Water turbines market is expected to grow steadily from 2025 to 2035 due to rising renewable energy funding and fossil fuel powered grid decarbonization initiatives and evolving power generation requirements for sustainable operations. Water turbines operate as central elements in hydropower systems that change water motion energy to mechanical forces which generates electrical output. The water turbine market will show a 4.4% annual growth rate throughout the forecast period from 2025 to 2035 while increasing from USD 2,630.9 million in 2025 to USD 4,236.9 million in 2035.
The hydropower capacity expansion continues to receive momentum from supportive government policies and growing rural electricity consumption requirements and requirements for stable power grids. Industrial growth in fish-friendly technologies combined with modular system deployment and low-head turbine development tackles existing environmental challenges and cost barriers.
Manufacturing companies develop smart monitoring technologies and enhanced efficiency blades to enhance production efficiency. Water turbines have become essential for developing nations because they provide powerful clean continuous solutions for grid-connected power generation.
Key Market Metrics
| Metric | Value |
|---|---|
| Industry Size (2025E) | USD 2,630.9 million |
| Industry Value (2035F) | USD 4,236.9 million |
| CAGR (2025 to 2035) | 4.4% |
The market segmentation shows that water turbine technology varies in type and capacity which affects both their operating design principles and power plant site selection and also their conversion efficiency. Pelton and Francis and Kaplan describe three different types of turbines that operate best when matched to particular height and flow rates of water.
The energy requirements and water resources determine the capacity extent which spans from small hydro units measuring below 10 MW up to utility-grade installation platforms. Water turbines demonstrate flexibility through different operational segments that adapt to a variety of geographical conditions and power supply plans found across the globe.
Steady demand in North America from modernization of aging hydro plants. Funding for efficient turbine retrofits and rural electrification through small-scale hydropower projects also comes from the USA and Canada.
Hydroelectric expansion is further promoted in Europe as part of its green transition agenda. Advanced pump-turbine technology in alpine and river-based power stations in Norway, Austria and Switzerland
Large scale installation of hydro projects drives growth in Asia-Pacific. Rising electricity demand and rural electrification spur investments in water turbine infrastructure across China, India, and Southeast Asia.
Challenge
Environmental Constraints and Site-Specific Design Limitations
Regulatory pressure on the environmental impact of water turbines is rising, such as regulations limiting underwater habitats and fish migration. Large-scale installations also change river ecosystems, interrupt fish migration and require expensive environmental impact assessments. Also, water turbine systems are extremely site-specific the flow rate of the water, head height, and amount of sediment have a direct impact on efficiency and design feasibility.
In regions with no standardized hydro planning, this makes upfront project complexity and costs much higher. Many small hydro operators are also increasingly finding it hard to access funding and technical know-how, stymieing the rollout of micro and mini-hydro projects in rural or off-grid applications despite growing demand for energy.
Opportunity
Renewable Energy Shift and Small-Scale Hydro Development
As global decarbonization efforts accelerate, water turbines provide an essential source of renewable, base-load power. Governments worldwide are upgrading and improving the efficiency of existing hydropower, and investing in small-scale hydro systems that work to balance out the variability of wind and solar. Kaplan, Francis, and Pelton turbine technology advancements are yielding optimized energy output, even under low-flow conditions.
Generating electricity from hydro resources using micro and pico-hydro installations are being used mainly in off grid and rural electrification projects in different parts of Asia, Africa and South America. As digital monitoring, predictive maintenance, and hybridization of renewable systems become more integrated, water-based turbines are evolving to simultaneously accomplish goals of environmental sustainability along with long-term energy reliability.
The water turbine market steadily increased between 2020 and 2024 as aging hydroelectric plants were retrofitted and small hydro projects modestly expanded. But scrutiny on environmental grounds and lengthy permitting timelines delayed progress on large dam projects. Operators took this step to bring new improvements and extend the lifespan of existing plants.
