Improving the primary steam parameters is one of the most direct ways to improve the cycle efficiency of a powergeneration system. In the present study, the typical problem connected to the excessively high superheat ...Improving the primary steam parameters is one of the most direct ways to improve the cycle efficiency of a powergeneration system. In the present study, the typical problem connected to the excessively high superheat degree ofextraction steam in an ultra-supercritical (USC) double-reheat unit is considered. Using a 1000 MW power plantas an example, two systems (case 1 and case 2) are proposed, both working in combination with a regenerativesteam turbine. The thermal performances of these two systems are compared with that of the original systemthrough a heat balance method and an exergy balance strategy. The results reveal that the two coupled systemscan significantly reduce the superheat degree of extraction steam, turbine heat rate, and coal consumption of theunit and improve the energy utilization efficiency. These results will provide useful theoretical guidance to futureinvestigators wishing to address the general problem relating to energy conservation and modelling of the coupledextraction steam regenerative system of USC double-reheat units.展开更多
To decrease energy consumption of ladle furnace, exergy analysis and optimization were conducted based on the ladle furnace refining process of modern clean steelmaking. Exergy analysis results showed that exergy loss...To decrease energy consumption of ladle furnace, exergy analysis and optimization were conducted based on the ladle furnace refining process of modern clean steelmaking. Exergy analysis results showed that exergy loss induced by unavailable electric energy is the largest, and the electric energy efficiency is 46.20%. To cut down the unavailable electric energy, industrial experiments of submerged arc heating were carried out combined with slag composition modification. Results showed that submerged arc heating can be achieved within most heating period, average heating rate increased by 0. 5 ℃/min, unavailable electric energy decreased by 21. 730 MJ per ton steel, and electric energy efficiency was enhanced by 14.84 %. As the refining cycle was shortened, the exergy loss induced by heat elimination decreased from 19. 455 MJ per ton steel to 11. 066 MJ per ton steel.展开更多
The S-CO_(2) top-bottom combined cycle based on overlap energy utilization can lead to excessive heating area,due to the small temperature difference and the large thermal load for the heating surface at the tail of t...The S-CO_(2) top-bottom combined cycle based on overlap energy utilization can lead to excessive heating area,due to the small temperature difference and the large thermal load for the heating surface at the tail of the boiler.Therefore,reasonable optimization indexes are needed for design optimization.Common optimization indexes include heating area and working medium pressure drop,but lower working medium pressure drop usually leads to large heating area,for example,with the increase of tube inner diameter or boiler width,the pressure drop decreases but the heating area increases.Thus,if both are used as optimization indexes,it will be difficult to choose the optimum tube inner diameter and boiler width.In this paper,exergy loss analysis is used,in combination with economic analysis,the optimization index is unified to the cost per unit heat transfer of the heating surface.The thermal calculation and pressure drop calculation models are established for the heating surface at the tail of the boiler.The optimized heating surface can greatly improve the economic benefit.展开更多
This paper aims effect on crude distillation to investigate the multi-stage units (CDUs) in thermody- namics. In this regard, we proposed three-, four-, five-, and six-stage CDU processes with all variables constrai...This paper aims effect on crude distillation to investigate the multi-stage units (CDUs) in thermody- namics. In this regard, we proposed three-, four-, five-, and six-stage CDU processes with all variables constrained to be almost the same except for the number of stages. We also analyzed the energy and exergy to assess the energy consumed by each process. Because additional distillation units would share the processing load and thus prevent products with low boiling points from overheating, the heat demand of the CDUs decreases with increasing stages and thus reduces the heat supply. Exergy loss is considered as a key parameter to assess these processes. When the exergy losses in heat exchangers are disregarded, the three- and four-stage CDUs have lower exergy losses than the five- and six-stage CDUs. When the overall exergy losses are considered, the optimum number of stages of CDUs depends on the exergy efficiency of heat integration.展开更多
Energy savings in air-conditioning systems are important for achieving energy efficient buildings.A central air-conditioning system in the large building is installed with air ductwork.Alternative materials are replac...Energy savings in air-conditioning systems are important for achieving energy efficient buildings.A central air-conditioning system in the large building is installed with air ductwork.Alternative materials are replacing con-ventional(Galvanized Iron Steel)air ducts for supplying air to the air-conditioned area.This research studies the objective function relationship between exergy and economic variables in the alternative air ductwork compared with conventional air ductwork.The optimization method to identify the optimal type and thickness of air ducts in Thailand’s buildings.The result shows that the alternative ductwork has achieved maximum worthiness with more useful exergy than conventional air ductwork.The Pre-insulated duct(PID)with 30.00 mm wall thickness is 82.14%.It is the maximum of all exergies generated by the Air Handling Unit.展开更多
