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Lithium Battery Power & Battery Safety 2016
- 리튬 배터리 컨퍼런스 & 배터리 안전성 컨퍼런스 2016 -
개최: 미국, 베데스다
일정 : 2016/11/01 ~ 2016/11/04

Cambridge EnerTech 산하 Knowledge Foundation 주최 제12회
Lithium Battery Power 2016(리튬 배터리 컨퍼런스)
화학, 재료, 모델링 분야의 진보
2016년 11월 1일 - 2일|Hyatt Regency Bethesda|미국 메릴랜드주 베데스다

아젠다

새로운 배터리용 화학 기술, 전극과 전해질 재료, 대용량 캐소드와 어노드, 시스템 통합 분야의 비약적인 진보에 의해 자동차, 휴대용 기기, 고정형 시스템 등의 분야에서 배터리 용도가 크게 확대되고 있습니다. 리튬이온 배터리를 이용한 에너지 저장 기술을 위한 연구 및 설계면의 중요한 기술 혁신은 안전성 및 신뢰성 향상이라는 중요 성과와 함께 이 기술을 최첨단 영역으로 전진시키고 있습니다.

11월 1일(화)

7:30 등록, 커피

8:30 주최측 환영사

Craig Wohlers, Executive Director, Conferences, Knowledge Foundation, a Division of Cambridge EnerTech

8:35 의장 개회사

Daniel Abraham, Ph.D., Engineer, Chemical Sciences and Engineering, Argonne National Laboratory


8:45 기조 강연:자동차 업계용 리튬이온 배터리 - 재료에서 차량 전동화까지 다양한 영역의 주요 문제

K_RaghunathanK Raghunathan, Ph.D., Battery Systems Engineer, General Motors

GM has developed tools for assessing advanced electrode materials and cell designs. The tools integrate material properties, cell fabrication constraints, and vehicle requirements to estimate cell energy density, specific energy, and power-to-energy ratio. Key challenges to implementing battery technology in vehicles and GM perspectives about these challenges will be presented.

각종 용도와 시장

9:30 미국 에너지부 첨단에너지연구사업사무국(ARPA-E):에너지 저장에 관한 요구에 대한 대응을 목적으로 한 하이리스크 하이리워드 어프로치에 대한 투자

Sue_BabinecSusan Babinec, Senior Commercialization Advisor, ARPA-E, U.S. Department of Energy

This presentation highlights ARPA-E's Technology-to-Market efforts, which focus on preparing breakthrough energy technologies for the transition from lab to market.


10:00 새로운 진화의 출발점에 서는 에너지 저장 기술:리튬이온 배터리 이후의 기술

George_CrabtreeGeorge Crabtree, Ph.D., Director, Joint Center for Energy Storage Research (JCESR), Argonne National Laboratory & Distinguished Professor of Physics, Electrical and Mechanical Engineering, University of Illinois at Chicago

The high-energy density and low cost of lithium-ion batteries have created a revolution in personal electronics through music players, camcorders, laptops, tablets, smart phones and wearables, permanently changing the way we interact with people and information. We are at the threshold of similar potential transformations in transportation to electric cars and in the electricity grid to renewable generation, smart grids and distributed energy resources. These transformations require new levels of energy storage performance and cost. The potential of lithium-ion batteries and beyond-lithium-ion batteries to meet these performance and cost levels will be analyzed.

10:30 휴식시간

11:00 리튬이온 배터리의 한계 초월

Stan_WhittinghamM. Stanley Whittingham, D.Phil., Director & Distinguished Professor, Chemistry and Materials, Binghamton University

Today's Li-ion batteries deliver far less than their theoretical energy density. Two materials approaches will be described: "Closing the Gap" on layered oxides such as NCA, and "Beyond Olivine" which pursues intercalating more than 1 Li per redox center.

11:30 실용화 후 피드백 기반 전기자동차용 배터리의 성능과 안전성 향상

Rick_ChamberlainRick Chamberlain, Ph.D., CTO, Boston-Power

While improved battery performance remains a constant need in EV applications, today's Li-ion batteries demonstrate sufficient capability (driving distance, power, pack size and weight) to enable EVs and satisfy early market growth. This talk shares Boston-Power's recent advances in EV battery products based on our experience as both cell and pack provider to multiple vehicle classes.