During 2025- 2035, the market will be in transitive phase towards smart hydro systems based on new flow modelling, IoT sensors, grid-reactive technologies etc. Increased Focus on Low-Head and Run-of-River Projects to Expand Turbine Deployment in Eco-Sensitive Areas the role of water turbines will be redefined in future energy landscapes with decentralized hydro and hybrid renewable integration.
Market Shifts: Comparative Analysis 2020 to 2024 vs. 2025 to 2035
| Market Factor | 2020 to 2024 |
|---|---|
| Regulatory Landscape | Compliance with local water use and impact mitigation rules. |
| Technological Advancements | Focus on efficiency upgrades for traditional Kaplan, Pelton, and Francis turbines. |
| Sustainability Trends | Emphasis on emission-free energy, but limited in habitat-sensitive areas. |
| Market Competition | Dominated by traditional turbine manufacturers and national hydro developers. |
| Industry Adoption | Popular in national grids, irrigation projects, and large hydro dams. |
| Consumer Preferences | Demand for reliable, cost-effective renewable electricity. |
| Market Growth Drivers | Driven by energy security and legacy hydro modernization. |
| Market Factor | 2025 to 2035 |
|---|---|
| Regulatory Landscape | Expansion of environmental permitting, fish-friendly design mandates, and carbon credit alignment. |
| Technological Advancements | Growth in smart turbines, modular low-head systems, and digitally managed micro-hydro units. |
| Sustainability Trends | Expansion into eco-hydropower, hybrid micro grids, and sustainable river basin management. |
| Market Competition | Entry of green energy startups, decentralized utility providers, and tech-enabled solution firms. |
| Industry Adoption | Expands into community electrification, climate-resilient infrastructure, and off-grid solutions. |
| Consumer Preferences | Shift to low-impact, modular, and digitally optimized water power systems. |
| Market Growth Drivers | Accelerated by off-grid electrification, climate policies, and renewable integration mandates. |
The United States water turbine market is witnessing stable growth on the account of modernization of old hydropower infrastructure and focus on clean energy generation. Numerous existing dams are also retrofitted with high-efficiency Francis and Kaplan turbines to be able to maximize the output from them and to extend their life.
Policies supporting sustainable integration into the grid and improved micro-hydro installations from the government are putting pressure on private and municipal utilities to invest in water turbine systems that can scale. The environmental compliance regulations have increased focus on fish-friendly and low-head turbine technologies.
| Country | CAGR (2025 to 2035) |
|---|---|
| USA | 4.1% |
The UK water turbine market is moderately progressing, with interest in small-scale hydropower for rural electrification and sustainability goals. The UK, which has few large river systems, is turning to run-of-the-river and micro-hydro to supplement its renewable mix.
New compact turbines and lowmaintenance systems are making their way into community-based installations and off-grid uses. The deployment of turbines is still finding avenues of opportunity thanks to regulatory support for decentralized energy production.
| Country | CAGR (2025 to 2035) |
|---|---|
| UK | 4.0% |
Hydropower is the backbone of second-tier water turbine markets in the EU, driven by strong hydropower portfolios in Norway, Austria, and France. EU energy policies aimed at decarbonization and energy independence are driving investments in turbine upgrades and dam refurbishments.
Grid-flexibility supporting technologies, such as q reversible pumped-storage unit or variable-speed Peliton turbine, are being more implemented more widely. EU funding and public-private partnerships underpinned the market for large and distributed hydro solutions, enabling sooner uptake of hydro solutions.
| Region | CAGR (2025 to 2035) |
|---|---|
| European Union | 4.4% |
Japan market for water turbine grows steadily, as disaster-resilient, decentralized renewable power sources are prioritized. In mountainous regions where terrain is conducive to localized generation, small- and medium-sized hydro projects are also in the spotlight.
Japanese producers are creating small, efficient cross-flow and bulb turbines that can be applied in narrow rivers and irrigation channels. Because of environmental issues and restricted spaces, submerged and low-impact turbine systems are encouraging innovations.
| Country | CAGR (2025 to 2035) |
|---|---|
| Japan | 4.2% |
The rising interest of South Korea in developing the water turbine market reflects the country's goal of diversifying its renewable energy portfolio. Hydropower is being tapped for its reliability and compatibility with energy storage technologies, particularly in pumped-storage systems.
