Effect of metal oxide additives on the properties of

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Effect of metal oxide additives on the properties of European Congress of Chemical Engineering (ECCE-6) Copenhagen, 16-20 September 2007 Effect of metal oxide additives on the properties of Cu/ZnO/Al 2 O 3 catalysts in methanol synthesis from syngas F.Meshkini, a M.Taghizadeh Mazandarani, a M.Bahmani b a Chemical Engineering Department, Faculty of Engineering, Mazandaran University, P.O.Box:484, Babol, Iran, E-mail: taghizadehfr@yahoo.com, Tel: +98111-3234204, Fax: +98111-3234201 b Catalyst Research Group, Petrochemical Research and Technology Co., National Petrochemical Co., P.O.Box: 14458, Tehran, Iran Abstract The Cu/ZnO/Al 2 O 3 catalysts, prepared by co-precipitation method, has been modified by adding small amount of Mn, Mg, Zr, Cr, Ba, W and Ce oxide using design of experiments ( 1 / 16 full factorial design). Performance of the prepared catalysts for CO/CO 2 hydrogenation to methanol was evaluated by using a stainless steel fixed-bed reactor at 5MPa and 513 K. The oxide additives were found to influence the catalytic activity, dispersion of Cu, Cu crystallite size, surface composition of catalyst and stability of catalysts during their operations. The results showed that the Mn, Zr and Ba promoted catalysts have high performance for methanol synthesis from syngas. Keywords: Methanol synthesis, Cu/ZnO/Al 2 O 3 catalysts, metal oxide additives 1. Introduction Methanol (MeOH) is an important feedstock for the production of many chemicals and potentially a cleaner alternative fuel for the future [1]. Furthermore, as methanol is expected to be used for fuel cell systems and power plants, it could be more important in energy field and hence considered a safe medium for the storage and transportation of hydrogen [2, 3]. Commercially, methanol is produced from syngas prepared from natural gas or coal, which mainly contains CO and H 2 along with a small amount of CO 2. Recently, methanol synthesis from CO 2 hydrogenation has received much attention because it has been considered to be one of the promising ways for CO 2 migration. Many researchers have studied methanol synthesis from CO 2 rich feed hydrogenation [4]. Methanol is currently produced from syngas using using copper zinc-based oxide catalysts at 5.0 10.0 MPa and 473 523 K. Cu/ZnO/Al 2 O 3 catalysts have long been used in industrial methanol synthesis because of their high catalytic activity, long life time, high poison durability and relatively low reaction temperature and pressure [5,

F.Meshkini et al. 6]. Nevertheless, finding a better catalyst for methanol synthesis is still a subject of intense investigations. In order to increase Cu/ZnO/Al 2 O 3 activity and stability, this basic catalyst was often modified by different oxide additives such as boron [2], silica [4, 7], Chromium [8], palladium [9], tungsten [10], manganese [5, 11] and Zirconium [12]. In this work, a small amount of different oxide (Mn, Mg, Zr, Ce, Ba, Cr and W) were added to Cu/ZnO/Al 2 O 3 catalyst to evaluate the catalytic activity and stability by using design of experiments ( 1 / 16 full factorial design) in a stainless steel fixed-bed reactor at 5MPa and 513 K. 2. Experimental 2.1. Design of experiments By means of experimental designing method, optimizing the different process variables is possible and number of required runs would be reduced. A full factorial experiment considers potential interactions between the factors, and the conclusions are highly reproducible. Therefore it is economical for characterizing a complicated process [13, 14]. In this study, this method is chosen to investigate the effect of each promoter on the properties of catalyst and interaction between them. The design includes 1 / 16 of total runs. Because of considering two levels for each variable (presence or absence of each promoter), 8 ( 1 / 16 2 7 ) runs would be required. A design of experiments which is chosen to determine the experimental plan by MINITAB release 14 is shown in Table 1. The catalysts are named in the form of A-M which A indicates the catalyst with no promoter (Cu/ZnO/Al 2 O 3 ) and M indicates the promoter which is added. Table1. Experimental layout using 1 / 16 full factorial Run Catalyst name Mg Mn Zr Ce Ba Cr W 1 A-Ce-Ba-Cr 2 A-Mn-Cr-W 3 A-Mg-Ba-W 4 A-Mn-Mg-Ce 5 A-Zr-Ce-W 6 A-Zr-Ba-Mn 7 A-Mg-Zr-Cr 8 A-Mn-Mg-Zr-Ba-Ce-W-Cr + means presence of each promoter and - means absence of each promoter 2.2. Preparation of catalysts The oxide precursors of Cu/ZnO/Al 2 O 3 /MO (M 2 O 3 or MO 2 ), where M is Mn, Mg, Zr, Ce, Ba, Cr and W, with a nominal composition of 65 mol% Cu, 25 mol% ZnO and 10 mol% Al 2 O 3 and 2 mol% of each promoter were prepared by the conventional coprecipitation method. An aqueous solution of metal nitrate (only tungsten was introduced as Ammonium tungstate) and an aqueous solution of Na 2 CO 3 were added 2

