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Abstrak :
This research has the effort to develop catalyst for steam reforming of bio oil. The bio oil is liquid product that iv produced _from biomass pyrolysis. The reforming of bio oil produces hydrogen gas. The main challenge in reforming of organic compound especially aromatic, in bio oil as phenol, is carbon formation at the catalyst surface resulted in uncomplete reaction. The catalyst formulation resulted is expected to have high resistance to catalyst deactivation because of carbon formation. Beside that, it is expected too to have high stability and activity, compared to commercial nickel based catalyst. For those purposes, research of steam reforming of m-cresol in bench scale has been done. m-cresol is one of phenol compounds in bio oil, that has stable properties, difficult to react and disturb the catalyst activity. The catalyst formulation used is Ru-Ni/MgO.La;O3.Al2O3 mixture. This research has succeed to develop catalyst of reforming from Ni-Ru metal combination that having the good stability and activity to reform m-cresol. The best catalyst composition resulted is 2%Ru-15%Ni. In Ni and Ru catalyst combination, Ni catalyst is the mainly active component in reforming of oxygenated aromatic compound in bio oil The Ru catalyst function is to increase Ni metal dispersion on support, by then increasing the catalyst stability.

Abstrak :
Penelitian ini bertujuan untuk memproduksi hidrogen melalui proses steam reforming bio-oil dari tandan kosong kelapa sawit dengan katalis Ni-Ce/La2O3-γAl2O3. Penelitian ini menggunakan variasi rasio cerium terhadap nikel (Ce/Ni) pada katalis, yaitu sebesar 0,25; 0,5; 0,75; dan 1,00. Steam reforming dilakukan dengan fixed bed reactor pada suhu 700oC dengan tekanan atmosferik. Bio-oil yang digunakan merupakan bio-oil aqueous fraction dengan rumus empirik CH1,47O0,27. Senyawa yang paling banyak dikandung dalam bio-oil yang digunakan adalah asam asetat dan fenol. Hasil penelitian menunjukkan bahwa katalis Ni-0,25Ce mampu menghasilkan yield hidrogen tertinggi dan karbon terdeposisi terendah. Yield hidrogen tertinggi yang dicapai katalis Ni-0,25Ce adalah 18,53% pada menit ke-10 sedangkan karbon terdeposisi yang dicapai katalis Ni-0,25Ce adalah sebesar 0,0959 gram. Semakin banyak loading cerium dari suatu katalis akan mengurangi yield hidrogen karena luas permukaan inti aktif semakin berkurang karena dispersi nikel yang rendah. ...... This research has a purpose to produce hydrogen by steam reforming of bio-oil from empty fruit bunch with Ni-Ce/La2O3- γAl2O3 catalyst. Variation used in this research is cerium to nickel ratio (Ce/Ni) = 0,25; 0,5; 0,75; dan 1,00. Steam reforming is operated in a fixed bed reactor with 700oC temperature and atmospheric condition. Bio-oil used is bio-oil aqueous fraction with CH1,47O0,27 as its empirical formula. Major components contained inside bio-oil aqueous fraction are acetic acid and phenol. The results of this research shows that Ni-0,25Ce catalyst can produce hidghest hydrogen yield until 18.53% in minute 10. Moreover, deposited carbon resulted by Ni-0,25Ce is 0.0959 gram. The more cerium contained in a catalyst can lead to the decreasing of hydrogen production due to the decreasing of specific surface area because of low disperse of nickel.

Abstrak :
ABSTRAK
Produksi biohidrogen melalui reformasi kukus bio-oil berperan penting dalam perkembangan energi terbarukan yang berasal dari biomassa dalam memproduksi bahan bakar yang bersih. Walaupun demikian, kehadiran coke dan rendahnya konversi karbon merupakan permasalahan yang sering terjadi. Sehingga, penelitian ini bertujuan untuk mengurangi pembentukan deposit karbon dan meningkatkan konversi karbon dengan menggunakan core shell. Core shell akan meningkatkan luas permukaan, interaksi terhadap support katalis dan aktivitas katalitiknya. Core shell Ni/CaO-?-Al2O3@Ru disintesis dengan metode mikroemulsi dalam sistem larutan CTAB/n-heksanol/sikloheksana/aquades. Katalis dikarakterisasi dengan menggunakan XRD, BET, FESEM-EDS dan TEM. Fraksi aqueous bio-oil dianalisis menggunakan GC-MS. Hasil penelitian ini menunjukan bahwa yield hidrogen tertinggi dihasilkan dengan menggunakan core shell Ni/CaO-?-Al2O3@Ru adalah sebesar 16,34 pada menit ke-10. Jumlah deposit karbon terendah diperoleh dengan menggunakan core shell Ni/CaO-?-Al2O3@Ru yaitu 1,234 g. Konversi karbon dengan menggunakan core shell Ni/CaO-?-Al2O3@Ru meningkat 11,27 dibandingkan menggunakan Ni/CaO-?-Al2O3. Produksi yield hidrogen dengan menggunakan core shell Ni/CaO-?-Al2O3@Ru meningkat sebesar 4,56 dibandingkan dengan menggunakan Ni/CaO-?-Al2O3. Sehingga, core shell Ni/CaO-?-Al2O3@Ru lebih baik digunakan untuk produksi hidrogen dan mengurangi deposit karbon melalui reformasi kukus bio-oil dibandingkan dengan katalis Ni/CaO-?-Al2O3.

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ABSTRACT
Biohydrogen production through bio oil steam reforming plays an important role in the development of renewable hydrogen from biomass to produce the cleanest fuel. However, the existence of coke and low carbon conversion are problems that have been found in some studies. The purposes of this study were to reduce coke formation and to enhance carbon conversion by using core shell. Core shell can improve surface area, support interaction and its catalytic activity. Ni CaO Al2O3 Ru core shell catalysts were prepared by CTAB n hexanol cyclohexane water micro emulsion system. The catalysts were characterized by means XRD, BET, FESEM EDS and TEM. Bio oil aqueous fraction was analyzed by using GC MS. Based on experiment, the highest hydrogen yield was produced by using Ni CaO Al2O3 Ru core shell was 16.34 in minute 10. The lowest coke deposit production by using Ni CaO Al2O3 Ru core shell was 0.1234 g. Gas product carbon conversion by using core shell Ni CaO Al2O3 Ru enhanced more 11.27 than using Ni CaO Al2O3. Hydrogen yield production by using Ni CaO Al2O3 Ru core shell enhanced more 4.56 than using Ni CaO Al2O3 catalyst. The result showed that the effect of Ni CaO Al2O3 Ru core shell was more efficient for hydrogen production and to decrease coke deposit through steam reforming bio oil compared to Ni CaO Al2O3 catalyst.