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浮体式太阳能板市场:按产品、组件、产能、部署、实施 - 2024-2030 年全球预测Floating Solar Panels Market by Product (Stationary Floating Solar Panels, Tracking Floating Solar Panels), Component (Cabling, Combine Box, Floaters), Capacity, Deployment, Implementation - Global Forecast 2024-2030 |
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预计2023年浮体式太阳能板市场规模为3.2375亿美元,预计2024年将达到3.6536亿美元,2030年将达到7.7544亿美元,复合年增长率为13.28%。
浮体式太阳能板是安装在浮动结构上的光伏阵列,设计用于漂浮在水体上,例如水处理池、水力发电大坝、采矿池、工业池塘、湖泊和舄湖。浮体式太阳能通常由太阳能模型、框架、脚踏板和安装组件组成,并且浮体式结构被锚定和锚碇。该技术可在能源生产中提供更高的利润,减少水资源中的水蒸发,并补充水力发电厂的运作。由于工业化程度的提高,全球电力需求迅速增长,加上私营和公共部门对可再生能源的投资,正在推动浮体式太阳能板的需求。另一方面,极端天气条件下的成本密集型集中和维护以及操作复杂性正在阻碍市场成长。然而,浮体式太阳能电池板设计的改进以及用于维护和管理的人工智慧和物联网技术的整合预计将在未来几年扩大其用途。
主要市场统计 | |
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基准年[2023] | 3.2375亿美元 |
预测年份 [2024] | 36536万美元 |
预测年份 [2030] | 77544万美元 |
复合年增长率(%) | 13.28% |
产品:技术进步扩大了追踪浮体式太阳能板的可能性
在固定浮体式太阳能板中,太阳能电池板安装在固定係统上。太阳能电池板因其经济实惠、易于安装且强度高而成为商业性计划中最常见的安装方法。追踪浮体式太阳能电池板是安装在太阳能追踪器或追踪系统上的太阳能电池板,该系统旨在透过追踪太阳的位置来确保最大发电量。虽然安装比传统技术更复杂,成本也稍高,但追踪浮体式太阳能板可以比固定浮体式太阳能板多接收20%以上的阳光,并且可以由于电池板长时间垂直放置,因此可以获得很高的发电效率。在比较浮体式和履带式浮体式太阳能板时,您需要考虑效率、成本、安装复杂性和维护要求等因素。定置型浮体式太阳能板由于成本较低且设计简单,在经济上更可行,但它们可能不会产生与履带式系统那么多的能量。另一方面,追踪 FPV 可以透过全天追踪太阳的路径来显着增加发电量,但这会增加设计和安装的成本和复杂性。这两个选项之间的选择很大程度上取决于每个计划和行业的特定需求。
组件:透过开发光伏组件提高效率和输出
浮体式太阳能板系统的接线可确保电池板与逆变器和变压器等其他组件之间的正确电气连接。优选抗紫外线和防水电缆,以承受水下安装的恶劣条件。汇流箱在连接到变压器或逆变器之前将多个光伏 (PV) 模组的电力输出组合在一起。浮子为光伏组件提供浮力,使它们能够漂浮在水面上,同时保持抗风浪的稳定性。选择高密度聚苯乙烯(HDPE) 作为材料是因为其耐用性和抗紫外线辐射以及与水发生化学反应所引起的劣化。锚碇系统将浮体式太阳能装置锚定在水底或其他固定点,以保持稳定性并防止因水流和风而漂移。光伏组件将阳光转化为电能,是浮体式太阳能板系统的关键组成部分。首选具有耐用封装的高效模组,以最大限度地提高功率输出并抵御环境挑战。结晶电池由硅晶型结构製成,效率高,但成本高。多晶电池由多个小硅结晶组成,效率较低,但价格较便宜,因此常用于大型计划。变压器可调节浮体式太阳能发电厂和并联型点之间的电压水平,确保电力顺利传输到电网或当地能源消费者。输电系统有助于将浮体式太阳能发电厂产生的电力有效地输送到最终用户或电网基础设施。电缆的品质、距海岸的距离和电压等级将决定是否使用交流或直流传输系统。
容量:容量在 1 至 50 MW 之间的浮体式太阳能电池板往往是大中型商业计划的首选。
