Review
Energy & Fuels
Marcin Wolowicz, Piotr Kolasinski, Krzysztof Badyda
Summary: This article provides an overview of the technologies used and developed in small and micro cogeneration systems, including Stirling engines, gas and steam microturbines, various types of volumetric expanders, and fuel cells. It presents their basic features, power ranges, and examples of implemented installations based on these technologies.
Article
Green & Sustainable Science & Technology
Jakub Mascuch, Vaclav Novotny, Jan Spale, Vaclav Vodicka, Zbynek Zeleny
Summary: This paper provides insights into the early commercial development and pilot operation of a biomass-fired microcogeneration ORC unit, sharing operational data, issues, and economic considerations. The unit successfully operated for over 3000 hours, reaching significant heat and electricity production. The different paradigm adopted by the authors highlights the importance of assessing additional benefits beyond economic performance in investment evaluation.
Article
Green & Sustainable Science & Technology
Alibakhsh Kasaeian, Hamed Hadavi, Yasaman Amirhaeri, Fathollah Pourfayaz
Summary: A novel integrated structure is proposed to simultaneously produce power and heat using biomass fuel. The integrated system consists of multiple sections including gasification, solid oxide fuel cell, gas turbine cycle, Rankine cycle, ORC, and hot air and water line. The system utilizes heat recovery to supply the required heat for gasification and air. Wood chips are used as fuel for the solid oxide fuel cell through gasification. The results show that the cycle has an output power of 152.8 MW, an electrical efficiency of 51.43%, and an overall efficiency of 81.13%.
Article
Thermodynamics
Sofia Pelaez-Pelaez, Antonio Colmenar-Santos, Clara Perez-Molina, Ana-Esther Rosales, Enrique Rosales-Asensio
Summary: A techno-economic assessment was conducted for a hybrid combined generation system using renewable storage technologies such as fuel cells and hydrogen. The proposed system consists of photovoltaic, hydrogen generation, consumption and storage, fuel cell, and thermal subsystems. Economic assessment showed that while the system is not economically viable at present, it is technically feasible.
Article
Thermodynamics
Kyle Ferguson, Alexis Dubois, Kevin Albrecht, Robert J. Braun
Summary: The technology landscape in distributed generation is evolving in response to demand for efficient, low-emission, and low-cost power generation. Recent advancements in protonic ceramic fuel cells (PCFCs) offer potential for higher electric efficiencies in stationary power generation systems. The study explores system configurations and performance characteristics of PCFC-based systems for power generation, highlighting the fuel utilization capability and potential for high efficiencies without hybridization.
ENERGY CONVERSION AND MANAGEMENT
(2021)
Article
Chemistry, Physical
Shahriar Bozorgmehri, Hadi Heidary, Mohsen Salimi
Summary: Feed-in Tariffs are important support mechanisms for sustainable energy, and this study analyzes their implementation for distributed electricity generation in Iran and electricity generated by fuel cells in other countries. Different scenarios were designed to determine the pricing of electricity generated from fuel cells and support its market development. The calculated Feed-in Tariffs or expected support amount for each fuel cell unit varied depending on the utilization of different fuel cell products. The study also compared the cost of electricity generation using a production tax credit model and Iran's small-scale generator support guideline.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2023)
Article
Thermodynamics
F. Accurso, M. Gandiglio, M. Santarelli, J. Buunk, T. Hakala, J. Kiviaho, S. Modena, M. Muench, E. Varkaraki
Summary: The study analyzed the technical and economic feasibility of introducing a SOFC-based cogeneration system for non-residential buildings, showing that despite high investment costs, it is still a recommended energy-saving alternative in some countries, especially in the hospital sector.
