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2030 年智慧型穿戴装置电池市场预测:按类型、应用和地区分類的全球分析Smart Wearable Devices Batteries Market Forecasts to 2030 - Global Analysis By Type, Application and By Geography |
根据Stratistics MRC预测,2024年全球智慧型穿戴装置电池市场规模将达到37.6亿美元,预计在预测期内将以7.4%的复合年增长率成长,到2030年达到57.7亿美元。
智慧型穿戴装置的电池是专用电源,旨在满足健身追踪器、智慧型手錶和扩增实境眼镜等紧凑型多功能设备的独特需求。这些电池优先考虑轻质结构和高能量密度,无需频繁充电即可延长使用时间。随着穿戴式装置越来越多地采用先进的感测器、GPS 和连接功能,对能够提供可靠性能同时保持低调的电池的需求变得至关重要。
据Cisco称,连网穿戴装置预计将从 2018 年的 5.93 亿台成长到今年的 11.05 亿台。
穿戴式科技的采用增加
穿戴式科技的采用日益增多,智慧穿戴装置电池的开发也显着增加。随着越来越多的消费者采用健身追踪器、智慧型手錶和健康监测设备,对高效能、持久电池的需求正在迅速增加。製造商专注于提高电池容量和充电速度,同时保持紧凑的尺寸,以匹配穿戴式装置的时尚设计。此外,锂聚合物和固态电池等创新技术也在研究中,以提供更高的能量密度和安全性。这项演进不仅透过降低充电频率来改善用户体验,而且还支援整合更高级的功能,例如持续健康监测和连接。
智慧财产权问题
智慧财产权 (IP) 问题对创新和协作造成了障碍,严重阻碍了智慧型穿戴装置电池的进步。竞争格局充满了与电池技术、材料和製造流程相关的专利。公司经常进行广泛的诉讼来保护其智慧财产权,但这可能会阻碍研发工作。这种对法律斗争的关注转移了用于提高电池效率、寿命和永续性的资源。严格的智慧财产权保护可能会阻碍新兴企业进入市场,因为新兴企业可能没有财力来应对复杂的专利环境或应对潜在的侵权索赔。
日益关注小型化
随着製造商努力创造更小、更轻、更有效率的小工具,电池技术的进步至关重要。固态电池和锂硫化学等创新技术可以在不牺牲设备尺寸的情况下实现更高的能量密度和更长的使用时间。增强的能源管理系统优化了电力消耗,使穿戴式装置能够长时间高效运作。这种小型化趋势不仅促进了复杂的设计,提高了使用者的舒适度,而且还为整合健康监测和扩增实境(AR) 等先进功能开闢了新的可能性。
先进技术的扩充性有限
随着这些设备需求的增加,电池需求变得越来越复杂,需要更高的能量密度、更快的充电能力和更长的使用寿命。目前的电池技术(例如锂离子电池)在小型化和效率方面有其局限性,因此很难在保持设备小型化和轻量化的同时保持性能。整合健康监测和连接等功能将为现有电池技术带来额外压力。替代材料和设计正在研究中,例如固态电池电池和柔性电池,但由于生产成本高和製造复杂性,扩充性仍然是一个障碍。
COVID-19的爆发对智慧穿戴装置市场产生了重大影响,尤其是电池技术。由于健身追踪和在封锁期间监测健康状况的需要,对健康监测健身的需求激增,製造商面临供应链中断,影响了电池生产。锂和其他重要材料等关键部件的短缺导致了延误和成本增加。製造商开始投资研发,以提高电池效率、寿命和充电速度,同时也探索替代材料以减少供应链漏洞。
锂铜氧化物电池领域预计将在预测期内成为最大的领域
预计锂铜氧化物电池产业在预测期内将是最大的。透过添加氧化铜,这些电池可以实现更高的效率并延长使用时间,而无需增加设备的尺寸或重量。这对于需要小型、轻量电源来保持舒适性和易用性的穿戴式装置尤其重要。此外,锂铜氧化物电池具有更快的充电能力和稳定的放电倍率,并提高了智慧型装置的整体效能。这些电池能够承受多次充电週期而不会显着劣化,有助于提高穿戴式装置的永续性和可靠性。
预计智慧腕带细分市场在预测期内复合年增长率最高
智慧腕带细分市场预计在预测期内复合年增长率最高。随着消费者越来越依赖这些设备进行健康追踪、通知和健身监测,对更耐用电池的需求正在激增。製造商正在探索先进的电池技术,例如锂硫电池和固态电池,以实现更高的能量密度和更快的充电时间。动能充电和太阳能充电等能源采集技术正在被集成,以延长使用时间,而无需频繁充电。优化的电源管理系统以及节能感测器和处理器进一步有助于延长电池寿命。这种演变不仅改善了用户体验,而且支持了健康、保健和监控的成长趋势。
在整个估计期间,亚太地区在智慧型穿戴装置电池市场中占据最大份额。随着消费者对创新穿戴装置的需求不断增加,各公司正联手利用电池技术、材料科学和製造流程的互补专业知识。高科技公司、研究机构和电池製造商之间的合作正在推动电池能量密度、充电速度和使用寿命的进步,这对智慧型装置的功能至关重要。伙伴关係关係促进了知识共用和新技术的快速部署,确保产品满足全部区域消费者对性能和永续性的期望。
欧洲地区在预估期间内将出现盈利成长。以安全为重点的法规可确保电池符合严格的效能标准,降低故障风险并增强消费者信心。旨在加强回收流程的倡议鼓励行业内循环经济实践的发展,最大限度地减少废弃物并促进负责任的材料采购。这种监管环境不仅创造了鼓励企业创新的竞争环境,也符合欧盟永续性和减少碳足迹的更广泛目标。这些因素正在推动该地区的成长。
According to Stratistics MRC, the Global Smart Wearable Devices Batteries Market is accounted for $3.76 billion in 2024 and is expected to reach $5.77 billion by 2030 growing at a CAGR of 7.4% during the forecast period. Smart wearable devices batteries are specialized power sources designed to meet the unique demands of compact and often multi-functional gadgets like fitness trackers, smartwatches, and augmented reality glasses. These batteries prioritize lightweight construction and high energy density to ensure extended usage without frequent recharging. As wearables increasingly incorporate advanced sensors, GPS, and connectivity features, the need for batteries that can deliver reliable performance while maintaining a slim profile becomes paramount.