Domestic companies are making use of high-efficiency Kaplan and Francis turbines for existing reservoirs and new river-based projects. South Korea’s smart grid and carbon neutrality rationale may provide incentives to expand hydropower infrastructure long term.
| Country | CAGR (2025 to 2035) |
|---|---|
| South Korea | 4.7% |
Increased reliance on hydropower to achieve clean energy goals, improve grid reliability, and decarbonize the electricity mix is driving continued growth in the water turbine market as governments and private utilities increasingly embrace the strengths of hydropower. And the kinetic and potential energy of flowing water is converted into mechanical energy, driving a generator to create hydroelectric power at the water turbines.
The Francis turbine is the leading machine type on the market due to its versatility, high efficiency as well as use in medium to high-head hydropower plants. Based on application, power generation holds the biggest market share, since water turbines continue to be the leading technology for renewable electricity generation, in both large and small scale installations. Collectively, these segments comprise a market for which sustainable development, energy security, and long-term operational stability are paramount.
Hydroelectric projects, especially those that use strong turbine designs such as Francis turbines, are on the rise as countries prioritize meeting climate targets Learn More. Because water turbines are critical for providing base-load renewable energy, both the design and application segments are pivotal to future energy transitions.
| Design Type | Market Share (2025) |
|---|---|
| Francis Turbine | 38.6% |
Francis turbines are at the forefront of the design sector over a large spread of water head conditions, usually between 40 and 600 meters. These inward-flow reaction turbines are deployed in medium to large hydroelectric plants by engineers because they combine aspects of axial and radial flow, leading to energy conversion efficiencies of up to 95%. This characteristic provides reliability and low cost to utilities looking for consistent performance and low maintenance in long-term energy projects. They are compatible with vertical and horizontal installations due to their enclosed design.
Francis turbines are often preferred by operators in grid-connected hydro plants since load balancing and continuous generation are more important in these plants. When water availability is seasonal, the hydraulic turbines handle fluctuating water flow rates while ensuring efficient power output.
Blade geometry, hydraulic profiles and digital monitoring systems continue to be refined by manufacturers to increase equipment life and performance. In developing countries and mountainous areas, the demand for hydropower solutions is booming, while proven machines and engineering design flexibility benefits Francis machine development.
| Application Type | Market Share (2025) |
|---|---|
| Power Generation | 84.2% |
The application segment of the water turbine market is dominated by power generation, as hydropower is the most developed and reliable form of renewable energy worldwide. Hydroelectric power plants utilize one or more water turbines to transform the energy in river flow, discharge from reservoirs or pumped water into electricity that can be used to provide base-load power demand from the residential, commercial, and industrial sectors.
And countries with abundant amounts of water resources use water turbines to provide a much higher rate of their energy mix to stabilize voltage, manage peak loads, and support variable renewables such as wind and solar.
Small hydro projects, run-of-river installations and large dams remain closely connected to long-term power output where turbines are the predominant investment for utility, independent power producers and others. Grid operators in many regions rely upon hydropower for its rapid responsiveness and low operating cost, particularly when electricity demand is high.
As societies strive to transition away from fossil fuels to mitigate environmental impacts, water turbines are essential to sustainable energy plans. With the capability to provide clean, dependable electricity, power generation will continue to be the leading application of the water turbine market for many years to come.
The global water turbine market has a significant role in hydroelectric power generation, where kinetic and potential energy of water is transformed into mechanical and then electrical energy. Water turbines like Kaplan, Francis, Pelton, cross-flow types are used in large hydropower plants, small hydro stations and pumped storage systems.
As countries invest in clean energy infrastructure and repowering of their aging hydropower assets, the demand for high-efficiency, low-maintenance turbine systems continues to increase. Market leaders include global engineering conglomerates as well as hydro-specialist manufacturers that compete based on turbine output optimization, site-specific adaptability, durability under variable flow conditions, and adherence to environmental flow regulations.
