Algılayıcı Türlerinin Güneş Takip Sisteminde Etkinliğinin Araştırılması

Yıl 2021, Sayı: 25, 112 - 119, 31.08.2021

Ahmet Yönetken Tuğba Gürsoy

https://doi.org/10.31590/ejosat.843262

Cited By: 1

Öz

Teknolojinin gelişmesiyle enerjiye olan talep gün geçtikçe artmaktadır. Fosil yakıtların sınırlı olması alternatif enerji kaynakları aramaya teşvik etmektedir. Yenilenebilir enerji kaynakları kullanımı artan enerji talebini karşılamada önemli bir yere sahiptir. Güneş enerji teknolojileri günümüzde sıkça kullanılmaya başlanmıştır. Güneş enerjisinden yüksek verimlilikle güç elde etmede güneş takip sistemleri gündeme gelmektedir.
Bu çalışmada çift eksenli tasarlanmış üç güneş takip sisteminde aynı özellikte yerleştirilen panellerin üzerinde üç farklı algılayıcının performansları karşılaştırılmıştır. Sistemin sabit ve hareketli konumda belirli aralıklarla gerilim ve akım değerleri ölçülmüştür. Elde edilen verilere göre güneş panellerinin sabit ve hareketli konumda toplam üretimleri karşılaştırıldığında hareketli konumda sabit konuma göre; LilyPad Işık Sensörlü sistemde %36,68 oranında, SMD Sensörlü sistemde %38,42 ve LDR’li sistemde %43,58 oranında artış görülmüştür.

Anahtar Kelimeler

Algılayıcılar, Yenilenebilir enerji,, Güneş takip sistemleri,

Investigation of the Activities of Sensor Types in Solar Tracking System

Öz

The development of technology and the demand for energy are increasing day by day. The limited fossil fuels encourage the search for alternative energy sources. The use of renewable energy sources has an important place in meeting the increasing energy demand. Solar energy technologies are being used frequently today. Solar tracking systems are on the agenda in obtaining power from solar energy with high efficiency. In this study, solar tracking systems are designed as biaxial. Solar panels have the same technical features. Three different types of sensors are placed on the solar panels. The performances of the sensor types against the same type of energy production have been compared. The voltage and current values of the system were measured in fixed and mobile positions at regular intervals. According to the data obtained, when the total productions of solar panels in fixed and mobile position are compared; There was an increase of %36.68 in the LilyPad Light Sensor system, %38.42 in the SMD Sensor system and %43.58 in the system with LDR. 

