TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ

Proje Grubu: TÜBİTAK MAG Proje Sayfa Sayısı: 187 Proje No: 214M308 Proje Bitiş Tarihi: 15.05.2018 Metin Dili: Türkçe

TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ

Öz:
Bu çalısmada, yakın alan ısınımını (YAI) incelemek ve siyah cisim ısımasının üzerinde ısı geçisi elde edebilmek amacıyla, karakteristik uzunlugu ısıl ısıma dalgaboylarından daha küçük olan, nanometrik bosluklu yapılar gelistirilmistir. Literatürde vakum ortamlarında yapılan çalısmaların aksine, gerçek çalısma ortamında testler yapabilmek için birbirine bakan yüzeyleri nanometre mertebesinde vakum boslugu ile ayrılmıs yongalar tasarlanıp üretilmistir. Isımayı, elektriksel dönüsüme elverisli sekilde harmanlamak için uygun rezonans frekanslarında yüzey modlarına sahip malzemeler teorik olarak incelenmistir. Sonrasında silisyum karbürün (SiC), silisyum (Si) yüzeyler üzerine ince film olarak kaplaması yapılmıstır. Farklı film kalınlıgı ve yonga içi bosluk mesafesi kombinasyonlarının rezonans frekansına etkileri teorik olarak incelenmistir. Ince filmlerin kristal yapısı ısıl islem ile iyilestirilmis ve karakterizasyonları yapılmıstır. Yonga dısındaki atmosferik basınç ile yonga içi vakum (düsük basınç) farkından dogan bükülmeyi azaltmak ve pul yüzeylerinin sızdırmaz sekilde birlestirmesinde, iletim ısı geçisi alanını minimum olacak sekilde saglamak üzere farklı yonga içi yöntemleri ile üretilmistir. Toplam ısı geçisi (iletim + ısınım) dahilinde iletim ve ısınım bilesenlerini mertebesel olarak belirleyebilmek için, toplam boyutları sabit, farklı ısı iletim alanlarına sahip dört farklı yapıda yonga tasarlanmıstır. Sözkonusu yongalar, SiC kaplı Si pulların üzerinde bir dizi mikro-elektro-mekanik sistem (MEMS) üretim basamagı izlenerek üretilmistir. Bu yongaların bos iç yüzeylerinde bulunabilecek farklı nano-çıkıntıların YAI üzerine etkileri, olusturulan sayısal bir model ile arastırılmıs ve üretilmesi en uygun tasarım belirlenmistir. Içinde 10-5 mbar mertebesinde vakumu tutabilen ve ısınım alanı iletim alanının 1.4 ila 6 katı olacak sekilde tasarlanmıs yongalar, basarı ile üretilmis ve test edilmistir. Proje kapsamında ayrıca, vakum ortamı dısında gerçek bir yonganın testlerinin yapılabilmesi için uluslararası düzeyde, özgün bir deney düzenegi gelistirilmis, kontrollü ısıtma ve sogutma yapabilen ve ısı akısını hassas ölçebilen bu düzenekte deneyler basarıyla tamamlanmıstır. 0,1 mm düz duvarlı yapıda ısınımın toplam ısı transferine oranı %13.6 olarak ayrıstırılabilmistir. Olusturulan düzenek, farklı arastırma gruplarının gelistirecegi termofotovoltaik (TPV) hücrelerin hassas bir biçimde test edilmesine olanak saglamaktadır
Anahtar Kelime: nano-ölçekte ısıma yakın alan ısınımı termofotovoltaik hücreler Enerji harmanlama

Konular: Mühendislik, Elektrik ve Elektronik Mühendislik, Makine
Erişim Türü: Erişime Açık
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APA OKUTUCU ÖZYURT H, MENGÜÇ M (2018). TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ. , 1 - 187. 214M308
Chicago OKUTUCU ÖZYURT Hanife Tuba,MENGÜÇ Mustafa Pınar TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ. (2018): 1 - 187. 214M308
MLA OKUTUCU ÖZYURT Hanife Tuba,MENGÜÇ Mustafa Pınar TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ. , 2018, ss.1 - 187. 214M308
AMA OKUTUCU ÖZYURT H,MENGÜÇ M TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ. . 2018; 1 - 187. 214M308
Vancouver OKUTUCU ÖZYURT H,MENGÜÇ M TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ. . 2018; 1 - 187. 214M308
IEEE OKUTUCU ÖZYURT H,MENGÜÇ M "TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ." , ss.1 - 187, 2018. 214M308
ISNAD OKUTUCU ÖZYURT, Hanife Tuba - MENGÜÇ, Mustafa Pınar. "TERMOFOTOVOLTAİK ENERJİ HARMANLAMA SİSTEMLERİNDE YAKIN ALAN IŞINIM DENEYLERİ". (2018), 1-187. https://doi.org/214M308
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