모빌리티를 위한 전기차 섀시 배너
e모빌리티의 미래를 선도하는 데 도움을 드립니다.

열폭주 전파 및 배터리 조립부터 e모터와 그 이상까지, 3M에서 영감을 얻어보세요.

3M 전기차 전문가에게 문의하기

전기차 배터리 및 e파워트레인 설계 및 제조 솔루션

강력하고 신뢰할 수 있으며 확장 가능한 EV 배터리 및 e파워트레인 설계를 제공하는 방법을 확인하세요. 열폭주 보호, 배터리 조립 및 분해, e모터 조립 등과 관련된 어려운 문제를 해결하세요. 생산의 문제점을 극복하고 최적화하세요.

3M은 리튬 이온 배터리 기술에서 입증된 세계적 수준의 전문성과 100년 이상의 자동차 산업 경험을 결합합니다. 우리의 엔지니어들은 귀하의 설계 요구 사항을 이해하기 위해 함께 협력할 것이며, 우리의 배터리 부품 테스트 실험실은 다양한 응용 시뮬레이션 테스트 방법을 갖추고 있습니다. 글로벌 규모와 공급 원천 덕분에 도움은 멀리 있지 않습니다.

귀하가 e모빌리티의 미래를 선도함에 따라 3M은 설계부터 납품 및 그 이상까지 항상 귀하의 곁에 있을 것입니다

파워트레인 설계 문제 탐구

배터리 열폭주

셀 간 열폭주 전파 및 배출 경로 보호 솔루션

  • 열폭주 아이콘 - 원 안에 불꽃과 그것을 가로지르는 선

    당사의 첨단 소재를 사용하여 배터리 설계에서 열폭주 전파를 완화하고 배출 경로를 보호하는 데 도움을 드립니다.

    선택된 차단 소재는 낮은 열전도성과 뛰어난 온도 안정성을 높은 전기 저항성, 내화성 및/또는 압축 성능과 결합합니다. 이제 어려운 조건에서도 최적의 배터리 성능을 유지할 수 있습니다. 응용 분야에는 셀과 배터리 모듈 간, 덮개 아래 등이 포함됩니다.

    당사의 첨단 배출 경로 보호 소재는 높은 온도 안정성과 강력한 단열성을 결합할 수 있습니다. 열폭주가 발생하면 고속으로 배출되는 가스를 배터리 덮개 및 인접 셀을 포함한 주요 구성 요소로부터 격리할 수 있습니다.

    배터리 기술 분야에서 입증된 전문성과 광범위한 배터리 소재 테스트 역량을 갖춘 3M 전문가들은 귀하의 요구에 맞는 차단 솔루션을 식별하기 위해 협력할 수 있습니다. 어떻게 도와드릴 수 있는지 알려주세요.

    보기:
     

전기차 배터리 케이스 다이어그램, 3M의 셀 위 배터리 소재 및 배출 경로 보호 소재 사용 위치 표시

  • 1 00:01:27,750 --> 01:30:27,750 Text: 3M. Science. Applied to Life. ePowertrain Solutions: 3M Testing Capabilities. A lot filled with many vehicles. A man wearing safety glasses addresses the viewer. A machine issues fire. Two workers look at a piece of paper-like material that's been burned by the machine. Text: Mark Fairbanks. 3M Lead Verification and Validation. A machine issues flames and sparks. Three batteries. A battery pack structure. A worker pours a substance into a machine as another worker observes. A machine issues fire at a paper-like material. Two workers analyze the material. 2 00:02:15,083 --> 01:33:15,083 A worker puts a metal box over batteries that have been taped together. Mark connects a wire to a metal structure. Mark walks through a lab. He approaches a coworker. They work on computers together. A machine goes up in smoke in a control room. Mark and a coworker walk down a hall. Mark addresses the viewer. Text: We'll help you drive the future of eMobility. Contact 3M battery experts today. www.3m.com/evbattery. 3M. Science. Applied to Life. 3M 2023. All rights reserved. 3M is a trademark of 3M. Fades to black.

    3M 기술자가 토치&그릿 테스트를 진행 중입니다.

    설명: 3M 기술자가 토치&그릿 테스트를 진행 중입니다.

  • 첨단 배터리를 위한 첨단 테스트

    자동차 전기화의 신속한 진화는 우리가 다양한 전기차 배터리 응용에서 제품을 어떻게 사용할 수 있는지, 미래를 위해 어떻게 혁신할 수 있는지 완벽히 이해할 필요가 있음을 의미합니다. 3M이 어떻게 첨단 소형 규모 테스트 능력을 활용하여 OEMs에게 대규모 영향을 전달하는지 살펴보세요.

