Microsoft Word - 12-822-ed.doc Engineering, Technology & Applied Science Research Vol. 6, No. 6, 2016, 1269-1273 1269 www.etasr.com El-Sinawi: Production of Hydrogen from Poly Ethylene Terephthalate (PET) using CT 434 ZSM-5... Production of Hydrogen from Poly Ethylene Terephthalate (PET) using CT 434 ZSM-5 Catalyst at Considerably Low Temperatures Abdulaziz H. El-Sinawi College of Engineering King Faisal University Saudi Arabia aelsinawi@kfu.edu.sa Abstract—The production of hydrogen from Poly Ethylene Terephthalate (PET) using CT 434 ZSM-5 is investigated in this research study. Gas chromatography equipped with a thermal conductivity detector is used to detect the amount of hydrogen produced at different temperatures. The Chromatograph spectrum of pure hydrogen as well as the spectra of evolved gases at 250oC, 280oC, 310oC and 340oC are obtained to validate the presence of hydrogen. The spectra of percentage of hydrogen and peak area to height ratio with increasing temperature shows a similar trend except at the temperature of 340oC. Maximum hydrogen percentage of 20.11% is found in the evolved gases collected at temperature of 250oC. The retention time of sample collected at 340oC is very close to reference retention time 2.014 min observed for a pure hydrogen sample. Keywords-hydrogen; Poly Ethylene Terephthalate (PET); Gas Chromatograph (GC); Thermal Conductivity Detector (TCD) I. INTRODUCTION The production of hydrogen has recently attracted the attention of scientists and researchers due to the increase in energy consumption to commensurate the rapidly growing technology and the dramatically increase in population. Among different energy sources, the most popular and widely used energy source is fossil fuels. Considering the over consumption, the decrease in the available stock and the high emissions of carbon dioxide, hydrogen may be an ideal candidate to be used as a greener energy. The production, storage and transport of hydrogen in an economical and safer way are major challenges for hydrogen to replace other sources of energy. Today’s generation of hydrogen from hydrocarbon based compounds and derivatives are very popular [1-6]. Hydrogen can also be produced by a steam reforming process. Presently, a famous industrial process for the production of hydrogen is steam reforming of natural gas using methanol and ethanol as raw materials [7-9]. Gases may be produced from the solid wastes first and then a steam-reforming process can be employed for hydrogen production [10]. Recently a process to produce hydrogen from polyethylene (PE) milled with nickel hydroxide and calcium hydroxide was reported [11]. Nickel hydroxide was dispersed completely among the samples converted to nickel metal during the heating process that act as catalyst to enable the conversion. Calcium hydroxide fixed the carbon dioxide and allowed the production of hydrogen in high purity. Production of hydrogen from PET (C10H8O4) using a CT 434 ZSM-5 catalyst may provide an easy and sophisticated procedure to get hydrogen that can be used as green energy in the future. In this paper the production of hydrogen gas from PET using a CT 434 ZSM-5 catalyst at various temperatures is studied. A PerkinElmer Clarus 580 gas chromatograph with a built-in auto-sampler equipped with a thermal conductivity detector had been used to detect the evolved hydrogen as a result of reaction. II. EXPERIMENTAL SET-UP A. Materials A list of the materials used is given below:  Polyethylene Terephthalate (PET) square shape pieces (1cm×1cm): 20gm  CT 434 ZSM-5 catalyst powder: 10gm  Electric heater  Five air tight glass vials with rubber lids for hydrogen samples collection  Three necked (flanges) round bottom flask  An ebro TCL 730 infrared thermometer with readings up to 350oC  Plastic tubes of 20 cm length with external diameter 3mm and internal 2mm having syringe needles on one end  A gas tight glass Syringe for sample collection  Hydrogen (H2): purity>99.99%  Nitrogen (N2): purity >99.99% Engineering, Technology & Applied Science Research Vol. 6, No. 6, 2016, 1269-1273 1270 www.etasr.com El-Sinawi: Production of Hydrogen from Poly Ethylene Terephthalate (PET) using CT 434 ZSM-5... B. Instrument A PerkinElmer Clarus 580 gas chromatograph with thermal conductivity detector with a built in auto-sampler and a data acquisition system was used. A typical schematic diagram of the gas chromatograph (GC) system is shown in Figure 1. Fig. 1. A typical schematic diagram of a gas chromatograph with a thermal conductivity detector. C. Method- Sample Collection Small pieces of Polyethylene Terephthalate (PET) are obtained by cutting empty Nestle mineral water plastic bottles in Square shapes of 1×1 cm. These pieces are washed with boiling water and dried using an air drier. The round bottom flask with three flanges is used as a reactor. A sample of 20 gm of those pieces are placed in the reactor. CT 434 ZSM-5 catalyst powder 10 gm is dispersed almost uniformly among the plastic pieces. An Ebro TCL 730 infrared thermometer is fixed into the central flange of the reactor to record the temperature of the reactor. The thermometer is adjusted very carefully to read the temperature easily at different instants of time during the experiment. A glass capillary tube with a valve is open into the reactor through one