Microsoft Word - 211.docx CHEMICAL ENGINEERING TRANSACTIONS VOL. 61, 2017 A publication of The Italian Association of Chemical Engineering Online at www.aidic.it/cet Guest Editors: Petar S Varbanov, Rongxin Su, Hon Loong Lam, Xia Liu, Jiří J Klemeš Copyright © 2017, AIDIC Servizi S.r.l. ISBN 978-88-95608-51-8; ISSN 2283-9216 Deep Oxidation of Hydrocarbons on Polyoxide Nickel- Containing Catalysts Zauresh T. Zheksenbaeva, Svetlana A. Tungatarova*, Tolkyn S. Baizhumanova, Rabiga O. Sarsenova D.V. Sokolsky Institute of Fuel, Catalysis and Electrochemistry, 142 Kunaev str., 050010, Almaty, Kazakhstan tungatarova58@mail.ru The data on investigation of polyoxide Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalysts on carriers with specified properties for deep oxidation of hydrocarbon - toluene, which has a strong toxic effect on living organism and flora, are given. The influence of technological parameters (temperature, space velocity, concentration of toluene in a mixture with air) on the completeness of the conversion of toluene (to CO2 and H2O) on an effective polyoxide catalyst has been studied. It was shown that the synthesized polyoxide Ni-Cu-Cr catalyst supported on 2 % Ce/θ-Al2O3 provides 98.8 % conversion of toluene to CO2 in the oxidation reaction of toluene at a space velocity of 5×103 h-1, 723 - 773 K and the content of toluene 100 - 570 mg/m3 in mixture with air. 1. Introduction The problem of chemical safety and sanitary protection of air basin acquires particular relevance in connection with the increase in harmful emissions of industrial enterprises that have a strong toxic effect. Cleaning of air polluted by exhaust gases of industrial enterprises and motor vehicles is the most actual direction of environmental protection. Harmful emissions of industrial enterprises (paint and varnish, furniture, cable, pharmaceutical, printing) and motor vehicles are the main polluters of cities. Many chemical compounds (toluene, xylene, styrene, phenol, tricresol, white spirit, etc.), which adversely affect the living organisms, are harmful toxic emissions of industrial enterprises (Zheksenbaeva et al., 2015). Large amounts of harmful industrial emissions occur mainly in large cities, where their maximum permissible concentration (MPC) is much higher than normal. The content of harmful emissions above the MPC in industrial plants and in the atmosphere of air basin of cities cause negative impact on the living organism and lead to various diseases, thereby creating a threat to chemical safety of the environment (Brattoli et al., 2014). Thermocatalytic purification of waste gases is becoming increasingly widespread among methods of cleaning harmful emissions of industrial enterprises (Popova et al., 2006). Catalysts based on platinum metals have high activity at low temperatures, durability, heat resistance and the ability to work stably at high space velocities. In the conditions of deficit and high cost of platinum group metals, the purpose of this work is to develop new approaches to the development of highly effective thermostable and poisonous polyoxide catalysts that do not contain noble metals that are stable for long periods of operation. At present, the creation of gas cleaning catalysts that do not contain noble metals or contain them in small quantities is an important task. One promising way to solve this problem is the use of palladium catalysts with a low metal content, or catalysts based on mixed oxides. Toluene was chosen as a model neutralization substance, as the main component of emissions from furniture, cable, shoe and other industries. 