    더 많은 정보를 보려면:
     

배터리 조립/해체

전기차 배터리 조립 및 해체 솔루션

  • 아이콘 - 두 개의 플랫폼이 화살표로 각각 외부와 내부를 가리키는 모습

    배터리 접합 성능을 최적화하는 혁신적인 구조용 접착제를 찾으세요. 내구성, 신뢰성 등을 높이세요.

    당사의 구조용 접착제는 셀-투-팩과 같은 배터리 설계 트렌드를 지원하며, 다양한 재료 간 접합 및 경량화와 같은 주요 조립 도전 과제를 해결하는 데 도움을 줍니다.

    무게 추가 없이 스트레스를 견디는 샤시 장착 솔루션을 즐기세요. 당사의 마찰 쉼은 더 작고 가벼운 볼트와 조임기를 사용하여 무거운 배터리 팩의 무게를 견디는 데 도움을 줍니다. 알루미늄, 전기 도금, 도료 및 복합 재료 표면과 같은 다양한 접합 표면과 작업할 수 있습니다. 또한 부품을 축소하고 조립 효율성을 향상시키는 데 도움을 줄 수 있습니다.

    100년 넘는 역사를 자랑하는 3M의 접착제, 밀폐제, 필름, 조임기 및 테이프는 다양한 산업에서 사이클 시간을 단축하고 조립 효율성을 향상시키는 데 도움이 되었습니다. 우리에게 귀하를 위해 무엇을 할 수 있는지 알려주세요.

전기차 배터리 다이어그램, 3M 배터리 솔루션이 적용될 수 있는 위치 표시

(C) 셀 간 부착


(D) 밀폐


(E) Pack-to-chassis attachment


특수 접착


*이 조립 제품은 산업용 제품으로, 자동차 응용을 위해 설계된 것이 아닙니다. 또한 모든 조립 제품이 자동차 응용을 위해 테스트되거나 검증된 것은 아닙니다. 전체 자동차 사용 소재면허 성명서를 읽어보세요 (PDF, 67.2KB)

**전체 접착 및 결합 솔루션 사용 목적 및 제한 사용 성명서를 읽어보세요 (PDF, 95.8 KB)

***전체 밀폐 사용 목적 및 제한 사용 성명서를 읽어보세요 (PDF, 94.9 KB)


서비스성의 중요성: 수리, 재사용 및 재활용

  • 잎 아이콘으로 표시된 배터리 재활용

    EV 배터리의 서비스성은 중요합니다. 수리가 필요할 때는 배터리 케이스와 덮개가 쉽게 열릴 수 있어야 합니다. 재사용할 때는 구성 요소를 손상시키지 않고 배터리를 해체해야 합니다. 수명이 다해 폐기할 때는 알루미늄, 구리 및 코발트, 니켈, 리튬과 같은 귀중한 광물을 추출할 수 있어야 합니다.

    당사의 밀폐제는 해체 과정을 단순화하는 데 도움을 줄 수 있습니다:
     

    산업은 배출량을 줄이고 2050년 기후 목표를 달성하기 위해 수리, 재사용 및 재활용이 중요할 것입니다. 서비스 가능성을 제공하는 솔루션이 이 방정식의 중요한 부분이 될 것입니다.

전기 절연/연결

EV 배터리 전기 절연 및 연결 솔루션

  • 번개 아이콘과 네 개의 화살표가 향하는 배터리 다이어그램

    당사의 전기 차단 소재, 수지 및 테이프 다양한 포트폴리오로 효율적인 에너지 절약형 배터리 설계를 해제하세요.

    셀 캔, 콜드 플레이트, 배터리 모듈 및 기타 고가 부품을 절연하세요. 고온 전기 절연 응용에서 강력한 전압 내구성, 열전도성 및 장기 다이렉트리 장력을 달성하세요. 전기 분말 수지로 금속 및 전도체 표면을 보호하세요. 이는 복잡하고 곡선 모양의 표면에 쉽게 접착할 수 있습니다.

    3M은 리튬 이온 배터리 설계에 대한 세계적인 전문 지식을 전자 접착 분야에서 수십 년간의 경험과 결합합니다. 당사의 절연 및 연결 솔루션이 귀하의 설계 요구 사항을 충족시킬 수 있는 방법을 확인하세요.