According to Cisco Systems, connected wearable devices are expected to increase from 593 million in 2018 to 1,105 million this year.
Rising adoption of wearable technology
The rising adoption of wearable technology is significantly enhancing the development of smart wearable device batteries. As more consumers embrace fitness trackers, smartwatches, and health-monitoring devices, the demand for efficient, long-lasting batteries has surged. Manufacturers are focusing on improving battery capacity and charging speeds while maintaining compact sizes to fit the sleek designs of wearables. Furthermore, innovations like lithium-polymer and solid-state batteries are being explored to offer greater energy density and safety. This evolution not only enhances user experience by reducing charging frequency but also supports the integration of more advanced features, including continuous health monitoring and connectivity.
Intellectual property issues
Intellectual property (IP) issues significantly hinder the advancement of smart wearable device batteries by creating barriers to innovation and collaboration. The competitive landscape is fraught with patents related to battery technologies, materials, and manufacturing processes. Companies often engage in extensive litigation to protect their IP, which can stifle research and development efforts. This focus on legal battles diverts resources away from advancing battery efficiency, longevity and sustainability. Stringent IP protections can inhibit startups from entering the market, as they may lack the financial means to navigate complex patent landscapes or defend against potential infringement claims.
Increased focus on miniaturization
As manufacturers strive to create smaller, lighter, and more efficient gadgets, advances in battery technology are crucial. Innovations such as solid-state batteries and lithium-sulfur chemistries are enabling higher energy densities, which means longer usage times without compromising device size. Enhanced energy management systems are optimizing power consumption, allowing wearables to operate efficiently for extended periods. This miniaturization trend not only facilitates sleek designs that enhance user comfort but also opens up new possibilities for integrating advanced features, such as health monitoring and augmented reality.
