This content is not included in
your SAE MOBILUS subscription, or you are not logged in.
Influence of Titanium Oxide Nanoparticle on Solar Desalination with Phase Change Material
Technical Paper
2020-28-0464
ISSN: 0148-7191, e-ISSN: 2688-3627
This content contains downloadable datasets
Annotation ability available
Sector:
Language:
English
Abstract
The present study is focused on the significance of solar desalination heat storage method. The Solar energy is a prime source of energy existing directly or indirectly from the nature. The primary drawback of solar energy, which is existing in hours only. Thermal storage devices can overcome this problem as they can store the energy in daylight that can be utilized in off sunshine hours. The purpose of this work is to evaluate the increase in productivity of the solar desalination by using phase change material and combination of PCM with TiO2 (Nano particles). The present work is focused on performance of solar water desalination using Phase Change Materials along with TiO2 Nanoparticles. The Titanium Oxide Nanoparticles were synthesized by Sol-Gel method. The Titanium oxide Nano particles were characterized by XRD, SEM, EDS, and FTIR etc. In this experiment paraffin 34-carbons is used as phase change materials and Titanium Oxide Nanoparticles used for energy storage materials. The water is taken about 15(ltrs) and the optimal depth of water found to be 1cm. The energy materials paraffin 34-carbon along with TiO2 shown improvement in collection efficiency.
Authors
Topic
Citation
krupakaran, R., Palampalle, B., Balasubramanian, D., and Reddy, G., "Influence of Titanium Oxide Nanoparticle on Solar Desalination with Phase Change Material," SAE Technical Paper 2020-28-0464, 2020.Data Sets - Support Documents
| Title | Description | Download |
|---|---|---|
| Unnamed Dataset 1 | ||
| Unnamed Dataset 2 |
Also In
References
- Fath , H.E.S. Technical Assessment of Solar Thermal Energy Storage Technologies Renew. Energy 14 35 40 1998
- Mohammed , M. , Amar , M. , Siddique , A. , and Said , A. A Review on Phase Change Energy Storage: Materials and Applications Energy Convers. Manag. 45 1597 1615 2004
- Abhat , A. Low Temperature Latent Heat Thermal Energy Storage: Heat Storage Materials Sol. Energy 39 339 346 1991
- El-Sebaii , A.A. , Al-Ghamdi , A.A. , Al-Hazmi , F.S. , and Faidah , A.S. Thermal Performance of a Single Basin Solar Still with PCM as a Storage Medium Appl. Energy 86 1187 1195 2009
- Radhawan , A.M. Transient Performance of a Stepped Solar Still with Built-In Latent Heat Thermal Energy Storage Desalination 171 61 76 2004
- Dashtban , M. , and Tabrizi , F.F. Thermal Analysis of a Weir-Type Cascade Solar Still Integrated with PCM Storage Desalination 279 415 422 2011
- Arunkumar , T. , Denkenberger , D. , Ahsan , A. , and Jayaprakash , R. The Augmentation of Distillate Yield by Using Concentrator Coupled Solar Still with Phase Change Material Desalination 314 189 192 2013
- Haji-Sheikh , A. , Eftekhar , J. , and Lou , D.Y.S. Some Thermophysical Properties of Paraffin Wax as a Thermal Storage Medium American Institute of Aeronautics and Astronautics 1982
- Barford , N.C. Experimental Measurements: Precision Error and Truth New York John Wiley & Sons 1990
- Dashtban , M. , and Tabrizi , F.F. Thermal Analysis of a Weir-Type Cascade Solar Still Integrated with PCM Storage Desalination 279 415 422 2011
- Kabeel , A.E. Performance of Solar Still with a Concave Wick Evaporation Surface Energy 34 1504 1509 2009
- Sharqawy , M.H. , Lienhard , J.H.V. , and Zubair , S.M. The Thermophysical Properties of Seawater: A Review of Existing Correlations and Data Desalination Water Treatment 16 354 380 2010
- Sharqawy , M.H. , Lienhard , J.H.V. , and Zubair , S.M. On Exergy Calculations for Seawater with Application to Desalination Systems J. Thermal Sci. 50 2 187 196 2011