2. Experimental 2.1 Catalysts preparation Polyoxide catalysts were prepared by the capillary impregnation of cerium-modified alumina with mixed aqueous solutions of nitrate salts of metals by the moisture capacity of the carrier, followed by drying at 453 - 473 K (4 - 5 h) and calcination at 873 K (1 - 1.5 h) in air. Ball -Al2O3 (manufactured at the Institute of Catalysis of the SB DOI: 10.3303/CET1761309 Please cite this article as: Zheksenbaeva Z.T., Tungatarova S.A., Baizhumanova T.S., Sarsenova R.O., 2017, Deep oxidation of hydrocarbons on polyoxide nickel-containing catalysts, Chemical Engineering Transactions, 61, 1867-1872 DOI:10.3303/CET1761309 1867 RAS, Novosibirsk) with a diameter of 3 - 4×10-3 m, specific surface of 100 m2/g, bulk density of 0.80 g/cm3, mechanical strength of 150 MPa and pore volume of 0.48 cm3/g was used as a carrier for polyoxide catalysts (Tungatarova et al., 2014). To stabilize the structure and thermal stability, θ-Al2O3 was modified with cerium oxide, which forms a surface perovskite of the CeAlO3 type with aluminum oxide, stable up to 1,373 K. 2.2 Experimental Deep oxidation of toluene was carried out on the PKU-2VD catalytic installation intended for testing of catalysts at pressures up to 3.4 MPa. Analysis of the initial mixture and reaction products were carried out using CHROMOS GC-1000 chromatograph with CHROMOS software. The temperature of thermal conductivity detector – 473 K, evaporator temperature – 553 K, column temperature - 313 K. The rate of carrier gas Ar - 10 mL/min. Catalytic activity of catalysts was determined in flow installation at deep oxidation of toluene in air at various temperatures (523 – 773 K), space velocities (5 - 15×103 h-1) and toluene concentration (320 mg/m3) in the initial mixture. The chromatographic peaks were calculated from the calibration curves plotted for the respective products using the "Chromos" software for pure substances (accurately measured quantities of a pure component or mixture of substances with known concentrations were injected into the chromatograph using a microsyringe). Based on the measured areas of peaks corresponding to the amount of the introduced substance, a calibration curve V = f (S) was constructed, where V - the amount of substance in ml, S - the area of peak expressed in cm2. Concentrations of the obtained products were determined on the basis of the obtained calibration curves. The phase composition of catalysts was determined by X-ray diffractometer DRON-4.7, Co anode, 25 kV, 25 mA, 2θ – 5 - 80o (XRD). The BET specific surface area was determined by adsorption method using an Accusorb instrument (Micromeritics, United States) at the low temperature adsorption of N2. The morphology, particle size, chemical composition of the Ni-Cu-Cr catalysts were investigated by transmission electron microscope EM-125K at 80,000 magnification by the replica method with extraction using a microdiffraction. 3. Results and discussion 3.1 Study of the effect of temperature on the activity of catalysts in the oxidation of toluene The effect of temperature on the deep oxidation of toluene to CO2 and H2O on synthesized bimetallic and tricomponent Ni catalysts was investigated, Table 1. The activity of catalysts was studied at space velocity of 5,000 h-1 in the temperature range 523 - 773 K. It was determined that as the temperature rises from 523 to 773 K, the degree of toluene conversion increases on all catalyst compositions. It should be noted that the degree of toluene conversion stabilizes at a temperature of 723 K on all catalyst compositions. Table 1: Effect of temperature on the deep oxidation of toluene to CO2 and H2O on synthesized Ni-Cu-Cr- containing catalysts at GHSV = 5×103 h-1; Сtoluene - 320 mg/m3 T, K Degree of conversion of toluene, % Ni-Cu/2 % Ce/θ-Al2O3 Ni-Cr/2 % Ce/θ-Al2O3 Cu-Cr/2 % Ce/θ-Al2O3 Ni-Cu-Cr/2 % Ce/θ-Al2O3 523 70.1 60.0 55.0 74.3 573 75.2 67.2 58.2 90.2 623 78.4 68.5 62.5 94.1 673 83.2 73.1 65.2 96.5 723 84.1 75.2 67.5 98.8 773 84.1 75.2 67.5 98.8 A further increase in temperature did not affect the conversion of toluene. Table 1 shows that the degree of conversion of toluene is lower on bimetallic composites for all the results of study compared to the three- component composition, when the temperature increases from 673 to 723 K. From these results, it follows that the maximum conversion of toluene occurs at Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst at 723 K (Zheksenbaeva et al., 2012). The reaction of deep oxidation of model toluene on Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst modified with small additions (0.05 %) of noble metals (Pd and Pt) was studied. Table 2 shows the dependence of the degree of conversion of toluene on the catalysts as a function of the reaction temperature from 523 to 773 K at GHSV = 5,000 h-1 and Ctoluene = 320 mg/m3. It was found that the degree of toluene conversion increases and reaches maximum of 99 % at 723 K on polyoxide Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst promoted by Pd as the temperature rises. A further increase in the reaction temperature to 773 K does not lead to a change in the activity of catalyst. 