Laura Castro scite author profile

On-site power and mass flow rate measurements were conducted in a hydroelectric power plant (Mexico). Mass flow rate was obtained using Gibson's water hammer-based method. A numerical counterpart was carried out by using the commercial CFD software, and flow simulations were performed to principal components of a hydraulic turbine: runner and draft tube. Inlet boundary conditions for the runner were obtained from a previous simulation conducted in the spiral case. The computed results at the runner's outlet were used to conduct the subsequent draft tube simulation. The numerical results from the runner's flow simulation provided data to compute the torque and the turbine's power. Power-versus-efficiency curves were built, and very good agreement was found between experimental and numerical data.

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Small Organic Rankine Cycle Coupled to Parabolic Trough Solar Concentrator

Caldiño-Herrera

Castro

Jaramillo

et al. 2017

Energy Procedia

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Computational fluid dynamics simulation and geometric design of hydraulic turbine draft tube

Sosa

Urquiza

García

et al. 2015

Advances in Mechanical Engineering

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Any hydraulic reaction turbine is installed with a draft tube that impacts widely the entire turbine performance, on which its functions are as follows: drive the flux in appropriate manner after it releases its energy to the runner; recover the suction head by a suction effect; and improve the dynamic energy in the runner outlet. All these functions are strongly linked to the geometric definition of the draft tube. This article proposes a geometric parametrization and analysis of a Francis turbine draft tube. Based on the parametric definition, geometric changes in the draft tube are proposed and the turbine performance is modeled by computational fluid dynamics; the boundary conditions are set by measurements performed in a hydroelectric power plant. This modeling allows us to see the influence of the draft tube shape on the entire turbine performance. The numerical analysis is based on the steady-state solution of the turbine component flows for different guide vanes opening and multiple modified draft tubes. The computational fluid dynamics predictions are validated using hydroelectric plant measurements. The prediction of the turbine performance is successful and it is linked to the draft tube geometric features; therefore, it is possible to obtain a draft tube parameter value that results in a desired turbine performance.

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Diagnostic and failure analysis in blades of a 300 MW steam turbine

Segura

Castro

Rosales

et al. 2017

Engineering Failure Analysis

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Laura Castro

Failure analysis of a hydraulic Kaplan turbine shaft

Experimental and Numerical Simulations Predictions Comparison of Power and Efficiency in Hydraulic Turbine

Small Organic Rankine Cycle Coupled to Parabolic Trough Solar Concentrator

Computational fluid dynamics simulation and geometric design of hydraulic turbine draft tube

Diagnostic and failure analysis in blades of a 300 MW steam turbine

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