 

12:00 연제 미정

 
12:30 휴식시간

12:45 런천 프레젠테이션(스폰서 모집) 또는 개별 점심식사

13:15 휴식시간

진단, 모델링, 시뮬레이션

14:00 의장 발언

George Crabtree, Ph.D., Director, Joint Center for Energy Storage Research (JCESR), Argonne National Laboratory & Distinguished Professor of Physics, Electrical and Mechanical Engineering, University of Illinois at Chicago

14:05 리튬이온 배터리의 노후화에 따른 전극간 크로스 토크

Daniel_AbrahamDaniel Abraham, Ph.D., Engineer, Chemical Sciences and Engineering, Argonne National Laboratory

Cells containing layered-oxide-based positive electrodes and graphite-based negative electrodes are being cycled at high voltages (>4.3 V) to increase energy density. We detail the performance changes in these cells during cycling, with a particular focus on the cross-talk between electrodes. The performance consequences of this cross-talk, and methods to mitigate this cross-talk, will be highlighted.

14:35 배터리 계측:투과형 전자현미경에 의한 리튬이온 배터리 및 차세대 배터리 내부의 부식 해명

Huolin_XinHuolin Xin, Ph.D., Staff Scientist, Electron Microscopy, Center for Functional Nanomaterials, Brookhaven National Laboratory

Tailoring the surface chemistry to enhance corrosion resistance lies at the heart of materials processing for corrosion control of structural materials. I show that the rate capacity of a large family of phase conversion anode materials, i.e., transition metal oxides, is dependent on the stochastic process of passivity breakdown which can be described by a Poisson model.

15:05 스폰서 제공 프레젠테이션(발표자 모집)

15:20 휴식시간

재료의 제조와 설계

15:50 리튬이온 배터리용 저가격, 고에너지밀도 합금계 음극의 개발

Timothy Hatchard, Ph.D., Research Associate, Department of Chemistry, Dalhousie University

Since the introduction of the Li-ion battery in 1990, the materials used have remained relatively unchanged. Only recently has the LiCoO2 cathode begun to be replaced with NMC type materials. We summarize some of our efforts to explore nanostructured alloy anodes using relatively inexpensive and abundant starting materials, to keep costs down. We also discuss the role of functionality of polymer binders and the utility of some relatively inexpensive polymer binders.

16:20 A123에 의한 차량 전동화용 첨단재료 개발:저전압 용도 및 고전압 용도용 어프로치

Derek_JohnsonDerek C. Johnson, Ph.D., Executive Director R&D, A123 Systems, LLC

To produce safe, high-energy density cells utilizing nickel-rich NCM cathodes and large-capacity anode materials, A123 is implementing the same crystal level doping and surface coating approach that has been effective for low-voltage material development. We focus on the high-power material development resulting in LiSBs with cold crank capabilities that surpass lead-acid batteries and high-energy advancements at the material and cell level to achieve energy densities approaching 300 Wh/kg and 600 Wh/L for EV applications.


저온 충전

16:50 안전성 높은 저온 충전 기술의 가능성

Corey_LoveCorey T. Love, Ph.D., Materials Research Engineer, U.S. Naval Research Laboratory

Recent lithium-ion battery safety incidents have resulted from operation or charging at low temperatures. Slow mass transport and charge transfer kinetics at low temperature can lead to lithium dendrite formation on the anode surface. We have shown the onset time for dendrite nucleation and growth as well as dendrite morphology to be temperature-dependent processes. We highlight advanced materials, cell component selection and informed charging protocols as a combined strategy to overcome the dendrites issue observed at low temperature.

