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市场调查报告书
商品编码
1569793
2030 年先进电池市场预测:按类型、电压等级、应用和地区分類的全球分析Advanced Battery Market Forecasts to 2030 - Global Analysis By Type, Voltage Level (High Voltage, Low Voltage and Medium Voltage ), Application and By Geography |
根据Stratistics MRC的数据,2024年全球先进电池市场规模为1,069.4亿美元,预计到2030年将达到1,915.2亿美元,预测期内复合年增长率为10.2%。
先进电池是下一代能源储存系统,与传统电池相比具有更优越的性能。这些电池旨在提高能量密度、功率输出、充电速度和使用寿命,同时减轻重量、成本和环境影响。先进电池通常采用锂离子、固体电解质等尖端材料以及锂硫和钠离子等创新化学物质,以提高效率和安全性。
电动车需求不断成长
随着越来越多的消费者为了环境效益和效率而转向电动车,製造商面临着提高电池性能、容量和耐用性的压力。锂离子电池是电动车中最常用的电池,目前正在进行最佳化,以延长续航里程、缩短充电时间并提高能量密度。电动车的快速普及也推动了替代电池化学的创新,例如固态电池,它有望实现更高的能源效率和安全性。此外,增加对电池回收技术的投资旨在减少对锂、钴和镍等原材料的依赖,同时解决环境问题。
原料供应链挑战
由于锂、钴和镍等关键原材料的短缺,先进电池产业面临重大的供应链挑战。这些原料对于生产为电动车 (EV) 和能源储存系统提供动力的锂离子电池至关重要。随着世界向清洁能源转型,对这些矿物的需求正在迅速增加,但供应受到有限的采矿能力、地缘政治紧张局势和环境问题的限制。例如,钴主要来自刚果民主共和国,该国政局不稳定,有供应风险。
工业应用的采用率提高
工业应用中越来越多地采用先进电池,正在推动电池技术的显着增强。由于其效率高、生命週期长且对环境影响较小,製造、能源储存和电力运输等产业越来越依赖这些电池来满足其能源需求。这种不断增长的需求正在推动製造商进行创新,以提高能量密度、充电速度和安全性。可再生能源储存、电动车和电网稳定等应用正受益于这些进步,因为它们需要可靠的高性能电池。
监管和安全问题
监管和安全问题对先进电池的开发和部署有重大影响。随着电池技术的发展,特别是固态电池和锂硫电池等高能量密度电池的出现,监管机构必须确保这些创新符合严格的安全和性能标准。先进电池通常使用新材料和化学品,可能会带来热失控和环境危害等新风险。这些问题需要严格的测试和认证过程,以防止事故并确保长期可靠性。儘管法规旨在解决这些风险,但它们也可能因为需要广泛的检验和合规程序而减缓新技术的引入。
COVID-19 大流行对先进电池行业产生了重大影响,扰乱了供应链并减缓了生产。封锁和旅行限制导致电池製造必需的锂、钴和镍等关键原材料短缺。工厂关闭和劳动力减少阻碍了先进电池的生产和组装。疫情也扰乱了研发活动,减缓了电池技术的创新和进步。儘管有这些挑战,这场危机不仅将加速电动车和可再生能源储存等关键应用的电池技术的进步,而且还将发展更具弹性的本地化供应链,这凸显了这样做的重要性。
钠硫电池产业预计将在预测期内成为最大的产业
钠硫电池领域预计将在预测期内成为最大的领域。钠硫 (Na-S) 电池代表了能源储存领域的重大进步,与传统锂离子系统相比,可提供更高的性能和成本效率。这些电池在高温下运行,并且由于在阴极材料中使用硫和在阳极材料中使用钠而具有高能量密度。钠和硫之间的化学反应可实现大规模能源储存解决方案,使其成为电网能源储存等注重稳定性和成本效益的应用的理想选择。它们有效储存和释放大量能源的能力使它们成为平衡间歇性再生能源来源的有前途的选择。
消费性电子产业预计在预测期内复合年增长率最高。
由于各种设备对更持久、更快充电和更有效率电源的需求,预计家用电子电器产业在预测期内将出现最高的复合年增长率。电池化学方面的创新,例如固态电池的使用,正在提高安全性和能量密度,并实现更轻、更紧凑的设计。锂离子技术的改进也有助于延长使用寿命和缩短充电时间。增强型能源储存解决方案对于穿戴式科技、智慧型手机、笔记型电脑和其他可携式电子设备的发展至关重要,可为使用者提供更长的使用时间和更少的充电频率。
在估计期间,欧洲地区透过推动技术创新、提高产能和加速向永续能源解决方案的过渡,占据了最大的市场份额。欧洲公司和研究机构正在结盟,共用专业知识、资源和技术,推动尖端电池技术和更有效率製造流程的发展。这种合作对于克服技术挑战和扩大生产以满足不断增长的需求至关重要。透过汇集知识和投资,合作伙伴可以利用规模经济、降低成本并加速先进电池在整个全部区域电动车和可再生能源储存系统中的部署。
预计欧洲地区在预测期内将实现盈利成长。透过引入严格的环境和安全标准,欧洲正在鼓励电池技术的创新和投资。这些法规的重点是减少碳排放、改善回收流程并确保电池生产符合永续性目标。例如,欧盟的电池指令为电池回收和减少有害物质设定了雄心勃勃的目标,并鼓励製造商开发更有效率、更环保的解决方案。此外,地平线欧洲等项目的大量资金和支持正在加速先进电池技术的研究和开发。
According to Stratistics MRC, the Global Advanced Battery Market is accounted for $106.94 billion in 2024 and is expected to reach $191.52 billion by 2030 growing at a CAGR of 10.2% during the forecast period. An advanced battery is a next-generation energy storage system that offers superior performance compared to traditional batteries. These batteries are designed to enhance energy density, power output, charging speed, and lifespan while reducing weight, cost, and environmental impact. Advanced batteries often incorporate cutting-edge materials like lithium-ion, solid-state electrolytes, and other innovative chemistries such as lithium-sulfur or sodium-ion, which improve efficiency and safety.