In compressed air energy storage systems,throttle valves that are used to stabilize the air storage equipment pressure can cause significant exergy losses,which can be effectively improved by adopting inverter-driven ...In compressed air energy storage systems,throttle valves that are used to stabilize the air storage equipment pressure can cause significant exergy losses,which can be effectively improved by adopting inverter-driven technology.In this paper,a novel scheme for a compressed air energy storage system is proposed to realize pressure regulation by adopting an inverter-driven compressor.The system proposed and a reference system are evaluated through exergy analysis,dynamic characteristics analysis,and various other assessments.A comprehensive performance analysis is conducted based on key parameters such as thermal storage temperature,component isentropic efficiency,and designated discharge pressure.The results show that the novel system achieves a relative improvement of 3.64%in round-trip efficiency,demonstrating its capability to enhance efficiency without significantly increasing system complexity.Therefore,the system proposed offers a viable solution for optimizing compressed air energy storage systems.展开更多
A detailed thermal power plant model was developed to evaluate power plant waste heat usage in terms of the operating parameters,energy consumption,water consumption,and pollutant emissions.This model was used to anal...A detailed thermal power plant model was developed to evaluate power plant waste heat usage in terms of the operating parameters,energy consumption,water consumption,and pollutant emissions.This model was used to analyze the bypass flue gas energy cascade utilization design which provides excellent energy savings and emission reductions.This paper then presents a design to use the low-temperature waste heat and to extract water from the flue gas.The low-grade heat can be recovered from a coal-fired unit using absorption heat pumps to increase the air preheating.This method significantly reduces the turbine steam extraction in the low pressure stages which increases the turbine power and reduces the coal consumption.This design has a small heat transfer temperature difference between the air preheater and the air warmer,resulting in a smaller exergy loss.The power output of the present design was 1024.28 MW with a coal consumption savings of 3.69 g·(kWh)^(−1).In addition,the present design extracts moisture out of the flue gas to produce 46.48 t·h^(−1)of water.The main goal of this work is to provide a theoretical analysis for studying complex thermal power plant systems and various energy conservation and CO_(2)reduction options for conventional power plants.展开更多
The human basal state,a non-equilibrium steady state,is analysed in this paper in the light of the First and Second Laws of Thermodynamics whereby the thermodynamic significance of the basal metabolic rate and its dis...The human basal state,a non-equilibrium steady state,is analysed in this paper in the light of the First and Second Laws of Thermodynamics whereby the thermodynamic significance of the basal metabolic rate and its distinction to the dissipation function and exergy loss are identified.The analysis demonstrates the correct expression of the effects of the blood flow on the heat balance in a human-body bio-heat model and the relationship between the basal metabolic rate and the blood perfusion.展开更多
基金the Shandong Electric Power Engineering Consulting Institute science and technology project(Grant No.37-K2014-33).
文摘Improving the primary steam parameters is one of the most direct ways to improve the cycle efficiency of a powergeneration system. In the present study, the typical problem connected to the excessively high superheat degree ofextraction steam in an ultra-supercritical (USC) double-reheat unit is considered. Using a 1000 MW power plantas an example, two systems (case 1 and case 2) are proposed, both working in combination with a regenerativesteam turbine. The thermal performances of these two systems are compared with that of the original systemthrough a heat balance method and an exergy balance strategy. The results reveal that the two coupled systemscan significantly reduce the superheat degree of extraction steam, turbine heat rate, and coal consumption of theunit and improve the energy utilization efficiency. These results will provide useful theoretical guidance to futureinvestigators wishing to address the general problem relating to energy conservation and modelling of the coupledextraction steam regenerative system of USC double-reheat units.
文摘To decrease energy consumption of ladle furnace, exergy analysis and optimization were conducted based on the ladle furnace refining process of modern clean steelmaking. Exergy analysis results showed that exergy loss induced by unavailable electric energy is the largest, and the electric energy efficiency is 46.20%. To cut down the unavailable electric energy, industrial experiments of submerged arc heating were carried out combined with slag composition modification. Results showed that submerged arc heating can be achieved within most heating period, average heating rate increased by 0. 5 ℃/min, unavailable electric energy decreased by 21. 730 MJ per ton steel, and electric energy efficiency was enhanced by 14.84 %. As the refining cycle was shortened, the exergy loss induced by heat elimination decreased from 19. 455 MJ per ton steel to 11. 066 MJ per ton steel.
基金This work is supported by Beijing Nova Program(Z211100002121158).The authors are most grateful to Ms.Chao Liu at the North China Electric Power University for her help and advice during the preparation of this paper.