    보기:
     

EV 배터리 다이어그램에 3M 솔루션이 적용될 수 있는 위치를 표시합니다.

(A) 콜드 플레이트 절연/모듈 하우징 절연

경량화/열 관리

경량화/열 관리 솔루션

  • 경량화 및 열 관리 아이콘 - 깃털과 온도계

    전기차 배터리 응용분야에서 경량화와 열을 제어하기 위한 혁신적인 필러와 재료를 사용해보세요.

    글라스버블을 사용해 경량화를 달성하세요. 글라스버블은 작고 속이 비어 있으며 열을 차단하는 경량 필러입니다. 다양한 레진에서 무거운 필러를 대체할 수 있으며, 단열 요구 사항을 충족하면서도 높은 함량에서도 원하는 점도를 유지할 수 있습니다. 글라스버블은 시트 성형 복합재(SMC)의 배합에 사용될 수도 있으며, 배터리 케이스와 같은 중요한 구성 요소에 적합한 필러입니다.

    전기 절연에 영향을 미치지 않으면서 효과적인 폴리머의 열관리를 위해서는 Boron Nitride Cooling Fillers를 사용해보세요. 3M™ Boron Nitride Cooling Fillers는 방열접착제, 케이블 코팅, 배터리 하우징, 셀 사이의 방열패드, 셀 하단의 갭필러 등 다양한 응용분야에 사용될 수 있습니다.

    더 많은 관리가 필요하신가요? 예측할 수 없는 뜨거운 환경과 추운 환경에서 EV 배터리를 최적의 온도로 유지해 보세요. 3M BNCF는 압축성이 매우 뛰어나 배터리 팩과 배터리 커버 사이의 좁은 공간에서도 이상적으로 사용 될 수 있습니다.

    3M은 필러와 방열소재 기술에 있어 오랜기간의 전문 지식을 보유하고 있습니다. 3M 전문가를 만나보세요.

    동영상 보기:
     

EV 배터리 인클로저 다이어그램에 3M 경량화 및 열 관리 솔루션이 적용될 수 있는 위치를 표시합니다.

(A) 열 차단 매트

(B) 열 전도성 첨가제

(C) 열 차단 및 경량화 첨가제

쿠셔닝

쿠셔닝 솔루션

  • 쿠션 솔루션 아이콘 - 쿠션에 힘이 가해지는 모습

    오래 지속되는 쿠션 성능, 설치의 용이성, 수동 또는 자동 조립 라인과의 호환성을 즐기세요.

    셀 사이의 쿠션을 위해 설계된 당사의 미세세포 폴리우레탄 쿠션 폼은 압축 테스트를 거쳤으며 충전 사이클 동안 배터리 셀이 팽창하고 수축할 때 일관된 중간 압력을 제공합니다. 셀 수준에서의 제어된 압축은 높은 압력과 고르지 않은 압력 분포와 관련된 성능 저하를 줄이는 데 도움이 됩니다.

    3M에서는 자동차 OEM과 끊임없이 협력하여 요구 사항을 해결하기 위해 노력하고 있습니다. 연락 주시면 어떻게 도와드릴 수 있는지 알아보겠습니다.
     

EV 배터리 인클로저 다이어그램에 3M 쿠션 솔루션이 적용될 수 있는 위치를 표시합니다.

e모터

e모터 조립 및 제조 솔루션

  • 전기 기능이 포함된 내연기관 엔진 아이콘

    다양한 구성 요소와 응용 분야에서 e모터 제조를 간소화하는 방법을 알아보세요.

    슬롯, 웨지 및 단계에서 바니시와 수지를 전기 절연 슬롯 라이너로 대체할 수 있습니다. 이 슬롯 라이너는 경화 중에 팽창하고 접착합니다. 구조용 접착제를 사용하여 탁월한 금속 접착 강도와 높은 온도 안정성을 균형 있게 유지하면서 적층 스택 조립을 향상시킬 수 있습니다.

    우리는 전기 공학과 재료 과학에 대한 깊은 전문 지식과 자동차 산업에서 한 세기의 경험을 보유하고 있습니다. e모터 설계를 최적화하고 확장할 수 있도록 도와드리겠습니다.

3M 솔루션이 적용될 수 있는 e모터 다이어그램


e파워트레인 트렌드

3M에서는 e파워트레인 OEM이 직면하는 문제에 대해 항상 고민하고 있습니다. 최신 정부 규제, 산업 표준에 대한 탐색과 앞으로의 방향성에 대한 고민까지 우리는 도와드릴 준비가 되어 있습니다.

