Elektro-membran Biyoreaktör Kombine Güneş Enerjili Prosesler: MATLAB Modelleme

Year 2022, Issue: 42, 61 - 65, 31.10.2022

Gamze Nalcaci , Gülizar Kurtoğlu Akkaya

https://doi.org/10.31590/ejosat.1188755

Abstract

Bu çalışmada, Türkiye'de Antalya için batık elektro membran biyoreaktör ile sızıntı suyu arıtımında kullanılan DC güç kaynağı yerine güneş enerjisi için (PV) panel kullanılabileceği araştırılmıştır. Çalışma, güneş enerjili veya PV panellerden elde edilen elektrik enerjisinin MATLAB Simulink ile analizi ve modellemesi yapılmış ve bir mühendislik yaklaşımı sunmaktadır. SMEBR, 24 mA/cm2 (11,5 A) akım yoğunluğunda, 3+3 dakika maruz kalma süresinde elektrokinetik koşullar altında çalıştırıldı. Sonuç olarak, SMEBR elektrokinetik deney sonuçları ışığında paralel bağlanmış bir çift PV panelin bu bölge için SMEBR işlemi için 11.5 A sağladığı bulunmuştur. Elde edilen modellemede hacim miktarına bağlı olarak panel sayısının arttığı tespit edilmiştir. Ayrıca PV sistemin aküsüz çalışabileceği bir kontrol mekanizması ile sistemi kapattığı ve doğru akım sağladığı anlaşılmıştır. Sisteme pil eklenirse çalışmaya ara vermeden devam edebilir. Ancak bu sistem yaklaşık altı dakika çalışacağı için herhangi bir pil maliyeti gerekmeyecektir.

Keywords

Elektro Biyoreaktör, Elektrokoagülasyon, Sızıntı Suyu, Güneş Enerjisi, PV Panel, MATLAB

Electro-membrane Bioreactor Combined Solar Powered Processes: MATLAB Modelling

Abstract

In this study, it is researched that could use (PV) panel for solar energy instead of DC power supply used in leachate treatment by submerged electro membrane bioreactor for Antalya in Turkey. The study was made the analysis and modeling by MATLAB Simulink of electric energy obtained solar powered or PV panels and present an engineering approach. SMEBR was operated under electrokinetic conditions at a current density of 24 mA/cm2 (11,5 A), exposure time 3+3 minutes. As a result, in the light of SMEBR electrokinetic experimental results, it was found that a pair of PV panels connected in parallel provide 11.5 A for the SMEBR process for this region. In obtained modelling, it was determined the number of panels increases dependent on the amount of volume. Also, it was understood that PV system can work without battery via a control mechanism turn off the system, and it provides direct current. If a battery is added to the system, it can continue treatment without interruption. But since this system will run for about six minutes, no battery cost will be required.

Keywords

Electro Bioreactor, Electrocoagulation, Leachate, Solar Energy, PV Panel, MATLAB

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