Tuğba AKKAŞ BOYNUEĞRİ, Metin GÜRÜ

8414

HİDROJEL ESASLI $CoF_24 KATALİZÖR ile $NABH_4$’den HİDROJEN SALINIMI

Bu makalede, NaBH4'ün dehidrojenasyon reaksiyonu, Co iyon yüklü hidrojel katalizör varlığında gerçekleştirilmiştir. Reaksiyonlar sırasıyla 25, 35 ve 45 °C'de 27, 18 ve 9 saat içinde gerçekleşmiştir. Bununla beraber, $NABH_4$'ün başlangıç konsantrasyonu ile salınan hidrojen arasındaki ilişki 45 °C' de araştırılmıştır. Başlangıç borohidrür konsantrasyonu ile üretilen $H_2$ arasında doğrusal bir ilişki olduğu belirlenmiştir. Ayrıca, reaksiyon hız sabitleri ve reaksiyon mertebesini belirlemek için diferansiyel yöntem kullanılmıştır. Böylece, deneysel veriler kullanılarak birinci derece kinetik kanıtlanmıştır. Daha sonra, dehidrojenasyon reaksiyonu için lnk’ya karşılık 1/T grafiğinin eğiminden aktivasyon enerjisi 58.26 kJ/mol olarak bulunmuştur. Bu değer, katalitik dehidrojenasyon çalışmaları için literatürde beklenen 50 kJ/mol'e neredeyse eşittir. Hazırlanan poli (akrilamid-ko-akrilik asit) (p (AAm-co-AAc)-Co) hidrojel katalizörün hidrofilik ve makro-gözenekli yapısı $NABH_4$ çözeltisinin katalizörün iç kısımlarına kadar girebilmesine ve üretilen $H_2$'nin salınmasına olanak verdiği için gözenek difüzyon sınırlaması etkisi ihmal edilmiştir. $NABH_4$'ün dehidrojenasyon indeksi, sulu çözeltideki $NABH_4$ miktarına göre 2526,31 $mL H_2/g$ $NABH_4$ olarak hesaplanmıştır

RELEASING HYDROGEN FROM $NABH_4$ VIA HYDROGEL BASED $CoF_2$ CATALYST

In this paper, the dehydrogenation reaction of NaBH4 was performed in the presence of Co-ion loaded hydrogel catalyst. The reactions took place within 27, 18 and 9 hours at 25, 35 and 45 °C, respectively. In addition, the relation between the initial concentration of $NABH_4$and released hydrogen was investigated at 45°C. A linear relationship between initial borohydride concentration and produced $H_24 was determined. Also, differential method was used to determine reaction rate constants and rate order. Hence, first-order-kinetics was proved by using experimental data. After that, the activation energy was found as 58.26 kJ/mol by means of the slope of the graph of lnk versus 1/T for the dehydrogenation reaction. This value is nearly equal to 50kJ/mol, which was expected in literature for the studies of the catalytic dehydrogenation. As the hydrophilic and macroporous structure of the prepared poly(acrylamide-co-acrylic acid) (p(AAm-co-AAc)-Co) hydrogel catalyst allowed inlet of $NABH_4$ solution up to its interior and release of produced $CoF_2$, effect of pore diffusion limitation was neglected. Dehydrogenation index of NaBH4 was calculated as 2526.31 mL $H_2/g$ $NABH_4$ according to the amount of $NABH_4$ in the aqueous solution
PDF

