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3rd Next Generation Batteries 2013 - 제3회 차세대 배터리 컨퍼런스 2013 -
2013년 11월 12 - 13일
미국 캘리포니아주 샌디에고, Hyatt Mission Bay Resort & Marina

 
 
       
 
전시기업 플로어플랜
전시 기회
전시기업 상세정보

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배터리 분야는 새로운 화학물질과 전극 및 전해질 재료가 개발되고 모바일, 휴대용, 고정형 등 다양한 용도의 시스템에 통합되며 소형 의료기기용 배터리와 고에너지/고출력 자동차용 배터리 등 다채로운 제품이 개발되면서 무한한 가능성을 내포한 새로운 시장이 개척되고 있습니다. 각종 시판 시스템용 리튬이온 배터리는 출력, 에너지, 비용, 안전성 면에서 우수한 특징을 가지고 있으나, 리튬 이외의 화학물질을 사용한 배터리의 연구도 진행되고 있으며 향후 성과가 주목됩니다.
본 컨퍼런스에서는 배터리 재료, 시스템 설계와 통합, 제조, 상업화 분야의 저명 전문가가 한자리에 모여 중요한 시기를 맞이하고 있는 배터리 업계의 새로운 문제 등에 대해 논의합니다.


·         에너지/출력 향상과 저비용화에 기여하는 새로운 화학물질과 재료
·         리튬과 비리튬 재료:출력과 에너지의 적정량 분석
·         제조업체 견해 - 설계 단계부터 용도에 맞는 새로운 배터리 시스템 개발 방법
·         다양한 배터리 구조를 위한 새로운 재료:실리콘, 아연, 망간 및 바나듐
·         리튬 공기 배터리와 리튬 산소 배터리
·        배터리 기술 개발에서 주도적인 역할을 담당하는 나노재료
·         플로우 배터리, 미소유체 및 레독스 배터리의 발전
·         박막 배터리
·         유연성 높은 프린티드 배터리
·         새로운 재료와 컴포넌트, 시스템 아키텍처와 통합 기술
·         전기자동차 문제에 대처하는 배터리:사이클 수명, 출력과 에너지, 비용과 안전성
·         하이브리드 배터리 디바이스               
 
 
 
 미디어 스폰서 및 컨퍼런스 파트너
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 
 
 

2013년 11월 12일(화)

8:00 등록, 전시 관람/포스터 준비, 커피 & 간식

8:50 주최사 인사

9:00 전기자동차를 위한 변환 에너지 저장 기술:ARPA-E 포트폴리오 개요
Ping Liu, PhD, Program Director, ARPA-E, U.S. Department of Energy
Advanced Research Projects Agency Energy (ARPA-E) has invested in transformational energy storage technology to enable more widespread adoption of electric vehicles (EVs). This presentation will highlight some of the promising projects that are helping to drive down cost, increase range, and improve safety for EVs. Approaches for improvement include novel materials for battery architectures, lithium-air, and flow batteries. There is also a group of projects with a focus on robust designs: electrochemical energy storage chemistries and/or architectures (i.e. physical designs) that avoid thermal runaway and are immune to catastrophic failure regardless of manufacturing quality or abuse conditions.

9:30 나트륨 이온 배터리용 파이로인산 철나트륨 음극 유리 세라믹
Tsuyoshi Honma, PhD, Assistant Professor, Functional Glass Engineering Laboratory, Nagaoka University of Technology, Japan
Triclinic Na2−xFe1+x/2P2O7/C composite was prepared by glass-ceramics method. We found that Na2−xFe1+x/2P2O7/C composite can be used as cathode active materials for Sodium ion battery with high current density rate performance over 10C (2 mA cm−2) condition and stable electrochemical cycle performance. A 2 μm glass precursor powder in composition of Na2−xFe1+x/2P2O7 (x = 0-0.44) was crystallized in tubular furnace around 600 °C with carbon source to reduce iron valence state and to coat grain surface with carbon. By means of charge-discharge testing Na2FeP2O7/C composite exhibits 86 mAh g−1 (253 Wh kg−1) as reversible discharge energy density that is half amount of that for LiFePO4, however in 10C condition they kept 45 mAh g−1 (110 Wh kg−1) even in 2 μm grain size.

10:00 나트륨 전도 소재를 위한 재료 설계
Taku Onishi, PhD, Assistant Professor, School of Engineering, Department Chemistry for Materials, Mie University, Japan
A sodium ion conductor for a sodium ion secondary battery was theoretically designed by hybrid DFT calculations. It was concluded that NaAlO(CN)2 shows the high sodium ion conductivity along Z-axis. The activation energy along Z-axis was estimated to be 0.06 eV. Chemical bonding analysis on conductive sodium was also performed, based on Onishi chemical bonding rule.