Market Share Analysis by Company
| Company Name | Estimated Market Share (%) |
|---|---|
| General Electric Company (GE Renewable) | 20-24% |
| Voith Hydro Holding GmbH & Co. KG | 15-19% |
| ANDRITZ Hydro GmbH | 12-16% |
| Toshiba Energy Systems & Solutions | 9-13% |
| Hitachi Mitsubishi Hydro Corporation | 7-11% |
| Harbin Electric Corporation | 6-10% |
| Other Companies (combined) | 18-26% |
| Company Name | Key Offerings/Activities |
|---|---|
| GE Renewable Energy | Delivered digitalized Francis and Kaplan turbines with predictive analytics for large hydro plants in 2025. |
| Voith Hydro GmbH | Launched modular small hydro turbines with fish-friendly features and variable-speed control in 2024. |
| ANDRITZ Hydro | Rolled out high-head Pelton turbines with enhanced efficiency for alpine hydropower stations in 2024. |
| Toshiba ESS | Installed low-noise, eco-sensitive Kaplan turbines in urban mini-hydro systems across Japan in 2025. |
| Hitachi Mitsubishi Hydro | Released compact hydro units with smart automation for run-of-river and small-scale pumped storage in 2024. |
| Harbin Electric | Expanded large-capacity turbine manufacturing for state-run hydro projects in China and Southeast Asia in 2025. |
Key Company Insights
GE Renewable Energy
GE Renewable leads the global water turbine market through its comprehensive portfolio of digitalized hydro turbines and grid-integrated systems. Its turbines support modernization and digital twins, improving uptime and efficiency in both Greenfield and brownfield hydropower stations.
Voith Hydro Holding GmbH & Co. KG
Voith is known for highly engineered turbine solutions and hydropower modernization services. It’s variable-speed and environmentally optimized turbine designs cater to both large hydroelectric dams and community-scale micro-hydro installations.
ANDRITZ Hydro GmbH
ANDRITZ focuses on high-performance turbine units across all types, especially Pelton and Francis variants for high-head and mid-range applications. Its capabilities include turnkey installation and retrofitting of legacy hydro stations.
Toshiba Energy Systems & Solutions
Toshiba ESS delivers compact and eco-conscious turbine systems, ideal for Japan’s urban rivers and constrained hydro sites. Its low-noise, high-efficiency turbines meet strict environmental and operational standards.
Hitachi Mitsubishi Hydro Corporation
HM Hydro develops small and mid-scale water turbines with robust automation systems. The company’s compact turbines are widely used in run-of-river installations and integrated energy management systems.
Harbin Electric Corporation
Harbin Electric focuses on supplying large-capacity hydro turbines for national energy projects in Asia. Its mass manufacturing capabilities and project execution experience make it a strategic partner for developing countries investing in hydroelectric infrastructure.