___

  • Balbay A. and Şahin Ö., 2014, Hydrogen production from sodium borohydride in boric acid- water mixtures, Energy Sources, Part A, 36 (11), 1166-74.
  • Boynuegri T.A., Karabulut A.F. and Gürü M., 2016, Synthesis of borohydride and catalytic dehydrogenation by hydrogel based catalyst, J Electronic Materials, 45 (8), 3949-56.
  • Boynuegri T.A. and Guru M., 2017, Catalytic dehydrogenation of calcium borohydride by using hydrogel catalyst, Int. J Hydrogen Energy, 42, 17869-73.
  • Çakanyıldırım Ç. and Gürü M., 2009, Production of NaBH4 and hydrogen release with catalyst, Renew Energy, 34, 2362-65.
  • Çakanyıldırım Ç. and Gürü M., 2010, Supported CoCl2 catalyst for NaBH4 dehydrogenation, Renew Energy, 35, 839-844.
  • Çakanyıldırım Ç. and Gürü M., 2008, Processing of LiBH4 from its elements by ball milling method, Renew Energy, 33, 2388–92.
  • Eberle U., Felderhoff M. and Schüth F., 2009, Chemical and physical solutions for hydrogen storage, Angewandte Chemie Int. Ed., 48(36), 6608-30.
  • Fernandez-Moreno J., Guelbenzu G., Martı´n A.J., Folgado M.A., Ferreira-Aparicio P., Chaparro A.M., 2013, A portable system powered with hydrogen and one single air-breathing PEM fuel cell, Appl Energy, 109, 60-6.
  • Ingersoll J.C., Mani N., Thenmozhiyal J.C. and Muthaiah A., 2007, Catalytic hydrolysis of sodium borohydride by a novel nickel–cobalt–boride catalyst, J Power Sources, 173(1), 450-57.
  • Jeong S.U., Kim R.K., Cho E.A., Kim H.J., Nam S.W., OH I.H., Hong S.A. and Kim S.H., 2005, A study on hydrogen generation from NaBH4 solution using the high performance Co-B catalyst, J Power Sources, 144 (1), 129-134.
  • Kaufman C.M., 1981, Catalytic Generation of Hydrogen from the Hydrolysis of Sodium-Borohydride: Application in a Hydrogen/Oxygen Fuel Cell, Ph.D. Thesis, The Louisiana State University and Agricultural and Mechanical College, Baton Rouge, LA.
  • Kaya S., Gürü M. and Ar I., 2011, Synthesis of magnesium borohydride from its elements and its usage in hydrogen recycle, Energy Sources, Part A, 33 (23), 2157-70.
  • Nayar M.G., 1981, Hydrogen Energy: An inexhaustible abundant clean energy system, Proc. Indian Acad. Sci. Section C: Engineering Sciences, 4, 57-73.
  • Nunes H.X., Ferreira M.J.F., Rangel C.M. and Pinto A.M.F.R., 2016, Hydrogen generation and storage by aqueous sodium borohydride (NaBH4) hydrolysis for small portable fuel cells (H2 - PEMFC), Int. J Hydrogen Energy, 41, 15426-32.
  • Sahiner N. and Yaşar A.O., 2014, H2 generation from NaBH4 and NH3BH3 using metal catalysts prepared within p(VI) capsule particles, Fuel Processing Tech., 125, 148-154.
  • Sahiner N., Ozay O., Inger E. and Aktas N., 2011, Superabsorbent hydrogels for cobalt nanoparticle synthesis and hydrogen production from hydrolysis of sodium boron hydride, Applied Catalysis B: Environmental, 102, 201-6.
  • Sahiner N., Butun S. and Turhan T., 2012, p(AAGA) hydrogel reactor for in situ Co and Ni nanoparticle preparation and use in hydrogen generation from the hydrolysis of sodium borohydride, Chem. Engineering Sci., 82, 114–20.
  • Schlesinger H.I., Brown H.C., Finholt A.E., Gilbreath J.R., Hoekstra H.R. and Hyde E.K., 1953, Sodium borohydride, its hydrolysis and use as a reducing agent and in the generation of hydrogen, J. Am. Chem. Soc., 75, 215–19.
  • Schüth F., Bogdanovic´ B. and Felderhoff M., 2004, Light metal hydrides and complex hydrides for hydrogen storage, The Royal Society of Chemistry, 2249-58.
  • Seven F. and Sahiner N., 2013, Poly(acrylamide-co-vinyl sulfonic acid) p(AAm-co-VSA) hydrogel templates for Co and Ni metal nanoparticle preparation and their use in hydrogen production, Int. J Hydrogen Energy, 38, 777-784.
  • Seven F. and Sahiner N., 2014, NaOH modified P(acrylamide) hydrogel matrices for in situ metal nanoparticles preparation and their use in H2 generation from hydrolysis of NaBH4, J Applied Polymer Sci., 131 (22).
  • Xu D., Zhang H., and Ye W., 2007, Hydrogen generation from hydrolysis of alkaline sodium borohydride solution using Pt/C catalyst, Catal Commun., 8(11), 1767-71.
  • Zhao M., McCormack A. and Keswani M., 2016, The formation mechanism of gradient porous Si in a contactless electrochemical process, J. Mater. Chem. C, 4, 4204.
Isı Bilimi ve Tekniği Dergisi-Cover
  • ISSN: 1300-3615
  • Yayın Aralığı: Yılda 2 Sayı
  • Başlangıç: 1977
  • Yayıncı: TÜRK ISI BİLİMİ VE TEKNİĞİ DERNEĞİ
Arşiv
Sayıdaki Diğer Makaleler

