日本浮动太阳光电市场评估：依产品、系统、应用、区域、机会和预测（FY2018-FY2032F）

日本浮动太阳光电市场规模预计将从2024年度的2.3014亿美元增至2032年度的4.0832亿美元，预计2025年度至2032年度的年复合成长率为 7.43%。近年来，市场呈现显着成长，预计在预测期内将保持显着扩张速度。

浮动太阳光电（FPV）系统是一种可行的太阳能利用方法，特别是对于土地面积较小和人口稠密的国家。此外，对清洁能源的需求不断增加，尤其是在日本，对浮动太阳能等创新再生能源解决方案的需求也不断成长。製造商不断改进浮动太阳光电技术。浮动结构的耐用性和先进的锚固系统创新使浮动太阳能装置更加可靠和更具成本效益。此外，政府对再生能源计画的政策和财政激励支持预计将继续显着推动浮动太阳光电市场的成长。

例如，2024年 5月，SolarDuck BV 和房地产公司 Tokyo Land 建造了日本第一个海上浮动太阳光电计画。该浮动太阳光电厂产生的能量将储存在附近的BESS 装置中，并为附近的电力车队提供动力。

模组化设计与系统可扩充性

浮动太阳光电系统的模组化设计本质上是可扩展的，允许逐步扩展工厂。随着再生能源需求的增加或更多资本的可用，公用事业提供者可以透过添加模组将工厂从小规模扩大到大型规模。模组化设计能力对于开发商和电力公司尤其有利。可扩展性允许根据性能资料和不断变化的能源需求进行调整，使浮动太阳光电系统成为更易于管理且风险更低的投资。

浮动太阳光电系统的模组化设计可以定制，以适应特定的专案要求和环境条件。可根据水体特征和气候条件选择组件尺寸、类型和配置，以透过浮动太阳能光电系统实现能源生产目标。此外，客製化功能使 FPV 系统成为多功能解决方案。浮动太阳光电（FPV）系统可以适应独特的场地条件并最佳化能源输出，进一步推动浮动太阳光电在日本的采用。

此外，浮动太阳光电的模组化设计可以轻鬆且经济地在水上部署。浮式太阳能发电系统可以安装在任何类型或尺寸的水面上，包括人工水库、天然湖泊、池塘、河流、进水坝和海洋。甚至设计模组都可以适应不同形状和深度的水体，这增加了漂浮式太阳能发电的适用性和市场潜力。

因此，浮动太阳光电系统的模组化设计和可扩展性特征提供了灵活性、成本效率、对不同计画规模和条件的适应性以及更高的财务可行性，推动日本浮动太阳光电市场的成长。

例如，根据国家再生能源实验室2022年的报告，日本约占浮动太阳光电（FPV）装机总量的10%。

耐候功能满足市场需求

浮动太阳光电系统透过提供可持续和适应性的发电方法来显着支持气候适应能力。浮动太阳光电系统还具有多种环境效益，包括较低的蒸发率，减少对气候变迁的影响。此外，浮动太阳光电系统可以节省宝贵的水资源，可用于农业、住宅和自然栖息地活动。浮动太阳光电系统有助于最大限度地减少土地使用问题，保护生态系统，并保持土地可用于其他商业用途。在各种形式的再生能源发电技术中，浮动太阳光电技术可以节省土地和水资源，否则这些资源将用于该国的城市化和农业扩张。

本报告研究和分析了日本浮动太阳光电市场，提供市场规模和预测、市场动态以及主要参与者的现状和前景。

目录

第1章 专案范围与定义

第2章 研究方法

第3章 执行摘要

第4章 日本浮动太阳光电市场展望（2018年度-2032年度）

• 市场规模分析与预测
  • 金额
  • 数量
• 市占率分析与预测
  • 依产品
  • 依系统
  • 依用途
  • 依地区
  • 市占率分析：依公司（价值）（前5名公司及其他 -2024年度）
• 市场地图分析（2024年）
  • 依产品
  • 依系统
  • 依用途
  • 依地区

第5章 波特五力分析

第6章 PESTLE 分析

第7章 市场动态

• 市场驱动因素
• 市场挑战

第8章 市场趋势与发展

第9章 个案研究

第10章 竞争态势

• 前5名市场领导者的竞争矩阵
• 前5名的公司的SWOT分析
• 前10名主要企业状况
  • Sungrow Power Supply Co., Ltd.
  • Ciel Terre Japan Co., Ltd.
  • BayWa r.e. Japan K.K.
  • LS ELECTRIC Japan Co., Ltd.
  • Trina Solar Japan Energy Co., Ltd.
  • Sumitomo Mitsui Construction Co., Ltd.
  • ABL Group
  • SolarDuck B.V.
  • Kyocera TCL Solar LLC
  • Laketricity Japan Co., ltd.