1至50兆瓦的容量是浮体式太阳能板安装的常见规模,可满足大中型公共的需求。此容量范围非常适合土地空间有限但湖泊、水库、污水处理池等水体丰富的国家和地区。这些装置有助于节省宝贵的土地资源,同时生产清洁能源,而不会对环境产生重大影响。由于规模经济,1至50兆瓦的浮体式太阳能发电厂可以提供高投资收益。容量为 1 MW 或以下的浮体式太阳能板主要适用于住宅、私人企业或能源需求有限的设施的小型安装。容量在1兆瓦或以下时,可以从未使用的水体(例如小池塘和水库)中获取绿色能源,而无需占用土地空间。 50MW及以上的浮体式太阳能板适用于大型公共产业和需要大规模发电能力的计划。这些设施对于希望在不牺牲大片土地的情况下利用水体实现大部分可再生能源发电目标的政府和电力公司来说是理想的选择。大于 50 兆瓦的系统初始成本最高,但与较小的安装相比,可提供更大的规模经济和长期投资收益。
部署:先进的浮体式太阳能板併网部署,满足併并联型大规模电力需求
离网浮体式太阳能板系统专为无法连接到主电网或连接到主电网的费用昂贵的偏远地区而设计。这种独立系统可以作为农村地区、岛国和个人消费者的可靠和永续的电源,这些消费者需要电力来满足照明、抽水和运作小型电器等基本需求。离网浮体式太阳能板系统是首选,因为它们透过利用水库、池塘和湖泊等未使用的水体来减少土地使用衝突,而不是占用宝贵的农田和森林。另一方面,併网浮体式太阳能板系统连接到主电网,旨在满足大规模的能源需求。这些装置非常适合人口稠密的都市区、工业设施和公用事业公司,希望透过清洁、可再生能源来源来实现能源组合多样化。人们对併网浮体式太阳能板的偏好是由于需要进行大规模发电而不占用传统上太阳能发电场所需的大片土地。与离网方案相比,併网浮体式太阳能发电系统也受惠于规模经济,并提供更具竞争力的电费。
发展:太阳能与水力发电结合的发电工程需求不断增长
整合浮体式太阳能电池板是一种太阳能电池板系统,可无缝整合到现有水力发电设施(例如水力发电大坝或水库)的设计中。这种独特的方法使我们能够同时利用土地和水资源,最大限度地发挥发电潜力。整合系统的一个主要好处是它们透过减少水体的暴露表面积来减少蒸发问题。一般来说,在传统太阳能装置的土地有限或节水工作至关重要的情况下,根据需要优先选择整合系统。独立式浮体式太阳能板专为在湖泊、池塘和舄湖等开放水域独立运作而设计。与传统的地面安装面板相比,这些系统具有许多优点,特别是由于水体的自然冷却效应,安装成本更低,高功率。在可用土地稀缺且都市化和工业发展迅速的地区,根据需要可能会首选独立式浮体式太阳能电池板。此外,这些系统在容易发生洪水和极端温度波动的地区具有优势。此整合系统适合与现有水利基础设施计划协同部署,具有发电和节水的双重效益。相比之下,独立系统在位置和尺寸变化方面提供了更大的弹性。
区域洞察
近年来,美洲(主要是北美)的浮体式太阳能板市场一直处于积极成长的轨道,因为可再生能源投资活跃,各国浮体式太阳能发电工程的开发不断增加。南美洲也是浮体式太阳能板的机会,全球公司的进入增加了对浮体式太阳能发电厂的兴趣和投资。在亚太地区,由于私营部门投资和政府倡议,日本、中国、印度和韩国等国家正成为采用包括太阳能在内的清洁能源解决方案的领跑者。此外,由于不断的研究努力,原材料的便捷获取和浮体式太阳能电池技术的进步正在支持该地区的市场成长。欧洲、中东和非洲地区正在积极推动安装浮体式太阳能板,作为帮助欧洲实现其雄心勃勃的低碳能源目标的关键策略。由于对永续能源解决方案的兴趣日益浓厚,中东和非洲也有发展浮体式太阳能的潜力。
FPNV定位矩阵
FPNV定位矩阵对于评估浮体式太阳能板市场至关重要。我们检视与业务策略和产品满意度相关的关键指标,以对供应商进行全面评估。这种深入的分析使用户能够根据自己的要求做出明智的决策。根据评估,供应商被分为四个成功程度不同的像限。最前线 (F)、探路者 (P)、利基 (N) 和重要 (V)。
市场占有率分析
市场占有率分析是一种综合工具,可以对浮体式太阳能板市场供应商的现状进行深入而详细的研究。全面比较和分析供应商在整体收益、基本客群和其他关键指标方面的贡献,以便更好地了解公司的绩效及其在争夺市场占有率时面临的挑战。此外,该分析还提供了对该细分市场竞争特征的宝贵见解,包括在研究基准年观察到的累积、分散主导地位和合併特征等因素。这种详细程度的提高使供应商能够做出更明智的决策并制定有效的策略,从而在市场上获得竞争优势。
1. 市场渗透率:提供有关主要企业所服务的市场的全面资讯。
2. 市场开拓:我们深入研究利润丰厚的新兴市场,并分析其在成熟细分市场的渗透率。
3. 市场多元化:包括新产品发布、开拓地区、最新发展和投资的详细资讯。
4. 竞争评估和情报:对主要企业的市场占有率、策略、产品、认证、监管状况、专利状况和製造能力进行全面评估。
5. 产品开发与创新:包括对未来技术、研发活动和突破性产品开发的见解。
1.浮体式太阳能板市场的市场规模与预测为何?
