CONTROL SYSTEM OF CONTROLLERS OF A FLAT SOLAR COLLECTOR WITH A THERMOSIFON CIRCULATION

This paper discusses the creation of a control and monitoring system for the operation of a solar collector based on the use of the Mojo v3 platform. A measurement of 6 digital sensors (DS18B20 Dallas), mounted in the collector system with 16 wires, is provided. Offered software with IEEE library on Mojo v3. Using Dallas sensors and the appropriate software, you can monitor the temperature and the amount of heat in the system. Software included in the Mojo v3 database is implemented in the language (VHDL, VERILOG).

1. Duffie, J. A., and W. A. Beckman, Solar Engineering of Thermal Processes, John Wiley and Sons, New York, 1991.

2. Ahmet Samanci and Adnan Berber, “Experimental investigation of single-phase and twophase closed thermosyphon solar water heater systems”, Scientific Research and Essays, Vol. 6 (4), pp. 688-693, 18 February, 2011.

3. M. A. Islam, M. A. R. Khan and M. A. R. Sarkar, “Performance of a Two-Phase Solar Collector in Water Heating”, Journal of Energy & Environment 4 (2005), Technical Note 117 - 123.

4. K. Chuawittayawuth & S. Kumar, “Experimental investigation oftemperature and flow distribution in a thermosyphon solar water heating system”, Renewable Energy 26 (2002) 431-448.

5. H. Taherian, A. Rezania, S. Sadeghi & D.D. Ganji, “Experimental validation of dynamic simulation of the flat plate collector in a closed thermosyphon solar water heater”, Energy Conversion and Management 52 (2011) 301-307.

6. A. Zerrouki, A. Boume dien & K. Bouhadef, “The natural circulation solar water heater model with linear temperature distribution”, Renewable Energy 26 (2002) 549-559.

7. Samuel Luna Abreu, Sergio Colle, “An experimental study of two-phase closed thermosyphons for compact solar domestic hot-water system”, Solar Energy 76 (2004) 141-145.

8. Alireza Hobbi, Kamran Siddiqui, “Experimental study on the effect of heat transfer enhancement devices in flat-plate solar collectors”, International Journal of Heat and Mass Transfer 52 (2009) 4650-4658.

9. N. V. Ogueke, E. E. Anyanwu, and O. V Ekechukwu, “A review of solar water heating systems” Journal of Renewable and Sustainable Energy 1, 043106, 2009.

10. Dr. Akeel Abdullah Mohammed, “Heat Transfer and Pressure Drop Characteristics of Turbulent Flow in a Tube Fitted With Conical Ring and Twisted Tape Inserts” Engg. & Tech. Journal, vol. 29, no. 2, 2011. J. U. Duncombe, “Infrared navigation—Part I: An assessment of feasibility (Periodical style),” IEEE Trans. Electron Devices, vol. ED- 11, pp. 34-39, Jan. 1959

11. De Marchi Neto, I., Padilha, A.: Refrigerator COP with thermal storage. Appl. Therm. Eng. 29(1), 2358-2364 (2008)

12. Souza, L.M.P: Levantamento de Coeficientes de Desempenho de Armazenador Te rmico Associado a Refrigerador Dome stico Modificado. Universidade Estadual Paulista-Ju lio de Mesquita Filho, Campus de Baum, Mestrado (2011)

13. Taheri, H.: PhD’s Thesis. Phd Thesis, Karlsruhe Institut fu "r Technologie (KIT), Karlsruhe, Germany (2014)

14. Rosen, M.A., Kumar, R.: Performance of a photovoltaic/thermal solar air heater: effect of vertical fins on a double pass system. Int. J. Energy Environ. Eng. 2(4), 1-4 (2011)

15. Sugathan, A., Kirthyvijay, G.J., Thomson, J.: Application of Arduino based platform for wearable health monitoring system. In: Presented at the 1st International Conference on Condition Assessment Techniques in Electrical Systems (2013)

16. Faizan, V., Galib, M., Khan, A., Afzal, S.: Arduino web server for efficiently control and monitoring of solar power system. Int. J. Comput. Eng. Appl. 8 (1), 148