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Publikationer

Publikationer av Justin Chiu

Refereegranskade

Artiklar

[1]
A. Konig-Haagen et al., "Analysis of the discharging process of latent heat thermal energy storage units by means of normalized power parameters," Journal of Energy Storage, vol. 72, 2023.
[2]
E. Manyumbu, V. Martin och J. N. Chiu, "Prospective PCM-Desiccant Combination with Solar-Assisted Regeneration for the Indoor Comfort Control of an Office in a Warm and Humid Climate-A Numerical Study," Energies, vol. 16, no. 14, 2023.
[3]
T. Reboli et al., "Thermal energy storage based on cold phase change materials : Discharge phase assessment," Journal of Energy Storage, vol. 73, s. 108939, 2023.
[4]
F. Gallardo et al., "Assessing sizing optimality of OFF-GRID AC-linked solar PV-PEM systems for hydrogen production," International journal of hydrogen energy, 2022.
[5]
M.-H. Hu, T. Xu och J. N. Chiu, "Experimental analysis of submerged coil and encapsulated slab latent heat storage," Applied Thermal Engineering, vol. 209, 2022.
[6]
T. Xu et al., "Experimental and numerical investigation of a latent heat thermal energy storage unit with ellipsoidal macro-encapsulation," Energy, vol. 238, 2022.
[7]
H. Koide et al., "Performance analysis of packed bed latent heat storage system for high-temperature thermal energy storage using pellets composed of micro-encapsulated phase change material," Energy, vol. 238, 2022.
[8]
X.-F. Shao et al., "Polyvinylpyrrolidone (PVP)-enabled significant suppression of supercooling of erythritol for medium-temperature thermal energy storage," Journal of Energy Storage, vol. 46, s. 103915, 2022.
[9]
T. Reboli et al., "Thermal energy storage based on cold phase change materials : Charge phase assessment," Applied Thermal Engineering, vol. 217, 2022.
[10]
A. Abdi et al., "Experimental investigation of solidification and melting in a vertically finned cavity," Applied Thermal Engineering, vol. 198, 2021.
[11]
T. Xu et al., "Latent heat storage integration into heat pump based heating systems forenergy-efficient load shifting," Energy Conversion and Management, vol. 236, no. 114042, 2021.
[12]
A. Abdi, J. N. Chiu och V. Martin, "Numerical Investigation of Latent Thermal Storage in a Compact Heat Exchanger Using Mini-Channels," Applied Sciences, vol. 11, no. 13, s. 5985, 2021.
[13]
T. Xu et al., "Performance evaluation of three latent heat storage designs for cogeneration applications," Solar Energy, vol. 225, s. 444-462, 2021.
[14]
S. N. Gunasekara et al., "Thermal Energy Storage Materials (TESMs)-What Does It Take to Make Them Fly?," Crystals, vol. 11, no. 11, s. 1276, 2021.
[15]
H. Koide et al., "Development of Novel Microencapsulated Hybrid Latent/Chemical Heat Storage Material," ACS Sustainable Chemistry and Engineering, vol. 8, no. 39, s. 14700-14710, 2020.
[16]
A. Abdi et al., "Experimental investigation of thermo-physical properties of n-octadecane and n-eicosane," International Journal of Heat and Mass Transfer, vol. 161, 2020.
[17]
B. Nourozi et al., "Heat transfer model for energy-active windows – An evaluation of efficient reuse of waste heat in buildings," Renewable energy, vol. 162, s. 2318-2329, 2020.
[18]
X.-F. Shao et al., "Hydroxyl group functionalized graphene oxide nanosheets as additive for improved erythritol latent heat storage performance : A comprehensive evaluation on the benefits and challenges," Solar Energy Materials and Solar Cells, vol. 215, 2020.
[19]
T. Xu et al., "Numerical thermal performance investigation of a latent heat storage prototype toward effective use in residential heating systems," Applied Energy, vol. 278, 2020.
[20]
T. Xu et al., "Thermal behavior of a sodium acetate trihydrate-based PCM : T-history and full-scale tests," Applied Energy, vol. 261, 2020.
[21]