第11章 战略建议

第12章 关于本公司，免责声明

Japan floating photovoltaics market is projected to witness a CAGR of 7.43% during the forecast period FY2025- FY2032, growing from USD 230.14 million in FY2024 to USD 408.32 million in FY2032. The market has experienced significant growth in recent years and is expected to maintain a significant pace of expansion in the forecast years.

The floating photovoltaics (FPV) system is a feasible approach to the utilization of sunlight, particularly for countries with small land areas and over-population. Furthermore, with the rise in the demand for clean energy, especially in Japan, will boost the need for innovative renewable energy solutions such as floating photovoltaic. Manufacturers are constantly improving the technology for floating photovoltaics. Innovations in the durability of floating structures and advanced anchoring systems make floating photovoltaic installations more dependable and cost-effective. Moreover, supporting government policies and financial incentives regarding renewable energy projects will continue to drive the floating photovoltaic market growth significantly.

For instance, in May 2024, SolarDuck B.V. and Tokyo Land, a real estate company, built Japan's first offshore floating PV project. The floating PV plant's energy will be stored in a nearby BESS unit and power a nearby electric fleet.

Modular Design and Ease of Scalability of the Systems

The modular design of a floating photovoltaics system is scalable in nature and allows for incremental expansion of plants. The utility provider will be able to change the size of the plant from small to large capacity by adding more modules as the demand for renewable energy increases or as more capital is available. The modular design capability is particularly beneficial for developers and utilities as scalability allows for adjustments based on performance data and evolving energy needs, which result in floating photovoltaic systems in more manageable and lower-risk investments.

The modular design of floating photovoltaic systems can be customized to meet specific project requirements and environmental conditions. The module sizes, types, and configurations could be chosen based on the water body characteristics and climatic conditions to achieve the energy production goals through a floating photovoltaics system. Moreover, the customization capability feature makes FPV systems a versatile solution. Floating photovoltaics (FPV) systems are able to cater to unique site conditions and optimize energy output, which further boosts the adoption of floating photovoltaics in Japan.

In addition, the deployment of modular design floating photovoltaics on water bodies is easy and economical. The floating photovoltaic systems can be installed on any water surface type and size, including artificial reservoirs, natural lakes, ponds, rivers, impounding dams, and oceans. Even the design modules are capable of adapting the varying shapes and depths of water bodies, which boosts floating photovoltaics applicability and market potential.

Thus, the modular design and scalability attributes of floating photovoltaic systems offer flexibility, cost efficiency, adaptability to different project sizes and conditions, and improved financial viability, which drive the growth of the Japan floating photovoltaics market.

For instance, as per the FY2022 report by the National Renewable Energy Laboratory, Japan accounted for approximately 10% of the total floating photovoltaic (FPV) installed capacity.

Climate Resilience Feature to Cater the Market Demand

The floating photovoltaic system significantly supports climate resilience by providing a sustainable and adaptive approach to energy generation. The system offers several environmental benefits such as low evaporation rate which lowers the impact of climate change. Additionally, floating photovoltaic systems preserve valuable water resources which could be used for agriculture, housing, or natural habitat activities. The floating photovoltaic systems contribute to minimizing the issue of using land, preserving the ecosystems, and keeping the land available for other commercial uses. Among different forms of renewable energy generation technologies, the floating photovoltaics technology saves land and water resources which would be used for urbanization and agricultural expansion within the country.

Floating photovoltaics systems are inherently resilient to direct impacts of climate change, such as rising sea levels and increased flooding. Floating photovoltaics installations are designed to float on water which overcomes the problems associated with traditional ground-mounted solar farms. In Japan, coastal and low-lying areas, where rising sea levels pose a significant risk to renewable energy infrastructure, floating photovoltaics systems offer a robust alternative which continue operating even as water levels change.