2.在浮体式太阳能板市场的预测期内,我们应该考虑投资哪些产品和应用?
3.浮体式太阳能板市场的技术趋势和法规结构是什么?
4.浮体式太阳能板市场主要厂商的市场占有率为何?
5.进入浮体式太阳能板市场的适当型态和策略手段是什么?
[189 Pages Report] The Floating Solar Panels Market size was estimated at USD 323.75 million in 2023 and expected to reach USD 365.36 million in 2024, at a CAGR 13.28% to reach USD 775.44 million by 2030.
Floating solar panels are an array of photovoltaics that are designed and installed on buoyant structures to keep them afloat in water bodies such as water treatment ponds, hydroelectric dams, mining ponds, industrial ponds, lakes, and lagoons. Floating solar often consists of solar models, frames, footrests, and mounting assembly, and the floating structures are anchored and moored. The technology provides higher gains in energy production, reduces water evaporation in water resources, and complements operations with hydroelectric power plants. The surging demand for power worldwide with increasing industrialization, coupled with private and public sector investments in renewable energy, drives the need for floating solar panels. On the other hand, cost-intensive deployment and maintenance and operational complexities in extreme weather conditions hinder market growth. However, the improvements in floating solar panel design and integration of AI and IoT technologies for maintenance and management are expected to proliferate their usage in the coming years.
KEY MARKET STATISTICS | |
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Base Year [2023] | USD 323.75 million |
Estimated Year [2024] | USD 365.36 million |
Forecast Year [2030] | USD 775.44 million |
CAGR (%) | 13.28% |
Product: Increasing scope for tracking floating solar panels with technological advancements
In stationary floating solar panels, solar panels are attached to fixed systems. They are the most common type of mounting commercially used in projects due to their affordability, simple deployment, and strength. Tracking floating solar panels are solar panels installed on solar trackers or tracking systems, which are mounting systems designed to ensure maximum power generation by following the position of the sun. Although their installation is complex and slightly cost-intensive compared to conventional technology, tracking floating solar panels receives over 20% more sunlight than stationary floating solar panels, ensuring higher efficiency as the panels are aligned perpendicular to the sun's rays for an extended period. When comparing stationary and tracking floating solar panels, key factors to consider include efficiency, cost, installation complexity, and maintenance requirements. Stationary floating solar panels are more economically accessible due to their lower costs and simpler designs, but may not generate as much energy as tracking systems. On the other hand, tracking FPVs can produce significantly more electricity by following the sun's path throughout the day; however, it comes with increased costs and complexities in design and installation. The choice between these two options primarily depends on the specific needs of each project or industry.