  • (DESCRIPTION) Logo, 3M. Text, Science, Applied to life. Addressing Sustainability and Recyclability in Cell-to-Pack Designs. Slide title, Battery E V does not equal Zero Emission... Slide text, Battery material and cell production. Research estimates B E Vs to be 40-50% higher in C O2 footprint primarily contributed by energy consumption in battery material and cell making, causing a carbon debt to be repaid in the total life cycle of B E V. Use phase. B E Vs have higher tank—to—wheel efficiency therefore contributes less carbon footprint than engine vehicles does on a comparable kg.C O 2/K M basis. The proportion of green energy in the grid could further positively reduce carbon footprint caused by vehicle use. (SPEECH) When it comes to battery electric vehicles, we also have to review through the lens whether battery EV is creating sustainability benefits. Battery EV is invented for such a purpose. However, it's not as green as we imagined. The primary reason is the manufacturing process of battery is very energy-intensive, especially during mining and processing steps. Research shows that the initial carbon footprint of a battery EV is 40% to 50% higher than internal combustion engine vehicle. So battery vehicles has a higher carbon debt that has to be repaid during its entire life cycle in the use phase as battery EV uses electricity and has a higher energy efficiency that generates lower carbon footprint. But some researchers also suggest that battery vehicles need to drive 40,000 to 60,000 kilometers before they can clean the debt of carbon footprint created at manufacturing phase. The average lifetime mileage of a passenger vehicle is normally around 120,000 to 160,000 kilometers. That means a battery EV is not able to create environmental benefit until one third of its lifespan. These facts and calculations remind us how important it is to extend the lifespan of EV battery and get more efficiency out of its entire life cycle. That's why the second-life use of a battery and the end-of-life handling are so important. (DESCRIPTION) Slide title, Real life use case of sustainable and recyclable EV battery. 1, Rework and Repair. In the process of battery pack manufacturing and daily used of E Vs, various causes can lead to failures in components and cells within battery system that need rework and repair, 2, Reuse. With capacity, durability and performance remaining, retired E V batteries can be reused in secondary life for energy storage, light mobility and noncritical applications. 3, Recycle. At the end of life, metals such as aluminum and copper, and precious minerals, such as cobalt, nickel, and lithium, need to be extracted and recycled from spent batteries. (SPEECH) Here are a few real-life use cases of how to enhance the sustainability element of EV battery. First, batteries need to be reworked and repaired due to defects caused in manufacturing process and use phase. Second, after retiring from its primary use, a battery can be repurposed and reused for second life. And finally, at end-of-life, batteries need to be recycled. In the next few slides, I'll talk more details of each use case. (DESCRIPTION) Slide title, Repair remains a required use case for E V battery. Battery failure modes, Cell defect, Harsh working condition (e.g., water ingress), car crash, other components failure. At the center of these modes is battery failure. Text, Lithium-ion battery price survey results: volume-weighted average. Graph, Battery pack price (dollars per kilowatt hour. From 2010 to 2021, the price decreases from 1220 to 132. The solid line plateaus while a dotted line continues decreasing. (SPEECH) An EV battery needs a repair for two reasons. First, battery will experience failures. Some are caused by manufacturing defects. Some are caused by unexpected conditions in daily use, such as car crash, and this type of battery failures is inevitable. And since battery cost is significant in total vehicle cost, and it will probably remain significant for another few years, there's a good economic reason to make EV batteries repairable. (DESCRIPTION) Slide title, Reuse improves battery lifetime cost effectiveness. Use of second life battery. A house, electric bike, solar panels. Graph, Price comparison of new battery and second life battery. New Battery Price (2019), approximately 150, Second