Other Key Players (18-26% Combined)
Numerous regional turbine manufacturers and engineering firms contribute to the global water turbine market through specialized equipment, site-specific design, and niche hydropower solutions:
Table 1: Global Market Value (US$ Mn) Forecast by Region, 2017-2032
Table 2: Global Market Volume (Units) Forecast by Region, 2017-2032
Table 3: Global Market Value (US$ Mn) Forecast by Design, 2017-2032
Table 4: Global Market Volume (Units) Forecast by Design, 2017-2032
Table 5: Global Market Value (US$ Mn) Forecast by Application, 2017-2032
Table 6: Global Market Volume (Units) Forecast by Application, 2017-2032
Table 7: North America Market Value (US$ Mn) Forecast by Country, 2017-2032
Table 8: North America Market Volume (Units) Forecast by Country, 2017-2032
Table 9: North America Market Value (US$ Mn) Forecast by Design, 2017-2032
Table 10: North America Market Volume (Units) Forecast by Design, 2017-2032
Table 11: North America Market Value (US$ Mn) Forecast by Application, 2017-2032
Table 12: North America Market Volume (Units) Forecast by Application, 2017-2032
Table 13: Latin America Market Value (US$ Mn) Forecast by Country, 2017-2032
Table 14: Latin America Market Volume (Units) Forecast by Country, 2017-2032
Table 15: Latin America Market Value (US$ Mn) Forecast by Design, 2017-2032
Table 16: Latin America Market Volume (Units) Forecast by Design, 2017-2032
Table 17: Latin America Market Value (US$ Mn) Forecast by Application, 2017-2032
Table 18: Latin America Market Volume (Units) Forecast by Application, 2017-2032
Table 19: Europe Market Value (US$ Mn) Forecast by Country, 2017-2032
Table 20: Europe Market Volume (Units) Forecast by Country, 2017-2032
Table 21: Europe Market Value (US$ Mn) Forecast by Design, 2017-2032
Table 22: Europe Market Volume (Units) Forecast by Design, 2017-2032
Table 23: Europe Market Value (US$ Mn) Forecast by Application, 2017-2032
Table 24: Europe Market Volume (Units) Forecast by Application, 2017-2032
Table 25: Asia Pacific Market Value (US$ Mn) Forecast by Country, 2017-2032
Table 26: Asia Pacific Market Volume (Units) Forecast by Country, 2017-2032
Table 27: Asia Pacific Market Value (US$ Mn) Forecast by Design, 2017-2032
Table 28: Asia Pacific Market Volume (Units) Forecast by Design, 2017-2032
Table 29: Asia Pacific Market Value (US$ Mn) Forecast by Application, 2017-2032
Table 30: Asia Pacific Market Volume (Units) Forecast by Application, 2017-2032
Table 31: MEA Market Value (US$ Mn) Forecast by Country, 2017-2032
Table 32: MEA Market Volume (Units) Forecast by Country, 2017-2032
Table 33: MEA Market Value (US$ Mn) Forecast by Design, 2017-2032
Table 34: MEA Market Volume (Units) Forecast by Design, 2017-2032
Table 35: MEA Market Value (US$ Mn) Forecast by Application, 2017-2032
Table 36: MEA Market Volume (Units) Forecast by Application, 2017-2032
Figure 1: Global Market Value (US$ Mn) by Design, 2022-2032
Figure 2: Global Market Value (US$ Mn) by Application, 2022-2032
Figure 3: Global Market Value (US$ Mn) by Region, 2022-2032
Figure 4: Global Market Value (US$ Mn) Analysis by Region, 2017-2032
Figure 5: Global Market Volume (Units) Analysis by Region, 2017-2032
Figure 6: Global Market Value Share (%) and BPS Analysis by Region, 2022-2032
Figure 7: Global Market Y-o-Y Growth (%) Projections by Region, 2022-2032
Figure 8: Global Market Value (US$ Mn) Analysis by Design, 2017-2032
Figure 9: Global Market Volume (Units) Analysis by Design, 2017-2032
Figure 10: Global Market Value Share (%) and BPS Analysis by Design, 2022-2032
Figure 11: Global Market Y-o-Y Growth (%) Projections by Design, 2022-2032
Figure 12: Global Market Value (US$ Mn) Analysis by Application, 2017-2032
Figure 13: Global Market Volume (Units) Analysis by Application, 2017-2032
Figure 14: Global Market Value Share (%) and BPS Analysis by Application, 2022-2032
