8 results ·
● Live web index
M
mdpi.com
article
https://www.mdpi.com/1996-1073/9/3/164
Evaluation of the Fluid Model Approach for the Sizing of Energy Storage in Wave-Wind Energy Systems. Analysis of the Potential for Use of Floating Photovoltaic Systems on Mine Pit Lakes: Case Study at the Ssangyong Open-Pit Limestone Mine in Korea. The aim is to provide a snapshot of some of the most exciting work published in the various research areas of the journal. In this study, a Francis turbine with specific speed of 130 m-kW was designed on the basis of the port area and loss analysis. The results show that the effect of the port area of runner blade on the flow exit angle from runner passage is significant. In this study, a new method on basis of the port area and loss analysis to design a Francis turbine runner was developed for the Miryang power station in Korea. The meridional shape of the runner was designed on the basis of the combination of the guide vane loss analysis and experience.
J
jffhmt.avestia.com
article
https://jffhmt.avestia.com/2025/036.html
### Study the Effect of Blade Angle on Hydrokinetic Turbine Performance. ***Abstract -*** *Harnessing renewable energy from water currents, such as rivers and tidal streams, without extensive infrastructure, positions hydrokinetic turbines as a highly promising technology. This research details the design and optimization of hydrokinetic turbine blade profiles to significantly improve their efficiency and overall performance. A comprehensive analysis, utilizing Computational Fluid Dynamics (CFD) simulations, was conducted to investigate the influence of varying angles on blade hydrodynamic performance. The findings conclusively demonstrate that the optimal selection of the blade angle can substantially enhance turbine efficiency, thus bolstering its potential for large-scale energy production. Furthermore, a specific angle of 67.5 degrees exhibited an unexpectedly superior power output compared to angles of 15 and 45 degrees. This work advances hydrokinetic technology and provides a robust framework for the continued optimization of renewable energy systems.*. ***Keywords:*** CFD, energy, hydrokinetic turbine, blade angle. The objective of this project is to design, build, and test a hydrokinetic turbine with different blade angles.
R
researchgate.net
research
https://www.researchgate.net/publication/321115990_Effect_of_blade_angle_on_t…
The results from the laboratory indicated that the HST with a twenty-one degree blade angle had 38.10% efficiency at the water flow rate of 2 m/s. It could
S
sciencedirect.com
article
https://www.sciencedirect.com/science/article/abs/pii/S0960148124019906
by MS Roh · 2025 · Cited by 12 — Based on the optimized blade angles, the efficiencies are improved by 1.12 % and 1.42 % at N S = 150 and 270 respectively with a constant power output of 30 MW.
R
rgu-repository.worktribe.com
article
https://rgu-repository.worktribe.com/OutputFile/1380146
by F MOHAMED · Cited by 5 — Pressure and power coefficients for 'S' shaped blades have been calculated and it is reported that the use of deflectors decreases the power output of the VAWT.
T
testbook.com
article
https://testbook.com/mechanical-engineering/francis-turbine
Francis Turbine: Construction, Working Principle, Diagram, PDF & Efficiency. Francis Turbine: Construction, Working Principle, Diagram, PDF & Efficiency Exam Preparation. A Francis Turbine is a widely used type of reaction turbine that efficiently converts both the pressure energy and kinetic energy of water into mechanical energy. Known as a mixed-flow reaction turbine, water enters the turbine radially and exits axially, allowing smooth and effective energy conversion. Francis Turbines are particularly suitable for medium-head hydroelectric power plants, with water heads ranging from 40 meters to 600 meters. The turbine’s performance is measured through Francis Turbine efficiency, which includes mechanical, hydraulic and overall efficiency parameters, providing insight into energy conversion effectiveness. Operating as a reaction turbine, it harnesses the power of water under high pressure, utilising both the reaction and impulse forces generated as the water flows past its blades. This turbine is widely employed in hydroelectric power plants for energy generation.
E
en.wikipedia.org
article
https://en.wikipedia.org/wiki/Francis_turbine
# Francis turbine. Francis inlet scroll at the Grand Coulee Dam. Side-view cutaway of a vertical Francis turbine. Here water enters horizontally in a spiral-shaped pipe (spiral case) wrapped around the outside of the turbine's rotating *runner* and exits vertically down through the center of the turbine. The **Francis turbine** is a type of water turbine. Francis turbines are the most common water turbine in use, and can achieve over 95% efficiency. A wicket gate "Wicket gate (hydraulics)") around the outside of the turbine's rotating runner controls the rate of water flow through the turbine for different power production rates. Francis turbines are usually mounted with a vertical shaft, to isolate water from the generator. The Francis turbine is a type of reaction turbine, a category of turbine in which the working fluid comes to the turbine under immense pressure and the energy is extracted by the turbine blades from the working fluid.
P
pubs.aip.org
article
https://pubs.aip.org/aip/adv/article/13/7/075208/2901828/Numerical-study-of-t…
The maximum efficiency is achieved at the lean angle of 5°. When the lean angle exceeds 5°, the efficiency drops dramatically. The power is