Effect of metal oxide additives on the properties of simultaneously to a vessel containing deionized water under vigorous stirring. The precipitation was carried out at 343 K and a constant ph 7. The precipitates were aged in mother liquid at 343 K for 5 hr under stirring. 2.3. Catalytic activity CO/CO 2 hydrogenation tests were carried out using a stainless steel tubular, down flow, high pressure, fixed bed reactor (interior ID: 10 mm), which contained 1.1 gr (1 Cm 3 ) catalysts placed between two layers of SiC. All catalysts were reduced in diluted H 2 (3% in N 2 ) flow at 513 K and atmospheric pressure for 15 h before syngas exposure. The catalytic activity in the methanol synthesis was determined at 5 MPa pressure and 513 K with a mixture of CO/CO 2 /H 2 = 1/1/14.5 and GHSV=12 hr. The outlet gases (products and unconverted feed) were cooled up to 255K and the water and methanol in liquids were analyzed by Varian Star GC (CP-3800). H 2, CO, CO 2 and small amount of CH 4 were determined by RGA (Agilent 6890N) chromatographs. 3. Results and discussion The results of catalytic activity tests on catalysts with different promoters are given in Table 2. In this table, initial activity and the activity after 64 hrs, average carbon conversion (mol %) and methanol selectivity are shown. Table 2: The activity and selectivity of the catalysts for methanol synthesis MeOH Space time yield Carbon conversion Catalyst name (gr CH3OH/Kg Cat.hr) (mol%) Initial activity Activity after 64 hr MeOH selectivity A-Zr-Ba-Mn 684.06 642.04 28.77 99.49 A-Mn-Cr-W 608.33 505.43 24.78 99.62 A-Mg-Zr-Cr 599.38 567.29 24.85 99.49 A-Mg-Ba-W 574.69 481.89 23.18 99.08 A-Mn-Mg-Ce 488.14 507.00 21.68 98.32 A-Ce-Ba-Cr 440.63.24 18.41 99.17 A-Zr-Ce-W 423.06 440.63 18.77 98.54 A-Mn-Mg-Zr-Ba-Ce-W-Cr 376.68 395.44 16.69 98.97 According to the results obtained from the design of experiments with regarding each response individually, four catalysts (catalyst without any promoter, with Mn, with Zr and with Mn-Zr) were prepared and tested again at the same conditions. MeOH space time yield of these catalysts are illustrated in Figures 1-4. A small amount of Mn added to the CuO/ZnO/Al 2 O 3 increased the catalyst activity but had no effect on the catalyst stability. The activity of the catalyst with Zr as a promoter became higher after 50 hrs than that of the catalyst without promoter. By using Mn and Zr as promoters together, the catalyst became stable and its activity after nearly 30 hrs was more than that of the catalyst without any promoter (Figure 4). 3