For instance, in May 2024, SolarDuck B.V. decided to open new office in Tokyo (Japan) to oversee the country's activities. Asia-Pacific offers attractive growth prospects for market growth. Developing countries are able to understand the FPV advantage on climate which boosts the FPV demand in the market.

Technological Development in Market Creates Opportunity

The development of tracking solar system technology is creating new opportunities for the floating photovoltaics market. The tracking panels boost the efficiency and energy yield in solar installations at water bodies. Solar-tracking PV systems observe the movement of the sun and change the position and orientation of solar modules with the view of collecting the highest possible solar power.

Compared to stationary systems, floating photovoltaics tracking systems are capable of maximizing sunlight captured by the panels since the adjustment of the panel is made according to the movement of the sun. Consequently, the total energy yield from tracking FPV systems is higher than the fixed systems. The increased energy output would significantly enhance the profitability of floating photovoltaics installations, especially in regions with high solar irradiance. In addition, the tracking feature in floating photovoltaics systems improves the return on investment for solar projects which make the system more financially attractive for developers and utility providers.

Moreover, modern tracking systems would be able adjust the panels position according to the directions of sun rays, that stands well with the weather conditions to protect the panels and optimize performance. Upcoming developments in tracking technology make the FPV systems more adaptable to changing environmental conditions, including the speed of wind and water currents which boosts the demand for floating photovoltaics technology in the market.

Development of tracking technology for floating photovoltaics systems represents a significant advancement which enhances the efficiency, performance, and market potential of floating photovoltaics (FPV) installations in the forecast years.

Stationary Floating Solar Panels Dominates the Market Share

Japan floating photovoltaics market is dominated by the stationary floating solar panel due to high adoption rate in country. Stationary floating solar panels offer fewer points of failure which lowers lifetime maintenance and operating expenses of the system. Stationary floating solar panel products are economical and cost effective in nature. Additionally, regulatory agencies and governments consistently promote the use of renewable energy technology, such as floating photovoltaics technology which drive the growth of the market for stationary floating solar panel products. Fixed floating solar panels have made the product economically viable option for investors and developers. Several beneficial aspects of stationary floating solar panels sustain their dominance in the market.

Central Region to Lead the Floating Photovoltaics Market Share in Japan

Japan floating photovoltaics market is expected to be dominated by the central region, including Kanto and Chubu, in the forecast years. The central region includes several manufacturers of solar panels and developers of solar projects, which makes the region particularly appropriate for the deployment of floating photovoltaic panels. The region includes several water bodies consisting of major reservoirs, lakes, and irrigation ponds, possibly ideal for installing floating solar panels. The region includes several dams and man-made reservoirs that generate hydroelectric power, creating the opportunity to generate electricity in the region using FPV solar panels.

Central Japan has ambitious renewable energy goals and state policy to reduce state greenhouse gas emissions and have cleaner energy which drive the floating photovoltaic markets in the country. The Japan floating photovoltaics market is driven by the country's targets for generating renewable energy and state policies to lower greenhouse gas emissions and provide cleaner energy.

For instance, Kyocera company has developed the floating solar (FPV) power plant on the Yamakura Dam reservoir in Chiba Prefecture, Japan. The FPV plant capacity is 13.7MW, which is the largest plant in Japan.

Future Market Scenario (FY2025 - FY2032F)

Ongoing innovations and advancement in floating photovoltaics technology will improve the design of panels which will enhance the feasibility and cost-effectiveness of the systems.

Japan pushes and focuses on more sustainable energy solutions for generating electricity, which is expected to drive the growth of floating photovoltaics solar panels in the country.

Features such as solar tracking and hydraulic pumps of floating photovoltaics systems will boost the demand for solar-tracking floating solar panels in the forecast years.

Rise in government supportive policies and financial incentives for renewable energy projects is anticipated to boost the photovoltaics market in Japan.

Key Players Landscape and Outlook

Continuous innovation characterizes the landscape of floating photovoltaics, as the companies compete for solar projects, energy efficiency, and unique features. The market seems to have a positive outlook, owing to the increased demand for renewable energy. Floating photovoltaics players are concerned with supply chain resilience, energy efficiency, and environmental practices. Collaborations and developing technologies are projected to increase competition in this fast-paced market.

For instance, in January 2024, Laketricity Japan Co, Ltd (Ciel & Terre International Group) developed a floating solar power plant and began selling electricity to Ondani Ike in Japan. The plant is equipped with 665-W panels and is expected to produce 3,196MWh of electricity in its first year.