10:30 휴식, 전시/포스터 관람

11:00 전력망 에너지 저장용 수소-브롬 레독스 흐름 배터리 개발
Adam Z. Weber, PhD, Staff Scientist, Electrochemical Technologies Group, Environmental Energy Technologies Division, Lawrence Berkeley National Laboratory; and
Markus S. Ding, Institute of Technical Electrochemistry, Technische Universität München, Germany
*
LBNL has been working on a high-power redox flow battery (RFB) by utilizing hydrogen and bromine to develop a cost-effective electrochemical system for storing grid-scale energy. In this study, we will report on technical approaches, which have been taken to develop the RFB. It will be described in detail how cell components and structure could be optimized to minimize the losses associated with kinetics, ohmic and mass transfer properties, and therefore leading to the first-in-class RFB performance. We will also report on the cyclic performance of the RFB, and especially the effect of operating conditions such as electrolyte concentration, cut-off potential, and current on the cyclic performance. Various diagnostic methods such as measurement of over-potential with open-circuit-voltage (OCV) monitoring cell, analysis of exit gas from cell with a real time gas analyzer (RTGA), and characterization of species cross-over by capillary electrophoresis (or bromide-selective electrode) were utilized to find the proper operating conditions to minimize performance loss and side reactions. This work was funded by Advanced Research Projects Agency-Energy (contract # DE-AC02-05CH11231) with cost share provided by Robert Bosch LLC.
*In collaboration with: K.T.Cho, V.Battaglia, and V.Srinivasan, LBNL

11:30 PSI 실리콘 위스커와 카본 나노섬유 복합 어노드를 사용한 고에너지밀도 셀 구축 노력
Christopher M. Lang, PhD, Group Leader, Energy Technologies, Physical Sciences Inc.
Silicon is one of the most appealing anode materials for higher energy density batteries. However, many challenges exist to efficiently access the large theoretical potential of this material. Physical Sciences Inc. has developed and demonstrated a composite material with good capacity, rate and cycling performance. In this presentation, we will present on our efforts to construct high energy density cylindrical and prismatic cells with this anode material. In particular, the impact on cycling performance of the cathode material and electrolyte choice will be examined.

12:00 고에너지 솔리드 스테이트 의사커패시터
Daniel Sweeney, PhD, Principal Investigator, Space Charge LLC
A solid-state pseudocapacitor promising high energy and power density pseudocapacitors are hybrid energy storage devices having the attributes of both batteries and true capacitors. Conventional pseudocapacitors utilize liquid electrolytes of very low dielectric strength, which ultimately constrain energy density. Space Charge LLC has substituted thin films comprised of materials, which have high dielectric strength and high ionic mobility. This combination of virtues supports charge storage exceeding that of advanced batteries while permitting rapid charging and potentially tens of thousands of charge-discharge cycles.

12:30 Knowledge Foundation 멤버십 프로그램 후원 오찬회

2:00 차세대 배터리 로드맵
Cosmin Laslau, PhD, Analyst, Lux Research Inc.
Next-generation battery technologies such as lithium-air, lithium-sulfur, and solid-state threaten to disrupt the growing $20 billion Li-ion market. However, advancing Li-ion itself will present a moving target, as high-voltage cathodes and improved anodes move the performance needle. Lux Research looked at transportation, consumer electronics, and military applications to assess cost, performance, and outlook, and built a roadmap to show which next-generation energy storage technologies have the best chance of adoption, in which applications, and when.

2:30 세계의 리튬이온 배터리 시장 - 충전인가, 방전인가
Vishal Sapru, Research Manager, Energy & Power Systems, Frost & Sullivan, Inc.
The presentation will focus on market opportunities for lithium-ion batteries, with an end-user focus on consumer, industrial, automotive, and renewable energy / grid storage applications. The presentation will highlight the impact of the hybrid and electric vehicle slowdown on the lithium-ion battery market, and its potential impact on the renewable/grid storage battery business. The presentation will focus on key challenges, drivers and restraints, potential market size, and trends, among others.

3:00 수급 관점으로 본 리튬이온 배터리 시장
Sam Jaffe, Senior Research Analyst, Navigant Research
Navigant Research will launch an advanced battery tracker in the third quarter of 2013. The tracker will follow Li-Ion shipments from factory gate to end use application. It will cover the automotive, stationary, consumer electronics and other markets. This presentation will reveal initial results of the tracker, including market sizing and forecasting for each major sub-market.