Life Battery Buying Price, approximately 75, Repurpose cost, approximately 90, Second Life Battery Selling Price, approximately 90. (SPEECH) A retired battery can be repurposed and reused for non-critical applications, such as temporary energy storage for homes, batteries for scooters, and components for large energy storage facilities. Research shows the cost of repurposing an EV battery is nearly half of a new battery. From economic standpoint, this is quite attractive. (DESCRIPTION) Slide title, Recycling is attractive for cost and carbon footprint reasons. At the left, text, Circular economy motivation. Battery total cost. Manufacturing 19%, Material 72%, Battery material cost, Other: 5%, Housing: 9%, Electrolyte: 10%, Anode: 15%, Separator: 17%, Cathode: 44%, At the right, Emission reduction motivation. In two graphs, Battery Cell Manufacturing Emissions and Battery Recycling Emissions, the emission in kilograms C O2 e kilogram per battery range from 8 to 10. (SPEECH) And finally, recycle and end of life, the materials inside battery cells are valuable and important as natural resource supply is limited. In addition to the economic aspect, energy-saving aspect is also important. Research shows that the recycle process commonly used today is comparable to making brand new batteries. This indicates that the new technologies need to be developed to reach a greener recycle process. (DESCRIPTION) Technical Information: The technical information, guidance, and other statements contained in this document or otherwise provided by 3M are based upon records, tests, or experience that 3M believes to be reliable, but the accuracy, completeness, and representative nature of such information is not guaranteed. Such information is intended for people with knowledge and technical skills sufficient to assess and apply their own informed judgment to the information. No license under any 3M or third party intellectual property rights is granted or implied with this information. Product Selection and Use: Many factors beyond 3M's control and uniquely within user's knowledge and control can affect the use and performance of a 3M product in a particular application. As a result, customer is solely responsible for evaluating the product and determining whether it is appropriate and suitable for customer's application, including conducting a workplace hazard assessment and reviewing all applicable regulations and standards (e.g., OSHA, A N S I, etc.). Failure to properly evaluate, select, and use a 3M product and appropriate safety products, or to meet all applicable safety regulations, may result in injury, sickness, death, and/or harm to property. Warranty, Limited Remedy, and Disclaimer: Unless a different warranty is specifically stated on the applicable 3M product packaging or product literature (in which case such warranty governs), 3M warrants that each 3M product meets the applicable 3M product specification at the time 3M ships the product. 3M makes no other warranties or conditions,express or implied,including,but not limited to,any implied warranty or condition of merchantability,fitness for a particular purpose,or arising out of a course of dealing,custom,or usage of trade. If a 3M product does not conform to this warranty, then the sole and exclusive remedy is, at 3M's option, replacement of the 3M product or refund of the purchase price. Limitation of Liability: Except for the limited remedy stated above, and except to the extent prohibited by law, 3M will not be liable for any loss or damage arising from or related to the 3M product, whether direct, indirect, special, incidental, or consequential (including, but not limited to, lost profits or business opportunity), regardless of the legal or equitable theory asserted, including, but not limited to, warranty, contract, negligence, or strict liability. Automotive and Aerospace Solutions Division 3M Center. St. Paul, Minnesota 55144-1000. Phone: 1-800-328-1684. Web: w w w dot 3M dot com slash e v battery. 3M, Command, Dual Lock, Dyneon, lnteram, Isoloss, Post-it, Scotch, Scotch-Weld, Scotchcal, Scotchcast, Scotchlite, Thinsulate and Three-M-lte are trademarks of 3M Company and its affiliates. All other trademarks are the property of their respective owners. Copyright 3M 2023 All rights reserved. Logo, 3M. Text, Science, Applied to life.

