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2030年薄膜电池市场预测:按充电性别、电压、技术、应用和地区进行全球分析Thin Film Battery Market Forecasts to 2030 - Global Analysis By Chargeability (Disposable and Rechargeable), Voltage (Below 1.5V, 1.5 to 3V and Above 3V), Technology, Application and By Geography |
根据Stratistics MRC预测,2024年全球薄膜电池市场价值将达5.9亿美元,预计2030年将达到19.3亿美元,预测期内复合年增长率为21.8%。
薄膜电池是一种紧凑的能源储存装置,具有层状结构,其中正极、负极和电解质形成超薄膜。这些电池使用先进的材料和製造技术,例如溅镀和化学沉淀,来製造厚度仅为几微米的薄膜。它们尺寸小、重量轻,非常适合整合到各种应用中,包括穿戴式装置、感测器和微电子产品。此外,它可以在软式电路板上製造,从而实现曲面和行动装置中的创新应用。
根据国际资料公司(IDC)预测,印度穿戴式装置市场到 2023 年将成长 34%,达到 1.342 亿台。
对可携式电子设备的需求增加
对智慧型手机、穿戴式装置和物联网设备等可携式电子设备不断增长的需求正在推动薄膜电池技术的进步。与传统电源相比,这些电池具有多种优势,包括轻量化设计、灵活的外形规格和快速充电功能。随着消费者为其日益移动的生活方式寻求更高效、更紧凑的电源解决方案,製造商正在专注于开发能够提供更高能量密度和更长使用寿命的薄膜电池。固体电解质和奈米结构电极等材料的创新进一步提高了性能,同时确保了安全性和环境永续性。
有限的能量密度
薄膜电池以其轻质和灵活的设计而闻名,但由于其有限的能量密度而面临重大挑战。能量密度是指每单位体积或重量储存的能量,对于需要紧凑型电源的应用至关重要。薄膜技术通常使用比传统散装电池能源储存容量更低的材料。然而,这种限制源于薄电极和电解质层,这增加了灵活性并减小了尺寸,同时限制了可用于能源储存的活性材料的总量。
无线感测器的采用增加
无线感测器的日益普及极大地促进了薄膜电池的开发和利用。随着产业越来越多地转向无线技术用于物联网、环境监测和智慧设备等应用,对小型、轻量和高效电源的需求不断增加。薄膜电池以其灵活性和高能量密度而闻名,是这些无线感测器的完美补充,可无缝整合到各种环境中。使用软式电路板製造的能力允许创新设计,使感测器能够嵌入到从可穿戴设备到智慧包装的各种表面中。
监管障碍
虽然薄膜电池因其轻质和灵活的设计而前景广阔,但它们面临着阻碍其广泛使用的重大监管障碍。这些电池通常使用传统法律规范之外的新材料和製造工艺,导致安全、性能和环境标准的合规性存在不确定性。监管机构可能缺乏有效评估这些创新技术所需的具体指南,导致核准流程冗长。各地区的不同法规使製造商的市场准入变得复杂,他们必须应对各种要求。这会导致成本增加和延误、抑制创新并限制研发投资。
COVID-19 的爆发对薄膜电池产业产生了重大影响,影响了供应炼和研发活动。停工和限制扰乱了製造流程,并延迟了薄膜电池必需原料的生产和运输。许多公司面临劳动力短缺,营运能力下降并阻碍创新。由于研究计划的资金被转向直接的医疗保健需求,薄膜电池技术的进步陷入停滞。
预计在预测期内可充电细分市场将是最大的
预计可充电细分市场在预测期内将是最大的。薄膜电池的特点是重量轻、结构灵活,并且正在开发技术以实现更高的能量密度和更快的充电/放电週期。锂聚合物和固体电解质等材料的创新提高了安全性和使用寿命,并解决了先前的洩漏和劣化等限制。这些电池特别适合空间和重量都非常宝贵的新技术,例如便携式电子产品、穿戴式装置、物联网和电动车。此外,先进製造技术(例如卷对卷加工)的整合可实现经济高效的大规模生产。
陶瓷电池领域预计在预测期内复合年增长率最高
由于创新材料和製造技术的整合,陶瓷电池产业预计在预测期内将出现最高的复合年增长率。薄膜电池以其轻质和灵活的特性而闻名,越来越多地采用陶瓷组件来增强,以提高热稳定性和能量密度。陶瓷材料可以承受高温并提供出色的离子电导率,从而实现更高效的充放电循环。这项增强功能不仅可以延长电池寿命,还可以加快充电速度。此外,陶瓷的使用可以降低漏电风险并提高安全性,使这些电池适用于更广泛的应用,例如便携式电子产品、医疗设备和电动车。
由于电池技术研发(R&D)资金的增加,北美地区在整个估计期间占据了最大的市场份额。这项投资正在推动材料和製造流程的创新,从而带来更有效率、更轻、更灵活的电池。随着消费性电子、电动车和可再生能源储存等产业寻求改进的能源解决方案,薄膜技术的进步变得越来越重要。此外,北美公司正在利用这笔资金与学术和研究机构合作,以培育蓬勃发展的创新生态系统。
预计欧洲地区在预测期内将实现盈利成长。各国都实施了支持研究和创新的政策,为该全部区域专注于薄膜电池的新兴企业和老牌公司提供资金和津贴。这些倡议旨在减少对石化燃料的依赖,并根据欧盟雄心勃勃的气候变迁目标促进永续能源来源的发展。此外,正在建立法律规范,以促进将这些先进的电池技术整合到现有的能源系统中,鼓励公共和私营部门之间的合作。这些因素正在推动区域成长。
According to Stratistics MRC, the Global Thin Film Battery Market is accounted for $0.59 billion in 2024 and is expected to reach $1.93 billion by 2030 growing at a CAGR of 21.8% during the forecast period. A thin film battery is a compact energy storage device characterized by its layered structure, typically composed of a cathode, an anode, and an electrolyte, all deposited in ultra-thin films. These batteries utilize advanced materials and fabrication techniques, such as sputtering or chemical vapor deposition, to create films that can be just a few micrometers thick. Their small size and lightweight design make them ideal for integration into various applications, including wearables, sensors, and microelectronics. Additionally, they can be manufactured on flexible substrates, allowing for innovative applications in curved or portable devices.
