments for use in design of battery thermal management systems.
Buy Now -
Solid Electrolytes and Bulk Scale Solid-State Batteries
Recently, the push to move beyond Li – ion battery technology has grown. Several advanced battery technologies & chemistries have been identified as promising candidates including i) solid-state batteries with Li metal anode, ii) Li – S chemistries, iii) Li – air(oxygen), and iv) flow batteries. Although an engineered solution using liquids may be possible for some of these options, a solid electrolyte is an enabling technology for each of these beyond Li – ion alternatives. This webinar will introduce the operating principles of each of these cell technologies and solid electrolytes will be discussed in this context. The requirements of a solid electrolyte will be outlined & several state of the art solid electrolytes will be compared. Recent technical progress towards the fabrication of solid-state batteries will be reviewed. Finally, an overview of market applications for solid-state will be presented.
This webinar will focus on the following key topics:
• Overview of beyond Li – ion battery technologies enabled by solid electrolytes
• Comparison of state of the art solid electrolytes
• Recent technical progress towards solid-state batteries
• Review of market applications for solid-state batteriesPresenter
Travis Thompson – Post Doctorate Research Fellow at University of Michigan
Travis received his B.S. in Mechanical Engineering in 2010 from California State Polytechnic University, Pomona, and his PhD in Materials Science at Michigan State University in 2014. His graduate work has focused on synthesis & processing of materials for direct thermal-to-electric energy conversion & storage. This includes ambient drying of silica aerogels, processing of oxide based thermoelectric materials, & electrochemical characterization of ceramic solid electrolytes for advanced batteries. He is now a Research Fellow at The University of Michigan and is exploring commercialization of Solid-State Batteries from his graduate work.
Buy Now