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R K, Kumar
- Numerical Prediction of Erosion in Coal Burner of 210 MW Boiler Through Computational Fluid Dynamics Modeling
Abstract Views :181 |
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Authors
Affiliations
1 Central Power Research Institute, Bangalore-560080, IN
1 Central Power Research Institute, Bangalore-560080, IN
Source
Power Research, Vol 12, No 2 (2016), Pagination: 325-334Abstract
The splitter plates of coal burners in Indian thermal plants are subjected to severe erosion and erosioncorrosion conditions owing to the combined effect of abrasive nature of coal and elevated service temperature environment. During service, tilting of splitter plates is adopted to achieve the desired final steam outlet temperature which shifts the fireball location and heat release area in the combustion zone. The tilt condition gives rise to a change in the incidence angle of the coal particle as well as the change in flow profile. The erosion life of these plates is predominantly affected by the coal particle velocity, impact angle, particle size and steady state metal temperature during service. The sensitivity of burner tilt angle on the erosion life requires an understanding of primary air with coal particle flow phenomenon within the burners. The effect of burner tilt angle on the erosion of presently used SS310 grade splitter material was studied through computational fluid dynamics. The erosion sensitive velocity exponent was calculated based on the laboratory simulated erosion tests at elevated temperatures upto 700°C. The life of the splitter plates was calculated based on the predicted erosion rate intensity.Keywords
Coal burner, high-temperature erosion, Computational Fluid Dynamics (CFD)- Root Cause Analysis of Failure of 40th Stage Moving Blade of Single Cylinder Condensing Turbine
Abstract Views :174 |
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Authors
Affiliations
1 Joint Director, Central Power Research Institute, Bangalore -560080, IN
2 Sampoorna Rotor Dynamics Consultancy, Bangalore-560040, IN
1 Joint Director, Central Power Research Institute, Bangalore -560080, IN
2 Sampoorna Rotor Dynamics Consultancy, Bangalore-560040, IN
Source
Power Research, Vol 12, No 2 (2016), Pagination: 335-350Abstract
Blade failures in steam and gas turbines are quite a common occurrence. The last stages of steam turbines are designed to have the lowest possible fluid temperature. In view of the longest blade length in the last stages, the blades are subjected to highest bending moment forces and susceptible for erosion-corrosion phenomenon owing to the low service temperature environment. The failure analysis of last stage blade of 54 MW direct condensing type gas turbine are presented. The blade was made of martensitic grade stainless steel. Detailed analysis of the blade surface, lacing wire hole as well as the fracture morphology was analyzed using SEM-EDX. The probable reason for the failure of the blade was brought out based on the detailed investigations of the failed blade as well as the vibration signature analysis at the time of failure incidence.Keywords
Failure Analysis, Gas Turbine Blade, Vibration Frequency, Fractography- Solid Particle Erosion of HVOF Sprayed (35WC-Co/NiCrBSi Coating at Higher Temperature
Abstract Views :185 |
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Authors
Affiliations
1 Senior Research Fellow, Materials Technology Division, Central Power Research Institue, Bangalore-560080, IN
2 Joint Director, Materials Technology Division, Central Power Research Institue,Bangalore-560080, IN
3 Additional Director, Materials Technology Division, Central Power Research Institue,Bangalore-560080, IN
1 Senior Research Fellow, Materials Technology Division, Central Power Research Institue, Bangalore-560080, IN
2 Joint Director, Materials Technology Division, Central Power Research Institue,Bangalore-560080, IN
3 Additional Director, Materials Technology Division, Central Power Research Institue,Bangalore-560080, IN