According to the International Data Corporation (IDC), the Indian wearable market saw a 34% growth, recording 134.2 million units in 2023.
Increasing demand for portable electronics
The rising demand for portable electronics, such as smartphones, wearables, and IoT devices, is significantly driving advancements in thin film battery technology. These batteries offer several advantages over traditional power sources, including lightweight design, flexible form factors, and faster charging capabilities. As consumers seek more efficient and compact power solutions for their increasingly mobile lifestyles, manufacturers are focusing on developing thin film batteries that can deliver higher energy densities and longer lifespans. Innovations in materials, such as solid-state electrolytes and nanostructured electrodes, are further enhancing performance while ensuring safety and environmental sustainability.
Limited energy density
Thin film batteries, known for their lightweight and flexible design, face significant challenges due to limited energy density. Energy density refers to the amount of energy stored per unit volume or weight, and is crucial for applications requiring compact power sources. Thin film technologies typically utilize materials that offer lower energy storage capacity compared to traditional bulk batteries. However, this limitation arises from the thin electrodes and electrolyte layers, which, while enhancing flexibility and reducing size, restrict the overall amount of active material available for energy storage.
Increasing adoption of wireless sensors
The rising adoption of wireless sensors is significantly enhancing the development and utilization of thin film batteries. As industries increasingly turn to wireless technology for applications in IoT, environmental monitoring, and smart devices, the demand for compact, lightweight, and efficient power sources grows. Thin film batteries, known for their flexibility and high energy density, perfectly complement these wireless sensors, offering a seamless integration in various environments. Their ability to be produced on flexible substrates allows for innovative designs, enabling sensors to be embedded in diverse surfaces, from wearables to smart packaging.
Regulatory hurdles
Thin film batteries, while promising for their lightweight and flexible design, face significant regulatory hurdles that impede their widespread adoption. These batteries often use novel materials and manufacturing processes that fall outside traditional regulatory frameworks, leading to uncertainties in compliance with safety, performance, and environmental standards. Regulatory agencies may lack the specific guidelines needed to evaluate these innovative technologies effectively, resulting in prolonged approval processes. the variability in regulations across different regions complicates market entry for manufacturers, who must navigate a patchwork of requirements. This can lead to increased costs and delays, stifling innovation and limiting investment in research and development.
