市場調查報告書
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2030年薄膜電池市場預測:按充電性別、電壓、技術、應用和地區進行全球分析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 |
根據Stratistics MRC預測,2024年全球薄膜電池市場價值將達5.9億美元,預計2030年將達到19.3億美元,預測期內複合年成長率為21.8%。
薄膜電池是一種緊湊的能源儲存裝置,具有層狀結構,其中正極、負極和電解質形成超薄膜。這些電池使用先進的材料和製造技術,例如濺鍍和化學沉澱,來製造厚度僅為幾微米的薄膜。它們尺寸小、重量輕,非常適合整合到各種應用中,包括穿戴式裝置、感測器和微電子產品。此外,它可以在軟式電路板上製造,從而實現曲面和行動裝置中的創新應用。
根據國際資料公司(IDC)預測,印度穿戴式裝置市場到 2023 年將成長 34%,達到 1.342 億台。
對可攜式電子設備的需求增加
對智慧型手機、穿戴式裝置和物聯網設備等可攜式電子設備不斷成長的需求正在推動薄膜電池技術的進步。與傳統電源相比,這些電池具有多種優勢,包括輕量化設計、靈活的外形規格和快速充電功能。隨著消費者為其日益移動的生活方式尋求更高效、更緊湊的電源解決方案,製造商正在專注於開發能夠提供更高能量密度和更長使用壽命的薄膜電池。固體電解質和奈米結構電極等材料的創新進一步提高了性能,同時確保了安全性和環境永續性。
有限的能量密度
薄膜電池以其輕質和靈活的設計而聞名,但由於其有限的能量密度而面臨重大挑戰。能量密度是指每單位體積或重量儲存的能量,對於需要緊湊型電源的應用至關重要。薄膜技術通常使用比傳統散裝電池能源儲存容量更低的材料。然而,這種限制源於薄電極和電解質層,這增加了靈活性並減小了尺寸,同時限制了可用於能源儲存的活性材料的總量。
無線感測器的採用增加
無線感測器的日益普及極大地促進了薄膜電池的開發和利用。隨著產業擴大轉向無線技術用於物聯網、環境監測和智慧設備等應用,對小型、輕量和高效電源的需求不斷增加。薄膜電池以其靈活性和高能量密度而聞名,是這些無線感測器的完美補充,可無縫整合到各種環境中。使用軟式電路板製造的能力允許創新設計,使感測器能夠嵌入到從穿戴式設備到智慧包裝的各種表面中。
監管障礙
雖然薄膜電池因其輕質和靈活的設計而前景廣闊,但它們面臨著阻礙其廣泛使用的重大監管障礙。這些電池通常使用傳統法律規範之外的新材料和製造程序,導致安全、性能和環境標準的合規性存在不確定性。監管機構可能缺乏有效評估這些創新技術所需的具體指南,導致核准流程冗長。各地區的不同法規使製造商的市場准入變得複雜,他們必須應對各種要求。這會導致成本增加和延誤、抑制創新並限制研發投資。
COVID-19 的爆發對薄膜電池產業產生了重大影響,影響了供應鍊和研發活動。停工和限制擾亂了製造流程,並延遲了薄膜電池必需原料的生產和運輸。許多公司面臨勞動力短缺,營運能力下降並阻礙創新。由於研究計劃的資金被轉向直接的醫療保健需求,薄膜電池技術的進步陷入停滯。
預計在預測期內可充電細分市場將是最大的
預計可充電細分市場在預測期內將是最大的。薄膜電池的特點是重量輕、結構靈活,並且正在開發技術以實現更高的能量密度和更快的充電/放電週期。鋰聚合物和固體電解質等材料的創新提高了安全性和使用壽命,並解決了先前的洩漏和劣化等限制。這些電池特別適合空間和重量都非常寶貴的新技術,例如攜帶式電子產品、穿戴式裝置、物聯網和電動車。此外,先進製造技術(例如卷對卷加工)的整合可實現經濟高效的大規模生產。
陶瓷電池領域預計在預測期內複合年成長率最高
由於創新材料和製造技術的整合,陶瓷電池產業預計在預測期內將出現最高的複合年成長率。薄膜電池以其輕質和靈活的特性而聞名,擴大採用陶瓷組件來增強,以提高熱穩定性和能量密度。陶瓷材料可以承受高溫並提供出色的離子電導率,從而實現更高效的充放電循環。這項增強功能不僅可以延長電池壽命,還可以加快充電速度。此外,陶瓷的使用可以降低漏電風險並提高安全性,使這些電池適用於更廣泛的應用,例如攜帶式電子產品、醫療設備和電動車。
由於電池技術研發(R&D)資金的增加,北美地區在整個估計期間佔據了最大的市場佔有率。這項投資正在推動材料和製造流程的創新,從而帶來更有效率、更輕、更靈活的電池。隨著消費性電子、電動車和可再生能源儲存等產業尋求改進的能源解決方案,薄膜技術的進步變得越來越重要。此外,北美公司正在利用這筆資金與學術和研究機構合作,以培育蓬勃發展的創新生態系統。
預計歐洲地區在預測期內將實現盈利成長。各國都實施了支持研究和創新的政策,為該全部區域專注於薄膜電池的新興企業和老牌公司提供資金和津貼。這些舉措旨在減少對石化燃料的依賴,並根據歐盟雄心勃勃的氣候變遷目標促進永續能源來源的發展。此外,正在建立法律規範,以促進將這些先進的電池技術整合到現有的能源系統中,鼓勵公共和私營部門之間的合作。這些因素正在推動區域成長。
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).