1868 Table 2: Change in the degree of oxidation of toluene from the temperature and composition of catalysts at GHSV = 5,000 h-1 and Ctoluene = 320 mg/m3 T, K Degree of conversion of toluene, % Ni-Cu-Cr/2 % Ce/θ-Al2O3 Ni-Cu-Cr+Pd/2 % Се/θ-Al2O3 Ni-Cu-Cr+Pt/2 % Се/θ-Al2O3 523 74.3 81.0 83.2 573 90.2 92.5 95.3 623 94.1 97.0 98.4 673 96.5 98.2 99.0 723 98.8 99.0 100.0 773 98.8 99.0 100.0 Similar dependence of the activity on temperature was observed on the catalyst promoted by Pt. As can be seen from the table data, the conversion of toluene on the Pt-containing catalyst is higher than that of the polyoxide and Pd-containing catalysts and reaches 100 %. Thus, the promotion by small additives (0.05 %) of Pd and Pt increases the activity of the synthesized three- component Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst in the deep oxidation of toluene. It was found from the analysis of the obtained data, that the conversion of toluene on Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst promoted by Pt reaches 100 % to the desired product at a temperature of 723 K. 3.2 Investigation of the effect of space velocity of the process on the efficiency of catalytic oxidation The effect of varying the process space velocity on the degree of deep toluene conversion on the developed three-component Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst was investigated. Experiments on deep oxidation were carried out in the temperature range 573 - 773 K and the concentration of toluene in the initial mixture with air equal to 320 mg/m3. From the data in Table 3 it can be seen that the degree of toluene conversion increases regardless of the change in space velocity with increase in the reaction temperature from 523 to 773 K. It was found that the highest conversion of toluene up to 98.8 % is achieved at the temperatures of 723 - 773 K and space velocity of 5,000 h-1 as the space velocity increases from 5,000 to 15,000 h-1. The toluene conversion decreases to 93.5 and 89.3 % at higher space velocities to 10,000 and 15,000 h-1 at temperature of 723 - 773 K, respectively. Table 3: Study of the change in the degree of conversion of toluene in the deep oxidation of toluene on Ni-Cu- Cr/2 % Ce/θ-Al2O3 catalyst while varying temperature and space velocity T, K Space velocity, h-1 5,000 10,000 15,000 α, % α, % α, % 523 73.7 81.0 82.1 573 89.5 85.7 83.8 623 94.7 90.5 85.7 673 97.5 91.5 89.3 723 98.5 93.5 89.3 773 98.5 95.2 89.3 Note - The concentration of toluene in the initial air mixture is 320 mg/m3 3.3 Determination of the influence of toluene concentration in gas-air mixture on the activity of catalysts Influence of concentration of toluene in the initial mixture to the efficiency of its conversion on the polyoxide catalysts of various compositions were studied. Table 4 shows that increasing the concentration of toluene from 100 to 320 mg/m3 in the initial mixture with air leads to a slight decrease in the degree of conversion of toluene on the two component Ni-Cu/2 % Ce/θ-Al2O3 and Cu-Cr/2 % Ce/θ-Al2O3 catalysts. A noticeable decrease in activity among two component oxide catalysts were found on the Ni-Cr-containing catalyst from 76.6 to 73.0 %. Ni-Cu-Cr/2 % Cr/θ-Al2O3 catalyst was the most stable. Thus, the optimal conditions of deep oxidation of toluene on oxide Ni-, Cu- and Cr-containing catalysts over 2 % Ce/θ-Al2O3 were determined. Degree of conversion of toluene reaches 98.5 – 98.8 % on the Ni-Cu-Cr/2 % Ce/θ- Al2O3 catalyst at temperatures of 723 – 773 K, GHSV - 5×103 h-1 and the concentration of toluene in the initial mixture with air – 100 - 320 mg/m3. 