Component: Developments in PV modules for higher efficiencies and improved power output
The cabling in floating solar panel systems ensures proper electrical connections between panels and other components, such as inverters and transformers. There is a preference for UV-resistant and waterproof cables to withstand the harsh conditions of water-based installations. A combined box consolidates electrical output from multiple photovoltaic (PV) modules before connecting to the transformer or inverter. Floaters provide buoyancy to the PV modules, enabling them to float on water surfaces while maintaining stability against waves and wind forces. Material preferences include high-density polyethylene (HDPE) for durability and resistance to degradation under UV exposure or chemical reactions with water. A mooring system anchors the floating solar installation to the bed of a body of water or another fixed point to maintain stability and prevent drifting due to currents or winds. PV modules convert sunlight into electricity and are the primary component of a floating solar panel system. High-efficiency modules with durable encapsulation materials are preferred to maximize power output and withstand environmental challenges. Monocrystalline cells are made from a single-crystal silicon structure, resulting in higher efficiency rates but at a higher cost. Polycrystalline cells, composed of multiple smaller silicon crystals, have lower efficiency rates but are less expensive, making them a popular choice for large-scale projects. Transformers adjust voltage levels between the floating solar plant and the grid connection point, ensuring smooth electricity transmission to the grid or local energy consumers. The transmission system facilitates efficient delivery of generated power from the floating solar plant to end users or the grid infrastructure. Cable quality, distance from shore, and voltage level determine AC or DC transmission system preferences.
Capacity: Growing preference for capacity of 1-50MW floating solar panels across medium to large-scaled commercial projects
The 1-50MW capacity is the common scale for floating solar panel installations, catering to the needs of medium to large-sized utility projects. This capacity range is ideal for countries and regions with limited land space but abundant water bodies such as lakes, reservoirs, and wastewater treatment ponds. These installations help save valuable land resources while generating clean energy without significant environmental impacts. 1-50MW floating solar plants can provide a higher return on investment owing to their potential for economies of scale. Floating solar panels with capacities less than 1MW cater to small-scale installations primarily for residential usage, private businesses, or facilities with limited energy requirements. Less than 1MW capacity enables users to harness green energy from unused water bodies such as small ponds or reservoirs without occupying land space. More than 50MW floating solar panels cater to large-scale utility projects that require massive electricity generation capacities. These installations are ideal for governments and utility companies looking to generate a significant portion of their renewable energy goals from water bodies without sacrificing vast tracts of land. More than 50MW systems have the highest upfront costs but also offer greater economies of scale and long-term returns on investment compared to smaller installations.
Deployment: Evolving on-grid deployment of floating solar panels to fulfill large-scale power demand through grid connectivity
Off-grid floating solar panel systems are designed for remote locations where connection to the main power grid is not feasible or expensive. These standalone systems often serve as a reliable and sustainable power source for rural communities, island nations, and individual consumers needing electricity for basic needs such as lighting, pumping water, or running small appliances. The preference for off-grid floating solar panel systems is high due to reduced land-use conflicts by utilizing under-utilized water bodies such as reservoirs, ponds, or lakes instead of occupying valuable agricultural or forest land. On the other hand, on-grid floating solar panel systems are linked to the main power grid and aim to fulfill large-scale energy demands. These installations are ideal for densely populated urban areas, industrial facilities, and utility companies looking to diversify their energy portfolio with clean and renewable sources. The preference for on-grid floating solar panels is driven by the need for large-scale power generation without occupying vast land areas traditionally required for solar farms. On-grid floating solar systems also benefit from economies of scale, resulting in more competitive electricity costs compared to off-grid options.
Implementation: Growing demand for integrated solar power projects along with hydroelectric power
Integrated floating solar panels are solar panel systems that have been seamlessly incorporated into the design of existing water facilities, such as hydroelectric dams or reservoirs. This unique approach allows for the simultaneous utilization of land and water resources, maximizing power generation potential. A key advantage of integrated systems is their ability to mitigate issues related to evaporation by reducing the exposed surface area of the water body. Need-based preferences for integrated systems typically arise in locations with limited available land for conventional PV installations or where water conservation efforts are paramount. Standalone floating solar panels are designed specifically for independent operation on open bodies of water such as lakes, ponds, or lagoons. These systems offer numerous benefits over traditional ground-mounted panels, particularly regarding reduced installation costs and higher power output due to natural cooling effects from water bodies. A need-based preference for standalone floating solar panels may arise in regions experiencing rapid urbanization or industrial development where available land is scarce. Additionally, these systems can be advantageous in areas prone to flooding or extreme temperature fluctuations. Integrated systems are well-suited for synergistic deployment alongside existing water infrastructure projects, offering dual power generation and water conservation benefits. In contrast, standalone systems offer greater flexibility regarding installation locations and size variation.
