한국해양대학교

Detailed Information

Metadata Downloads

Numerical and Experimental Study on Vortex Rope with MGV in the Micro-Class Hydro Francis Turbine

DC Field Value Language
dc.contributor.advisor 이영호 -
dc.contributor.author ENKHTAIVAN BATMUNKH -
dc.date.accessioned 2019-12-16T02:53:29Z -
dc.date.available 2019-12-16T02:53:29Z -
dc.date.issued 2018 -
dc.identifier.uri http://repository.kmou.ac.kr/handle/2014.oak/11667 -
dc.identifier.uri http://kmou.dcollection.net/common/orgView/200000014200 -
dc.description.abstract Energy consumption is a huge part of our daily life. Today we gather most of our energy from coal, oil and natural gas also known fossil fuels. Generating electricity on our planet, requires plenty of massive power plants and transmission grid system delivery to the power. Renewable energy comes from a source that is not depleted when using such as wind, solar and hydropower. Hydropower is the largest source of renewable energy which is capture the energy of falling water to generate electricity as well can be efforts produce number of benefits such as a water supply, flood control and irrigation system. Micro-hydropower installation can provide power to the out-settlement or small community. These usually range between 5kW-100kW of electricity output. In this study, numerical and experimental analysis of 3kW micro-class Francis turbine carried out to predict performance of the turbine. A Draft tube is one of the most important part of Francis turbine which connects the runner exit to the tailrace where the water is being finally discharged at atmospheric pressure from the reaction turbine. There are several issues in the draft tube like pressure pulsation, effect of cavitation on draft tube performance, vortex rope study etc. At part-load condition vortex form it hits structure constantly which is affect the performance of the turbine. This study focused on prediction of vortex behavior at the draft tube and numerical results obtained the hydraulic performance of 3kW micro-class Francis turbine with the inlet pipe, a spiral casing with 12 guide vanes, 6 stay vanes and the runner having 13 blades and a draft tube. Ansys CFX software used to simulate for the numerical analysis of micro-class Francis turbine. Three misaligned guide vane (MGV) openings with 5 different MGV openings were chosen to analyze the influence of the pressure pulse in the turbine. Additionally, PIV technique was used to investigate flow velocity in the draft tube. In the numerical simulation, different sets of operating points were selected to get performance characteristics of the turbine and best efficiency point indicated 91.67% efficiency at 0.02m3/s, power output 3.32kW. For misaligned guide vanes, more options can be tried out by misaligning more guide vanes, at higher angles. Additionally, based on the numerical analysis of a Francis turbine, the results for efficiency obtained from simulation are found to good agreement with the model results obtained from the manufacturer. From the performed experiment on performance test of Francis turbine using the Francis turbine experimental set-up in the Flow Informatics Laboratory at Korean Maritime and Ocean University. The experimental analysis of the turbine showed a significant result. The turbine operated at different vane angle setting were obtained and tested by varying the parameters as a guide vane angle in the 6 different range of between 2-12 degrees, speed, and 500-1700 rpm respectively. The lowest difference between the experimental and numerical results was 2.03% and the maximum difference between the experimental and numerical results was 6.12 %. Numerical efficiency higher than experimental efficiency. -
dc.description.tableofcontents CHAPTER 1. INTRODUCTION 1 1.1 Background 1 1.2 History of hydropower 2 1.3 Classification of the hydropower plant 3 1.3.1 River Power Plant (Run-Of-River) 4 1.3.2 Pumped storage hydropower plant 5 1.3.3 Reservoir hydropower plant 5 1.3.4 Instream technology using existing facilties 6 1.4 Organization of hydropower plant 6 CHAPTER 2. HYDRO TURBINES 8 2.1 Classification of turbine 8 2.1.1 Based on head and quantity of water available 8 2.1.2 Classification based on action of the water flowing through runner 9 2.1.3 Classification based on Direction of flow of water in runner 10 2.1.4 Classification based on specific speed 10 2.2 Francis turbine 12 2.2.1 Components of the Francis turbine 12 2.2.2 Spiral Casing 13 2.2.3 Runner 13 2.2.4 Guide vanes and stay vanes 14 2.2.5 Draft tube 14 2.3 Cavitation in francis turbine 19 CHAPTER 3. PERFORMANCE AND DESIGN OPTIMIZATION OF SETUP TURBINE 22 3.1 Modeling 22 3.2 Numerical analysis 28 3.2.1 Computational fluid dynamics (CFD) 28 3.2.2 Grid discretization 29 3.2.3 Boundary condition 31 3.2.4 Hydraulic efficiency and power characteristic 32 3.2.5 Flow feature and pressure distribution 34 3.3 Unsteady flow analysis 41 3.3.1 Unsteady flow at full load 41 3.3.2 Unsteady flow at partial load 45 3.3.3 A draft tube swirl 46 3.3.4 Vortex rope in part flow 46 3.4 Signal analysis 52 3.5 Misaligned guide vane 55 CHAPTER 4. EXPERIMENTAL ANALYSIS 58 4.1 Eexperimental setup 58 4.2 Experimental apparatus specifications 60 4.2.1 Torque Transducer 60 4.2.2 Powder brake 62 4.2.3 Pressure transducers 63 4.2.4 Flow mmeter 64 4.3 Calibration and uncertainty analysis 66 4.4 Eexperimental procedure 67 4.4.1 Starting the Pump 67 4.4.2 Starting the Francis turbine 67 4.4.3 Hydraulic efficiency of experimental 67 4.5 PIV experiment 70 4.5.1 Overview of PIV Flow Visualization 70 4.5.2 Configuration of PIV experiment device 71 4.5.3 Lighting and tracking particles 73 4.5.4 Result of the PIV experiment 75 CHAPTER 5. CONCLUSION 82 Acknowledgement 83 References 84 -
dc.language eng -
dc.publisher 한국해양대학교 대학원 -
dc.rights 한국해양대학교 논문은 저작권에 의해 보호받습니다. -
dc.title Numerical and Experimental Study on Vortex Rope with MGV in the Micro-Class Hydro Francis Turbine -
dc.type Dissertation -
dc.date.awarded 2018-02 -
dc.contributor.department 대학원 기계공학과 -
dc.contributor.affiliation 한국해양대학교 대학원 기계공학과 -
dc.description.degree Master -
dc.subject.keyword Francis turbine, Vortex rope, Misaligned guide vane, Computational Fluid Dynamic (CFD), PIV -
dc.identifier.holdings 000000001979▲200000000139▲200000014200▲ -
Appears in Collections:
기계공학과 > Thesis
Files in This Item:
Numerical and Experimental Study on Vortex Rope with MGV in the Micro-Class Hydro Francis Turbine.pdf Download

Items in Repository are protected by copyright, with all rights reserved, unless otherwise indicated.

Browse