市場調查報告書
商品編碼
1530880
到 2030 年的能源採集市場預測:按組件、能源來源、最終用戶和地區進行的全球分析Energy Harvesting Market Forecasts to 2030 - Global Analysis By Component, Source, End User and By Geography |
根據Stratistics MRC的數據,2024年全球能源採集市場規模為45.1億美元,預計到2030年將達到148.3億美元,預測期內複合年成長率為21.96%。
能源採集是指從環境中的各種來源捕獲環境能量並將其轉換為可用電能的過程。這種方法對於為傳統電池更換或連續並聯型不切實際或不可能的電子設備和系統供電至關重要。常見的環境能源來源包括太陽輻射、振動、熱梯度和電磁波。
根據喬治亞理工學院最近的研究,摩擦起電效應透過摩擦或接觸兩種不同的材料產生令人難以置信的能量。
對節能解決方案的需求不斷成長
對節能解決方案不斷成長的需求正在推動能源採集技術的重大進步。能源採集從環境中捕獲並儲存少量的環境能量,例如陽光、振動和熱量,並將其轉化為可用的電力。由於這種方法可以減少對傳統能源的依賴並降低營運成本,因此在各個行業中越來越受歡迎。在物聯網設備等電池壽命和維護至關重要的領域,能源採集透過延長使用壽命和消除頻繁更換電池的需要,提供了一種永續的替代方案。
監管和政策挑戰
能源採集面臨重大的監管和政策挑戰,阻礙了其廣泛採用和融入主流能源解決方案。一個主要障礙是缺乏管理不同地區和司法管轄區的能源採集技術的標準化法規。這些技術通常跨越多個領域,例如 IT/通訊、物聯網和基礎設施,每個領域都有自己的法規結構。缺乏明確的指導方針使能源採集設備的認證、部署和可擴展性變得複雜。然而,與能源補貼、獎勵和電網整合相關的政策在確定能源採集計劃的經濟可行性方面發揮著重要作用。
物聯網設備和無線感測器網路的普及
物聯網設備和無線感測網路的激增正在推動能源採集技術的重大進步。這些技術可從光、熱和振動等環境能源來源中提取能量,從而減少或消除傳統電池更換和並聯型的需要。對於物聯網和感測器網路應用來說,這種功能尤其具有顛覆性,因為這些應用中的裝置通常位於遠端或難以到達的位置。此外,能源採集透過增加可再生能源的使用和減少對環境的影響來提高永續性。
實施成本高
高實施成本是能源採集技術廣泛使用的主要障礙。這些技術旨在捕捉太陽輻射、振動和熱梯度等環境能源來源並將其轉化為可用電力,通常需要專門的材料和組件;目前,它們的製造和整合到現有系統中的成本昂貴。然而,開發高效能的能源採集設備需要複雜的工程和製造程序,這進一步推高了成本。
COVID-19 大流行對能源採集行業產生了重大影響。最初,全球供應鏈的中斷影響了能源採集技術的生產和分配,導致延誤和短缺。隨著各國實施封鎖和限制,研發活動放緩,影響了創新和新技術的引進。然而,景氣衰退導致許多行業將短期財務穩定置於長期永續性目標之上,並減少了對可再生能源計劃的投資,包括能源採集舉措。
預計射頻領域在預測期內將是最大的
預計射頻領域在預測期內將是最大的。射頻 (RF)能源採集涉及捕獲 Wi-Fi 路由器、手機訊號塔和廣播公司等各種來源發出的環境 RF 波,並將這些電磁能量轉換為可用功率。該技術越來越受到關注,因為它有潛力為小型電子設備和感測器無線供電,從而無需電池和頻繁充電。射頻能源採集通常利用設計為在特定頻率下諧振的天線來有效捕獲射頻波,並透過整流電路將其轉換為直流 (DC) 電。
無線感測網路產業預計在預測期內複合年成長率最高。
無線感測網路領域預計在預測期內複合年成長率最高。無線感測網路(WSN) 擴大利用能源採集技術來提高營運的永續性和自主性。能源採集允許感測器從周圍環境中發電,從而減少或消除電池更換或充電的需要。該技術使無線感測器網路能夠在傳統電源無法使用的偏遠或難以到達的地點運作。 WSN 設計中融入了各種能源採集方法,例如太陽能、風能、振動和熱能,以適應特定的環境條件。
由於對節能自主設備的需求不斷成長,北美地區在估計期間佔據了最大的市場佔有率。這些技術使設備能夠利用周圍環境的能源,減少對傳統電源的依賴,並延長其全部區域的使用壽命。提高能源效率對於全部區域的消費性電子、工業自動化和智慧基礎設施等各個產業至關重要。太陽能、熱能和動能轉換等能源採集技術的進步正在刺激創新,使全部區域的設備更加自立、更環保。
預計歐洲地區在預測期內將保持盈利成長。近年來,歐洲透過創新的政府措施和政策,在加強能源採集方面取得了重大進展。推動這一進步的一個值得注意的政策框架是《歐洲綠色交易》,其目標是到 2050 年使歐洲實現氣候中和。這項雄心勃勃的計畫包括可再生能源部署和能源效率提高的目標,從而在全部區域創造有利於能源採集技術的環境。此外,地平線歐洲等各種資助計畫分配大量資源用於永續能源解決方案的研究和開發,包括先進的能源採集技術。
According to Stratistics MRC, the Global Energy Harvesting Market is accounted for $4.51 billion in 2024 and is expected to reach $14.83 billion by 2030 growing at a CAGR of 21.96% during the forecast period. Energy harvesting refers to the process of capturing and converting ambient energy from various sources in the environment into usable electrical energy. This approach is crucial for powering electronic devices and systems where conventional battery replacement or continuous grid connection is impractical or impossible. Common sources of ambient energy include solar radiation, vibrations, thermal gradients, and electromagnetic waves.
According to a recent research in Georgia Institute of technology, the triboelectric effect creates surprising amounts of electric power by rubbing or touching two different materials together, due to this discovery they found a new way to power mobile devices such as sensors and smartphones.
