Cambridge EnerTech’s

Battery Engineering Symposium

Building Better Batteries

13-14 June 2022

 

Battery engineering involves the important aspects of designing electrodes and cells that will take maximum advantage of the active materials, designing packs that will guarantee reliable cell performance, and integrating battery packs into vehicles (or other machines) and meeting vehicle constraints while ensuring safety, reliability, and durability. Cell design, including the choice of non-active components has a considerable impact on battery performance and reliability. Battery pack design and integration presents thermal, mechanical, and electrical engineering challenges, almost independent of cell chemistry. Optimizing cell and pack design according to the duty cycle of the application requires a careful balance between cell and pack energy, power, manufacturability, abuse tolerance, thermal characteristics, and cost.

Sunday, 12 June

16:00 Early Registration* (Rheinfoyer Garderobe)

*Come in early to get your badge and avoid the Monday morning rush!

18:00 Early Registration Ends

Monday, 13 June

07:30 Registration and Morning Coffee (Rheinfoyer Garderobe)

ROOM LOCATION: Gutenberg 2

BATTERY SAFETY

09:00 Organizer's Remarks

Victoria Mosolgo, Conference Producer, Cambridge EnerTech

09:05

Chairperson's Remarks

Gregory J. Offer, PhD, Professor in Electrochemical Engineering, Imperial College London
09:10

Safety of Li-Ion Batteries: Current Challenges and R&D Needs

Natalia Lebedeva, PhD, Scientific Project Officer, Energy Storage, European Commission

In this presentation, various aspects of thermal runaway and propagation in Li-ion batteries, including thermal runaway detection criteria and questions facing development of a regulatory test procedure, are discussed. Liquid, gas, and solid emissions from Li-ion batteries in several scenarios including battery fire are analyzed allowing more quantitative risk assessment of such emissions.

09:30

Lithium-Ion Battery Degradation: What You Need to Know, How to Model It, and How to Predict It

Gregory J. Offer, PhD, Professor in Electrochemical Engineering, Imperial College London

The journey of discovery his group has made over the past ten years in understanding lithium-ion battery degradation, how to model it, and how to diagnose it. The journey began with pioneering work demonstrating how different thermal management approaches strongly affected the degradation rates of lithium-ion pouch cells. At around the same time, the group began working on understanding and modelling the physical mechanisms of degradation.

09:50

Clean Coolants – Enabling Next-Generation Battery Cooling by Filtration and Separation

Michael Harenbrock, PhD, Principal Expert, Engineering Electric Mobility, MANN+HUMMEL GmbH

As immersion cooling systems dissipate heat from battery cells faster and more efficiently than state-of-the-art solutions, e.g.; with cooling plates, the interest in this technology is rising continuously. With coolants coming into direct contact with battery cells, fulfilling cleanliness requirements for the liquids is essential to prevent breakdown of dielectric properties. This presentation highlights solutions for particle filtration and water removal from Polyol Ester Oils in an OEM application.

10:10 MODERATED Q&A:

Session Wrap-Up

Panel Moderator:
Gregory J. Offer, PhD, Professor in Electrochemical Engineering, Imperial College London
Panelists:
Natalia Lebedeva, PhD, Scientific Project Officer, Energy Storage, European Commission
Michael Harenbrock, PhD, Principal Expert, Engineering Electric Mobility, MANN+HUMMEL GmbH
10:30 Networking Coffee Break (Rheinfoyer Garderobe)
10:50

Thermal Abuse Testing of Cylindrical Lithium-Ion Batteries Studied by Means of Accelerating Rate Calorimetry (ARC)

Sebastian Ohneseit, Group Batteries Calorimetry and Safety, Institute for Applied Materials – Applied Materials Physics (IAM-AWP), Karlsruhe Institute of Technology (KIT)

Thermal runaway behavior of commercial cylindrical LIB was evaluated using Accelerating Rate Calorimetry (ARC). With the Heat-Wait-Seek (HWS) test thermal abuse was studied and exothermal reaction temperature rates were evaluated and compared for different states of charge of 30, 60, 80, and 100%. Different cathode materials were studied, such as NCA, NMC, and LFP, as well as a comparison of type 18650 and type 21700 cells was done.