The COVID-19 pandemic significantly impacted the thin film battery sector, affecting both supply chains and research and development activities. Lockdowns and restrictions led to disruptions in the manufacturing processes, causing delays in production and shipment of raw materials essential for thin film batteries. Many companies faced workforce shortages, leading to reduced operational capacity and hindering innovation efforts. Funding for research projects was redirected to immediate healthcare needs, stalling advancements in thin film battery technology.
The Rechargeable segment is expected to be the largest during the forecast period
Rechargeable segment is expected to be the largest during the forecast period. Thin film batteries, characterized by their lightweight, flexible structure, are increasingly being engineered for higher energy density and faster charge/discharge cycles. Innovations in materials, such as lithium polymer and solid-state electrolytes, enhance safety and longevity, addressing previous limitations like leakage and degradation. These batteries are particularly well-suited for portable electronics, wearable devices, and emerging technologies like IoT and electric vehicles, where space and weight are critical. Furthermore, the integration of advanced manufacturing techniques, such as roll-to-roll processing, allows for cost-effective production at scale.
The Ceramic Battery segment is expected to have the highest CAGR during the forecast period
Ceramic Battery segment is expected to have the highest CAGR during the forecast period by integrating innovative materials and manufacturing techniques. Thin Film Batteries, known for their lightweight and flexible nature, are increasingly being enhanced with ceramic components, which improve their thermal stability and energy density. Ceramic materials can withstand higher temperatures and offer superior ionic conductivity, leading to more efficient charge and discharge cycles. This enhancement not only prolongs battery life but also enables faster charging capabilities. Additionally, the use of ceramics can reduce the risk of leakage and enhance safety, making these batteries suitable for a wider range of applications, including portable electronics, medical devices, and electric vehicles.
North America region commanded the largest share of the market throughout the extrapolated period due to the increased funding for research and development (R&D) in battery technologies. This investment is driving innovation in materials and manufacturing processes, leading to the creation of more efficient, lightweight, and flexible batteries. As industries such as consumer electronics, electric vehicles, and renewable energy storage demand improved energy solutions, advancements in thin film technology are becoming increasingly crucial. Furthermore, North American companies are leveraging this funding to collaborate with academic institutions and research organizations, fostering a vibrant ecosystem of innovation.
Europe region is estimated to witness profitable growth during the projected period of time. Various countries are implementing policies that support research and innovation, offering funding and grants to startups and established companies focused on thin film batteries across the region. These initiatives aim to reduce dependence on fossil fuels and promote sustainable energy sources, aligning with the EU's ambitious climate goals. Additionally, regulatory frameworks are being established to facilitate the integration of these advanced battery technologies into existing energy systems, encouraging collaborations between public institutions and private enterprises. These elements are boosting the regional growth.
Key players in the market
Some of the key players in Thin Film Battery market include Nissan Chemical Corporation, Johnson Energy Storage, Inc, Toshiba Corporation, Kopin Corporation, Prieto Battery Inc, Amprius Technologies, STMicroelectronics, SunPower Corporation, Angstrom Engineering Inc, Enfucell Flexible Electronics LTD and Molex, LLC.
In February 2024, LionVolt, a Dutch startup, started developing 3D solid-state batteries made up of a thin film containing billions of solid pillars, creating a patented 3D architecture with a large surface area. The company also raised EUR 15 million (USD 16 million) to scale up the production of these batteries.
In January 2024, Battery start-up BTRY raised CHF 900,000 in pre-seed financing to develop safe, long-lasting thin-film solid-state batteries that can be charged and discharged in one minute. The company has developed thin-film cells, which are only a few micrometers thick, into more powerful batteries. It has also developed a process that uses high-precision vacuum coating and no toxic solvents.
In October 2023, Toppan, a global leader in communication, decor materials, security, packaging, and electronics solutions, collaborated with the National Institute of Information and Communications Technology (NICT) and developed PQC CARD. This card is the world's first smart card equipped with post-quantum cryptography.
In September 2022, Molex expanded its manufacturing operations in Hanoi to add a new 16,000-square-meter facility. This expansion supports the growing demand for its products in different applications, including smartphones, TVs, home appliances, test equipment, and medical devices.
In January 2022, NGK signed a partnership with Exeter, a Swedish industrial company, to reach additional markets and expand new sectors by offering manufacturers low-power solutions and devices with prolonged or infinite battery life. As per the partnership, both companies would work closely to strengthen manufacturing capacity and enable each to bring products to market in areas such as the Internet of Things (IoT) and electronics (such as e-shelf labels, sensors, and remote controls).