    지속 가능성 다이어그램
    EV 배터리 지속 가능성 사용 사례

    효과적인 EV 배터리 수리, 재사용 및 재활용이 어떻게 더 지속 가능한 미래로 이끌 수 있는지 확인해 보세요.

  • (DESCRIPTION) Logo, 3M. Text, Science, Applied to life. Addressing Sustainability and Recyclability in Cell-to-Pack Designs. What are the sustainability and recyclability challenges in C T P designs? (SPEECH) We have talked through the reasons why sustainability and recyclability are important to EV batteries. Now let's put them in the context of cell-to-pack design and see what they mean from a battery design point of view. (DESCRIPTION) Slide title, Evolution of battery pack designs — Cell-to-modules. Pouch, Prismatic, Cylindrical, German O E M Design, 35 modules, Chinese O E M Design, 12 modules, American O E M design, 21 modules. More text follows. (SPEECH) The traditional approach to construct a battery pack is first to assemble battery cells into modules and then modules into packs. Packaging at module and pack level adds weight and redundancy and therefore reduces energy density. (DESCRIPTION) Pouch, Prismatic, Cylindrical, American O E M Design, Large Modular Architecture, European O E M NextGen Platform, Large Modular Architecture, American O E M Design, Large Modular Architecture. More text follows. (SPEECH) Well, a cell-to-pack design significantly reduces the number of modules and even completely removes the module level assembly, building the whole battery pack from cell level. The benefit is that this design reduces the complexity of battery architecture, enables higher manufacturing process, and lower cost. (DESCRIPTION) Slide title, Evolution of battery pack designs — Use of bonding material. Heading, Featured design concepts. Slide text, Non—cell components and space reduced to minutesimum level to maximize energy density and drive range. Cross members in battery tray and on top of lid eliminated. Battery cells, cooling system and lid become structural components. More text follows. (SPEECH) An important feature of cell-to-pack design is to use more bonding materials to assemble the whole structure together. For instance, thermal conductive structure adhesive is used to bond the battery cells to cooling plate, potting resins, or foams are used to bond the cells, battery trays, and lid together. (DESCRIPTION) Slide title, Reconcile between CTP and repair, reuse, recycle. Life Cycle of E V Battery. In a diagram, batteries undergo repair, reuse, and recycling. Heading, Application Scenarios. Slide text, Rework and repair. In near future, defect rate of battery cell production and battery system design is still too high to disregard the need of replacement of battery cells. Cost of batteries is too high for a disposable business model and remains necessary as a service item. Heading, Reuse. Slide text, In secondary life reuse for energy storage, battery cells/modules need to be tested for state of health and arrayed in the new pack. Spent battery packs need to be dismantled to at least module level. Heading, Recycle. More text follows. (SPEECH) Well, as mentioned before, the sustainable elements of battery design require us to consider repair and rework, reuse, and recycle. This target is seemingly going against cell-to-pack design in which battery structure is more compact, less modularized, and more difficult to dismantle. So there is a strong need to reconcile these two trends. We can take a closer look at the major steps of battery repair, reuse, and recycle to get a sense of what might be the problems to solve. (DESCRIPTION) Heading, #1 Problem to be solved: Characterization of used L i B. Need for efficient selection for second life and recycling decision. Heading, Inspection. Slide text, At the end of the first life cycle, the lithium—ion batteries are collected and inspected visually or by air pressure for obvious defects such as mechanical damage or leaks. Heading, Data Evaluation. Slide text, By evaluating the usage data such as self-discharge, charge/discharge process, and state variables, a decision can be made on the further use of the battery without any major measurement effort. Heading, State of Health (S O H) Determination. Bullet points, Capacity and power determinations are costly and time consuming, as they require the use of expensive measuring equipment. By measuring the chemical and physical properties of the lithium—ion battery, such as the cathodic galvanostatic pulses or the A C measurement, the battery condition can be determined. Heading, Resistance Determination. More text follows. (SPEECH) The first problem to solve is to understand the health and performance level of used lithium ion batteries. Data such as battery chemistry, form factor, years of use, origination are used to be collected for analysis. State of health needs to be determined in a cost-effective way. And similarly, internal resistance of battery needs to be tested. All the data combined together serve the purpose to determine whether a battery can be repaired or reused or should be recycled. (DESCRIPTION) Slide