T. Xu et al., "Experimental investigation on cylindrically macro-encapsulated latent heat storage for space heating applications," Energy Conversion and Management, vol. 182, s. 166-177, 2019.
[22]
J. T. Gao et al., "Feasibility and economic analysis of solution transportation absorption system for long-distance thermal transportation under low ambient temperature," Energy Conversion and Management, vol. 196, s. 793-806, 2019.
[23]
A. Abdi, V. Martin och J. N. Chiu, "Numerical investigation of melting in a cavity with vertically oriented fins," Applied Energy, vol. 235, s. 1027-1040, 2019.
[24]
S. N. Gunasekara et al., "Thermal conductivity measurement of erythritol, xylitol, and their blends for phase change material design : A methodological study," International Journal of Energy Research, vol. 43, no. 5, s. 1785-1801, 2019.
[25]
V. Gkoutzamanis et al., "Thermal energy storage for gas turbine power augmentation," Journal of the Global Power and Propulsion Society, vol. 3, s. 592-608, 2019.
[26]
S. N. Gunasekara et al., "Thermodynamic assessment of binary erythritol-xylitol phase diagram for phase change materials design," Calphad, vol. 60, s. 29-36, 2018.
[27]
J. F. Castro Flores et al., "Assessing the techno-economic impact of low-temperature subnets in conventional district heating networks," Energy Procedia, vol. 116, no. C, s. 260-272, 2017.
[28]
S. N. Gunasekara et al., "Erythritol, Glycerol, their Blends, and Olive Oil, as Sustainable Phase Change Materials," Energy Procedia, vol. 135, s. 249-262, 2017.
[29]
S. N. Gunasekara et al., "Experimental phase diagram of the dodecane–tridecane system as phase change material in cold storage : [Diagramme de phase expérimental du système dodécane–tridécane comme matériau à changement de phase pour des applications d'entreposage frigorifique]," International journal of refrigeration, vol. 82, s. 130-140, 2017.
[30]
S. N. Gunasekara, V. Martin och J. N. Chiu, "Phase equilibrium in the design of phase change materials for thermal energy storage: State-of-the-art," Renewable & sustainable energy reviews, vol. 73, s. 558-581, 2017.
[31]
J. F. Castro Flores et al., "Techno-Economic Assessment of Active Latent Heat Thermal Energy Storage Systems with Low-Temperature District Heating," International Journal of Sustainable Energy Planning and Management, s. 5-17, 2017.
[32]
S. N. Gunasekara et al., "The Experimental Phase Diagram Study of the Binary Polyols System Erythritol-Xylitol," Solar Energy Materials and Solar Cells, vol. 174, s. 248-262, 2017.
[33]
J. F. Castro Flores et al., "Energetic and exergetic analysis of alternative low-temperature based district heating substation arrangements," International Journal of Thermodynamics, vol. 19, no. 2, s. 71-80, 2016.
[34]
J. N. W. Chiu et al., "Industrial surplus heat transportation for use in district heating," Energy, vol. 110, s. 139-147, 2016.
[35]
S. N. Gunasekara et al., "Polyols as phase change materials for surplus thermal energy storage," Applied Energy, vol. 162, s. 1439-1452, 2016.
[36]
J. N. Chiu, P. Gravoille och V. Martin, "Active free cooling optimization with thermal energy storage in Stockholm," Applied Energy, vol. 109, no. SI, s. 523-529, 2013.
[37]
E. Oró et al., "Comparative study of different numerical models of packed bed thermal energy storage systems," Applied Thermal Engineering, vol. 50, no. 1, s. 384-392, 2013.
[38]
E. Oró et al., "Stratification analysis in packed bed thermal energy storage systems," Applied Energy, vol. 109, no. SI, s. 476-487, 2013.
[39]
J. N. Chiu och V. Martin, "­Multistage Latent Heat Cold Thermal Energy Storage Design Analysis," Applied Energy, vol. 112, no. SI, s. 1438-1445, 2013.
[40]
J. N. Chiu och V. Martin, "Submerged finned heat exchanger latent heat storage design and its experimental verification," Applied Energy, vol. 93, no. SI, s. 507-516, 2012.