ENERGY CONVERSION AND MANAGEMENT
(2021)
Article
Chemistry, Physical
Alexander R. Hartwell, Thomas S. Welles, Jeongmin Ahn
Summary: The study introduces a novel method for producing IC-tSOFC, which can be directly integrated into the combustion chamber with minimal alterations. Through SEM and performance characterization, it is confirmed that IC-tSOFCs exhibit good performance with a peak power density of 369 mW center dot cm(-2) and an open circuit voltage (OCV) of 0.98 V, indicating successful novel production methods.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2021)
Article
Chemistry, Physical
Xukai Hou, Rongfeng Sun, Jikai Huang, Wenguang Geng, Luyuan Wang, Tiantian Zhao
Summary: A combined heat and power system using proton exchange membrane fuel cells has been designed to provide electricity and heat for a hydrogen high-speed service area. The system performance is influenced by key parameters such as current density and hydrogen inlet pressure. The thermal-led strategy can prevent heat energy waste but leads to a power shortage.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2023)
Article
Chemistry, Physical
Mustafa Umut Karaoglan, Alper Can Ince, Andreas Glusen, C. Ozgur Colpan, Martin Mueller, Detlef Stolten, Nusret Sefa Kuralay
Summary: This study compares experimental measurements, mathematical models, and short-stack testing to gain a deeper understanding of the effects of operating parameters on DMFC performance. The results show that the mathematical model can accurately describe experimental results under low methanol concentrations and temperatures, with slightly higher voltage outputs compared to experimental results at certain current densities.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2021)
Article
Green & Sustainable Science & Technology
Alexander R. Hartwell, Cole A. Wilhelm, Thomas S. Welles, Ryan J. Milcarek, Jeongmin Ahn
Summary: The study investigates the impact of carbon monoxide and hydrogen concentration ratios on SOFC performance using simulated methane combustion exhaust as fuel and dilute hydrogen baseline tests. Results show that despite the involvement of complex reaction pathways, the presence of carbon monoxide leads to lower performance reductions compared to similarly dilute hydrogen gas.
Review
Chemistry, Physical
Shuang Cao, Tong Sun, Jin-Rong Li, Qin-Zhu Li, Chun-Chao Hou, Qi Sun
Summary: This review highlights the recent development of ORR catalysts in proton exchange membrane fuel cells (PEMFCs) and emphasizes the importance of designing efficient catalysts at the membrane electrode assembly (MEA) and full-cell levels.
Article
Energy & Fuels
Jinwon Yun, Eun-Jung Choi, Sangmin Lee, Younghyeon Kim, Sangseok Yu
Summary: This study investigates nine configurations of system integration design to evaluate the potential improvement of system efficiency using energy separation devices in solid oxide fuel cells (SOFC). The models were developed using Matlab/Simulink(R) platform with Thermolib(R) module. The inclusion of a catalytic converter, SOFC hybridization, and energy separation device in the layouts improved the thermal energy utilization and overall efficiency through the boost of gas temperature.
Article
Energy & Fuels
Jonas Breitinger, Mark Hellmann, Helerson Kemmer, Stephan Kabelac
Summary: This study showcases the impact of media supply adaption, system architecture and test rig restrictions on the transient voltage response of a PEM fuel cell stack in automotive application. Current step and load profile experiments were conducted on a system test rig and a short stack test bench, and a time scale analysis was performed to identify the predominant effect for the voltage response in each test case. The voltage response was found to be dominated by air supply, membrane humidification or coolant temperature dynamics. This systematic comparison highlights the importance of application-like system level testing in shaping the electrical stack behavior.
Article
Energy & Fuels
Mahsa Rajabi, Mehdi Mehrpooya, Asal Sami
Summary: Environmental and atmospheric pollution have become significant global issues in the past decades, with energy supply sectors using non-renewable resources being major contributors. Therefore, it is urgent to switch to power generation systems using renewable resources with minimal environmental pollution. This study presents an integrated multi-generation system utilizing clean and renewable fuels. Extensive performance analysis is conducted to determine optimal values and the system's efficiency rates are reported.
JOURNAL OF ENERGY STORAGE
(2022)
Article
Energy & Fuels
Gianluca Valenti, Aldo Bischi, Stefano Campanari, Paolo Silva, Antonino Ravida, Ennio Macchi
Summary: Experimental and numerical study of a small-size commercial Stirling unit in cycling operations showed that an optimized operating strategy led to a significant reduction of daily startups and energy savings.
Article
Chemistry, Physical
Elena Crespi, Giulio Guandalini, Soenke Goessling, Stefano Campanari
Summary: The study focuses on constructing and demonstrating a highly flexible PEMFC power plant fueled by hydrogen to provide grid support. Different layouts for innovative MW-scale plant are simulated to optimize design and operation under atmospheric or mild pressurized conditions, achieving higher net power and efficiency through energy recovery.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2021)
Article
Engineering, Chemical
Simone Polimeni, Alfredo Nespoli, Sonia Leva, Gianluca Valenti, Giampaolo Manzolini
Summary: This paper presents a two-layer hierarchical energy management system for islanded photovoltaic microgrids, evaluating optimal unit commitment based on photovoltaic forecasts and managing power sharing in real time to achieve optimal management. Experimental study demonstrates the capability of the proposed system to operate an islanded microgrid in safe conditions, even with inaccurate day-ahead photovoltaic forecasts.