3:30 휴식시간 및 전시/포스터 관람

4:00 수성 리튬이온 배터리의 최근 진전
Haiyan Wang, PhD, Researcher, School of Chemistry and Chemical Engineering, Central South University, China
The aqueous lithium-ion battery (ALIB) has been demonstrated to be one of the most promising stationary power sources for sustainable energies such as wind and solar power. During the past decades, many efforts have been made to improve the performance of the aqueous lithium-ion battery. On the basis of our group's research, the latest advances in the exploration and development of battery systems and relative materials will be demonstrated.

4:30 배터리급 LiOH를 생산하기 위한 프로세스 개발 및 최적화:물과 에너지 소비의 최적화
Wilson Alavia, PhD, Researcher Center for Advanced Research in Lithium and Industrial Minerals-Celimin, Universidad de Antofagasta, Chile*
To satisfy the current and future energy demand in Chile, the government is investing in ERNC and energy storage technologies, and specifically in lithium battery technologies. The components of our lithium batteries are fabricated from LiOH, which is produced from Li2CO3. In this presentation we will discuss development and optimization of a process for fabrication of LiOH battery grade from Li2CO3 using the metallurgic process simulator Metsim. We have determined the optimal conditions to produce the battery grade LiOH and to reduce water and energy consumption.
*In collaboration with: A.Gonzales, S.Ushak, M.Grageda

5:00 리튬이온 배터리 열전기화학 모델과 우주 애플리케이션용 궤도 열분석 소프트웨어의 결합
William Walker, Researcher, NASA Johnson Space Center
Lithium-ion batteries (LIBs) are replacing some of the Nickel Metal Hydride (NiMH) batteries on the International Space Station. Knowing that LIB efficiency and survivability are highly influenced by the effects of temperature, this study focused on coupling orbital-thermal analysis software, Thermal Desktop (TD) v5.5, with LIB thermo-electrochemical models representing the local heat generated during charge/discharge cycles. Before attempting complex orbital analyses, a simple sink temperature model needed development to determine the compatibility of the two techniques. LIB energy balance equations solved for local heating (Bernardi's equation) were used as the internal volumetric heat generation rate for native geometries in TD. The sink temperature, various environmental parameters, and thermophysical properties were based on those used in a previous study for the end of 1, 2, & 3 Coulomb (C) discharge cycles of a 185 Amp-Hour (Ah) capacity LIB. The TD model successfully replicated the temperature vs. depth of discharge (DoD) profiles and temperature ranges for all discharge and convection variations with minimal deviation. In this study, we successfully developed the capability of programming the logic of the variables and their relationship to DoD into TD. This coupled version of orbital thermal analysis software and thermo-electrochemical models provides a new generation of techniques for analyzing thermal performance of batteries in orbital-space environments.

5:30 전력망 접속 에너지 저장을 위한 전력 변환 시스템 아키텍처
Kyle B. Clark, Engineering Manager, Advanced Systems, Dynapower Corporation
Abstract not available at time of printing. Visit www.KnowledgeFoundation.com for the latest Program updates

6:00 - 7:00 칵테일 리셉션



 
2013년 11월 13일(수)

8:00 전시/포스터 관람 및 커피 & 간식

9:00 수송 리튬이온 배터리 전망
Ralph Brodd, PhD, President, Broddarp of Nevada
The talk will summarize the recent NRC publication "Transitions to Alternative Vehicles and Fuels." The time line for introduction and the main factors controlling the transitions electrified transportation will be discussed. The study included a comparison of fuel cell, battery powered and hybrid vehicles as well as alternative fuels, such as ethanol, etc.

9:30 첨단 배터리 설계 툴박스
Bor Yann Liaw, Hawaii Natural Energy Institute, University of Hawaii at Manoa
We have recently developed a mechanistic model as a battery design toolbox that can emulate “what if� scenarios to predict battery performance and life under various duty cycle requirements. Based on half-cell data, we can compose metrics for cell performance by matching electrode loading and loading ratio to construct different configurations for performance and life prediction. This unique capability will allow the user through simple design panel to estimate various “what if� criteria to design the cell with the performance and life in mind. The presentation will explain the approach and utility offered by this model and toolbox.

10:00 무선 전원에 의한 리튬이온 배터리 충전
William von Novak, Principal Engineer, QUALCOMM
Wireless charging for portable devices is becoming more popular, with several competing technologies currently on the market. Each has its drawbacks and benefits, and each presents different challenges for charging of lithium ion batteries. Tightly coupled technologies are highly efficient but tend to concentrate heat dissipation in the area near the battery; loosely coupled technologies are less efficient overall but result in more distributed heating. In addition, integration of the battery with common PMIC's (power management IC's) and portable device chipsets presents design challenges to the power system designer, including issues during dead battery startup and charge termination. This talk will provide an overview of the various types of wireless charging, along with their relative benefits and drawbacks, and will present some specific test results for charging on a loosely coupled (A4WP compliant) system. It will also present some general guidelines for designing wireless power systems to be compatible with lithium ion battery systems.

