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Switch To Lithium-ion Battery: The Next Big Shift In the Indian Auto Space

2022-08-03
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India is in the midst of transition to electric vehicles (EVs). Several think-tanks including NITI Aayog and CEEW have predicted that there would be 80 per cent EV adoption in two wheelers and three wheelers by 2030. Even a conservative estimate predicts that there would be 6 million EVs in India by 2025.

Venkat Rajaraman, CEO & founder, Cygni

Lithium demand: The main driver for adoption is the FAME-II scheme, favorable state level polices, mandated emission reduction and proven lower lifecycle cost for electric vehicles. This EV adoption is also clearly driven by the Lithium batteries. Even at a conservative 40 per cent EV penetration, we would need about 60 giga-watt-hour of lithium-ion battery. Overall Lithium battery requirement will be much bigger because of applications such as telecom, rooftop solar, DG offset etc. In an optimistic scenario, this could be 150 giga-watt-hour of lithium requirement. Hence Lithium is going to drive India's EV revolution front and center.

India's EV ecosystem is unique. Indian population mostly rides on two wheelers and three wheelers, which constitutes over 80 per cent of the vehicles on the road. Disruption is clearly underway in this segment. There are also new players such as Bounce and Vogo, who are coming up with newer business models for e-mobility. Commercial three wheelers and L5 Loader vehicles are on the fastest mode of EV adoption. This disruption is driven by the rising fuel costs and favorable policy incentives.

Battery cost: There has been significant reduction in the cost of lithium-ion battery over the last decade, in accordance with Wright's Law. The cost has come from a cost of $1,000 per kilowatt hour in 2010 to about $150 per kilowatt hour. In spite of cost fluctuations over the last few quarters, the overall EV adoption can be directly linked to the fall in the Lithium-ion battery cost. So as the battery costs continue to fall, the demand for EV will continue to rise.

India recently launched Advanced Cell Chemistry - Production Linked Incentive (ACC-PLI) scheme for setting up 50 giga-watt-hour of lithium cell production. This scheme is technology and chemistry agnostic. With higher energy density and higher cycle life, the incentives are proportionately higher and is open for new technological innovation in cell chemistry.

Lithium-ion technology: Technology for Lithium batteries is constantly evolving. Until recently there are two main chemistries – LFP (Lithium Ferro Phosphate) and NMC (Nickel Manganese Cobalt). NMC chemistry has higher energy density and LFP has higher life cycle and is considered safer especially for Indian conditions. Even under NMC there are variants such NMC111, NMC622, NMC811 and so on (which specifies the percentage of Nickel, Manganese and Cobalt in a cathode of a lithium cell). Solid state batteries are inherently safer because they are nonflammable, and lot of research is going on in this area. Research is being done on silicon or a metal anode as well. Continuous research and constant technological improvement in Lithium battery is expected to continue throughout this decade.

Software and semiconductor: Battery Management System (BMS) is the brain behind Lithium battery, and it monitors, controls, and protects the battery against any abuse conditions. Typical BMS consists of high-end microcontroller and other active semiconductor components. It monitors and controls the Lithium battery through high-end algorithms and software. This is one area India can truly lead the rest of the world, due to India's inherent strength in software and semiconductor. BMS provides algorithms for estimation of state of charge, state of health, thermal management, cell balancing, state of safety etc. To get better performance, increased safety, and higher cycle life of the Lithium battery, software and semiconductor is going to play a key role.

Lithium availability: It is a well-known fact that India does not have the needed mineral reserve for lithium manufacturing. These reserves are predominantly available in Australia, Latin America, Democratic Republic of Congo, and certain East European countries. Lithium supply chain is dominated by China, controlling over 70% of the processing and material supply. India doesn't have any cell manufacturing yet with near zero presence in upstream manufacturing of cathode/anode manufacturing, chemical processing etc. This is one of the biggest challenges for India in switching to Lithium.

Urban mining and lithium-ion recycling: India has over 1 billion mobile phones and a few tens of millions of laptops and other electronic gadgets. Urban Mining is where you extract the key metals from the used batteries. It is shown elsewhere in the world that lithium-ion battery recycling can be done in zero effluent plants where we can recover over 90% of the metals. Now India could aspire to become the urban mining capital of the world. It is estimated that through recycling, we could produce about 80 giga-watt-hour of lithium capacity by 2030 meeting most of its demands through Urban Mining.

Safety: The key thing for India is going to be the safety of the battery in the vehicle. There has been a lot of focus on range of the vehicle, fast charging, battery cycle life, light weighting of the battery, affordability etc. But the key question that needs to be asked, is it safe for Indian conditions?

Testing standards: AIS-156 testing standard for Lithium battery is comparable to any international standard. These standard tests the battery pack for all electrical, mechanical, and thermal conditions. Standardization bodies are continuously working to improve the testing standards. Bureau of Indian Standards (BIS) recently came up with IS-17855 standard, which is the test specifications for Lithium-Ion battery pack performance. In this standard, BIS has come up with a new range of performance tests to measure energy efficiency, cranking power, fast charging efficiency, temperature dependent degradation, loss of charge during storage etc. Bureau of Energy Efficiency (BEE) also has recently come up with a Star Rating program for Lithium battery. The Star rating program from BEE has been successful in other products and it provides an easy-to-understand rating and consumers would be in a better position to distinguish various battery packs in terms of their safety, quality, etc.