1869 Table 4: Effect the content of toluene in the initial mixture with air on degree of its conversion on the various catalysts Catalysts Concentration of toluene, mg/m3 100 320 Degree of conversion of toluene,% 5 % Cu-Cr/2 % Ce/θ-Al2O3 73.7 81.0 5 % Ni-Cr/2 % Ce/θ-Al2O3 89.5 85.7 5 % Cu/2 % Се/θ-Al2O3 94.7 90.5 9 % Ni-Cu-Cr/2 % Ce/θ-Al2O3 97.5 91.5 Note – T – 723 K; GHSV - 5×103 h-1 From the obtained experimental data, it follows that the synthesized three-component catalyst exhibits a high activity in the deep oxidation of toluene. 3.4 The study of multicomponent oxide catalysts based on NiCuCr over 2 % Ce/θ-Al2O3 by electron microscopy The morphology and particle size of the developed catalysts were investigated using a transmission electron microscope EM-125K with an increase of 80,000 times by replicas with extraction using microdiffraction of electrons, Figure 1. It was found that single, double and triple metal oxides, whose particle size decreases from 50 - 80 Å (Ce/Al2O3) to 20 - 30 Å (Ni-Cu-Cr), are formed in the process of complicating the composition of copper three-component catalyst. Figure 1: Electron microscopic photographs of the supported copper three-component catalyst: (a) Ni-Cu-Cr (873 K), (b) Ni-Cu-Cr + Pd (873 K), (c) Ni-Cu-Cr + Pd (1,473 K) According to electron microscopy and microdiffraction of electrons follows that the catalysts contain mainly nanoparticles of oxides (20 - 100 Å) and their mixtures, as well as larger, dense particles of aluminates of the type АВ2О4, АВО3 of 200 - 300 Å size (Table 5) after heating at 873 K. Also two types of particles: small oxides (60 – 150 Å) and larger aluminates are formed at introduction of Pt and Pd into Ni-Cu-Cr catalyst. Particles with a size greater than 1,000 Å are found in the case of promotion by Pd, especially when heated to 1,473 K. Most of the particles in the promotion by Pt are finely dispersed, which become larger after heating at 1,473 K to 200 – 500 Å due to the formation of aluminates and chromates. The relative content of large particles of metal aluminates in the Ni-Cu-Cr catalyst increases with the promotion by Pt and Pd and high-temperature heating. According to electron microscopy and microdiffraction data, nanoparticles of metal oxides or their mixtures are formed in the initial oxide Ni-Cu-Cr catalyst after the decomposition of metal nitrates at 873 K. The process of interaction of elements with the -Al2O3 carrier with the formation of larger aluminates of copper and nickel of the type АВ2О4, АВО3 also occurs with an increase in temperature, despite its protection by cerium (CeAlO3) (Komashko et al., 2002). 1870 Table 5: Electron microscopy data of polyoxide Ni-Cu-Cr catalysts on 2 % Ce/θ-Al2O3 Catalysts T heating, K Particle size, Ǻ Diffraction data Ni1-Cu3-Cr0,1 873 20-30 NiCr2O4, CuCrO4, CuAl2O4, CuAlO4, NiAl2O4, 20-100 CrO2, Cr2O3, CuAlO2, AlCu, NiCrO4, Cr2O3 1,473 200 CuAl2O4, NiAl2O4, CeAlO3 Ni1-Cu3-Cr0,1 + Pd 873 100, oxides of Cu, Ni, Cr, CeO2 200-500 aluminates of Cu, Ni, CuCr2O4, Pd, PdO, Ce2O3, (flaky particles) CrO2, NiCrO3, CuAl2O4, CuCr2O4, 1473 1,000 NiCrO3, CeAlO3, oxides of Cu, Ni, Cr, NiAl26O42Cu2O, Ni2O Ni1-Cu3-Cr0,1 + Pt 873 60-150 oxides of Cu, Ni, Cr, Pt Cu2O, Ni2O, PtO, NiAl2O3 1,473 200-500 CuAl2O4, CrO4, Cr2O3, Ni2O3 (dispersing and enlarging) Cu2O, Pt, NiCrO4, Ni2O 3.5 Study of polyoxide catalysts based on Ni, Cu and Cr oxides on 2 % Ce/θ-Al2O3 by XRD method The developed Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst was investigated by X-ray diffraction analysis (XRD). The phase composition of the catalysts was determined on a DRON-4-7 X-ray diffractometer, Co-anode, 25 kV, 25 mA, 2θ - 5-80°C. Table 6 shows the results of determining the phase composition of the initial 2 % Ce/θ-Al2O3 and Ni-Cu-Cr on 2 % Ce/θ-Al2O3 catalysts after preparation (T heating = 873 K, 1 h) and prolonged heating (5 h) in air with an increase in temperature from 873 K to 1,473 K. Table 6: X-ray phase analysis of polyoxide Ni1-Cu3-Cr0.1 catalysts supported on 2 % Ce/-Al2O3 Catalyst Promoter, % T heating, K СеО2, 1,91 Ǻ -Al2O3, 1,74 Ǻ -Al2O3, 2,31 Ǻ NiAl2O4, CuAl2O4, 1,43 Ǻ Less