title, #2 Problem to be solved: Disassembly. Heading, Cell-to-module. Slide text, Pouch. Modules are bonded to coiling plate with semi-structural adhesive. Inside the modules, cell tabs are welded together. Between cells are cushioning foams and the bottom of the module is potted with gap filler. Prismatic. Cell poles are connected and welded together. Battery cells are often bonded tightly to side plates with adhesives. Between the cells could be separators made from non-woven materials. Cylindrical. Large number of cells welded or bonded to cell connection and frame. Potting material between cells is difficult to remove. Heading, Cell-to-pack. Slide text, Battery pack design with structural integrity casts significant challenge to disassembly process when needed. (SPEECH) The second problem to solve is to disassemble the battery pack. As we mentioned, battery packs designed to achieve structural integrity has brought significant challenges for disassembly, and we'll talk about this point later in details. (DESCRIPTION) Slide title, #3 Problem to be solved: An easy recycle process. Heading, Recycle Process. In a diagram, a battery goes through a series of steps using N1, heat, hot nitrogen gas that utilizes exhaust heat, and pure cathode and anode powder. In the final step is lithium with manganese, nickel, and cobalt. Heading, Efficiency and Financials. Text, Aluminum Recovery Rate, 99.2%. Electrode Powder Recovery Rate, 99%. Electrolyte Recovery Rate, 50%. Copper Recovery Rate, 99%. Metal parts Recovery Rate, 99.5%. Plastic Recovery Rate, 80%. Total Power, 580 kilowatts, Inert Gas, 400 M 3. Other statistics follow. (SPEECH) The final problem to solve is an efficient recycle process. As we mentioned before, a recycle process needs to be both cost-effective and green. Valuable materials such as lithium and cobalt need to be recovered as much as possible. Important metals like aluminum and copper also need to be recovered with a fine design process. The energy consumption and overall cost also need to be attractive. (DESCRIPTION) Technical Information: The technical information, guidance, and other statements contained in this document or otherwise provided by 3M are based upon records, tests, or experience that 3M believes to be reliable, but the accuracy, completeness, and representative nature of such information is not guaranteed. Such information is intended for people with knowledge and technical skills sufficient to assess and apply their own informed judgment to the information. No license under any 3M or third party intellectual property rights is granted or implied with this information. Product Selection and Use: Many factors beyond 3M's control and uniquely within user's knowledge and control can affect the use and performance of a 3M product in a particular application. As a result, customer is solely responsible for evaluating the product and determining whether it is appropriate and suitable for customer's application, including conducting a workplace hazard assessment and reviewing all applicable regulations and standards (e.g., O S H A, A N S I, etc.). Failure to properly evaluate, select, and use a 3M product and appropriate safety products, or to meet all applicable safety regulations, may result in injury, sickness, death, and/or harm to property. Warranty, Limited Remedy, and Disclaimer: Unless a different warranty is specifically stated on the applicable 3M product packaging or product literature (in which case such warranty governs), 3M warrants that each 3M product meets the applicable 3M product specification at the time 3M ships the product. 3M makes no other warranties or conditions, express or implied,including, but not limited to,any implied warranty or condition of merchantability,fitness for a particular purpose,or arising out of a course of dealing,custom,or usage of trade. If a 3M product does not conform to this warranty, then the sole and exclusive remedy is, at 3M's option, replacement of the 3M product or refund of the purchase price. Limitation of Liability: Except for the limited remedy stated above, and except to the extent prohibited by law, 3M will not be liable for any loss or damage arising from or related to the 3M product, whether direct, indirect, special, incidental, or consequential (including, but not limited to, lost profits or business opportunity), regardless of the legal or equitable theory asserted, including, but not limited to, warranty, contract, negligence, or strict liability. Automotive and Aerospace Solutions Division. 3M Center. St. Paul, Minnesota 55144-1000. Phone: 1-800-328-1684. Web: w w w dot 3M dot com slash e v battery. 3M, Command, Dual Lock, Dyneon, lnteram, Isoloss, Post-it, Scotch, Scotch-Weld, Scotchcal, Scotchcast, Scotchlite, Thinsulate and Three-M-lte are trademarks of 3M Company and its affiliates. All other trademarks are the property of their respective owners. Copyright 3M 2023. All rights reserved. Logo, 3M. Text, Science, Applied to life.