Konferensbidrag

[41]
L. Shan, A. R. Martin och J. N. Chiu, "Techno-Economic Analysis of Latent Heat Thermal Energy Storage Integrated Heat Pump for Indoor Heating," i 36th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2023, 2023, s. 2265-2276.
[42]
B. Nourozi et al., "Integrated Energy Active Windows with Low-Temperature Heating Systems in Cold Climates," i The 16th Conference of the International Society of Indoor Air Quality & Climate, 2020, s. 1054-1059.
[43]
A. Abdi, J. N. Chiu och V. Martin, "State of the art in hydrogen liquefaction," i Proceedings of the ISES Solar World Congress 2019 and IEA SHC International Conference on Solar Heating and Cooling for Buildings and Industry 2019, 2020, s. 1311-1320.
[44]
T. Xu et al., "Design Aspects of a Latent Heat Storage Unit for Heat Production Shifting at a Cogeneration Plant," i SWC2019 Proceedings, 2019.
[45]
R. Guedez et al., "Techno-economic comparative analysis of innovative combined cycle power plant layouts integrated with heat pumps and thermal energy storage," i Proceedings of the ASME Turbo Expo : Turbomachinery Technical Conference and Exposition, 2019, Vol 3, 2019.
[46]
V. G. Gkoutzamanis et al., "Thermal energy storage in combined cycle power plants : Comparing finite volume to finite element methods," i E3S Web of Conferences : SUPEHR19 Sustainable PolyEnergy generation and Harvesting, 2019.
[47]
S. Fujii et al., "Techno economic analysis of thermochemical energy storage and transport system utilizing "zeolite Boiler" : Case study in Sweden," i Energy Procedia, 2018, s. 102-111.
[48]
S. N. Gunasekara et al., "Thermal Conductivity Measurement of Erythritol, Xylitol and Their Blends for Phase Change Materials Design : a Methodological Study," i The 14th International Conference on Energy Storage, 2018, s. 364-378.
[49]
S. N. Gunasekara, J. N. Chiu och V. Martin, "Binary Phase Equilibrium Study of the Polyols Blend Erythritol-Xylitol with the T-History Method for Phase Change Materials Design," i The 13th International Conference on Energy Storage- Greenstock 2015, 2015.
[50]
J. F. Castro Flores et al., "Conceptual study of a solar-assisted low-temperature district heating substation," i Book of abstracts: International Conference on Smart EnergySystems and 4th Generation District Heating : Low-temperature district heating and buildings, 2015.
[51]
J. F. Castro Flores et al., "Energetic and exergetic analysis of a low- Temperature based district heating substation for low energy buildings," i ECOS 2015 - 28th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, 2015.
[52]
N. J. Chiu et al., "Environomic Assessment of Industrial Surplus Heat Transportation," i Smart Energy Infrastructure and Storage Options, 2015.
[53]
N. J. Chiu, B. H. Meany och V. Martin, "Industrial Surplus Heat Utilization through Mobile Thermal Energy Storage with Enhanced Operating Strategy," i Greenstock : Industrial Energy Storage Application/ Transportation Energy Storage/ Grid integration, 2015.
[54]
J. N. W. Chiu och V. Martin, "Industrial surplus heat storage in smart cities," i ASME 2015 9th International Conference on Energy Sustainability, ES 2015, collocated with the ASME 2015 Power Conference, the ASME 2015 13th International Conference on Fuel Cell Science, Engineering and Technology, and the ASME 2015 Nuclear Forum, 2015.
[55]
S. N. Gunasekara et al., "Polyols as phase change materials for low-grade excess heat storage," i Energy Procedia : Volume 61, International Conference on Applied Energy, ICAE2014, 2014, s. 664-669.
[56]
S. N. Gunasekara, V. Martin och J. N. Chiu, "Phase Diagrams as Effective Tools in Thermal Energy Storage (TES) Design using Phase Change Materials (PCM)," i ICAE2013, 2013.
[57]
A. Vadiee et al., "Thermal energy storage systems in closed greenhouse with component and phase change material design," i Sustainable Energy Storage in Buildings (SESB) Conferenc, 2013.
[58]
J. N. Chiu, P. Gravoille och V. Martin, "Active Free Cooling Optimization with Thermal Energy Storage in Stockholm," i InnoStock The 12th International Conference on Energy Storage : Book of Abstract, 2012, s. 106-107.
[59]
E. Oró et al., "Enhancement of the stratification with packed bed thermal energy storage systems," i InnoStock The 12th International Conference on Energy Storage: Book of Abstract, 2012, s. 284-285.
[60]
P. Johansson, J. N. Chiu och V. Martin, "Impact of Convective Heat Transfer Mechanism in Latent Heat Storage Modeling," i InnoStock 2012, The 12th International Conference on Energy Storage, 16-18 May 2012, Lleida, Spain, 2012.
[61]
N. J. Chiu, "Recent Development in Phase Change Materials for Thermal Energy Storage," i BIT's 1st Annual World Congress of Advanced Materials 2012 : Innovation, Cutting-Edge and Smartness, 2012, s. 299-300.
[62]
J. N. Chiu och V. Martin, "Thermal Energy Storage: Climate Change Mitigation Solution?," i International Conference for Sustainable Energy Storage, 2011.
[63]
J. N. Chiu, R. Khodabandeh och R. Furberg, "Advanced Thermosyphon Cooling with Nanoporous Structured Mini Channel Evaporators," i PROCEEDINGS OF THE ASME MICRO/NANOSCALE HEAT AND MASS TRANSFER INTERNATIONAL CONFERENCE, VOL 3, 2010, s. 183-189.
[64]
J. N. Chiu och V. Martin, "Thermal energy storage for sustainable future : impact of power enhancement on storage performance," i International Conference on Sustainable Refrigeration and Heat Pump Technology, Stockholm, June 13-16, 2010., 2010.
[65]
J. N. Chiu, V. Martin och F. Setterwall, "A Review of Thermal Energy Storage Systems with Salt Hydrate Phase Change Materials for Comfort Cooling," i 11th International Conference on Thermal Energy Storage, June 14-17 , 2009, Stockholm, Sweden., 2009.
[66]
J. N. Chiu, V. Martin och F. Setterwall, "System Integration of Latent Heat Thermal Energy Storage Systems for Comfort Cooling Integrated in district cooling network," i 11th International Conference on Thermal Energy Storage, EFFSTOCK 2009, Stockholm, Sweden, June 14-17, 2009., 2009.