Figure 15: Global Market Y-o-Y Growth (%) Projections by Application, 2022-2032
Figure 16: Global Market Attractiveness by Design, 2022-2032
Figure 17: Global Market Attractiveness by Application, 2022-2032
Figure 18: Global Market Attractiveness by Region, 2022-2032
Figure 19: North America Market Value (US$ Mn) by Design, 2022-2032
Figure 20: North America Market Value (US$ Mn) by Application, 2022-2032
Figure 21: North America Market Value (US$ Mn) by Country, 2022-2032
Figure 22: North America Market Value (US$ Mn) Analysis by Country, 2017-2032
Figure 23: North America Market Volume (Units) Analysis by Country, 2017-2032
Figure 24: North America Market Value Share (%) and BPS Analysis by Country, 2022-2032
Figure 25: North America Market Y-o-Y Growth (%) Projections by Country, 2022-2032
Figure 26: North America Market Value (US$ Mn) Analysis by Design, 2017-2032
Figure 27: North America Market Volume (Units) Analysis by Design, 2017-2032
Figure 28: North America Market Value Share (%) and BPS Analysis by Design, 2022-2032
Figure 29: North America Market Y-o-Y Growth (%) Projections by Design, 2022-2032
Figure 30: North America Market Value (US$ Mn) Analysis by Application, 2017-2032
Figure 31: North America Market Volume (Units) Analysis by Application, 2017-2032
Figure 32: North America Market Value Share (%) and BPS Analysis by Application, 2022-2032
Figure 33: North America Market Y-o-Y Growth (%) Projections by Application, 2022-2032
Figure 34: North America Market Attractiveness by Design, 2022-2032
Figure 35: North America Market Attractiveness by Application, 2022-2032
Figure 36: North America Market Attractiveness by Country, 2022-2032
Figure 37: Latin America Market Value (US$ Mn) by Design, 2022-2032
Figure 38: Latin America Market Value (US$ Mn) by Application, 2022-2032
Figure 39: Latin America Market Value (US$ Mn) by Country, 2022-2032
Figure 40: Latin America Market Value (US$ Mn) Analysis by Country, 2017-2032
Figure 41: Latin America Market Volume (Units) Analysis by Country, 2017-2032
Figure 42: Latin America Market Value Share (%) and BPS Analysis by Country, 2022-2032
Figure 43: Latin America Market Y-o-Y Growth (%) Projections by Country, 2022-2032
Figure 44: Latin America Market Value (US$ Mn) Analysis by Design, 2017-2032
Figure 45: Latin America Market Volume (Units) Analysis by Design, 2017-2032
Figure 46: Latin America Market Value Share (%) and BPS Analysis by Design, 2022-2032
Figure 47: Latin America Market Y-o-Y Growth (%) Projections by Design, 2022-2032
Figure 48: Latin America Market Value (US$ Mn) Analysis by Application, 2017-2032
Figure 49: Latin America Market Volume (Units) Analysis by Application, 2017-2032
Figure 50: Latin America Market Value Share (%) and BPS Analysis by Application, 2022-2032
Figure 51: Latin America Market Y-o-Y Growth (%) Projections by Application, 2022-2032
Figure 52: Latin America Market Attractiveness by Design, 2022-2032
Figure 53: Latin America Market Attractiveness by Application, 2022-2032
Figure 54: Latin America Market Attractiveness by Country, 2022-2032
Figure 55: Europe Market Value (US$ Mn) by Design, 2022-2032
Figure 56: Europe Market Value (US$ Mn) by Application, 2022-2032
Figure 57: Europe Market Value (US$ Mn) by Country, 2022-2032
Figure 58: Europe Market Value (US$ Mn) Analysis by Country, 2017-2032
Figure 59: Europe Market Volume (Units) Analysis by Country, 2017-2032
Figure 60: Europe Market Value Share (%) and BPS Analysis by Country, 2022-2032
Figure 61: Europe Market Y-o-Y Growth (%) Projections by Country, 2022-2032
Figure 62: Europe Market Value (US$ Mn) Analysis by Design, 2017-2032
Figure 63: Europe Market Volume (Units) Analysis by Design, 2017-2032
Figure 64: Europe Market Value Share (%) and BPS Analysis by Design, 2022-2032
Figure 65: Europe Market Y-o-Y Growth (%) Projections by Design, 2022-2032