文摘The S-CO_(2) top-bottom combined cycle based on overlap energy utilization can lead to excessive heating area,due to the small temperature difference and the large thermal load for the heating surface at the tail of the boiler.Therefore,reasonable optimization indexes are needed for design optimization.Common optimization indexes include heating area and working medium pressure drop,but lower working medium pressure drop usually leads to large heating area,for example,with the increase of tube inner diameter or boiler width,the pressure drop decreases but the heating area increases.Thus,if both are used as optimization indexes,it will be difficult to choose the optimum tube inner diameter and boiler width.In this paper,exergy loss analysis is used,in combination with economic analysis,the optimization index is unified to the cost per unit heat transfer of the heating surface.The thermal calculation and pressure drop calculation models are established for the heating surface at the tail of the boiler.The optimized heating surface can greatly improve the economic benefit.
文摘This paper aims effect on crude distillation to investigate the multi-stage units (CDUs) in thermody- namics. In this regard, we proposed three-, four-, five-, and six-stage CDU processes with all variables constrained to be almost the same except for the number of stages. We also analyzed the energy and exergy to assess the energy consumed by each process. Because additional distillation units would share the processing load and thus prevent products with low boiling points from overheating, the heat demand of the CDUs decreases with increasing stages and thus reduces the heat supply. Exergy loss is considered as a key parameter to assess these processes. When the exergy losses in heat exchangers are disregarded, the three- and four-stage CDUs have lower exergy losses than the five- and six-stage CDUs. When the overall exergy losses are considered, the optimum number of stages of CDUs depends on the exergy efficiency of heat integration.
基金funded by Faculty of Engineering at Kamphaeng Saen Kasetsart University,in the year 2021.
文摘Energy savings in air-conditioning systems are important for achieving energy efficient buildings.A central air-conditioning system in the large building is installed with air ductwork.Alternative materials are replacing con-ventional(Galvanized Iron Steel)air ducts for supplying air to the air-conditioned area.This research studies the objective function relationship between exergy and economic variables in the alternative air ductwork compared with conventional air ductwork.The optimization method to identify the optimal type and thickness of air ducts in Thailand’s buildings.The result shows that the alternative ductwork has achieved maximum worthiness with more useful exergy than conventional air ductwork.The Pre-insulated duct(PID)with 30.00 mm wall thickness is 82.14%.It is the maximum of all exergies generated by the Air Handling Unit.
基金supported by the Key Research and Development Program of Hubei Province,China(No.2022BAD163)the Foundation of State Key Laboratory of Coal Combustion,China(No.FSKLCCA2112).
文摘In compressed air energy storage systems,throttle valves that are used to stabilize the air storage equipment pressure can cause significant exergy losses,which can be effectively improved by adopting inverter-driven technology.In this paper,a novel scheme for a compressed air energy storage system is proposed to realize pressure regulation by adopting an inverter-driven compressor.The system proposed and a reference system are evaluated through exergy analysis,dynamic characteristics analysis,and various other assessments.A comprehensive performance analysis is conducted based on key parameters such as thermal storage temperature,component isentropic efficiency,and designated discharge pressure.The results show that the novel system achieves a relative improvement of 3.64%in round-trip efficiency,demonstrating its capability to enhance efficiency without significantly increasing system complexity.Therefore,the system proposed offers a viable solution for optimizing compressed air energy storage systems.
基金The authors acknowledge financial support from the National Natural Science Foundation of China(No.51876057)the NSFC Projects of International Cooperation and Exchanges(No.52061125101)the Fundamental Research Funds for the Central Universities(No.2022JG006).
文摘A detailed thermal power plant model was developed to evaluate power plant waste heat usage in terms of the operating parameters,energy consumption,water consumption,and pollutant emissions.This model was used to analyze the bypass flue gas energy cascade utilization design which provides excellent energy savings and emission reductions.This paper then presents a design to use the low-temperature waste heat and to extract water from the flue gas.The low-grade heat can be recovered from a coal-fired unit using absorption heat pumps to increase the air preheating.This method significantly reduces the turbine steam extraction in the low pressure stages which increases the turbine power and reduces the coal consumption.This design has a small heat transfer temperature difference between the air preheater and the air warmer,resulting in a smaller exergy loss.The power output of the present design was 1024.28 MW with a coal consumption savings of 3.69 g·(kWh)^(−1).In addition,the present design extracts moisture out of the flue gas to produce 46.48 t·h^(−1)of water.The main goal of this work is to provide a theoretical analysis for studying complex thermal power plant systems and various energy conservation and CO_(2)reduction options for conventional power plants.
文摘The human basal state,a non-equilibrium steady state,is analysed in this paper in the light of the First and Second Laws of Thermodynamics whereby the thermodynamic significance of the basal metabolic rate and its distinction to the dissipation function and exergy loss are identified.The analysis demonstrates the correct expression of the effects of the blood flow on the heat balance in a human-body bio-heat model and the relationship between the basal metabolic rate and the blood perfusion.