Article
Energy & Fuels
R. Scaccabarozzi, M. Gatti, S. Campanari, E. Martelli
Summary: This paper presents a new hybrid cycle integrating a pressurized solid oxide fuel cell (SOFC) and a semi-closed regenerative intercooled Brayton cycle, using CO2-rich stream as the working fluid. By optimizing design variables using Aspen Plus, the cycle achieves outstandingly high efficiency of 75.7% with CO2 capture. The sensitivity analysis shows that similar efficiency values can be achieved under less challenging operating conditions.
Article
Thermodynamics
Dario Alfani, Marco Binotti, Ennio Macchi, Paolo Silva, Marco Astolfi
Summary: This paper focuses on the potential of supercritical carbon dioxide closed cycle for waste heat recovery applications, demonstrating the advantages of sCO2 technology in industrial waste heat recovery through analysis and optimization of cycle configurations, performance assessment, and cost-effectiveness.
APPLIED THERMAL ENGINEERING
(2021)
Article
Chemistry, Physical
Roberta Caponi, Andrea Monforti Ferrario, Enrico Bocci, Gianluca Valenti, Massimiliano Della Pietra
Summary: The anticipated growth of hydrogen mobility is crucial for decarbonizing the transportation sector, with a focus on deploying refueling infrastructure and vehicles simultaneously. By utilizing a lumped model in a tank-to-tank refueling event for fuel cell buses, the study shows the importance of Average Pressure Ramp Rate (APRR) in achieving efficient and safe refueling processes.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2021)
Article
Chemistry, Physical
Elena Crespi, Paolo Colbertaldo, Giulio Guandalini, Stefano Campanari
Summary: This study compares the use of hydrogen, battery, and hybrid hydrogen-battery systems to meet the 1 MW load locally generated by a photovoltaic plant. Results show that installing PV panels is cost-effective and as the self-generation ratio increases, the separation of generation and consumption becomes necessary.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2021)
Article
Energy & Fuels
Gianluca Valenti, Stefano Murgia, Ida Costanzo, Matteo Scarnera, Francesco Battistella
Summary: This study experimentally determined the performance parameters of an electric-driven sliding-vane air compressor designed for electric and electrified heavy-duty vehicles during transient cold start-ups. It was found that the start-up time, air flow rate, and power input were all significantly affected by the thermostatic temperature, with lower temperatures leading to longer start-up times and lower initial air flow rates.
Article
Chemistry, Physical
Camilla Nicol Bonacina, Nima Bordbar Gaskare, Gianluca Valenti
Summary: The study investigates an offshore liquefied green hydrogen production plant for ship refueling, aiming to find the optimal capacities to minimize payback time. Model results indicate that wind farm capacity should be over 150 MW, with the electrolyzer capacity set between 80% and 90% of the wind farm capacity to achieve minimum payback time.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2022)
Editorial Material
Energy & Fuels
Matteo C. Romano, Cristina Antonini, Andre Bardow, Valentin Bertsch, Nigel P. Brandon, Jack Brouwer, Stefano Campanari, Luigi Crema, Paul E. Dodds, Stefania Gardarsdottir, Matteo Gazzani, Gert Jan Kramer, Peter D. Lund, Niall Mac Dowell, Emanuele Martelli, Luca Mastropasqua, Russell C. McKenna, Juliana Garcia Moretz-Sohn Monteiro, Nicola Paltrinieri, Bruno G. Pollet, Jeffrey G. Reed, Thomas J. Schmidt, Jaap Vente, Dianne Wiley
Summary: This paper responds to a previous study on blue hydrogen, highlighting the method and assumptions used. By analyzing the mass and energy balances of two blue hydrogen plants, the impact of methane leakage rate on the CO2 emissions is shown. The study concludes that blue hydrogen can have significantly lower CO2 emissions with proper CO2 capture technologies and low-emission natural gas supply chains.
