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A Comprehensive Thermal and Structural Transient Analysis of a Boiler’s Steam Outlet Header by Means of a Dedicated Algorithm and FEM Simulation
Increasing the share of renewables in energy markets influences the daily operation of thermal power units. High capacity power units are more frequently operated to balance power grids and, thus, steam boilers are exposed to unfavorable transient states. The aim of this work was to perform thermal...
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| Published in: | Energies (Basel) 2020-01, Vol.13 (1), p.111 |
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| cites | cdi_FETCH-LOGICAL-c361t-984988daafbb53b97a03fb6707e8200f8bfd34eb740ccfcb48ae990edb1b68a53 |
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| container_start_page | 111 |
| container_title | Energies (Basel) |
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| creator | Pilarczyk, Marcin Węglowski, Bohdan Nord, Lars O. |
| description | Increasing the share of renewables in energy markets influences the daily operation of thermal power units. High capacity power units are more frequently operated to balance power grids and, thus, steam boilers are exposed to unfavorable transient states. The aim of this work was to perform thermal and structural analyses of a boiler’s outlet steam header, with a capacity of 650∙103 kg/h (180 kg/s) of live steam. Based on the measured steam pressure and temperatures on the outer surface of the component, transient temperature fields were determined by means of an algorithm that allows determination of transient stress distributions on the internal and external surfaces, as well as at stress concentration regions. In parallel, a finite element method simulation was performed. A comparison of the obtained results to a finite element analysis showed satisfactory agreement. The analyses showed that the start-up time could be reduced because the total stress did not exceed the allowed values during the regular start-up of the analyzed power unit. The algorithm was efficient and easy to implement in the real control systems of the power units. The numerical approach employed in the presented algorithm also allowed for determination of the time- and place-dependent heating rate value, which can be used as input data for the control system of the power unit. |
| doi_str_mv | 10.3390/en13010111 |
| format | article |
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High capacity power units are more frequently operated to balance power grids and, thus, steam boilers are exposed to unfavorable transient states. The aim of this work was to perform thermal and structural analyses of a boiler’s outlet steam header, with a capacity of 650∙103 kg/h (180 kg/s) of live steam. Based on the measured steam pressure and temperatures on the outer surface of the component, transient temperature fields were determined by means of an algorithm that allows determination of transient stress distributions on the internal and external surfaces, as well as at stress concentration regions. In parallel, a finite element method simulation was performed. A comparison of the obtained results to a finite element analysis showed satisfactory agreement. The analyses showed that the start-up time could be reduced because the total stress did not exceed the allowed values during the regular start-up of the analyzed power unit. The algorithm was efficient and easy to implement in the real control systems of the power units. The numerical approach employed in the presented algorithm also allowed for determination of the time- and place-dependent heating rate value, which can be used as input data for the control system of the power unit.</description><identifier>ISSN: 1996-1073</identifier><identifier>EISSN: 1996-1073</identifier><identifier>DOI: 10.3390/en13010111</identifier><language>eng</language><publisher>Basel: MDPI AG</publisher><subject>Accuracy ; Algorithms ; Alternative energy sources ; Boilers ; Cold ; combined cycle ; Computer simulation ; Control systems ; Electric power grids ; Environmental policy ; Finite volume method ; Generators ; Heat ; Heating rate ; Load ; Mathematical models ; Power plants ; power unit ; Renewable resources ; start-up ; Steam electric power generation ; Steam pressure ; Stress ; Stress concentration ; Thermal power ; thermal stress ; Thermocouples ; thick-walled component ; transient state ; Working conditions</subject><ispartof>Energies (Basel), 2020-01, Vol.13 (1), p.111</ispartof><rights>2020. 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High capacity power units are more frequently operated to balance power grids and, thus, steam boilers are exposed to unfavorable transient states. The aim of this work was to perform thermal and structural analyses of a boiler’s outlet steam header, with a capacity of 650∙103 kg/h (180 kg/s) of live steam. Based on the measured steam pressure and temperatures on the outer surface of the component, transient temperature fields were determined by means of an algorithm that allows determination of transient stress distributions on the internal and external surfaces, as well as at stress concentration regions. In parallel, a finite element method simulation was performed. A comparison of the obtained results to a finite element analysis showed satisfactory agreement. The analyses showed that the start-up time could be reduced because the total stress did not exceed the allowed values during the regular start-up of the analyzed power unit. 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| issn | 1996-1073 1996-1073 |
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| subjects | Accuracy Algorithms Alternative energy sources Boilers Cold combined cycle Computer simulation Control systems Electric power grids Environmental policy Finite volume method Generators Heat Heating rate Load Mathematical models Power plants power unit Renewable resources start-up Steam electric power generation Steam pressure Stress Stress concentration Thermal power thermal stress Thermocouples thick-walled component transient state Working conditions |
| title | A Comprehensive Thermal and Structural Transient Analysis of a Boiler’s Steam Outlet Header by Means of a Dedicated Algorithm and FEM Simulation |
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