11:10

Thermal Simulations for Understanding and Optimizing Li-Ion Battery Pack Safety

Ankur Jain, PhD, Associate Professor, Mechanical & Aerospace Engineering, University of Texas, Arlington

The role of cell-to-cell gap, thermal conductivity of the interstitial material, and radiative properties of the partition between cells will be discussed. It will be shown that a careful thermal design of the battery pack may help mitigate several thermal runaway propagation related challenges.

Marc Blaufuß, Dipl.-Ing., Application Engineer, Leak Detection Tools, INFICON GmbH

High-voltage battery packs are part of every electrically powered vehicle. They are used in purely electric vehicles (EVs), hybrid vehicles (HEVs), but also in vehicles with fuel cell drive (FCVs). The battery packs have to be tested against water ingress - often according to IP67 - but also against coolant loss. The presentation will show how a suitable leakage rate specification can be determined and which testing processes can be used.

11:50 MODERATED Q&A:

Session Wrap-Up

Panel Moderator:
Gregory J. Offer, PhD, Professor in Electrochemical Engineering, Imperial College London
Panelists:
Sebastian Ohneseit, Group Batteries Calorimetry and Safety, Institute for Applied Materials – Applied Materials Physics (IAM-AWP), Karlsruhe Institute of Technology (KIT)
Ankur Jain, PhD, Associate Professor, Mechanical & Aerospace Engineering, University of Texas, Arlington
Marc Blaufuß, Dipl.-Ing., Application Engineer, Leak Detection Tools, INFICON GmbH
12:10 Networking Lunch (Kongress)

CELL ENGINEERING

13:40

Chairperson's Remarks

Michael Schoenleber, Co-Founder & CTO, Batemo GmbH
13:45

Prismatic, Pouch or Cylindric? A Cell Format Comparison

Michael Schoenleber, Co-Founder & CTO, Batemo GmbH

The race for the best cell format is open: From cylindric to pouch to prismatic approaches, all formats are currently out on the automotive battery market. In our talk we will shed light on the pros and cons of different formats and share insights we gained by opening and physically modelling a large variety of the cells, which are currently on the market.

14:05

Direct Comparisons of Pilot-Scale Li-Ion Cells in the Formats PHEV1, Pouch, 18650, and 21700

Thomas Waldmann, Project Manager & Scientist, ECM, Zentrum fur Sonnenenergie und Wasserstoff Forschung ZSW

We compare the cell formats PHEV1, pouch, 21700, and 18650 with the same cell chemistry on pilot-scale. Conclusions are drawn on the effect of cell design on rate capability, cell resistance, heating behavior, and cycling aging. The results are put into context with commercial cells.

14:25

Is Flexibility Contrary to High Throughput in Battery Cell Manufacturing? A New Approach for the Cell Stacking Process

Juergen Fleischer, PhD, Manager of Machines, Equipment & Process Automation, Karlsruhe Institute of Technology

In order to help align the two seemingly contradicting goals of highly flexible processes and large produced quantities, a new concept for the cell stacking process will be demonstrated. By interconnecting the traditional discrete stacking process and a continuous cutting operation, fast changes in regard to electrode dimension are made possible.

14:45 MODERATED Q&A:

Session Wrap-Up

Panel Moderator:
Michael Schoenleber, Co-Founder & CTO, Batemo GmbH
Panelists:
Thomas Waldmann, Project Manager & Scientist, ECM, Zentrum fur Sonnenenergie und Wasserstoff Forschung ZSW
Juergen Fleischer, PhD, Manager of Machines, Equipment & Process Automation, Karlsruhe Institute of Technology
15:05 Networking Refreshment Break (Rheinfoyer Garderobe)

THERMAL MANAGEMENT

15:25

Thermoplastic Composite Solutions for Battery Pack Enclosures

Takata Nobuaki, Business and Technology Incubation Section, Advanced Solutions Planning Division, Mitsubishi Chemical Corporation

Thermoplastic composite offers several solutions for battery pack enclosures such as flexibility of design range with parts integration, high productivity performance, lightweight, halogen-free, positive end-of-life with recyclable materials.


15:45

Next-Generation Thermal Barriers Used for Preventing Thermal Runaway Propagation in Battery Packs: The ESCO Approach

Marius Bauer, Project Head, Accumulators ECA, Zentrum fur Sonnenenergie und Wasserstoff Forschung ZSW

Our recent work on preventing thermal runaway propagation (TRP) by next-generation thermal barriers is presented. The focus is not only on our product design and approach, but also on best practices for bringing the barriers into the actual application.