17:20 첫째날 종료, 디너 워크샵 등록


17:30-20:30 디너 워크샵*

워크샵 1:에너지 저장 분야의 기술 혁신:미래의 전력을 담당하는 기술과 시장 - 상세 내용

Instructor: Chris Robinson, Research Analyst, Lux Research


워크샵 2:배터리 안전성에 관한 연수 - 상세 내용

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

 

* 별도 등록 필요   


11월 2일(수)

8:00 브렉퍼스트 디스커션

이 세션은 아침식사와 함께 진행되는 그룹 토론으로, 각 분야의 전문가가 중심이 되어 진행되는 문제 해결을 위한 논의에서 다양한 입장의 참가자가 각각의 토픽에 관련된 아이디어 및 경험을 소개하는 장소이며 향후 타사와의 협력 관계를 발전시키기 위한 출발점이 됩니다.

브렉퍼스트 디스커션의 상세 내용 

9:00 의장 발언

Corey T. Love, Ph.D., Materials Research Engineer, U.S. Naval Research Laboratory


9:05 기조 강연:증강현실(AR) 및 가상현실(VR) 기술의 부상으로 향후 PC 디바이스의 배터리에 관한 요구조건이 변화할 가능성

Jeremy_CarlsonJeremy Carlson, Battery Technology Engineer, Lenovo

Upcoming changes to the PC landscape could have significant impact on the battery requirements for mobile computing. Augmented reality/virtual reality will require more intensive processing and low latency communications for immersive environments. This discussion centers on how this could impact the battery requirements for the devices implementing these functions.

대용량 캐소드

9:35 첨단 리튬이온 배터리용 대용량 캐소드:문제와 가능성

Jagjit Nanda, Ph.D., Senior Staff Scientist, Materials Science & Technology Division, Oak Ridge National Laboratory

This approach has numerous issues ranging from changes in the cathode interfacial structure to gas generation and electrolyte decomposition that can undermine their stability. We discuss recent advances in this topic. The second part discusses the recent advances in polyanionic and conversion type cathodes that offer great promise but still have fundamental material challenges that need to be addressed before practical application. This research is supported by the Assistant Secretary for Energy Efficiency and Renewable Energy, Office of Vehicle Technologies of the U.S. Department of Energy.

10:05 스폰서 제공 프레젠테이션(발표자 모집)

10:20 전시회장 휴식시간, 포스터 발표 관람

11:00 대용량 캐소드 재료 CAM-7 기반 고에너지밀도 리튬이온 셀

Brian_BarnettBrian Barnett, Ph.D., Vice President, CAMX Power






Suresh Sriramulu, Ph.D., CTO, CAMX Power

Successful implementation of high-nickel cathode materials in Li-ion cells is recognized to be a key approach to ensure required increases in cell energy density for a wide range of applications. We highlight some challenges unique to high-nickel cathode material implementation in Li-ion cells and demonstrate successful strategies for overcoming these issues.

11:30 리튬이온 배터리용 니켈 기반 대용량 층상 산화물 캐소드

Wei_TongWei Tong, Ph.D., Scientist/Principal Investigator, Lawrence Berkeley National Laboratory

Considering the vast interest in Ni-rich layered oxide cathodes, we recently revisited lithium-nickel oxide, an end member of Ni-rich layered oxides, which potentially removes the complexity due to a combination of different transition metals in NMC and NCA. I present our recent study on the synthesis of phase pure LiNiO2 and use it as a model compound to elucidate the intrinsic performance degradation mechanism originating from the high Ni content for those complex Rm layered oxides.

12:00 리튬-황 배터리 캐소드에서의 중규모 영향

Partha_MukherjeePartha Mukherjee, Ph.D., Assistant Professor, Mechanical Engineering Department, Texas A&M University

The lithium-sulfur (Li-S) battery is a promising energy storage technology, especially in the context of beyond-lithium-ion battery chemistry. However, a key challenge in this conversion chemistry based Li-S battery is the "shuttle effect" due to the transport of intermediate discharge product species between the cathode and anode, which causes active material loss and performance decay. We discuss the mesoscale implications resulting from the microstructure-transport-interface coupling in the Li-S battery cathode.

12:30 휴식시간

12:45 런천 프레젠테이션(스폰서 모집) 또는 개별 점심식사

13:15 휴식시간

어노드의 구조

14:00 의장 발언

Brian Barnett, Ph.D., Vice President, CAMX Power

14:05 실리콘 어노드와 저연소성 전해질을 사용한 대형 리튬이온 셀의 개발

James Wu, Ph.D., Research Scientist/Engineer, NASA Glenn Research Center

NASA is developing safe, high-energy and high-capacity Li-ion cell designs and batteries for future missions under its Advanced Space Power System (ASPS) project. Advanced cell components, such as high specific capacity silicon anodes and low flammable electrolytes, have been developed for improving cell-specific energy and enhancing safety. We present performance results of these various battery cells and discuss post-test cell analysis results.