F.Meshkini et al. MeoH space tim e yield (g MeoH/Kgcat.hr) 0 20 40 60 80 MeOH space tim e yield (grmeoh/kgcat.hr) 0 20 40 60 80 100 120 Figure 1: MeOH space time yield for catalyst A (without any promoter). Figure 2: MeOH space time yield for catalyst A-Mn (containing Mn as a promoter). MeOH space tim e yield (grmeoh/kgcat.hr) 0 10 20 30 40 50 60 70 MeOH space tim e yield (grmeoh/kgcat.hr) 0 20 40 60 80 100 Figure 3: MeOH space time yield for catalyst A-Zr (containing Zr as a promoter). Figure 4: MeOH space time yield for catalyst A-Zr-Mn (containing Zr and Mn as promoters). Figure 5 shows the variations of the methanol yield with time on stream for the catalyst without any promoter (A) and the catalyst having the high activity and stability (A-Mn-Zr). 4

Effect of metal oxide additives on the properties of MeOH Space time yield (grmeoh/kg Cat.hr) 0 20 40 60 80 100 A-Mn-Zr A Figure 1: MeOH space time yield for catalyst A and catalyst A-Mn-Zr. 4. Conclusions Design of experiments, a good way for reducing the number of runs, applied in the field of catalyst preparation. The full factorial design using individual response evaluation was a useful tool to explore the influence of the additives on the catalyst activity and stability. If Zr and Mn were used as promoters together, Cu/ZnO/Al 2 O 3 catalyst became more stable and its activity after nearly 30 hrs was more than that of the catalyst without any promoter. It seems that Zr could be a good support for Cu/ZnO catalyst because it makes the catalyst more stable and also increase its activity. Acknowledgment This work was supported by Petrochemical Research and Technology Company of Iran. References [1] S. Fujita, S. Moribe, Y. Kanamori, M. Kakudate, N. Takezawa, (2001) Applied Catalysis A: General, 207, 121. [2] Jingang Wu, Masahiro Satio, Hirotaka Mabuse, (2000) Catalysis Letters, 68, 55-58. [3] Toyir, J., P. R. Piscina, J. L. G. Fierro, N, Homs, (2001) Applied Catalysis B: Environmental, 29, 207-215. 5

F.Meshkini et al. [4] J.Wu, M.Satito, M.Takeuchi, T.Watanabe, (2001) Applied Catalysis A: General, 218, 235. [5] Chen, H.Y., J. Lin, K.L. Tan, J. Li, (1998) Applied Surface Science, 126, 323-331. [6] D. Fang, Z. Liu, S. Meng, L. Wang, L. Xu, H. Wang, (2005) Jornal of natural gas chemistry, 14, 107. [7] Masami Takeuchi, Hirotaka Mabuse,Taiki Watanabe, Michiaki Umeno, Takashi Matsuda, Kozo Mori, Kenji Ushikoshi, Jamil Toyir, Shengcheng Luo, Jingang Wu, (2000) US 6 048 820. [8] X. Huang, L. Ma, M.S. Wainwright, (2004) Applied Catalysis A: General, 257, 235. [9] Cabrera, I. M., M.L. Granados, J.L. Fierro, (2002) Journal of Catalysis, 210, 285-294. [10] J. W. Tierney, I. Wender, V. M. Palekar, (1995), US 5 385 949. [11] J. Słocyński, R. Grabowski, P. Olszewski, A. Kozłowska, J. Stoch, M. Lachowska, J. Skrzpek, (2006) Applied Catalysis A: Gneral, 310, 12737. [12]. Y. W. Suh, S. H. Moon, H. K. Rhee, (2000) Catalysis Today, 63, 447. [13] H. Takatsuji, T. Arai, S. Tsuji, K. Kuroda, H. Saka, (1999) Thin Solid Films, 337, 235. [14] W.H. Yang, Y.S. Tarng, (1998) J. Mater. Process Technol., 84, 122. 6

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