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Numerical and Experimental Study on Micro Cross Flow Turbine Including the Prediction of Sediment Erosion
| DC Field | Value | Language |
|---|---|---|
| dc.contributor.author | MAUSAMSHRESTHA | - |
| dc.date.accessioned | 2017-02-22T02:24:59Z | - |
| dc.date.available | 2017-02-22T02:24:59Z | - |
| dc.date.issued | 2016 | - |
| dc.date.submitted | 2016-03-12 | - |
| dc.identifier.uri | http://kmou.dcollection.net/jsp/common/DcLoOrgPer.jsp?sItemId=000002235833 | ko_KR |
| dc.identifier.uri | http://repository.kmou.ac.kr/handle/2014.oak/8367 | - |
| dc.description.abstract | A hydro plant from 5kW up to 100kW is usually responsible to provide power for a small community or rural industry in remote areas away from the grid. It gives the best solution to the power need of rural and small communities which serves as decentralized power source to meet the local population requirement. Energy requirement for lighting cooking heating drying agro processing and other small scale industries activates can be met through these Micro hydro power (MHPs) in the most reliable way in the rural areas of the country like Nepal. Cross flow turbines are widely used in such MHPs due to their simple design, easier maintenance, low initial investment and modest efficiency. Also because of their suitability under low heads, efficient operation under a wide range of flow variations and ease of fabrication. Numerical simulation and Experimental analysis was carried out to achieve the objective of the study. Previous studies and experiment conducted in the lab were used as the reference for the further studies. Computational fluid dynamics (CFD) simulations and experiments have been conducted at various rotational speed, guide vane angle and different flow rates and the result has been compared. The previous study mostly focused on the change in the shape of the nozzle components and the casing. Based on such design the setup has been constructed. Performance study of the setup was conducted to validate the CFD results obtained. The change in the shape of the blade has been considered in this work and the performance with the change in nozzle has been studied. CFD simulation has been conducted for the change in the shape of the blade based on the inlet angle and the diameter ratio of the turbine. The change gives positive change in the efficiency and the performance of the turbine The structural strength of the turbine has been analyzed based on the pressure points obtained from the CFD simulations. The forces exerted by the water on the surface of the blades has been mapped on the using the Ansys Workbench Structural analysis and the stress and the deformation on the turbine blade has been studied. Sediment erosion is one of the key challenges in hydraulic turbines especially in the Himalayan from a design and maintenance perspective in Himalayas. The effect and has been studied of sediment erosion and its effects on the turbine has been done for the various size, shape and mass flow rate of the sediment particles. | - |
| dc.description.tableofcontents | Table of contents iii List of tables vi List of figures vii Abstract x List of abbreviations xii List of symbols xiii 1. Micro hydro power 1 1.1 Introduction 1 1.2 Research objectives 4 2. Hydraulic turbines 5 2.1 Introduction to hydraulic turbines 5 2.2 Types of hydro turbines 6 2.2.1 Classification based on the action of water on blades 6 2.2.2 Classification based on the direction of flow of fluid through runner 6 2.2.3 Classification based on specific speed 6 2.2.4 Reaction turbine 7 2.2.5 Impulse turbine 9 2.2.6 Cross flow turbine 10 2.2.7 Comparison of different types of turbines 12 2.2.8 Principle 15 2.2.9 Efficiency 15 2.2.10 Casing 17 2.2.11 Guide vanes 17 2.2.12 Rotor 18 2.2.13 Flow through a cross–flow turbine 19 2.3 Literature review and previous work on the cross flow turbine 22 2.3.1 Turbine setup and experiments results 24 2.3.2 Design optimization and results 27 3. Performance analysis and design optimization of setup turbine 30 3.1 Modeling 30 3.2 CFD simulations 31 3.3 Performance analysis of reference turbine for simulation 35 3.4 Experimental equipment and test procedures 41 3.4.1 The turbine 41 3.4.2 Installation 43 3.4.3 Instrumentation 46 3.4.4 Experimental results for the variation for rotational speed 51 3.4.5 Experimental results for the various flow rates 52 3.4.6 Experimental results for various guide vane angles 53 3.5 Comparison of experimental and CFD simulation results 54 3.6 Experimental result comparison for base turbine and setup turbine 57 3.7 CFD simulation for the change in blade with respect to the diameter ratio 58 3.8 Distribution based on the shape of the inlet angle of the blade 62 3.9 Performance at various numbers of blades 66 4. Static structural analysis 68 4.1 Static structure 68 4.2 Geometry and meshing 69 4.3 Boundary conditions 70 4.4 Results and analysis 71 5. Sediment erosion in cross flow turbine 75 5.1 Sediment erosion 75 5.2 Basic erosion models in ANSYS-CFX 79 5.2.1 Model of Finnie 79 5.2.2 Model of Tabakoff and Grant 80 5.3 Effect of the size of the particle on the erosion 84 5.4 Effect of the shape of the particle on the erosion 87 5.5 Effect of the sediment concentration 88 5.6 Effect of the erosion models on the results 90 6. Conclusions 92 Acknowledgements 94 References 95 | - |
| dc.language | eng | - |
| dc.publisher | Korea Maritime and Ocean University | - |
| dc.title | Numerical and Experimental Study on Micro Cross Flow Turbine Including the Prediction of Sediment Erosion | - |
| dc.title.alternative | Numerical and Experimental Study on Micro Cross Flow Turbine Including the Prediction of Sediment Erosion | - |
| dc.type | Thesis | - |
| dc.date.awarded | 2016-02 | - |
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