Abstract
Fossil fuels are energy sources that supply a large part of the world's energy generation. However, they produce greenhouse gases such as carbon dioxide (CO2), nitrogen oxide (NOx) and particulates that increase global warming. For this reason, other forms of renewable energy such as hydropower have begun to be implemented through turbomachinery such as Pelton turbines, which significantly reduce these emissions since they are highly efficient turbines based on the use of natural resources (water). Pelton turbines are based mainly on three components for their operation, which are the Pelton injector, the bucket and the wheel. The injector is an important component in the energy transformation of Pelton turbines. Although to analyze its behavior, it is possible to use fluid dynamics (CFD) software to predict the trajectory of the flow through a solid or free surface. The objective of this work is to analyze by means of computational fluid dynamics (CFD) the incidence of the length and the needle tip angle of a Pelton turbine injector on the generated power. For this, an ANSYS 2020R2 computational fluid analysis software was used to study how the variation of the injector needle tip angle influences through the volume of fluid (VOF) method, starting from the generation of a commercial model with a tip angle of 60° and two (2) geometries of 55° and 75° respectively. Numerical results show a better performance for the 75° angle of 96 % and lower for the 55° and 60° with 94.1 % and 95.5 % respectively, whereby steeper angles achieve higher performances. In summary, the present study pretends to increase the power generation, in the face of phenomena occurred in the energy transfer. Although the performance of the injector in each angle configuration must be tested in practice
Highlights
Nowadays, fossil fuels supply 84.3 % of the world’s total electricity generation
This study focuses only on the computational fluid dynamics (CFD) analysis of the variation in the needle tip angle using volume of fluid (VOF) simulation methods
Geometry results As a result of the design and modeling process of the injectors, three CAD models were obtained in commercial software ANSYS V20R1 in the «SPACECLAIM» module for 100 % opening, one of which corresponds to the commercial model of the Techydro brand with a 60° needle tip angle and two from the design equations described in the methodology
Summary
Fossil fuels supply 84.3 % of the world’s total electricity generation. the combustion and generation of pollutants emitted into the atmosphere such as carbon dioxide (CO2) and nitrogen oxides (NOx) increase the production of greenhouse gases (GHG) and, global warming. The injector plays an important role in the conversion of fluid pressure energy into kinetic energy For this reason, in recent years, Pelton turbine efficiency gains have been studied with the support of experimental and/or numerical me thodologies, modifying both geometrical and operational parameters in order to estimate the effects of the injector on energy transfer. [9, 10] adopted the VOF model configurations to analyze the jet characteristics in the face of head changes The results of their investigation revealed that the secondary flows induced by Dean vortices upstream of the injector caused deformations downstream of the injector affecting the turbine performance. [24, 25] compared the changes in turbine performance with changing geometrical parameters in the injector, confirming that the cause of jet dispersion is mainly due to the injector geometry
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