Övriga

[67]
J. N. Chiu et al., "Cavern Thermal Energy Storagefor District Cooling," , 2018.

Icke refereegranskade

Konferensbidrag

[68]
S. N. Gunasekara et al., "Experimental Phase Equilibrium Study of Dodecane-Tridecane System for Phase Change Materials Design for Thermal Energy Storage," i International symposium on innovative materials for processes in energy systems (IMPRES) 2016, 2016.
[69]
A. Rossi Espagnet et al., "Techno-economic assessment of Thermal Energy Storage integration into Low Temperature District Heating networks," i Book of abstracts : 2nd International Conference on Smart Energy Systems and 4th Generation District Heating, 2016.

Kapitel i böcker

[70]
J. N. Chiu och V. Martin, "Industrial Applications of Thermal Energy Storage Systems," i Advances in Energy Storage : Latest Developments from R&D to the Market, Andreas Hauer red., : John Wiley & Sons, 2022.

Avhandlingar

[71]
N. J. Chiu, "Latent Heat Thermal Energy Storage for Indoor Comfort Control," Doktorsavhandling Stockholm : KTH Royal Institute of Technology, Trita-KRV, 13:02, 2013.
[72]
J. N. Chiu, "Heat Transfer Aspects of Using Phase Change Material in Thermal Energy Storage Applications," Licentiatavhandling Stockholm : KTH Royal Institute of Technology, Trita-KRV, 11/04, 2011.

Rapporter

[73]
J. N. Chiu, V. Martin och F. Setterwall, "Next Generation Cost Effective Phase Change Materials : TUD Action COST-STSM-TU0802-05255," European Cooperation in Science and Technology, 2009.

Övriga

[74]
T. Xu et al., "Experimental and Numerical Investigation of a Latent Heat Thermal Energy Storage Unit with Ellipsoidal Macro-encapsulation," (Manuskript).
[75]
S. N. Gunasekara et al., "Thermodynamic Assessment of Binary Erythritol-Xylitol Phase Diagram for Phase Change Materials Design," (Manuskript).
Senaste synkning med DiVA:
2024-04-21 00:26:31