ENERGY SCIENCE & ENGINEERING
(2022)
Article
Engineering, Multidisciplinary
Camilla Nicol Bonacina, Paolo Tafani Alunno, Massimo Mastromatteo, Gianluca Valenti, Gilberto Serafini, Claudio Imboccioli, Matteo Russo, Caterina Soranno, Lorenzo Mori, Filippo Maria Lombardi
Summary: There is a lack of international standards for hydrogen measurement in legal frameworks. This study proposes a new approach for legally measuring pure hydrogen volume and volumetric flow rate based on international metrology standards. A wet drum meter filled with water is used as the reference meter. The selected reference instrumentation and procedures can be replicated in other laboratories. Simulations show that hydrogen diffusivity in water does not affect error estimations, but water evaporation does affect volumetric flow rate measurement. The expanded uncertainty of the total metrological chain is less than 0.25%. This reference procedure allows for testing the error of indication of new meters using hydrogen and other flowing gases with the same principles, instrumentation, and procedures, which is beneficial for the development and certification of new products for the upcoming energy transition.
Article
Chemistry, Physical
Alberto Cammarata, Maria Carmenza Diaz Lacharme, Paolo Colbertaldo, Alessandro Donazzi, Stefano Campanari
Summary: In this study, a micro-scale system based on solid oxide fuel cells (SOFCs) for low temperature operation is investigated. The expected performance is evaluated numerically and validated through experimental cell operation. The system is designed for powering gas-connected remote electronic devices with methane fuel. The challenges of feed pre-treating and carbon deposition are addressed, and several design configurations are proposed.
JOURNAL OF POWER SOURCES
(2022)
Article
Energy & Fuels
Stefano Consonni, Luca Mastropasqua, Maurizio Spinelli, Timothy A. Barckholtz, Stefano Campanari
Summary: The molten carbonate fuel cell system proposed in this study can significantly reduce direct CO2 emissions, increase hydrogen production, and maintain high efficiency. This system demonstrates a synergistic approach to hydrogen production with low emissions and high efficiency.
ADVANCES IN APPLIED ENERGY
(2021)
Article
Thermodynamics
Hai Zhao, Puzhen Gao, Xiaochang Li, Ruifeng Tian, Hongyang Wei, Sichao Tan
Summary: This study numerically investigates the interaction between flow-induced vibration and forced convection heat transfer in a tube bundle. The results show that the impact of flow-induced vibration on heat transfer varies in different flow velocity regions.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Rohit Chintala, Jon Winkler, Sugirdhalakshmi Ramaraj, Xin Jin
Summary: The current state of fault detection and diagnosis for residential air-conditioning systems is expensive and not suitable for widespread implementation. This paper proposes a cost-effective solution by introducing an automated fault detection algorithm as a screening step before more expensive tests can be conducted. The algorithm uses home thermostats and local weather information to identify thermodynamic parameters and detect high-impact air-conditioning faults.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
A. Azimi, N. Basiri, M. Eslami
Summary: This paper presents a novel optimization algorithm for improving the water-film cooling system of photovoltaic panels, resulting in a significant increase in net energy generation.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Duc-Thuan Phung, Chin-Hsiang Cheng
Summary: In this study, a novel CFDMD model is used to analyze and investigate the behavior of thermal-lag engines (TLE). The study shows that the CFDMD model effectively captures the thermodynamic behavior of the working gas and the dynamic behavior of the engine mechanism. Additionally, the study explores the temporal evolution of engine speed and the influence of various parameters on shaft power and brake thermal efficiency. The research also reveals the existence of a thermal-lag phenomenon in TLE.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Haiying Yang, Yinjie Shen, Lin Li, Yichen Pan, Ping Yang
Summary: The purpose of this article is to find a measure to improve the interfacial thermal transfer of graphene/silicon heterojunction. Through molecular dynamics simulation, it is found that surface modification can significantly reduce the thermal resistance, thereby improving the thermal conductivity of the graphene/silicon interface.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Qiong Wu, Yancheng Wang, Haonan Zhou, Xingye Qiu, Deqing Mei
Summary: This article introduces a visible methanol steam reforming microreactor, which uses an optical crystal as an observation window and measures the reaction temperature in real-time using infrared thermography. The results show that under lower oxygen to carbon ratio conditions, the microreactor has a higher heating rate and a stable gradient in temperature distribution.