Increasing demand for electric vehicles
As more consumers shift to EVs for their environmental benefits and efficiency, manufacturers are under pressure to enhance battery performance, capacity, and durability. Lithium-ion batteries, the most common type used in EVs, are being optimized to offer longer ranges, faster charging times, and greater energy density. This surge in EV adoption is also pushing innovation in alternative battery chemistries, such as solid-state batteries, which promise even higher energy efficiency and safety. Moreover, increased investments in battery recycling technologies are aimed at reducing dependency on raw materials like lithium, cobalt, and nickel, while addressing environmental concerns.
Raw material supply chain challenges
The advanced battery industry is facing significant supply chain challenges due to the scarcity of critical raw materials, such as lithium, cobalt, and nickel. These materials are essential for the production of lithium-ion batteries, which power electric vehicles (EVs) and energy storage systems. The demand for these minerals has surged with the global transition to clean energy, but their supply is constrained by limited mining capacity, geopolitical tensions, and environmental concerns. Cobalt, for example, is largely sourced from the Democratic Republic of Congo, a region prone to political instability, creating supply risks.
Increasing adoption in industrial applications
The increasing adoption of advanced batteries in industrial applications is driving significant enhancements in battery technology. Industries such as manufacturing, energy storage, and electric transportation are increasingly relying on these batteries for their energy needs due to their efficiency, longer life cycles, and reduced environmental impact. This growing demand encourages manufacturers to innovate, improving energy density, charging speed, and safety. Applications like renewable energy storage, electric vehicles, and grid stabilization benefit from these advancements, as they require reliable, high-performance batteries.
Regulatory and safety concerns
Regulatory and safety concerns significantly impact the development and deployment of advanced batteries. As battery technology evolves, especially with the advent of high-energy-density batteries like solid-state and lithium-sulfur, regulatory bodies must ensure these innovations meet stringent safety and performance standards. Advanced batteries often involve new materials and chemistries, which can introduce novel risks, such as thermal runaway or environmental hazards. These concerns necessitate rigorous testing and certification processes to prevent accidents and ensure long-term reliability. Regulations are designed to address these risks, but they can also slow down the introduction of new technologies by requiring extensive validation and compliance procedures.