    문서와 세 개의 배터리 아이콘
    셀-투-팩 디자인에서의 지속 가능성과 재활용성 문제

    셀-투-팩 디자인 트렌드가 어떻게 독특한 지속 가능성과 재활용성 문제를 초래하는지 자세히 알아보세요.

  • (DESCRIPTION) Logo text, 3M Science. Applied to Life. Addressing Sustainability and Recyclability in Cell-to-Pack Designs How are O.E.Ms addressing these challenges? Copyright 3M 2023. All Rights Reserved. 3M Public. (SPEECH) In the next two slides, I'll share a few specific design concepts that are addressing battery repair and disassembly challenges. Not every of them are realistic for real application, but they might be able to spark our thoughts regarding how to adapt a design approach to include more sustainability elements in a battery design. (DESCRIPTION) Text, Easy access and operation. On the left is a rectangle split down the middle longways with raised sides that lower down labeled Space and access for operation. Text underneath, A common challenge for operators to dismantle battery packs is limited space and access for operation. This example of a design of the lower tray of the battery consists of a bottom plate and a side frame that can be disassembled to allow access and sight that are necessary for the next operations. On the right is a rectangle with horizontal slats that fit cooling plates labeled Design for maintenance. Text underneath, Battery cells, cooling plates and holders are delicately designed to allow cells to be checked and text obscured individually. Mechanical connections text obscured used to hold the structure together. (SPEECH) The first example on the left is a concept to solve the issue of line of sight. a common challenge for operators to dismantle battery packs is limited space and access for operation. This example shows a design of a lower battery tray that is made up of a bottom plate and a side frame that can be disassembled to allow access inside that are necessary for next operations. The example on the right allows each battery cell to be checked and replaced individually without tearing down the entire module. (DESCRIPTION) Text, Modular disassembly. On the left is a rectangle broken up into a top half and bottom half that fits two rectangles that lock into place in each half. Text underneath, Strained module assembly. Use mechanical fixtures such as springs and buckel to fix modules with robustness desired. Reversible process allows easy disassembly. On the right is a rectangle with 10 compartments that each slide down and out. Text underneath, Swappable module. Bottom of battery tray is designed to be openable at module level. Delicately designed module structure text obscured system allows each individual module to be text obscured pack and replaced. (SPEECH) The third example on the left shows a concept to use springs and buckles to fix modules to battery pack frame. Instead of using adhesives to bond permanently, this approach allows easy disassembly. And the last example on the right refers to a concept that allows battery replacement at the module level. The bottom of the battery tray is designed to be openable at module level. And a delicate designed module structure and a connection system allows each individual module to be separated from pack and replaced. (DESCRIPTION) Text, How can 3M help O.E.Ms achieve their sustainability targets? (SPEECH) Now, let's talk about how 3M is able to help OEMs to achieve battery designs with sustainability elements. (DESCRIPTION) Text, Achieving CTP design with high standards for sustainability. Reuse, Recycle, Repair & Rework. Three materials layered on top of one another. Text, 3M Debond-on-Demand Technology. Thermally induced, Mechanically debond, Light induced, Electricity induced. (SPEECH) As we mentioned before, one of the important problems to solve in achieving cell-to-pack design without compromising on sustainability standard is to achieve battery disassembly. 3M has a very extensive technology platform to realize demand-on-demand, a solution feature that provides bonding strength at the desired level for working conditions, where it can be debonded as needed. Different mechanisms can be leveraged for debond that can be induced mechanically, or by heat, light, or even electricity. (DESCRIPTION) Text, Technical Information: The technical information, guidance, and other statements contained in this document or otherwise provided by 3M are based upon records, tests, or experience that 3M believes to be reliable, but the accuracy, completeness, and representative nature of such information is not guaranteed. Such information is intended for people with knowledge and technical skills sufficient to assess and apply their own informed judgment to the information. No license under any 3M or third party intellectual property rights is granted or implied with this information. Product Selection and Use: Many factors beyond 3M's control and uniquely within user's knowledge and control can affect the use and performance of a 3M product in a particular application. As a result, customer is solely responsible for evaluating the product and determining whether it is appropriate and suitable for customer's application, including conducting a workplace hazard assessment and reviewing all applicable regulations and standards (e.g., OSHA, ANSI, etc.). Failure to properly evaluate, select, and use a 3M product and appropriate safety products, or to meet all applicable safety regulations, may result in injury, sickness, death, and/or harm to property. Warranty, Limited Remedy, and Disclaimer: Unless a different warranty is specifically stated on the applicable 3M product packaging or product literature (in which case such warranty governs), 3M warrants that each 3M product meets the applicable 3M product specification at the time 3M ships the product. 3M MAKES NO OTHER WARRANTIES OR CONDITIONS, EXPRESS OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, ANY IMPLIED WARRANTY OR CONDITION OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR ARISING OUT OF A COURSE OF DEALING, CUSTOM, OR USAGE OF TRADE. If a 3M product does not conform to this warranty, then the sole and exclusive remedy is, at 3M's option, replacement of the 3M product or refund of the purchase price. Limitation of Liability: Except for the limited remedy stated above, and except to the extent prohibited by law, 3M will not be liable for any loss or damage arising from or related to the 3M product, whether direct, indirect, special, incidental, or consequential (including, but not limited to, lost profits or business opportunity), regardless of the legal or equitable theory asserted, including, but not limited to, warranty, contract, negligence, or strict liability. Automotive and Aerospace Solutions Division 3M Center St. Paul, MN 55144-1000. Phone: 1-800-328-1684. Web: www.3 M.com/ e v battery. 3M, Command, Dual Lock, Dyneon, Interam, ISOLOSS, Post-it, Scotch, Scotch-Weld, Scotchcal, Scotchcast, Scotchlite, Thinsulate and Three-M-Ite are trademarks of 3M Company and its affiliates. All other trademarks are the property of their respective owners. Copyright 3M 2023 All rights reserved Logo text, 3M Science. Applied to Life.

    배터리의 분해 영상
    재활용성 문제 해결 및 3M의 지원 방법

    다음 EV 배터리 디자인에서 더 지속 가능한 요소를 도입하도록 영감을 주는 디자인 개념을 보고, 3M 솔루션이 어떻게 도움이 되는지 이해하세요.

실험실에서 문서를 보고 있는 파란색 실험복과 보라색 장갑을 낀 두 사람
시작해봅시다

전 세계 자원과 공급원부터 개별 지원까지, 3M은 앞으로의 긴 여정에서 여러분과 함께합니다.

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