Limited scalability of advanced technologies
As the demand for these devices grows, their battery requirements become increasingly complex, necessitating higher energy densities, faster charging capabilities, and longer lifespans. Current battery technologies, such as lithium-ion, face constraints in miniaturization and efficiency, making it difficult to maintain performance while keeping the devices compact and lightweight. The integration of features like health monitoring and connectivity further strains existing battery technologies, which struggle to balance power output with size and weight limitations. Research into alternative materials and designs, such as solid-state or flexible batteries, is ongoing, but scalability remains a hurdle due to high production costs and manufacturing complexities.
The COVID-19 pandemic significantly impacted the smart wearable devices market, particularly in terms of battery technology. As demand for health monitoring devices surged-driven by the need for fitness tracking and health management during lockdowns-manufacturers faced supply chain disruptions that affected battery production. Shortages of key components, such as lithium and other essential materials, led to delays and increased costs. Manufacturers began investing in research and development to improve battery efficiency, lifespan, and charging speed, while also exploring alternative materials to mitigate supply chain vulnerabilities.
The Lithium-Copper Oxide Batteries segment is expected to be the largest during the forecast period
Lithium-Copper Oxide Batteries segment is expected to be the largest during the forecast period. By incorporating copper oxide, these batteries achieve higher efficiency, enabling longer usage times without increasing the size or weight of the device. This is particularly crucial for wearables, which require compact, lightweight power sources to maintain comfort and usability. Additionally, lithium-copper oxide batteries exhibit faster charging capabilities and a more stable discharge rate, enhancing the overall performance of smart devices. With their ability to withstand multiple charge cycles without significant degradation, these batteries contribute to the sustainability and reliability of wearables.
The Smart Wristband segment is expected to have the highest CAGR during the forecast period
Smart Wristband segment is expected to have the highest CAGR during the forecast period. As consumers increasingly rely on these devices for health tracking, notifications, and fitness monitoring, the demand for longer-lasting batteries has surged. Manufacturers are exploring advanced battery technologies, such as lithium-sulfur and solid-state batteries, which promise greater energy density and reduced charging times. Energy harvesting techniques, like kinetic and solar charging, are being integrated to extend usage without frequent recharges. Optimized power management systems, along with energy-efficient sensors and processors, further contribute to prolonged battery life. This evolution not only improves user experience but also supports the growing trend of health and wellness monitoring.
Asia Pacific region commanded the largest share of the Smart Wearable Devices Batteries market throughout the extrapolated period. As consumer demand for innovative wearables rises, companies are joining forces to leverage complementary expertise in battery technology, materials science, and manufacturing processes. Collaborations between tech firms, research institutions, and battery manufacturers are driving advancements in energy density, charging speed, and longevity of batteries, crucial for the functionality of smart devices. Partnerships facilitate knowledge sharing and the rapid deployment of new technologies, ensuring that products meet consumer expectations for performance and sustainability across the region.
Europe region is poised to witness profitable growth over the projected period of time. Regulations focused on safety ensure that batteries meet rigorous performance benchmarks, reducing risks of malfunctions and increasing consumer trust. Initiatives aimed at enhancing recycling processes encourage the development of circular economy practices within the industry, minimizing waste and promoting responsible sourcing of materials. This regulatory landscape not only fosters a competitive environment that pushes companies toward innovation but also aligns with broader EU goals of sustainability and reducing carbon footprints. These elements are boosting the regional growth.
Key players in the market
Some of the key players in Smart Wearable Devices Batteries market include Amperex Technology Limited, BYD Company, Cypress Semiconductor Corporation, Energizer Holdings, Inc, EVE Energy Co., Ltd, Nissan Chemical Industries Ltd, Samsung SDI, Sungrow Power Supply Co., Ltd, Tenergy Corporation and VivoPower International PLC.
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. Through the partnership, the two companies will invest approximately $3.5 billion to build a new battery cell manufacturing plant with an annual production capacity of 27GWh initially, targeting mass production in 2027.