Expanded glass sphere/lauryl alcohol composite in gypsum: Physico-mechanical properties, energy storage performance and environmental impact assessment
暂无分享,去创建一个
A. Sari | Abid Ustaoğlu | O. Gencel | Ali Yaraş | E. Erdoğmuş | G. Hekimoğlu | Abid Ustaoglu | Osman Gencel
[1] A. Sari,et al. Characteristics, energy saving and carbon emission reduction potential of gypsum wallboard containing phase change material , 2022, Journal of Energy Storage.
[2] A. Sari,et al. Glass Fiber Reinforced Gypsum Composites with Microencapsulated Pcm as Novel Building Thermal Energy Storage Material , 2022, SSRN Electronic Journal.
[3] Mehmet Emin Akay,et al. Energetic, exergetic, and environmental evaluation of railway transportation by diesel and electric locomotives , 2022, Environmental Progress & Sustainable Energy.
[4] A. Sari,et al. A novel energy-effective and carbon-emission reducing mortars with bottom ash and phase change material: Physico-mechanical and thermal energy storage characteristics , 2021, Journal of Energy Storage.
[5] A. Sari,et al. Eco-friendly building materials containing micronized expanded vermiculite and phase change material for solar based thermo-regulation applications , 2021, Construction and Building Materials.
[6] Waiching Tang,et al. Development of novel form-stable phase change material (PCM) composite using recycled expanded glass for thermal energy storage in cementitious composite , 2021 .
[7] Deepankar Kumar Ashish,et al. Expanded glass as light-weight aggregate in concrete – A review , 2021 .
[8] I. Tyagi,et al. Studies on the mechanical properties and thermal behavior of microencapsulated eutectic mixture in gypsum composite board for thermal regulation in the buildings , 2020 .
[9] Waiching Tang,et al. Thermal and Mechanical Properties of Cement Mortar Composite Containing Recycled Expanded Glass Aggregate and Nano Titanium Dioxide , 2020, Applied Sciences.
[10] Marzena Kurpińska,et al. Predicting Performance of Lightweight Concrete with Granulated Expanded Glass and Ash Aggregate by Means of Using Artificial Neural Networks , 2019, Materials.
[11] Gintaris Kaklauskas,et al. Compressive Strength and Durability Properties of Structural Lightweight Concrete with Fine Expanded Glass and/or Clay Aggregates , 2018, Materials.
[12] K. Mo,et al. Incorporation of expanded vermiculite lightweight aggregate in cement mortar , 2018, Construction and Building Materials.
[13] Zhaohui Huang,et al. Thermal behavior of composite phase change materials based on polyethylene glycol and expanded vermiculite with modified porous carbon layer , 2018, Journal of Materials Science.
[14] Zhaohui Huang,et al. Preparation and characterization of capric-palmitic-stearic acid ternary eutectic mixture/expanded vermiculite composites as form-stabilized thermal energy storage materials , 2018 .
[15] Thomas Statheros,et al. PCMs for Residential Building Applications: A Short Review Focused on Disadvantages and Proposals for Future Development , 2017 .
[16] G. Fang,et al. Preparation, characterization and thermal properties of fatty acid eutectics/bentonite/expanded graphite composites as novel form–stable thermal energy storage materials , 2017 .
[17] L. Bertolini,et al. Durability of Lightweight Concrete with Expanded Glass and Silica Fume , 2017 .
[18] P Pieter-Jan Hoes,et al. Ultra-lightweight concrete: energy and comfort performance evaluation in relation to buildings with low and high thermal mass , 2017 .
[19] J. Alexandre Bogas,et al. Contribution of structural lightweight aggregate concrete to the reduction of thermal bridging effect in buildings , 2016 .
[20] G. Martínez-Barrera,et al. A novel lightweight gypsum composite with diatomite and polypropylene fibers , 2016 .
[21] Sumin Kim,et al. Preparation of energy efficient paraffinic PCMs/expanded vermiculite and perlite composites for energy saving in buildings , 2015 .
[22] Jianping Zhu,et al. Preparation and properties of gypsum based energy storage materials with capric acid–palmitic acid/expanded perlite composite PCM , 2015 .
[23] Parviz Soroushian,et al. Experimental and numerical study of shape-stable phase-change nanocomposite toward energy-efficient building constructions , 2014 .
[24] Shazim Ali Memon,et al. Phase change materials integrated in building walls: A state of the art review , 2014 .
[25] Feng Xing,et al. Experimental assessment of position of macro encapsulated phase change material in concrete walls on indoor temperatures and humidity levels , 2014 .
[26] A. Sari. Composites of polyethylene glycol (PEG600) with gypsum and natural clay as new kinds of building PCMs for low temperature-thermal energy storage , 2014 .
[27] S. C. Solanki,et al. Heat transfer characteristics of thermal energy storage system using PCM capsules: A review , 2008 .
[28] Kamil Kaygusuz,et al. Capric acid and stearic acid mixture impregnated with gypsum wallboard for low‐temperature latent heat thermal energy storage , 2008 .
[29] Ö. Altan Dombaycı,et al. The environmental impact of optimum insulation thickness for external walls of buildings , 2007 .
[30] Zongjin Li,et al. Granular phase changing composites for thermal energy storage , 2005 .
[31] Shuli Liu,et al. Development of gypsum plasterboard embodied with microencapsulated phase change material for energy efficient buildings , 2021, Materials Science for Energy Technologies.
[32] D. Stephan,et al. Effect of different expanded aggregates on the properties of lightweight concrete , 2019, Magazine of Concrete Research.
[33] V. Vinayaka Ram,et al. PCM-mortar based construction materials for energy efficient buildings: A review on research trends , 2018 .
[34] Abdullah Yildiz,et al. ECONOMICAL AND ENVIRONMENTAL ANALYSES OF THERMAL INSULATION THICKNESS IN BUILDINGS , 2008 .