Peter Vervoort, Mr., Vice President Global Technology, ONEJOON GmbH

As price, quality and carbon footprint are playing an increasingly important role in the future of e-mobility, new kiln concepts are needed to reach these targets. The currently available kilns cannot provide the required performance for the heat treatment of the electrode raw materials or even solid-state battery systems. See how ONEJOON´s advanced kiln concepts provide revolutionary improvements in the heat treatment technology of cathode, anode, and solid electrolyte material systems. 

16:25 MODERATED Q&A:

Session Wrap-Up

Panel Moderator:
Michael Schoenleber, Co-Founder & CTO, Batemo GmbH
Panelists:
Takata Nobuaki, Business and Technology Incubation Section, Advanced Solutions Planning Division, Mitsubishi Chemical Corporation
Marius Bauer, Project Head, Accumulators ECA, Zentrum fur Sonnenenergie und Wasserstoff Forschung ZSW
Peter Vervoort, Mr., Vice President Global Technology, ONEJOON GmbH
16:45 Transition to Breakout Discussions
16:55 Interactive Roundtable Discussions (Kongress)

Roundtable discussions are informal, moderated discussions with brainstorming and interactive problem solving, allowing participants from diverse backgrounds to exchange ideas and experiences and develop future collaborations around a focused topic.

IN-PERSON ONLY: TABLE 1: Silicon Anodes for Battery Technology

Ewout Lubberman, Head of Product, LeydenJar Technologies BV

IN-PERSON ONLY: TABLE 2: Artificial Intelligence for Lithium-Ion Batteries

Weihan Li, Independent Junior Research Group Leader, RWTH Aachen University

IN-PERSON ONLY: TABLE 3: Comprehensive Battery Benchmarking

Tal Sholklapper, CEO & Co-Founder, Voltaiq, Inc.
Michael Schoenleber, Co-Founder & CTO, Batemo GmbH

IN-PERSON ONLY: TABLE 4: Innovations in Recycling Battery Materials & Second Life

Steve Sloop, PhD, President, OnTo Technology LLC

IN-PERSON ONLY: TABLE 5: Battery Cost vs CO2 Footprint – What Will the Proposed Legislation Bring?

Wenzel Prochazka, Senior Product Manager, Battery Systems, AVL List GmbH

IN-PERSON ONLY: TABLE 6: Silicon Anodes and Cells

Benjamin Park, PhD, Founder & CTO, Enevate Corp.

IN-PERSON ONLY: TABLE 7: Li-Ion NMC Fast Charging New Cells for E-Mobility

Shmuel De-Leon, CEO, Shmuel De-Leon Energy Ltd.

IN-PERSON ONLY: TABLE 8: Advances in Sodium-Ion Battery Materials

Philipp Adelhelm, PhD, Professor, Institute of Chemistry, Humboldt University Berlin
17:55 Grand Opening Networking Reception in the Exhibit Hall with Poster Viewing (Rheinfoyer)
18:55 Registration for Dinner Tutorials (Rheinfoyer Garderobe)
19:15 Recommended Dinner Tutorials*

*All Access Package, or separate registration required. See Tutorial page for details

20:45 Close of Day

Tuesday, 14 June

08:30 Registration and Morning Coffee (Rheinfoyer Garderobe)

ROOM LOCATION: Gutenberg 2

DIAGNOSTICS & MODELING

09:00 Organizer's Remarks

Victoria Mosolgo, Conference Producer, Cambridge EnerTech

09:05

Chairperson's Remarks 

Tim Holme, PhD, CTO, QuantumScape Battery Corporation
09:10

Battery Model Parameterisation under True Isothermal Conditions

Alastair Hales, PhD, Lecturer, Mechanical Engineering, University of Bristol

Battery models are only as good as the parameters which define them – poor temperature control during parameterisation experiments leads to error in battery model parameters, yet convection cooling remains the temperature control method of choice across the automotive industry. The problem will worsen in years to come as high-rate requirements and energy density continue to increase. We must use temperature as a controlled input rather than a poorly controlled variable, and add an additional dimension to the performance of our battery models and battery management system.