Table of Contents

1. Project Scope and Definitions

2. Research Methodology

3. Executive Summary

4. Japan Floating Photovoltaics Market Outlook, FY2018-FY2032F

• 4.1. Market Size Analysis & Forecast
  • 4.1.1. By Value
  • 4.1.2. By Volume
• 4.2. Market Share Analysis & Forecast
  • 4.2.1. By Product
    • 4.2.1.1. Stationary Floating Solar Panels
    • 4.2.1.2. Solar-tracking Floating Solar Panels
  • 4.2.2. By System
    • 4.2.2.1. Stand Alone FPV Systems
    • 4.2.2.2. Hybrid FPV Hydropower Systems
  • 4.2.3. By Application
    • 4.2.3.1. Man-made Water Bodies
    • 4.2.3.2. Natural Water Bodies
  • 4.2.4. By Region
    • 4.2.4.1. North [Hokkaido and Tohoku]
    • 4.2.4.2. Central [Kanto and Chubu]
    • 4.2.4.3. South [Kansai, Chugoku, Shikoku, Kyushu, Okinawa]
  • 4.2.5. By Company Market Share Analysis (Top 5 Companies and Others - By Value, FY2024)
• 4.3. Market Map Analysis, FY2024
  • 4.3.1. By Product
  • 4.3.2. By System
  • 4.3.3. By Application
  • 4.3.4. By Region

All segments will be provided for all regions

5. Porter's Five Forces Analysis

6. PESTLE Analysis

7. Market Dynamics

• 7.1. Market Drivers
• 7.2. Market Challenges

8. Market Trends and Developments

9. Case Studies

10. Competitive Landscape

• 10.1. Competition Matrix of Top 5 Market Leaders
• 10.2. SWOT Analysis for Top 5 Players
• 10.3. Key Players Landscape for Top 10 Market Players
  • 10.3.1. Sungrow Power Supply Co., Ltd.
    • 10.3.1.1. Company Details
    • 10.3.1.2. Key Management Personnel
    • 10.3.1.3. Products and Services
    • 10.3.1.4. Financials (As Reported)
    • 10.3.1.5. Key Market Focus and Geographical Presence
    • 10.3.1.6. Recent Developments/Collaborations/Partnerships/Mergers and Acquisition
  • 10.3.2. Ciel Terre Japan Co., Ltd.
  • 10.3.3. BayWa r.e. Japan K.K.
  • 10.3.4. LS ELECTRIC Japan Co., Ltd.
  • 10.3.5. Trina Solar Japan Energy Co., Ltd.
  • 10.3.6. Sumitomo Mitsui Construction Co., Ltd.
  • 10.3.7. ABL Group
  • 10.3.8. SolarDuck B.V.
  • 10.3.9. Kyocera TCL Solar LLC
  • 10.3.10. Laketricity Japan Co., ltd.

Companies mentioned above DO NOT hold any order as per market share and can be changed as per information available during research work.

11. Strategic Recommendations

12. About us and Disclaimer

List of Tables

• Table 1. Pricing Analysis of Products from Key Players
• Table 2. Competition Matrix of Top 5 Market Leaders
• Table 3. Mergers & Acquisitions/ Joint Ventures (If Applicable)
• Table 4. About Us - Regions and Countries Where We Have Executed Client Projects

List of Figures

• Figure 1. Japan Floating Photovoltaics Market, By Value, In USD Million, FY2018-FY2032F
• Figure 2. Japan Floating Photovoltaics Market, By Volume, In Megawatt (MW), FY2018-FY2032F
• Figure 3. Japan Floating Photovoltaics Market Share (%), By Product, FY2018-FY2032F
• Figure 4. Japan Floating Photovoltaics Market Share (%), By System, FY2018-FY2032F
• Figure 5. Japan Floating Photovoltaics Market Share (%), By Application, FY2018-FY2032F
• Figure 6. Japan Floating Photovoltaics Market Share (%), By Region, FY2018-FY2032F
• Figure 7. By Product Map-Market Size (USD Million) & Growth Rate (%), FY2024
• Figure 8. By System Map-Market Size (USD Million) & Growth Rate (%), FY2024
• Figure 9. By Application Map-Market Size (USD Million) & Growth Rate (%), FY2024
• Figure 10. By Region Map-Market Size (USD Million) & Growth Rate (%), FY2024