Regional Insights
In the Americas, particularly North America, the floating solar panels market has witnessed a positive growth trajectory in recent years due to the considerable investments in renewable energy and increasing deployment of floating solar projects in countries. South America also presents opportunities for floating solar panels, rising interest, and investments in floating solar farms with the entry of global players in the region. In the Asia-Pacific region, countries including Japan, China, India, and South Korea are emerging as frontrunners in adopting clean energy solutions that involve solar energy due to investments made by the private sector and initiatives launched by the regional governments. Moreover, the easy access to raw materials and advancements in floating solar technology with continuous research efforts support the market growth in the region. In the EMEA region, Europe is actively pursuing the installation of floating solar panels as a key strategy for achieving its ambitious low-carbon energy goals. The Middle East and Africa also hold potential for floating solar expansion due to their growing interest in sustainable energy solutions.
FPNV Positioning Matrix
The FPNV Positioning Matrix is pivotal in evaluating the Floating Solar Panels Market. It offers a comprehensive assessment of vendors, examining key metrics related to Business Strategy and Product Satisfaction. This in-depth analysis empowers users to make well-informed decisions aligned with their requirements. Based on the evaluation, the vendors are then categorized into four distinct quadrants representing varying levels of success: Forefront (F), Pathfinder (P), Niche (N), or Vital (V).
Market Share Analysis
The Market Share Analysis is a comprehensive tool that provides an insightful and in-depth examination of the current state of vendors in the Floating Solar Panels Market. By meticulously comparing and analyzing vendor contributions in terms of overall revenue, customer base, and other key metrics, we can offer companies a greater understanding of their performance and the challenges they face when competing for market share. Additionally, this analysis provides valuable insights into the competitive nature of the sector, including factors such as accumulation, fragmentation dominance, and amalgamation traits observed over the base year period studied. With this expanded level of detail, vendors can make more informed decisions and devise effective strategies to gain a competitive edge in the market.
Key Company Profiles
The report delves into recent significant developments in the Floating Solar Panels Market, highlighting leading vendors and their innovative profiles. These include Adani Green Energy Limited, Adtech Systems Limited, Ciel et Terre International SAS, EDF Renewables SA, First Solar, Inc, Hanwha Group, HelioRec S.A.S., Iberdrola, S.A., JA SOLAR Technology Co., Ltd., JinkoSolar Holding Co., Ltd., Kyocera Corporation, KYORAKU Co., Ltd., Larsen & Toubro Limited, LERRI Solar Technology Co., Ltd. by LONGi Green Energy Technology Co. Ltd., LG CNS Co., Ltd., Masdar, Nouria Energy Corporation, NRG ISLAND s.r.l., Ocean Sun AS, Pristine Sun LLC, Q ENERGY Solutions SE, REC Solar Holdings AS, RWE AG, Scotra Co., Ltd., SPG Solar, Inc., Sungrow Power Supply Co., Ltd., Swimsol GmbH, Tata Power Solar Systems Limited, The Sumitomo Mitsui Construction Company, Ltd., Trina Solar Co., Ltd., Vikram Solar Limited, Wuxi Suntech Power Co., Ltd., Xiamen Mibet New Energy Co., Ltd., and Yingli Energy Development Co., Ltd..
Market Segmentation & Coverage
1. Market Penetration: It presents comprehensive information on the market provided by key players.
2. Market Development: It delves deep into lucrative emerging markets and analyzes the penetration across mature market segments.
3. Market Diversification: It provides detailed information on new product launches, untapped geographic regions, recent developments, and investments.
4. Competitive Assessment & Intelligence: It conducts an exhaustive assessment of market shares, strategies, products, certifications, regulatory approvals, patent landscape, and manufacturing capabilities of the leading players.
5. Product Development & Innovation: It offers intelligent insights on future technologies, R&D activities, and breakthrough product developments.
1. What is the market size and forecast of the Floating Solar Panels Market?
2. Which products, segments, applications, and areas should one consider investing in over the forecast period in the Floating Solar Panels Market?
3. What are the technology trends and regulatory frameworks in the Floating Solar Panels Market?
4. What is the market share of the leading vendors in the Floating Solar Panels Market?
5. Which modes and strategic moves are suitable for entering the Floating Solar Panels Market?