In summary

The Indian automotive ecosystem is unique. The EV disruption is truly underway aided by rising fuel costs and favorable policy initiatives. The two wheelers and commercial three wheelers are on the fastest mode of EV adoption. Lithium-Ion battery will be pivotal to India's EV success. India can aspire to become the urban mining capital of the world by doing the Lithium recycling. India needs customized EV solution which are unique for Indian conditions and for the Lithium battery manufacturers the goal must be 100 per cent safety. The role of software and semiconductor in EV revolution is huge and India has an opportunity to lead the rest of the world in this segment. Going forward, with ongoing progress in battery technology, it is expected that these lithium-powered batteries will replace petrol/diesel as the source of power in vehicles.

参考译文
改用锂离子电池:印度汽车业的下一个重大转变
印度正处于向电动汽车(ev)过渡的过程中。包括NITI Aayog和CEEW在内的多家智库预测,到2030年,80%的电动汽车将采用两轮车和三轮车。据保守估计,到2025年,印度将有600万辆电动汽车。锂需求:采用的主要驱动因素是FAME-II计划、有利的州一级政策、强制减排和电动汽车已证实的较低生命周期成本。锂电池显然也推动了电动汽车的普及。即使在电动汽车渗透率达到40%的保守情况下,我们也需要大约60吉瓦时的锂离子电池。由于诸如电信、屋顶太阳能、DG补偿等应用,锂电池的总体需求将会大得多。在乐观的情况下,这可能是150吉瓦时锂的需求。因此,锂电池将推动印度的电动汽车革命,印度的电动汽车生态系统是独一无二的。印度人大多骑两轮车和三轮车,占道路上车辆的80%以上。这一领域的颠覆显然正在发生。此外,还有Bounce和Vogo等新玩家,它们正在为电子交通提出更新的商业模式。商用三轮车和L5装载机是电动汽车采用的最快模式。这种破坏是由不断上涨的燃料成本和有利的政策激励所驱动的。电池成本:根据莱特定律,锂离子电池的成本在过去十年中有了显著的降低。成本已从2010年的每千瓦时1,000美元降至每千瓦时约150美元。尽管过去几个季度的成本波动,但整体电动汽车的采用可以直接与锂离子电池成本的下降挂钩。因此,随着电池成本的持续下降,对电动汽车的需求将持续上升。印度最近推出了先进电池化学生产挂钩激励(ACC-PLI)计划,以建立50千兆瓦时的锂电池生产。这个方案与技术和化学无关。能量密度越高,循环寿命越长,对细胞化学的新技术创新就越有利。锂离子技术:锂电池技术在不断发展。直到最近,主要有两种化学物质——LFP(磷酸铁锂)和NMC(镍锰钴)。NMC化学具有更高的能量密度,LFP具有更高的生命周期,被认为是更安全的,特别是在印度条件下。即使在NMC下,也有诸如NMC111、NMC622、NMC811等变体(这指定了锂电池阴极中镍、锰和钴的百分比)。固态电池天生就更安全,因为它们是不易燃的,在这个领域有很多研究正在进行。对硅或金属阳极的研究也在进行中。锂电池的持续研究和技术改进有望在整个十年中持续下去。软件和半导体:电池管理系统(BMS)是锂电池背后的大脑,它监测、控制和保护电池免受任何滥用情况。典型的BMS由高端微控制器和其他有源半导体组件组成。它通过高端算法和软件对锂电池进行监控和控制。由于印度在软件和半导体方面的固有优势,这是印度可以真正引领世界其他国家的一个领域。BMS提供了用于估计充电状态、健康状态、热管理、电池平衡、安全状态等的算法。为了使锂电池获得更好的性能、更高的安全性和更高的循环寿命,软件和半导体将发挥关键作用。 锂的可用性:众所周知,印度没有制造锂所需的矿产储备。这些储备主要分布在澳大利亚、拉丁美洲、刚果民主共和国和某些东欧国家。锂的供应链由中国主导,控制着超过70%的加工和材料供应。印度还没有任何电池制造业,在阴极/阳极制造、化学加工等上游制造业几乎为零。这是印度转向锂电池的最大挑战之一。城市采矿和锂离子回收:印度有超过10亿部手机,几千万台笔记本电脑和其他电子产品。城市采矿是从用过的电池中提取关键金属。在世界其他地方,锂离子电池回收可以在零废水工厂完成,我们可以回收超过90%的金属。现在,印度可以立志成为世界城市矿业之都。据估计,通过回收利用,到2030年,我们可以生产约800千兆瓦时的锂,通过城市采矿满足其大部分需求。安全:对印度来说,关键是汽车电池的安全。人们一直在关注汽车的续航里程、快速充电、电池循环寿命、电池轻重量、可负担性等。但需要问的关键问题是,这对印度的条件安全吗?检测标准:锂电池AIS-156检测标准可与任何国际标准相媲美。这些标准测试电池组的所有电气、机械和热条件。标准化机构正在不断努力提高测试标准。印度标准局(BIS)最近制定了is -17855标准,这是锂离子电池组性能的测试规范。在该标准中,BIS提出了一系列新的性能测试,以衡量能源效率、启动功率、快速充电效率、温度依赖性退化、存储期间的充电损失等。美国能源效率局(BEE)最近也制定了锂电池的星级评价计划。BEE的星级评级计划已经在其他产品中取得了成功,它提供了一个易于理解的评级,消费者将在他们的安全,质量等方面更好地区分不同的电池组
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