Comparative Evaluation of Integrated Waste Heat Utilization Systems for Coal-Fired Power Plants Based on In-Depth Boiler-Turbine Integration and Organic Rankine Cycle

Huang, Shengwei; Li, Chengzhou; Tan, Tianyu; Fu, Peng; Wang, Ligang; Yang, Yongping

doi:10.3390/e20020089

Cited by 14 publications

(8 citation statements)

References 69 publications

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“…The heat in the exhaust flue gas can be used to preheat feedwater by a low-pressure economizer [5][6][7] and pre-dry brown coal [8][9][10][11]. The waste heat of exhaust flue gas can also be used to drive an organic Rankine cycle to produce electric power [5,[12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Waste Heat Recovery from Fossil-Fired Power Plants by Organic Rankine Cycles

Liu¹

2020

Organic Rankine Cycles for Waste Heat Recovery - Analysis and Applications

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More than 60% of the world's electricity is still produced from fossil-fired power plants. Recovering heat from flue gas, drained water, and exhaust steam which are discharged in power plants by organic Rankine cycles (ORCs) to generate power is an efficient approach to reduce fossil fuel consumption and greenhouse gas emissions. This chapter proposes conceptual ORC systems for heat recovery of drain from continuous blowdown systems, exhaust flue gas from boilers, and exhaust steam from turbines. The waste heat source temperatures range from 30 to 200°C. Environmentally friendly and nonflammable working fluids including R134a,

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Section: Introductionmentioning

confidence: 99%

Waste Heat Recovery from Fossil-Fired Power Plants by Organic Rankine Cycles

Liu¹

2020

Organic Rankine Cycles for Waste Heat Recovery - Analysis and Applications

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“…A TEG is a solid component that provides direct energy due to the variation of the surrounding thermal behavior, and electrical power can then be generated based on the “Seebeck effect” and temperature gradient [ 6 , 7 , 8 ]. Thermoelectric technology had become popular in heat recovery applications and it was implemented with various sources such as internal combustion engines [ 9 , 10 , 11 , 12 ], stoves [ 13 , 14 , 15 ], vehicles [ 16 , 17 , 18 , 19 ], biomass gasifiers [ 20 ], chimneys [ 21 , 22 ], diesel engines [ 23 , 24 , 25 , 26 ], and fuel cells [ 27 ].…”

Section: Introductionmentioning

confidence: 99%

New Concept of Power Generation Using TEGs: Thermal Modeling, Parametric Analysis, and Case Study

Faraj

Jaber

Chahine

et al. 2020

Entropy

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In this manuscript, an innovative concept of producing power from a thermoelectric generator (TEG) is evaluated. This concept takes advantage of using the exhaust airflow of all-air heating, ventilating, and air-conditioning (HVAC) systems, and sun irradiation. For the first step, a parametric analysis of power generation from TEGs for different practical configurations is performed. Based on the results of the parametric analysis, recommendations associated with practical applications are presented. Therefore, a one-dimensional steady-state solution for the heat diffusion equation is considered with various boundary conditions (representing applied configurations). It is revealed that the most promising configuration corresponds to the TEG module exposed to a hot fluid at one face and a cold fluid at the other face. Then, based on the parametric analysis, the innovative concept is recognized and analyzed using appropriate thermal modeling. It is shown that for solar radiation of 2000 W/m2 and a space cooling load of 20 kW, a 40 × 40 cm2 flat plate is capable of generating 3.8 W of electrical power. Finally, an economic study shows that this system saves about $6 monthly with a 3-year payback period at 2000 W/m2 solar radiation. Environmentally, the system is also capable of reducing about 1 ton of CO2 emissions yearly.

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“…Abdelmotalib et al remarked that due to very complicated processes, which occur in the fluidized bed combustors, it is difficult to cover all aspects of heat transfer [ 9 ]. Therefore some additional, auxiliary data, e.g., to adjust parameters or to solve complex differential equations are necessary, and even other assumptions should be made to get a trackable solution [ 33 , 34 , 35 , 36 , 37 , 38 ]. As an example, Zhou et al pointed out that simulations conducted on the platform of FLUENT 12 software with three processors parallel for 70 s with the number of meshes nearly 8500 costs nearly 60 days [ 15 , 39 ].…”

Section: Introductionmentioning

confidence: 99%

Heat Transfer Performance in a Superheater of an Industrial CFBC Using Fuzzy Logic-Based Methods

Krzywański

2019

Entropy

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The heat transfer coefficient in the combustion chamber of industrial circulating flidized bed (CFB) boilers depends on many parameters as it is a result of multifactorial mechanisms proceeding in the furnace. Therefore, the development of an effective modeling tool, which allows for predicting the heat transfer coefficient is interesting as well as a timely subject, of high practical significance. The present paper deals with an innovative application of fuzzy logic-based (FL) method for the prediction of a heat transfer coefficient for superheaters of fluidized-bed boilers, especially circulating fluidized-bed combustors (CFBC). The approach deals with the modeling of heat transfer for the Omega Superheater, incorporated into the reaction chamber of an industrial 670 t/h CFBC. The height above the grid, bed temperature and voidage and temperature, gas velocity, and the boiler’s load constitute inputs. The developed Fuzzy Logic Heat (FLHeat) model predicts the local overall heat transfer coefficient of the Omega Superheater. The model is in good agreement with the measured data. The highest overall heat transfer coefficient is equal 220 W/(m2K) and can be achieved by the SH I superheater for the following inputs l = 20 m, tb = 900 °C, v = 0.95, u = 7 m/s, M-C-R = 100%. The proposed technique is an effective strategy and an option for other procedures of heat transfer coefficient evaluation.

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Comparative Evaluation of Integrated Waste Heat Utilization Systems for Coal-Fired Power Plants Based on In-Depth Boiler-Turbine Integration and Organic Rankine Cycle

Cited by 14 publications

References 69 publications

Waste Heat Recovery from Fossil-Fired Power Plants by Organic Rankine Cycles

Waste Heat Recovery from Fossil-Fired Power Plants by Organic Rankine Cycles

New Concept of Power Generation Using TEGs: Thermal Modeling, Parametric Analysis, and Case Study

Heat Transfer Performance in a Superheater of an Industrial CFBC Using Fuzzy Logic-Based Methods

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