Rising Demand for energy-efficient solutions
The rising demand for energy-efficient solutions is driving significant advancements in energy harvesting technologies. Energy harvesting involves capturing and storing small amounts of ambient energy from the environment, such as sunlight, vibrations, or heat, and converting it into usable electrical power. This approach is gaining traction across various industries due to its potential to reduce reliance on conventional power sources and lower operational costs. In sectors like IoT devices, where battery life and maintenance are critical, energy harvesting offers a sustainable alternative by extending operational lifespans or eliminating the need for frequent battery replacements.
Regulatory and policy challenges
Energy harvesting faces significant regulatory and policy challenges that impede its widespread adoption and integration into mainstream energy solutions. One major hurdle is the lack of standardized regulations governing energy harvesting technologies across different regions and jurisdictions. These technologies often straddle multiple sectors such as telecommunications, IoT, and infrastructure, each with its own set of regulatory frameworks. The absence of clear guidelines complicates the certification, deployment, and scalability of energy harvesting devices. However, policies related to energy subsidies, incentives, and grid integration play a crucial role in determining the economic viability of energy harvesting projects.
Proliferation of IoT devices and wireless sensor networks
The proliferation of IoT devices and wireless sensor networks is driving significant advancements in energy harvesting technologies. These technologies enable the extraction of energy from ambient sources such as light, heat, and vibration, thereby reducing or eliminating the need for traditional battery replacements or grid connections. This capability is particularly transformative in IoT and sensor network applications where devices are often deployed in remote or inaccessible locations. Additionally, energy harvesting enhances sustainability by promoting renewable energy usage and reducing environmental impact.
High cost of implementation
The high cost of implementation is a significant barrier to the widespread adoption of energy harvesting technologies. These technologies, which aim to capture and convert ambient energy sources like solar radiation, vibrations, or thermal gradients into usable electrical power, often require specialized materials and components that are currently expensive to produce and integrate into existing systems. However, the development of efficient energy harvesting devices involves complex engineering and manufacturing processes, further driving up costs.