Anahtar Kelimeler

Renewable energy, Solar tracking systems, Sensors

Kaynakça

• Alif Ismail, M., Ramanathan, K.A., Hafizi Idris, M., Ananda-Rao, K., Mazlan, M., Fairuz, N., Improving the Performance of Solar Panels by The Used of Dual Axis Solar Tracking System with Mirror Reflection, Journal of Physics: Conference Series, (2020). 1432, Article number 012060.
• Allamehzadeh, H., An Update on Solar Energy and Sun Tracker Technology with a Dual Axis Sun Tracker Application, IEEE 46th Photovoltaic Specialists Conference (PVSC), Chicago, IL, USA, (2019). 2037-2044.
• Al-Rousan, N., Mat Isa, N.A., Mat Desa, M.K., Efficient Single and Dual Axis Solar Tracking System Controllers Based on Adaptive Neural Fuzzy Inference System, Journal of King Saud University - Engineering Sciences. (2020).
• Altayeb, M., Abdalla, S., Mustafa, A.H., (2018).Dual Axis Solar Sun Tracking System Based on GPS Satellite Receiver and Embedded System," 2018 International Conference on Computer, Control, Electrical, and Electronics Engineering (ICCCEEE), Khartoum, (2018).1-4.
• Amelia, A.R., Irwan, Y.M., Safwati, I., Leow, W.Z., Mat, M.H., Rahim, M.S.A., Technologies of Solar Tracking Systems: A Review, IOP Conference Series: Materials Science and Engineering, (2020). 767, Article number 012052.
• Ammach, S., Attia, A., 2019, Design and Implementation of Autonomous Energy Efficient Solar Tracking System for PV Power Plants, International Conference on Electrical and Computing Technologies and Applications, ICECTA 2019, (2019) Article number 8959537.
• Awad, S.R., Al Jbaar, M.A., Abdullah, M.A.M., Efficient and Low-Cost Arduino based Solar Tracking System, IOP Conference Series: Materials Science and Engineering, (2020). 745, Article number 012016.
• Awasthi, A., Shukla, A.K., Murali Manohar, S.R., Dondariya, C., Shukla, K.N., Porwal, D., Richhariya, G., Review on Sun Tracking Technology in Solar PV System, Energy Reports, (2020). 6, 392-405.
• Away, Y., Ikhsan, M., Dual-axis Sun Tracker Sensor Based on Tetrahedron Geometry, Automation in Construction, (2017). 73, 175-183.
• Benaboud, A., A Special Application of Power Electronics to the Field of Photovoltaic, Lecture Notes in Electrical Engineering, (2020). 624, 24-33.
• Farhan, A.J., Fabrication and Development Low Cost Dual Axis Solar Tracking System, IOP Conference Series: Materials Science and Engineering, (2020). 757, Article number 012042.
• Jamroen, C., Komkum, P., Kohsri, S., Himananto, W., Panupintu, S., Unkat, S., A Low-cost Dual-axis Solar Tracking System Based on Digital Logic Design: Design and Implementation, Sustainable Energy Technologies and Assessments, (2020). 37, Article number 100618.
• Makhija, S., Khatwani, A., Khan, M.F., Goel, V., Roja, M.M., Design & Implementation of An Automated Dual-axis Solar Tracker With Data-logging, 2017 International Conference on Inventive Systems and Control (ICISC), Coimbatore, (2017). pp. 1-4.
• Mane, S.G., Korachagaon, I., Hans, M.R., Sawant, A.S., Simulation of Dual Axis Solar Tracking System," 2018 International Conference on Information, Communication, Engineering and Technology (ICICET), Pune, (2018). 1-5.
• Mohaimin, H., Uddin, M.R., Hashim, H., Tuah, N., Zahari, M.R., Design and Simulation of Single-axis and Dual-axis Solar Tracking Systems, 7th Brunei International Conference on Engineering and Technology 2018 (BICET 2018), Bandar Seri Begawan, Brunei, (2018). 1-4.
• Mohaimin, A.H., Uddin, M.R., Law, F.K., Design and Fabrication of Single-Axis and Dual-Axis Solar Tracking Systems, 2018 IEEE Student Conference on Research and Development (SCOReD), Selangor, Malaysia, (2018). 1-4.
• Mohd Said, M.N.A., Jumaat, S.A., Jawa, C.R.A., Dual Axis Solar Tracker With Iot Monitoring System Using Arduino, International Journal of Power Electronics and Drive Systems, (2020). 11, 451-458.
• Mustafa, F.I., Al-Ammri, A.S., Ahmad, F.F., Direct and Indirect Sensing Two-axis Solar Tracking System, 2017 8th International Renewable Energy Congress (IREC), Amman, (2017). 1-4.
• Mustafa, F.I., Shakir, S., Mustafa, F.F., Naiyf, A.T., Simple Design and Implementation of Solar Tracking System Two Axis With Four Sensors for Baghdad City, 2018 9th International Renewable Energy Congress (IREC), Hammamet, (2018). 1-5.
• Natarajan, S.K., Kumar, A., Mohamed, R., Rathna, R., Mondal, S., Suraparaju, S.K., Design and Development of Dual Axis Sun Tracking System for Floating PV Plant, IOP Conference Series: Earth and Environmental Science, (2019). 312, Article number 012001.
• Pattanaik, P., Dual Axis Tracker for Photovoltaic Panel, International Journal of Innovative Technology and Exploring Engineering, (2019). 8, 906-910.
• Salih, N.M., Said, M.S.M., Jamil, N., Davion, T., Yahaya, A.H., System Identification of a Solar Maximum Power Point Tracking System for Dual Axis, International Journal of Innovative Technology and Exploring Engineering, (2019). 8, 5653-5657.
• Smirnov, A.A., Vozmilov, A.G., Sultonov, O.O., Investigating the Effectiveness of Solar Tracking for PV Facility in Chelyabinsk, Lecture Notes in Electrical Engineering, (2020).641, 501-508.
• Tiwari, N., Soni, R., Saraswat, A., Kumar, B., Comparative Simulation Study of Dual-axis Solar Tracking System on Simulink Platform, Lecture Notes in Electrical Engineering, (2020). 607, 359-365.
• Zhu, Y., Liu, J., Yang, X., , Design and Performance Analysis of A Solar Tracking System With A Novel Single-axis Tracking Structure to Maximize Energy Collection Applied Energy, (2020). p264, Article number 114647.