Waste Heat Recovery from Aluminum Production

Yu, Miao; Guðjónsdóttir, María; Valdimarsson, Páll; Sævarsdóttir, Guðrún

doi:10.1007/978-3-319-72362-4_14

Cited by 5 publications

(3 citation statements)

References 29 publications

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“…For exhaust gas temperatures between 200 and 300 • C, the best option found was an ORC with R141b as working fluid. As far as aluminum production plants are concerned, recently, Yu et al (2018) assessed the performance of heat recovery ORCs for an aluminum production plant located in Iceland wasting about 88 MW of thermal power from the smelter exhaust gases.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Organic Rankine Cycles for Waste Heat Recovery From Aluminum Production Plants

et al. 2019

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This paper presents the optimization of organic Rankine cycles (ORCs) for recovering waste heat from a hypothetical aluminum production plant to be installed in Norway. The case study is particularly interesting because it features two hot streams at different temperatures (the pot exhaust gases and the cell wall cooling air), which make available about 16 MWth below 250 • C. First, a recently proposed cycle optimization approach is adopted to identify the most promising working fluid and optimize the cycle variables (pressures, temperatures, mass flow rates) for the maximum energy performance. The analysis includes both pure fluids, including recently synthesized refrigerants, and binary zeotropic mixtures assessing in total 102 working fluids. The best pure fluid in terms of exergy efficiency turns out to be HFE-347mcc (which can achieve a target exergy efficiency of 85.28%), followed by neopentane, butane, and R114. HFO-1336mzz appears to be one of the most promising non-flammable alternatives with low Global Warming Potential (GWP). The mixture leading to the highest exergy efficiency is isobutane-isopentane, which can increase the net electrical power output by up to 3.3% compared to pure fluids. The systematic techno-economic optimization, repeated for two different electricity prices, shows that RE347mcc is the best option in both low and high electricity prices. The cost of the cycle using HFO-1336mzz is penalized by the larger evaporation heat (negatively influencing the heat integration) and the smaller regenerator.

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Section: Introductionmentioning

confidence: 99%

Optimization of Organic Rankine Cycles for Waste Heat Recovery From Aluminum Production Plants

et al. 2019

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“…The capacity of devices in each candidate solution is determined through physical analysis to maximize WHR utilization. A comparison is then performed among these solutions to identify the optimal candidate (Hassan, 2015;Pantaleo et al, 2018;Yu et al, 2018). For instance, Yu et al (Yu et al, 2018) defined three scenarios for WHR utilization from exhaust gas in the aluminum industry and compared the exergy efficiency and energy output power of these schemes.…”

Section: Introductionmentioning

confidence: 99%

“…A comparison is then performed among these solutions to identify the optimal candidate (Hassan, 2015;Pantaleo et al, 2018;Yu et al, 2018). For instance, Yu et al (Yu et al, 2018) defined three scenarios for WHR utilization from exhaust gas in the aluminum industry and compared the exergy efficiency and energy output power of these schemes. Their findings demonstrated that two of these scenarios adequately met the local basic space-heating load.…”

Section: Introductionmentioning

confidence: 99%

A novel approach for utilizing waste heat resources in the steel industry

Wang,

Zhang,

Yang

et al. 2023

Front. Energy Res.

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The efficient utilization of waste heat resources plays a pivotal role in enhancing energy efficiency and curbing carbon emissions. To address this, effective planning for waste heat recovery (WHR) utilization becomes imperative, guiding consumers in device installation and capacity allocation. This paper introduces a novel approach to WHR utilization planning, tailored specifically for steel factories, with the goal of achieving optimal WHR solutions. The approach automates device selection, capacity allocation, and operational strategies while considering their impact on the regular manufacturing processes of the factories to maximize overall benefits. Unlike existing methods, this approach introduces discrete capacity selection modeling, considering the constraints of the limited product range during device selection. A numerical study illustrates the effectiveness of the proposed model in delivering optimal WHR device selection, capacity allocation, and operational strategies under various economic conditions. These enhancements contribute to the increased practicality and realism of the proposed method in comparison to existing approaches.

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