14:35 내식성 초나노결정 다이아몬드 코팅 부품을 사용한 새로운 장수명 리튬이온 배터리

Orlando_AucielloOrlando Auciello, Ph.D., Endowed Chair Professor, Materials Science, Engineering and Bioengineering, University of Texas at Dallas

Novel electrically conductive/corrosion-resistant nitrogen-deposed ultrananocrystalline diamond (N-UNCD) coating provides excellent chemically robust encapsulation of commercial natural graphite (NG)/copper (Cu) anodes for Li-ion batteries (LIB), providing a solution to the problem of LIBs' anode materials degradation. In addition, new preliminary data will be presented indicating that electrically conductive N-UNCD coatings can also be used to coat LIBs' anodes to protect them from Li-induced corrosion, and that insulating corrosion-resistant UNCD coating can be used to coat the inner walls of metallic LIBs' cases to also protect them from corrosion induced by the Li-based battery environment.

15:05 스폰서 제공 프레젠테이션(발표자 모집)

15:20 전시회장 휴식시간, 포스터 발표 관람

16:00 리튬-전해질 계면에서 수지상 결정의 기구적 억제에 대한 기준

Venkat_ViswanathanVenkat Viswanathan, Ph.D., Assistant Professor, Mechanical Engineering, Carnegie Mellon University

A Li-metal anode that can reversibly cycle without forming dendrites is crucial for enabling next-generation battery chemistries like lithium-air and lithium-sulfur. Mechanical suppression of dendrite growth through solid or polymer electrolytes has shown potential for alleviating the problem. We present findings to fill the gaps in our current understanding of the mechanical suppression of dendrite growth at electrode-electrolyte interfaces by explicitly accounting for the anisotropic effects.

16:20 폭넓은 작동 온도에서 사용 가능한 전해질 개발

Dee_StrandDee Strand, Ph.D., CSO, Wildcat Discovery Technologies

Automotive applications require batteries with adequate power down to -30℃ to start the vehicle. This presentation highlights development of electrolyte formulations with wide operating ranges on both graphite and lithium-titanate anodes. The audience will gain an appreciation for the competing solvent/SEI effects over wide temperature ranges. Over the last decade, many governments have implemented more stringent regulations on vehicle fuel economy and CO2 emissions. Start-stop vehicle engines, which shut off during stops for traffic or at a light, play an important role in achieving these targets.

16:40 성능 향상을 촉진하는 요인과 제조 가공비용에 관한 이해를 통한 현재 및 향후 어노드 재료 가격 목표의 달성

Bridget Deveney, Senior Research Associate, GraftTech International

Lithium-ion has the potential to convert transportation in the U.S. over to fully electric green technology. The major remaining barrier is not technical but cost. This talk details the performance drivers and tradeoffs of various types of anode materials and how the traditional graphite industry can bring capital equipment infrastructure and production-scale knowledge to produce low-cost, high-performance anode materials now and in the future.

지적재산 전략과 영향

17:00 성장세가 뚜렷한 첨단 배터리 업계를 위한 지적재산 전략

Dan_AbrahamDan Abraham, Ph.D., Vice President, Science and Business Strategy, MPEG LA

Intellectual Property has become a valuable and contentious asset in the advanced battery industry. Drawing upon lessons from other industries, we address how IP creation and enforcement may affect a burgeoning industry. We explore: strategies for avoiding battery IP wars in a manner that fosters industry-wide development and growth, and new opportunities for making IP rights widely available while rewarding IP owners for their innovation.

17:00 Battery Safety Conference 등록

17:30 전시회장 환영 리셉션, 포스터 발표 관람

18:30 Lithium Battery Power 폐막


* 주최측 사정에 따라 사전 예고없이 프로그램이 변경될 수 있습니다.


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