Figure 66: Europe Market Value (US$ Mn) Analysis by Application, 2017-2032
Figure 67: Europe Market Volume (Units) Analysis by Application, 2017-2032
Figure 68: Europe Market Value Share (%) and BPS Analysis by Application, 2022-2032
Figure 69: Europe Market Y-o-Y Growth (%) Projections by Application, 2022-2032
Figure 70: Europe Market Attractiveness by Design, 2022-2032
Figure 71: Europe Market Attractiveness by Application, 2022-2032
Figure 72: Europe Market Attractiveness by Country, 2022-2032
Figure 73: Asia Pacific Market Value (US$ Mn) by Design, 2022-2032
Figure 74: Asia Pacific Market Value (US$ Mn) by Application, 2022-2032
Figure 75: Asia Pacific Market Value (US$ Mn) by Country, 2022-2032
Figure 76: Asia Pacific Market Value (US$ Mn) Analysis by Country, 2017-2032
Figure 77: Asia Pacific Market Volume (Units) Analysis by Country, 2017-2032
Figure 78: Asia Pacific Market Value Share (%) and BPS Analysis by Country, 2022-2032
Figure 79: Asia Pacific Market Y-o-Y Growth (%) Projections by Country, 2022-2032
Figure 80: Asia Pacific Market Value (US$ Mn) Analysis by Design, 2017-2032
Figure 81: Asia Pacific Market Volume (Units) Analysis by Design, 2017-2032
Figure 82: Asia Pacific Market Value Share (%) and BPS Analysis by Design, 2022-2032
Figure 83: Asia Pacific Market Y-o-Y Growth (%) Projections by Design, 2022-2032
Figure 84: Asia Pacific Market Value (US$ Mn) Analysis by Application, 2017-2032
Figure 85: Asia Pacific Market Volume (Units) Analysis by Application, 2017-2032
Figure 86: Asia Pacific Market Value Share (%) and BPS Analysis by Application, 2022-2032
Figure 87: Asia Pacific Market Y-o-Y Growth (%) Projections by Application, 2022-2032
Figure 88: Asia Pacific Market Attractiveness by Design, 2022-2032
Figure 89: Asia Pacific Market Attractiveness by Application, 2022-2032
Figure 90: Asia Pacific Market Attractiveness by Country, 2022-2032
Figure 91: MEA Market Value (US$ Mn) by Design, 2022-2032
Figure 92: MEA Market Value (US$ Mn) by Application, 2022-2032
Figure 93: MEA Market Value (US$ Mn) by Country, 2022-2032
Figure 94: MEA Market Value (US$ Mn) Analysis by Country, 2017-2032
Figure 95: MEA Market Volume (Units) Analysis by Country, 2017-2032
Figure 96: MEA Market Value Share (%) and BPS Analysis by Country, 2022-2032
Figure 97: MEA Market Y-o-Y Growth (%) Projections by Country, 2022-2032
Figure 98: MEA Market Value (US$ Mn) Analysis by Design, 2017-2032
Figure 99: MEA Market Volume (Units) Analysis by Design, 2017-2032
Figure 100: MEA Market Value Share (%) and BPS Analysis by Design, 2022-2032
Figure 101: MEA Market Y-o-Y Growth (%) Projections by Design, 2022-2032
Figure 102: MEA Market Value (US$ Mn) Analysis by Application, 2017-2032
Figure 103: MEA Market Volume (Units) Analysis by Application, 2017-2032
Figure 104: MEA Market Value Share (%) and BPS Analysis by Application, 2022-2032
Figure 105: MEA Market Y-o-Y Growth (%) Projections by Application, 2022-2032
Figure 106: MEA Market Attractiveness by Design, 2022-2032
Figure 107: MEA Market Attractiveness by Application, 2022-2032
Figure 108: MEA Market Attractiveness by Country, 2022-2032
The overall market size for the water turbine market was USD 2,630.9 million in 2025.
The water turbine market is expected to reach USD 4,236.9 million in 2035.
The increasing focus on renewable energy generation, rising adoption of hydroelectric power infrastructure, and growing implementation of Francis turbines in power generation applications fuel the water turbine market during the forecast period.
The top 5 countries driving the development of the water turbine market are the USA, UK, European Union, Japan, and South Korea.
Francis turbines and power generation applications lead market growth to command a significant share over the assessment period.
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