intensive phases Ni-Cu-Cr 873 13 37 10 CuO (2,51; 2,31; 1,85), NiO (2,08; 2,42; 1,48) 1,273 58 158 5 90 1,473 30 120 3 105 0,3 Pt 873 10 9 22 CuO, Al2O3 (2,12), NiO (2,42) 0,1 Pt 873 14 20 CuO, Al2O3 (2,12), Ce6O11, Cr5O12 (3,57) 0,1 Pt 1,073 26 20 10 10 CuO, NiO, Ce6O11, Al2O3 0,3 Pt 1,473 52 166 5 70 Ni-Cu-Cr 0,05 Pd 873 20 13 7 7 CuO, Ce6O11, Al2O3 (2,12) 0,05 Pd 1,273 45 148 2 55 Pd (2,25) 0,05 Pd 1,473 60 177 5 105 NiAl10O16 (1,99) Reflexes from -Al2O3, -Al2O3, and CeO2 (quantitative evaluation was carried out on reflections of 2.31 Å, 1.74 Å, 1.91 Å) are present both in 2 % Ce/-Al2O3 and in the carrier. The intensity of the CeO2 reflexes increases slightly as the Ce content in the catalyst increases and, especially after heating, successively at 873, 1,073, 1,273, 1,373, and 1,473 K. This indicates that the crystallization of amorphous CeO2 occurs as a result of heating. The same process is typical for supported on 2 % Ce/-Al2O3 catalysts, but to different degrees. Intensive reflexes from CuO and less intense from NiO, in addition to the phases of CeO2 and -Al2O3, are observed in the X-ray diffraction patterns of Ni-Cu-Cr/2 % Ce/-Al2O3 catalyst heated at 873 K. Not only the crystallization of CeO2, but also a sharp increase in the -Al2O3 content, starting from 1,273 K, occurs as the catalyst warms up. This indicates that the process of interaction of CuO, and also NiO with -Al2O3, followed by the destruction of spinel to -Al2O3 and oxides occurs. A significant decrease in the total surface area of catalysts is due to this process during heating. Promotion of the Ni-Cu-Cr catalyst by Pt and Pd also contributes to phase transformations in the catalyst during heating. Weak reflexes from NiO, Ce6O11, and also NiAl10O16 are present in the X-ray diffraction pattern, in addition to crystalline CeO2, -Al2O3, CuO, and Ni(Cu)Al2O4. (Grigor’eva et al., 2002). 1871 The use of X-ray phase analysis to study of polyoxide catalysts supported on 2 % Ce/-Al2O3 showed that the active components in the initial catalysts are mainly in the X-ray amorphous state. Part of Ni and Cu in the Ni- Cu-Cr catalyst is represented by Ni and Cu oxides, especially at the promotion by platinum. Ni-Cu-Cr catalyst heated up to 1,473 K undergoes significant changes in the phase composition: Cu oxide interacts with the carrier to form CuAl2O4, and due to the decomposition of the latter, the amount of -Al2O3 increases. 4. Conclusions As a result of the obtained data, it was found that among the synthesized Ni-, Cu-, Cr-containing catalysts supported on alumina modified with the addition of Ce, the highest degree of toluene conversion (up to 98.8 %) is observed on a three-component Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst at space velocity of 5,000 h-1 and a temperature of 723 - 773 K. It was determined that the promotion by small amount (0.05 %) of Pd and Pt of the synthesized polyoxide three-component Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst increases the conversion of toluene in deep oxidation to CO2 and H2O to 100 %. By X-ray diffraction and electron microscopy was determined the presence of CeO2 crystals and X-ray amorphous clusters (d = 20 – 100 Å) of metal oxides of variable valence NiO and CuO, and also solid metal solutions CuO(NiO) on a surface of Ni-Cu-Cr/2 % Ce/θ-Al2O3 catalyst calcined at 873 K. When the Ni-Cu-Cr catalyst is heated above 1,273 K in air, phase transformations take place: metal oxides interact with alumina to form aluminates of the MeAl2O4 type with d = 200 – 1,000 Å with simultaneous decrease in the specific surface area. Acknowledgments The work was supported by the Ministry of Education and Science of the Republic of Kazakhstan (Grant No 0246/GF4). References Brattoli M., Cisternino E., Gennaro G., Giungato P., Mazzone A., Palmisani J., Tutino M., 2014, Gas Chromatography Analysis with Olfactometric Detection (gc-o): an Innovative Approach for Chemical Characterizatio of Odor Active Volatile Organic Compounds (vocs) Emitted from a Consumer Product, Chemical Engineering Transactions, 40, 121-126. 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