The Covid-19 pandemic significantly impacted the energy harvesting sector. Initially, disruptions in global supply chains affected the production and distribution of energy harvesting technologies, leading to delays and shortages. As countries imposed lockdowns and restrictions, research and development activities slowed down, affecting innovation and the introduction of new technologies. However, the economic downturn caused many industries to reduce investments in renewable energy projects, including energy harvesting initiatives, as they prioritized immediate financial stability over long-term sustainability goals.
The Radio Frequency segment is expected to be the largest during the forecast period
Radio Frequency segment is expected to be the largest during the forecast period. Radio Frequency (RF) energy harvesting involves capturing ambient RF waves emitted from various sources such as Wi-Fi routers, cell towers, and broadcasting stations, and converting this electromagnetic energy into usable electrical power. This technology is gaining prominence due to its potential to power small electronic devices and sensors wirelessly, eliminating the need for batteries or frequent recharging. RF energy harvesting typically utilizes antennas designed to resonate at specific frequencies to efficiently capture and convert RF waves into direct current (DC) electricity through rectification circuits.
The Wireless Sensor Networks segment is expected to have the highest CAGR during the forecast period
Wireless Sensor Networks segment is expected to have the highest CAGR during the forecast period. Wireless Sensor Networks (WSNs) are increasingly leveraging energy harvesting techniques to enhance their operational sustainability and autonomy. Energy harvesting allows sensors to generate power from their surrounding environment, reducing or eliminating the need for battery replacements or recharging. This technology enables WSNs to operate in remote or hard-to-access locations where traditional power sources are impractical. Various energy harvesting methods such as solar, wind, vibration, and thermal are being integrated into WSN designs, tailored to specific environmental conditions.
North America region commanded the largest share of the market over the extrapolated period by the rising demand for power-efficient and autonomous devices. These technologies enable devices to harness energy from their immediate environment, reducing dependence on traditional power sources and extending operational lifetimes across the region. The push towards energy efficiency is crucial across various sectors including consumer electronics, industrial automation, and smart infrastructure throughout the region. Advancements in energy harvesting technologies such as solar, thermal, and kinetic energy conversion have spurred innovation, making devices more self-sustaining and environmentally friendly across the region.
Europe region is projected to hold profitable growth during the forecast period. In recent years, Europe has made significant strides in enhancing energy harvesting through innovative government initiatives and policies. One notable policy framework driving this progress is the European Green Deal, which aims to make Europe climate-neutral by 2050. This ambitious plan includes targets for renewable energy adoption and energy efficiency improvements, fostering a conducive environment for energy harvesting technologies across the region. Additionally, various funding programs such as Horizon Europe allocate substantial resources to research and development in sustainable energy solutions, including advanced energy harvesting techniques.
Key players in the market
Some of the key players in Energy Harvesting market include ABB Group, Cymbet Corporation, Energizer Holdings, Inc, GreenPeak Technologies, Honeywell International Inc, Lord Corporation, Microchip Technology Inc, Nextreme Thermal Solutions, Powercast Corporation and Siemens AG.
In October 2023, Powercast and Nichicon collaborated to showcase a demonstration of wireless charging capabilities tailored for small electronic devices. This innovative approach seamlessly integrates radio frequency (RF) charging technology with a compact lithium-ion (Li-Ion) battery, offering a convenient and efficient solution for powering a diverse range of portable devices.
In October 2023, ALD unveiled a groundbreaking innovation with the introduction of the inaugural supercapacitor balancing chip, pioneering its entry into the market. This advanced chip is designed to avert overvoltage failures by boasting a rating of 3.00 volts or higher, setting a new standard for reliability and safety in energy storage systems.
In October 2023, the U.S. government along with various private companies have announced plans for over 94 GW of new clean power generation projects, amounting an estimated USD 133 billion as investment as of August 2023. This is further anticipated to have a positive impact on the market growth.
In December 2022, the government of India announced that the country has planned the investment of over USD 25 billion in the renewable sector encompassing the adoption of advance technology including solar equipment, electric vehicles, & energy storage.