The COVID-19 pandemic had a significant impact on the advanced battery sector, disrupting supply chains and slowing production. Lockdowns and travel restrictions led to shortages of key raw materials, such as lithium, cobalt, and nickel, which are crucial for battery manufacturing. Factory closures and reduced workforce availability hampered the production and assembly of advanced batteries. The pandemic also disrupted research and development activities, delaying innovations and advancements in battery technology. Despite these challenges, the crisis underscored the importance of developing more resilient and localized supply chains, as well as accelerating advancements in battery technology for critical applications like electric vehicles and renewable energy storage.
The Sodium Sulfur Battery segment is expected to be the largest during the forecast period
Sodium Sulfur Battery segment is expected to be the largest during the forecast period. Sodium-sulfur (Na-S) batteries represent a significant advancement in the field of energy storage, offering enhanced performance and cost-efficiency compared to traditional lithium-ion systems. These batteries operate at high temperatures and feature a high energy density due to the use of sulfur as the cathode material and sodium as the anode. The sodium-sulfur chemistry allows for large-scale energy storage solutions, making them ideal for applications such as grid energy storage, where stability and cost-effectiveness are critical. Their ability to efficiently store and release large amounts of energy makes them a promising option for balancing intermittent renewable energy sources.
The Consumer Electronics segment is expected to have the highest CAGR during the forecast period
Consumer Electronics segment is expected to have the highest CAGR during the forecast period driven by the demand for longer-lasting, faster-charging, and more efficient power sources for a variety of devices. Innovations in battery chemistry, such as the use of solid-state batteries, are enhancing safety and energy density, allowing for lighter and more compact designs. Improvements in lithium-ion technology are also contributing to increased longevity and faster charging times. Enhanced energy storage solutions are pivotal for the evolution of wearable technology, smartphones, laptops, and other portable electronics, providing users with extended usage times and reducing the frequency of recharges.
Europe region commanded the largest share of the market over the extrapolated period by fostering innovation, enhancing production capabilities, and accelerating the transition to sustainable energy solutions. European companies and research institutions are forming alliances to share expertise, resources, and technology, leading to the development of cutting-edge battery technologies and more efficient manufacturing processes. These collaborations are crucial for overcoming technical challenges and scaling up production to meet growing demand. By pooling knowledge and investment, partners can leverage economies of scale, reduce costs, and expedite the deployment of advanced batteries in electric vehicles and renewable energy storage systems across the region.
Europe region is poised to witness profitable growth during the forecast period. By implementing stringent environmental and safety standards, Europe is driving innovation and investment in battery technologies. These regulations focus on reducing carbon emissions, improving recycling processes, and ensuring that battery production aligns with sustainability goals. For instance, the European Union's Battery Directive sets ambitious targets for recycling and reducing hazardous substances in batteries, which encourages manufacturers to develop more efficient and eco-friendly solutions. Additionally, substantial funding and support from programs like Horizon Europe are accelerating research and development in advanced battery technologies.
Key players in the market
Some of the key players in Advanced Battery market include Amperex Technology Limited, GS Yuasa Corporation, LG Energy Solution, Northvolt AB, Pathion Inc, PolyPlus Battery Company Inc, Samsung SDI, Sion Power Corporation and Tesla, Inc.
In August 2024, SAMSUNG SDI and General Motors Finalize Agreement to Establish Battery Joint Venture in the US - to invest approximately $3.5bn in an EV battery plant. The joint venture will be located in New Carlisle, Indiana, on a 680-acre site and is expected to more than 1,600 jobs supporting the local economy.
In May 2023, Honda Motor Co., Ltd. (Honda) and GS Yuasa International Ltd. (GS Yuasa) announced that they have signed a joint venture agreement toward the establishment of a new company. Honda and GS Yuasa Reach Basic Agreement Toward Collaboration for a High-capacity, High-output Lithium-ion Battery," the two companies have been discussing specifics for collaboration on high-capacity, high-output lithium-ion batteries, mainly for EVs.