Impregnation of porous material with phase change material for thermal energy storage T Nomura, N Okinaka, T Akiyama Materials Chemistry and Physics 115 (2-3), 846-850, 2009 | 331 | 2009 |
Technology of latent heat storage for high temperature application: a review T Nomura, N Okinaka, T Akiyama ISIJ international 50 (9), 1229-1239, 2010 | 240 | 2010 |
Thermal conductivity enhancement of erythritol as PCM by using graphite and nickel particles T Oya, T Nomura, M Tsubota, N Okinaka, T Akiyama Applied Thermal Engineering 61 (2), 825-828, 2013 | 208 | 2013 |
Microencapsulation of metal-based phase change material for high-temperature thermal energy storage T Nomura, C Zhu, N Sheng, G Saito, T Akiyama Scientific reports 5, 9117, 2015 | 203 | 2015 |
Macro-encapsulation of metallic phase change material using cylindrical-type ceramic containers for high-temperature thermal energy storage R Fukahori, T Nomura, C Zhu, N Sheng, N Okinaka, T Akiyama Applied Energy 170, 324-328, 2016 | 174 | 2016 |
Phase change composite based on porous nickel and erythritol T Oya, T Nomura, N Okinaka, T Akiyama Applied Thermal Engineering 40, 373-377, 2012 | 168 | 2012 |
Microencapsulated phase change materials with high heat capacity and high cyclic durability for high-temperature thermal energy storage and transportation T Nomura, N Sheng, C Zhu, G Saito, D Hanzaki, T Hiraki, T Akiyama Applied energy 188, 9-18, 2017 | 164 | 2017 |
High thermal conductivity phase change composite with percolating carbon fiber network T Nomura, K Tabuchi, C Zhu, N Sheng, S Wang, T Akiyama Applied energy 154, 678-685, 2015 | 160 | 2015 |
Waste heat transportation system, using phase change material (PCM) from steelworks to chemical plant T Nomura, N Okinaka, T Akiyama Resources, Conservation and Recycling 54 (11), 1000-1006, 2010 | 155 | 2010 |
Thermal analysis of Al–Si alloys as high-temperature phase-change material and their corrosion properties with ceramic materials R Fukahori, T Nomura, C Zhu, N Sheng, N Okinaka, T Akiyama Applied Energy 163, 1-8, 2016 | 125 | 2016 |
Heat storage in direct-contact heat exchanger with phase change material T Nomura, M Tsubota, T Oya, N Okinaka, T Akiyama Applied thermal engineering 50 (1), 26-34, 2013 | 114 | 2013 |
Shape-stabilized phase change composite by impregnation of octadecane into mesoporous SiO2 T Nomura, C Zhu, N Sheng, K Tabuchi, A Sagara, T Akiyama Solar Energy Materials and Solar Cells 143, 424-429, 2015 | 103 | 2015 |
Heat release performance of direct-contact heat exchanger with erythritol as phase change material T Nomura, M Tsubota, T Oya, N Okinaka, T Akiyama Applied Thermal Engineering 61 (2), 28-35, 2013 | 77 | 2013 |
Fabrication of paraffin@ SiO2 shape-stabilized composite phase change material via chemical precipitation method for building energy conservation R Luo, S Wang, T Wang, C Zhu, T Nomura, T Akiyama Energy and Buildings 108, 373-380, 2015 | 74 | 2015 |
Improvement in thermal endurance of D-mannitol as phase-change material by impregnation into nanosized pores A Sagara, T Nomura, M Tsubota, N Okinaka, T Akiyama Materials Chemistry and Physics 146 (3), 253-260, 2014 | 64 | 2014 |
Catalytic coal-tar decomposition to enhance reactivity of low-grade iron ore RB Cahyono, AN Rozhan, N Yasuda, T Nomura, S Hosokai, Y Kashiwaya, ... Fuel processing technology 113, 84-89, 2013 | 54 | 2013 |
Estimation of thermal endurance of multicomponent sugar alcohols as phase change materials T Nomura, C Zhu, A Sagara, N Okinaka, T Akiyama Applied Thermal Engineering 75, 481-486, 2015 | 52 | 2015 |
High thermal conductivity phase change composite with a metal-stabilized carbon-fiber network T Nomura, C Zhu, S Nan, K Tabuchi, S Wang, T Akiyama Applied energy 179, 1-6, 2016 | 50 | 2016 |
Performance analysis of heat storage of direct-contact heat exchanger with phase-change material T Nomura, M Tsubota, A Sagara, N Okinaka, T Akiyama Applied Thermal Engineering 58 (1-2), 108-113, 2013 | 49 | 2013 |
High‐temperature latent heat storage technology to utilize exergy of solar heat and industrial exhaust heat T Nomura, T Akiyama International Journal of Energy Research 41 (2), 240-251, 2017 | 45 | 2017 |