10:30 휴식시간 및 전시/포스터 관람

11:00 프레젠테이션 타이틀은 추후 공지
Rachid Yazami, PhD, Professor, School of Materials Science and Engineering, Nanyang Technological University, Singapore
Abstract not available at time of printing. Visit www.KnowledgeFoundation.com for the latest Program updates

11:30 마이크로파이버/나노섬유 배터리 분리기
Brian Morin, President and COO, Dreamweaver International
Current stretched porous film battery separators for lithium ion batteries are thin, strong, and provide a good barrier between electrodes, at the cost of having very high internal resistance and low ionic flow. In this work, linear nanofibers and microfibers are combined in wet laid nonwoven processes to give separators that are strong and thin, but have higher porosity (60%) and much higher ionic flow. Batteries made with these separators are able to give similar performance at much higher electrode coat weights, reducing the surface area of both current collectors and separator and also the volume of electrolyte needed. Total mass reduction can be as high as 20% (1.3 kg/kWh), with raw material cost savings of over 25% ($55/kWh). Volume savings are 0.5 liters/kWh. Batteries made with similar construction show much higher charge and discharge rate capability. Temperature stability is also improved, from a current stability temperature of about 110ËšC up to 175ËšC. Applications include all power source applications that require high energy density, high power, high temperature stability, including cell phones, laptop and tablet computers, power tools, and electric and hybrid vehicles.

12:00 새로운 열측정을 통한 리튬이온 배터리 형성 프로세스 개발
Jeff Xu, PhD, Principal Scientist, Powertrain Controls, Engine & Vehicle R&D Department Southwest Research Institute
An important step often overlooked or rarely investigated in lithium-ion battery manufacturing is the formation process. The formation process is the first full charging cycle of a lithium ion battery, which activates the cells before the lithium-ion cells can be used. The presentation will focus using novel thermal measurement tool to monitor heat profile during the first charging/discharging cycle of new cells. The novel formation protocol can thus be developed to determine the impact of the Lithium-ion battery formation process on battery performance such as capacity, cycle life, and safety.

12:30 폐회

* 주최측 사정에 따라 사전 예고없이 프로그램이 변경될 수 있습니다.

 

 
전시회 전시

이 컨퍼런스에서는 전시와 스폰서에 관한 다양한 옵션이 마련되어 있습니다. 특히 호평을 얻고 있는 옵션은 아래와 같습니다. 자세한 사항은 웹페이지 상단 전시 안내 PDF 링크를 통해 확인하시거나 문의해 주세요.

10x10 피트 전시 부스 비용:2,999달러

패키지 내용:
  • 전체 세션룸에 인접한 10x10 피트 부스
  • 풀 컨퍼런스 패스 1개
  • 전시회장에만 입장 가능한 부스 담당 직원용 패스 1개(패스 추가시 1개에 149달러)
  • 컨퍼런스 자료 1부
  • 컨퍼런스 자료 바인더에 8.5 x 11인치 흑백 광고 삽입(199달러의 추가요금으로 컬러 광고로 변경 가능)
  • 1회만 이용 가능한 컨퍼런스 참가자 메일링 라벨 1부를 컨퍼런스 종료 후 송부
  • 유망 고객에게 공동 메일링 서비스
  • 컨퍼런스 웹사이트 전시기업 섹션에 전시기업 리스트와 로고 게재(귀사 웹사이트 상호 링크 포함)
  • 메인 프로그램 'Product Showcase'에서 15분간 프레젠테이션
  • 귀사 웹사이트 링크를 컨퍼런스 전자판 뉴스레터에 게재
  • 메인 컨퍼런스 브로셔에 전시기업으로 게재 (기한내 신청한 전시기업만)
 
 

Poster Space Reservation fee:
US $79 (you must be registered for the Conference)
The academic/government rate is extended to all participants registering as full time employees of government and universities. To receive the academic/government rate you must not be affiliated with any private organizations either as consultants or owners or part owners of businesses.
 

Discount Accommodations and Travel:
A block of rooms has been allocated at a special reduced rate. Please make your reservations by November 12, 2012 to obtain this rate. When making reservations, please refer to The Knowledge Foundation. Contact The Knowledge Foundation if you require assistance.

Conference Venue:
Hyatt Mission Bay Resort & Marina
1441 Quivera Road
San Diego, CA  92109




 

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