ÜÇ KATMANLI GÖZENEKLİ YAKICIDA ÖN KARIŞIMSIZ YANMANIN FLAMELET MODELİ İLE SAYISAL İNCELENMESİ

Tanju ERGEN, Tamer ŞENER, Onur TUNCER, Cihat BAYTAŞ

$SU^2$ GERÇEK GAZ MODELLERİNİN SOĞUK GAZ İTİCİSİ PERFORMANS TAHMİNLERİ

Mehmet Halük AKSEL, Aysu ÖZDEN, Özgür Uğraş BARAN, Mehmet Ali AK

SERBEST DİSPLEYSIRLI BİR STİRLİNG MOTORUNUN NODAL TERMODİNAMİK VE DİNAMİK ANALİZİ

Can CINAR, Onur OZDEMIR, Halit KARABULUT, Mesut DUZGUN

SU2 GERÇEK GAZ MODELLERİNİN SOĞUK GAZ İTİCİSİ PERFORMANS TAHMİNLERİ

Aysu ÖZDEN, Özgür BARAN, Mehmet AKSEL, Mehmet AK

PASİF VE AKTİF KONTROL YÖNTEMLERİ OLARAK HEM BİR AYIRICI PLAKA HEMDE PLAZMA AKTÜATÖRLER KULLANILMASIYLA DAİRESEL BİR SİLİNDİR ETRAFINDA ETKİLİ AKIŞ KONTROLÜNÜN SAĞLANMASI

Hürrem AKBIYIK, Yahya AKANSU

KANATÇIKLI DİKDÖRTGEN KESİTLİ MİKROKANALDA NANOAKIŞKAN AKIŞININ SAYISAL İNCELENMESİ

Halime ÇELİK, Nezaket PARLAK

ELEKTRİKTE PİK TALEBİ TÖRPÜLEME İÇİN KULLANILACAK FDM-HAVA SOĞUK ENERJİ DEPOLAMA CİHAZI TASARIMI VE OPTİMİZASYONU

Göker TÜRKAKAR

HİDROJEL ESASLI $CoF_24 KATALİZÖR ile $NABH_4$’den HİDROJEN SALINIMI

Tuğba AKKAŞ BOYNUEĞRİ, Metin GÜRÜ

PİRİDİN VE İZOBÜTANOL KATKILI BENZİN-ETANOL-SU KARIŞIMLARININ TEK SİLİNDİRLİ BENZİN MOTORUNDAKİ PERFORMANS VE EMİSYONLARININ İNCELENMESİ

Amirkhan GARAYEV, Silver GÜNEŞ, Çiğdem GÜLDÜR

TUNҪBİLEK TERMİK SANTRALİNİN 150MWe ÜNİTESİNDE PÜLVERİZE KÖMÜRÜN BİYOKÜTLE İLE EŞ YANMASININ HESAPLAMALI ANALİZİ

Cansu DENIZ, Yakup BOKE, Ozer AYDIN, Ali BENİM