A model study for cyclic thermal loading and thermal performance of a thermoelectric generator

Almerbati, A.; Yilbaş, Bekir Sami; Sahin, Ahmet Z.

doi:10.1002/er.3152

Cited by 31 publications

(26 citation statements)

References 22 publications

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“…Hatzikraniotis et al showed that thermal cycling causes reduction in Seebeck effect and increase in thermal resistivity of TE elements, which in turn reduces the lifetime and efficiency of TEG modules. Al‐Merbati et al examined thermal stresses caused as a result of thermal cycling on TE elements. They showed that thermal cyclic loading influences the life cycle of the TE elements in a TEG module.…”

Section: Technical Issues Faced In Eteg and Possible Solutionsmentioning

confidence: 99%

Thermoelectric conversion of waste heat from IC engine-driven vehicles: A review of its application, issues, and solutions

Patowary

Baruah

2018

Int J Energy Res

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Summary Thermoelectric generator (TEG) is a promising thermoelectric (TE) conversion technology to effectively recover and convert waste heat from vehicle exhaust into useful energy, ie, electricity. Exhaust TEG (ETEG) is a system that is incorporated into the exhaust manifold of a vehicle. Exhaust TEG comprises of a heat exchanger, TEG modules, heat sink, and power conditioning unit. The present work reviews different vehicular ETEGs based on engine type, engine‐rated power, type and number of TEG module, efficiency of ETEG and TEG, exhaust and coolant temperature, and power output of ETEG. In addition to these, the technical issues faced in these ETEGs are addressed under 2 categories, viz., primary (TEG with low ZT TE material and inefficient heat exchanger and heat sink) and secondary issues (low operating temperature TEG modules and installation position of ETEG). In addition to it, effects of vibration and thermal cycling of exhaust system on TEG modules that may arise in ETEG are also discussed. A review of preventive solutions to the issues is also presented. Finally, the economic aspects of an ETEG are also discussed. The review highlights the need of commercialization of TE materials with ZT > 2, high‐temperature operating range, and segmented TEG modules in large volumes so that their practice can be extended in vehicular applications. Heat exchanger modeling using computational fluid dynamics and interfacing with heat transfer theory is essential to maintain temperature uniformity across the TEG modules. Installation of ETEG in the exhaust pipe should be such that it does not affect the performance of the engine. It is also realized that sturdy TEG modules should be developed for long‐term operation to prevent degradation due to mechanical vibration and thermal cycling of the vehicle. Further, ETEG is economically beneficial in vehicles such as trucks owing to availability of high thermal energy in their exhaust stream.

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Section: Technical Issues Faced In Eteg and Possible Solutionsmentioning

confidence: 99%

Thermoelectric conversion of waste heat from IC engine-driven vehicles: A review of its application, issues, and solutions

Patowary

Baruah

2018

Int J Energy Res

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“…Researchers have optimized the working performance of the TEG from structural parameters, exergy analysis, algorithm optimization, and so on [26][27][28][29][30]. The development of thermoelectric material technology and ICE manufacturing process have promoted the application of thermoelectric A review and selection of engine waste heat recovery technologies X.…”

Section: Thermoelectric Generatorsmentioning

confidence: 99%

A review and selection of engine waste heat recovery technologies using analytic hierarchy process and grey relational analysis

Liang

Wang

Shu

et al. 2014

Int. J. Energy Res.

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Summary In this paper, a brief review and comparison of the engine waste heat recovery technologies have been made. These five technologies are electric turbocompounding systems (ETC), thermodynamic organic Rankine cycle (ORC), thermoelectric generators (TEG), hydrogen generation by using exhaust gas heat energy, and hybrid pneumatic power systems (HPPS). According to comparison results, the HPPS system can achieve the highest fuel economy improvement among the five technologies. Though there are their own benefits by utilizing these different technologies, their disadvantages prevent the application of these advanced technologies to different extent. Besides, a combined evaluation method consisting of grey relational analysis and analytic hierarchy process has been applied to assess the five new engine waste heat recovery technologies from the perspective of technical, economic, and environmental aspect. Based on the final results of the new evaluation method, the HPPS was found to be the most promising WHR technology for vehicle engines. But because of the emphasis on economic benefit, TEG was found to be more favorable for working conditions, like power plant and marine engine. What is more, as is shown in the sensibility analysis, the weighing of the environment relevant factors can prominently influence the comparison results between ETC and HPPS. Copyright © 2014 John Wiley & Sons, Ltd.

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“…Sahin and Yilbas examined the performance characteristics of thermoelectric generators and confirmed that the operating temperature primarily contributed to the maximum output of the generator modules. Al‐Merbati et al reported the temperature stress values for module pins to establish the validation of thermal stress distribution in the context of the thermoelectric modules being subjected to cyclic loading. Sharma presented his research on dynamic pressure‐concentration isotherm properties of pairs of low‐temperature and high‐temperature metal hydrides and compared the results to static PCIs.…”

Section: Introductionmentioning

confidence: 99%

Design and fabrication of thermoelectric waste heat reutilization system-possible industrial application

et al. 2018

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Summary The current article discussed the detail design and development of an experimental test rig to derive usable energy by utilizing the waste heat energy through a heat exchanger made of Bi2Te3 material. The accuracy including the efficiency of the fabricated device is demonstrated further by verifying the associated parameter through a simulation model (commercial finite element package, ANSYS 15.0). To imitate the waste hot air from the industry is achieved via a heat gun and fed to the test rig for the generation of thermoelectric power. The simulation model accuracy has been demonstrated by juxtaposing the associated experimental data and computational readings. Subsequently, the feasibility and optimum range of design parameters are established by comparing the experimental and the simulation data (triggered temperature difference, voltage output, and heat flux) generated at the interface of the thermoelectric power generators. In addition, the coefficient of determination (R2) value has been evaluated statistically and verified with the current experimental results for the demonstration of the relevancy. The statistical study shows the existence of the correlation between the current experimental and the simulation model. Also, the experimental result indicates the possible implementation of the newly developed system for the recovery from the waste heat either the automobile exhaust or any other kind of dissipated heat from the industries.

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A model study for cyclic thermal loading and thermal performance of a thermoelectric generator

Cited by 31 publications

References 22 publications

Thermoelectric conversion of waste heat from IC engine-driven vehicles: A review of its application, issues, and solutions

Thermoelectric conversion of waste heat from IC engine-driven vehicles: A review of its application, issues, and solutions

A review and selection of engine waste heat recovery technologies using analytic hierarchy process and grey relational analysis

Design and fabrication of thermoelectric waste heat reutilization system-possible industrial application

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