APPLIED THERMAL ENGINEERING
(2024)
Review
Thermodynamics
Giulia Manco, Umberto Tesio, Elisa Guelpa, Vittorio Verda
Summary: In the past decade, there has been a growing interest in studying energy systems for the combined management of power vectors. Most of the published works focus on finding the optimal design and operations of Multi Energy Systems (MES). However, for newcomers to this field, understanding how to achieve the desired optimization details while controlling computational expenses can be challenging and time-consuming. This paper presents a novel approach to analyzing the existing literature on MES, with the aim of guiding practical development of MES optimization. Through the discussion of six case studies, the authors provide a mathematical formulation as a reference for building the model and emphasize the impact of different aspects on the problem nature and solver selection. In addition, the paper also discusses the different approaches used in the literature for incorporating thermal networks and storage in the optimization of multi-energy systems.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Xuepeng Yuan, Caiman Yan, Yunxian Huang, Yong Tang, Shiwei Zhang, Gong Chen
Summary: In this study, a multi-scale microgroove wick (MSMGW) was developed by laser irradiation, which demonstrated superior capillary performance. The surface morphology and performance of the wick were affected by laser scan pitch, laser power, repetition frequency, and scanning speed. The MSMGW showed optimal capillary performance in alumina material and DI water as the working fluid.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Maofei Mei, Feng Hu, Chong Han
Summary: This paper proposes an effective local search method based on detection of droplet boundaries for understanding the dynamic process of droplet growth during dropwise condensation. The method is validated by comparing with experimental data. The present simulation provides an effective approach to more accurately predict the nucleation site density in future studies.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Rahul Kumar Sharma, Ashish Kumar, Dibakar Rakshit
Summary: The study explores the use of phase change materials (PCM) as a retrofit with Heating Ventilation and Air-conditioning systems (HVAC) to reduce energy consumption and improve air quality. By incorporating PCM with specific thickness and fin configurations, significant energy savings can be achieved in comparison to standard HVAC systems utilizing R134a. This research provides policymakers with energy-efficient and sustainable solutions for HVAC systems to combat climate change.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Zhenhua Ren, Xiangjin Meng, Xingang Qi, Hui Jin, Yunan Chen, Bin Chen, Liejin Guo
Summary: This paper investigates the heat transfer mechanism and factors influencing thermal radiation in the process of supercritical water gasification (SCWG) of coal, and proposes a comprehensive numerical model to simulate the process. Experimental validation results show that thermal radiation accounts for a significant proportion of the total heat exchange in the reactor and a large amount of radiant energy exists in the important spectral range of supercritical water. Enhancing radiative heat transfer can effectively increase the temperature of the reaction medium and the gasification rate.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Mauro Abela, Mauro Mameli, Sauro Filippeschi, Brent S. Taft
Summary: Pulsating Heat Pipes (PHP) are passive two-phase heat transfer devices with a simple structure and high heat transfer capabilities. The actual unpredictability of their dynamic behavior during startup and thermal crisis hinders their large-scale application. An experimental apparatus is designed to investigate these phenomena systematically. The results show that increasing the number of evaporator sections and condenser temperature improves the performance of PHP. The condenser temperature also affects the initial liquid phase distribution and startup time.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Ke Gan, Ruilian Li, Yi Zheng, Hui Xu, Ying Gao, Jiajie Qian, Ziming Wei, Bin Kong, Hong Zhang
Summary: A 3-dimensional enhanced heat pipe radiator has been developed to improve heat dissipation and temperature uniformity in cooling high-power electronic components. Experimental results show that the radiator has superior heat transfer performance compared to a conventional aluminum fin radiator under different heating powers and wind speed conditions.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Xinyi Zhang, Shuzhong Wang, Daihui Jiang, Zhiqiang Wu
Summary: This study focuses on recovering waste heat from blast furnace slag using dry centrifugal pelletizing technology. A comprehensive two-dimensional model was developed to analyze heat transfer dynamics and investigate factors influencing heat exchange efficiency. The findings have important implications for optimizing waste heat recovery and ensuring safe operations.
APPLIED THERMAL ENGINEERING
(2024)
Article
Thermodynamics
Xincheng Wu, An Zou, Qiang Zhang, Zhaoguang Wang
Summary: The boosting heat generation rate of high-performance processors is challenging traditional cooling techniques. This study proposes a combined design of active jet intermittency and passive surface modification to enhance heat transfer.
APPLIED THERMAL ENGINEERING
(2024)