09:30

Data-Driven Parameter Identification of an Electrochemical Model for Lithium-Ion Batteries with Artificial Intelligence

Weihan Li, Independent Junior Research Group Leader, RWTH Aachen University

This work aims to develop a parameter identification framework that is suitable for fast and accurate identification of physical parameters of electrochemical models under real-world operation. The proposed data-driven parameter identification framework not only shows significant performance improvement compared with the other data-driven methods but also shows a higher identification accuracy compared with the state-of-the-art experimental identification method.

09:50

Advanced in situ and Operando Battery Diagnostics

Tazdin Amietszajew, PhD, Associate Professor, Battery Diagnostics, Institute for Future Transport & Cities, Coventry University

Current “state-of-the-art” monitoring and control techniques for battery cells rely on full-cell potential measurement and occasional surface temperature measurements. However, electrochemical cells are complex multi-component devices and as such these techniques have poor resolution, limiting applicability. To unlock the full battery performance without jeopardising safety, we enable live in-situ thermodynamic characterisation utilising a combination of developments on micron-scale sensor assemblies facilitating internal power mapping.

Brian Cahill, Director, Strategic Marketing, Battery Thermal, Aspen Aerogels

The Chinese government mandates that passengers must have a 5-minute window to exit their vehicle after detection of thermal runaway. While this is a step forward, a better goal is to stop thermal propagation. Single-cell thermal runaways that propagate to module-, pack-, or vehicle-level will, even at low incident rates, dampen acceptance of BEVs. Discover how aerogel-based thermal barrier materials can help achieve this goal within space, weight, and cost constraints.

10:30 MODERATED Q&A:

Session Wrap-Up

Panel Moderator:
Tim Holme, PhD, CTO, QuantumScape Battery Corporation
Panelists:
Alastair Hales, PhD, Lecturer, Mechanical Engineering, University of Bristol
Weihan Li, Independent Junior Research Group Leader, RWTH Aachen University
Tazdin Amietszajew, PhD, Associate Professor, Battery Diagnostics, Institute for Future Transport & Cities, Coventry University
Brian Cahill, Director, Strategic Marketing, Battery Thermal, Aspen Aerogels
10:50 Coffee Break in the Exhibit Hall with Poster Viewing (Rheinfoyer)

SOLID-STATE DEVELOPMENT

11:20

The Next-Generation of Electric Vehicle Battery Technology Relies on Solid-State Innovation

Tim Holme, PhD, CTO, QuantumScape Battery Corporation

This presentation will share the details of QuantumScape’s groundbreaking solid-state batteries technology with lithium-metal anodes and discuss how QuantumScape addresses the limitations of traditional lithium-ion batteries and previous attempts at solid-state technology, including charge time, cycle life, safety, and operating temperature.

11:40

Develop a New Generation of Battery Management Systems for the Future Solid-State Lithium-Ion Batteries

Chris Chunting Mi, PhD, Distinguished Professor & Chair, Electrical & Computer Engineering, San Diego State University

Solid-state lithium-ion batteries are predicted to become mainstream in the next few years due to their superior performance, such as high energy density (350Wh/kg), wide operating temperature (-10 to 70C), excellent safety, and lower cost. Solid-state batteries also offer a higher cell voltage of nearly 5V. However, the life cycle of the solid-state batteries may be much lower than the current lithium-ion battery. Hence, a new generation of battery management systems is necessary to manage the future solid-state lithium-ion batteries that can handle the high cell voltage and optimize the life cycle.


PREDICTIVE BATTERY ANALYTICS

Matthias Simolka, PhD, Solution Engineering, TWAICE

While virtual development and use of simulations are increasingly adopted by companies globally, combining the development phase with actual performance in the field remains difficult. Hybrid models are a unique technology that enables accurate development insights and assesses likely warranty cases across fleets, whilst understanding end-of-life challenges. A current case from the automotive industry will be presented.

12:20 MODERATED Q&A:

Session Wrap-Up

Panel Moderator:
Tim Holme, PhD, CTO, QuantumScape Battery Corporation
Panelist:
Chris Chunting Mi, PhD, Distinguished Professor & Chair, Electrical & Computer Engineering, San Diego State University
12:40 Close of Battery Engineering Symposium





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MONDAY 23 JUNE

Pre-Conference Tutorials

TUESDAY & WEDNESDAY
24-25 JUNE

CHEMISTRY - PART 1

WEDNESDAY & THURSDAY
25-26 JUNE

CHEMISTRY - PART 2

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