Electricity generation from low-temperature industrial excess heat—an opportunity for the steel industry

Johansson, Maria; Söderström, Mats

doi:10.1007/s12053-013-9218-6

Cited by 53 publications

(37 citation statements)

References 37 publications

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“…the heat production technology in the DH system. (Broberg Viklund and Johansson 2014) Johansson and Söderström (2013) studies electricity generation from low-temperature industrial excess heat within the steel industry, showing reduced CO2 emissions.…”

Section: Excess Heat Utilizationmentioning

confidence: 99%

Energy efficiency through industrial excess heat recovery—policy impacts

Viklund

2014

Energy Efficiency

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The EU target on energy efficiency implies a 20% reduction in the use of primary energy by implementation of energy efficiency measures. Not all potential cost-effective measures for improved energy efficiency are implemented. This energy efficiency gap is explained by market barriers. Policy instruments can be used to overcome these barriers. The target could, for example, be obtained through industrial excess heat recovery; but there is a knowledge gap on factors affecting excess heat utilization. In this study, interviews were carried out with energy managers in order to study excess heat utilization from industry's perspective. The study seeks to present how excess heat recovery can be promoted or discouraged through policy instruments, and several factors are raised in the paper. The interviews revealed that excess heat recovery is generally referred to in terms of heat deliveries to the district heating network. One may need to look for innovative recovery solutions and policies are needed to bring these solutions into action. Due to inefficient conversion for heat driven electricity generation, a system favoring this implementation could favor an inefficient system. Beyond external instruments, internal goals, visions and the importance of energy as a priority were shown to be important in the work with improved energy management.

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Section: Excess Heat Utilizationmentioning

confidence: 99%

Energy efficiency through industrial excess heat recovery—policy impacts

Viklund

2014

Energy Efficiency

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“…The WHR system converts the exhaust or coolant heat into either mechanical rotation or electrical power, which increases the thermal efficiency and, as a result, reduces the fuel consumption of the engine (Glover et al, 2014;Imran et al, 2015). Within the WHR system, three technologies were considered: Thermoelectric Generator (TEG), Organic Rankine Cycle (ORC) and Phase Change Material (PCM) engine system; these can be found in the literature (Johansson and Söderström, 2014). The selection of appropriate technology for the WHR is dependent on the type of heat source, the heat transfer requirement, and the application, etc.…”

Section: Introductionmentioning

confidence: 99%

“…The selection of appropriate technology for the WHR is dependent on the type of heat source, the heat transfer requirement, and the application, etc. The conversion efficiency of the PCM, TEG and ORC are, generally, up to 2.5%, 5% and 16%, respectively (Johansson and Söderström, 2014). Among these methods, the ORC is well established and preferred for waste heat recovery from low and medium grade heat sources because of its high thermal efficiency, low weight, small volume, simplicity, availability of components and compatibility with a range of heat sources (Gao et al, 2012;Shu et al, 2014;Johansson and Söderström, 2014).…”

Section: Introductionmentioning

confidence: 99%

Dynamic model of supercritical Organic Rankine Cycle waste heat recovery system for internal combustion engine

Chowdhury

Nguyen

Thornhill

2017

Int.J Automot. Technol.

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ABSTRACTThe supercritical Organic Rankine Cycle (ORC) for the Waste Heat Recovery (WHR) from Internal Combustion (IC) engines has been a growing research area in recent years, driven by the aim to enhance the thermal efficiency of the ORC and engine. Simulation of a supercritical ORC-WHR system before a real-time application is important as high pressure in the system may lead to concerns about safety and availability of components. In the ORC-WHR system, the evaporator is the main contributor to thermal inertia of the system and is considered to be the critical component since the heat transfer of this device influences the efficiency of the system. Since the thermophysical properties of the fluid at supercritical pressures are dependent on temperature, it is necessary to consider the variations in properties of the working fluid. The well-known Finite Volume (FV) discretization method is generally used to take those property changes into account. However, a FV model of the evaporator in steady state condition cannot be used to predict the thermal inertia of the cycle when it is subjected to transient heat sources. In this paper, a dynamic FV model of the evaporator has been developed and integrated with other components in the ORC-WHR system. The stability and transient responses along with the performance of the ORC-WHR system for the transient heat source are investigated and are also included in this paper.

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“…[7] A number of district heating (DH) systems in Sweden accept industrial excess heat as a part of their fuel mix and in 2011 excess heat accounted for 7.2% of the heat deliveries in the Swedish DH networks [8; 9]. Several research studies investigate excess heat recovery (both thermal applications and heat driven electricity generation) and heat storage technologies [10][11][12][13][14][15][16][17][18]. Johansson and Söderström [13] compare and evaluate heat driven electricity generation technologies for recovery of low-temperature industrial excess heat based on heat source temperature, efficiency, capacity, economy and potential electricity production.…”

Section: Introductionmentioning

confidence: 99%

“…The study indicates that investments in heat driven electricity generation technologies could be profitable, however not all associated costs are included in the study. [13] Campana et al [11] estimates the potential power output from excess heat driven Organic Rankine cycle (ORC) in the cement, steel, glass and oil and gas industry in 27 European countries. The authors conclude ORC to be a viable option for heat recovery and estimate the potential electricity generation from ORC to approximately 21.6 TWh per year.…”

Section: Introductionmentioning

confidence: 99%

Industrial excess heat use: Systems analysis and CO2 emissions reduction

Viklund¹,

Karlsson²

2015

Applied Energy

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The adopted energy efficiency directive stresses the use of excess heat as a way to reach the EU target of primary energy use. Use of industrial excess heat may result in decreased energy demand, CO2 emissions reduction, and economic gains. In this study, an energy systems analysis is performed with the aim of investigating how excess heat should be used, and the impact on CO2 emissions. The manner in which the heat is recovered will affect the system. The influence of excess heat recovery and the trade-off between heat recovery for heating or cooling applications and electricity production has been investigated using the energy systems modeling tool reMIND. The model has been optimized by minimizing the system cost. The results show that it is favorable to recover the available excess heat in all the investigated energy market scenarios, and that heat driven electricity production is not a part of the optimal solution. The trade-off between use of recovered excess heat in the heating or cooling system depends on the energy market prices and the type of heat production. The introduction of excess heat reduces the CO2 emissions in the system for all the studied energy market scenarios.

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Electricity generation from low-temperature industrial excess heat—an opportunity for the steel industry

Cited by 53 publications

References 37 publications

Energy efficiency through industrial excess heat recovery—policy impacts

Energy efficiency through industrial excess heat recovery—policy impacts

Dynamic model of supercritical Organic Rankine Cycle waste heat recovery system for internal combustion engine

Industrial excess heat use: Systems analysis and CO2 emissions reduction

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