Methods for Rendering Biosafety of Elements in Flow Paths of Hydraulic Turbines

Hydroelectric power belongs to renewable energy sources and contributes a considerable percentage of the electrical energy generated in the world. Its advantages include no carbon dioxide emission, excellent maneuverability, and high energy effectiveness. However, disadvantages do also exist caused...

Full description

Saved in:
Bibliographic Details
Published inThermal engineering Vol. 70; no. 11; pp. 932 - 938
Main Authors Volkov, A. V., Lyapin, V. Yu, Druzhinin, A. A., Biriulin, M. A., Tkach, M., Kachanov, I. V., Hernández, P. G.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.11.2023
Springer Nature B.V
Subjects
Carbon dioxide
Engineering
Engineering Thermodynamics
Flow paths
Heat and Mass Transfer
Hydraulic turbines
Hydraulics
Hydroelectric power
Modernization
Plankton
Rendering
Renewable energy sources
Renewable Energy Sources and Hydropower
Safety
runner spherical hub
biological resources
CFD-simulation
hydroturbines
biosafe hydroturbines
pressure difference
cavitation
Online AccessGet full text

Cover

More Information
Summary:Hydroelectric power belongs to renewable energy sources and contributes a considerable percentage of the electrical energy generated in the world. Its advantages include no carbon dioxide emission, excellent maneuverability, and high energy effectiveness. However, disadvantages do also exist caused by the influence of hydropower facilities on the bioenvironment. This paper presents a review of the most characteristic effects of elements of the flow path of hydroturbines during their operation on biofauna (fish and plankton). The most popular design solutions are examined, which are aimed at reducing the risk of negative impact of the elements of the flow path of hydraulic turbines on the bioenvironment. Obviously, the implementation of these solutions will deteriorate the performance of hydraulic turbines. However, we should bear in mind that the main purpose of these solutions is to ensure the biological safety of facilities, while their energy characteristics do not receive proper attention. The paper presents in some detail an option for rendering environmental safety, which is the modernization of the runner hub by eliminating the gaps between the blades and the hub. Numerical simulation has revealed that the application of a runner with the modified hub increases the hydraulic resistance, decreases the flowrate, and, as a result, reduces the generated power. An analysis of the simulation results has suggested that, despite some decrease in the energy characteristics, it seems worthwhile to develop biologically safer flow path design versions. In addition, a conclusion has been made that the flow path can be further modified to compensate for power losses.
ISSN:0040-6015
1555-6301
DOI:10.1134/S0040601523110125