of its flanges. A plastic tube with an internal diameter of 5 mm and external diameter of 7 mm having a syringe needle on its one end is fixed on the open end of glass capillary tube. The syringe needle is inserted into the glass vial. This vial is equipped with a purging valve. The third flange also has a valve to purge out the residual gases in the reactor before collecting the hydrogen gas sample. The reactor with above said arrangements is placed on an electric heater as shown in Figure 2. Electric power is turned on to start the heating process. It takes nearly 10 minutes to start the reaction between the PET pieces and the CT434 ZSM-5. Gases are evolved as a result of reaction with heating. These evolved gases can easily be observed. After few minutes, pressure is developed by the evolved gases and the air already present in the reactor. To minimize the presence of air in the reactor, the purging valve of third flange of reactor is opened and gases are released out freely. Gases were purged out of the reactor several times using the purging valve to minimize the presence of air in the reactor. When the temperature rises up to 230oC, the valve of the capillary tube is opened and gas is allowed to rush to the vial. After some time, when a sufficient amount of evolved gases is accumulated, the vial is purged and evacuated several times to ensure that no air or any other gases are accumulated before collecting the actual hydrogen samples. When temperature reaches 250oC the first evolved gases sample was collected by closing the purging valve. This sample of evolved gas is considered to be taken at 250oC for the convenience of analysis purpose. Similarly another vial is evacuated several times and then filled with evolved gases at 280oC. The same procedure was followed to collect two other samples at 310oC and 340oC respectively. The schematic diagram of experimental arrangements of the rector for hydrogen production and collection is shown in Figure 2. Fig. 2. A schematic diagram of experimental arrangements of the reactor for hydrogen production and collection D. Gas Chromatography  Experiment is conducted with Injector temperature of 150oC.  Volume of 1ml produced hydrogen was collected from each sample at 250oC, 280oC, 310oC and 340oC .  Each sample was manually injected through a septum with a gas tight syringe.  Approximately 99.99% pure commercially available Nitrogen is used as carrier gas with flow rate of 8.0ml/min. The Gas chromatograph system was calibrated using pure hydrogen, hence 1ml volume was injected manually into the injector port through septum using the gas tight syringe. The spectrum of pure hydrogen was obtained for reference, then 1 ml of the collected gas samples from the reactor were analyzed at different temperatures (250oC, 280oC, 310oC and 340oC) respectively. Spectra for gas samples collected at 250oC, 280oC, 310oC and 340oC was obtained for analysis. The sampling syringe had been purged several time to remove any residual gas from the previous runs. Engineering, Technology & Applied Science Research Vol. 6, No. 6, 2016, 1269-1273 1271 www.etasr.com El-Sinawi: Production of Hydrogen from Poly Ethylene Terephthalate (PET) using CT 434 ZSM-5... III. RESULTS AND DISCUSSION The statistical data for the calibration curve is shown in Table I. Table I shows the experimental results of the mean hydrogen peak areas for injected volume of 0.5-2.5 ml pure hydrogen. Figure 3 shows the linear fit of the peak points versus volume of injected hydrogen. It is clearly observed that the thermal conductivity response to the increasing volume of the injected hydrogen is approximately linear. TABLE I. STATISTICAL DATA OF INJECTED HYDROGEN AND PEAK AREA No Injected Volume (ml) Peak Area (µVS) 1 0.5 43739.4 2 1 87613 3 1.5 133864.8 4 2 201141.12 5 2.5 295130.14 Fig. 3. Linear fit of the peak area versus volume of pure hydrogen The reference spectra of pure hydrogen and the other spectra of collected samples of evolved gases at different temperatures, 250oC, 280oC, 310oC and 340oC are shown in Figure 4. The retention time of pure hydrogen is observed at 2.014 min. The appearance of hydrogen spectra of evolved gas samples at nearly the same retention time indicates the production of hydrogen as a result of pyrolysis reaction of PET1 in the presence of the CT434 ZSM-5 catalyst. The variation in retention time (peak position) versus the temperature of the reactor during the process is described in Figure 5. The retention time for a sample taken at 250oC is 2.025 min and reached to the maximum of 2.029 min at 275oC whereas the retention time of hydrogen gas did not stay at the maximum for a long time, hence it decreased slightly to 2.027 min at 310oC. This deceasing trend continues to a minimum value of 2.015 min at 340oC, which is very close to the reference retention time of pure hydrogen (i.e. 2.014 min). It was observed that at higher temperature than 310oC, the collected hydrogen has similar trend as that of pure hydrogen with retention time of 2.014 min. Fig. 4. Pure and evolved hydrogen spectra at 250, 280, 310 and 340� Fig. 5. Retention time of evolved hydrogen versus temperature of reactor The variation of hydrogen percentage with temperature of the reactor is shown in Figure 6. At temperature of 250oC, the hydrogen percentage is found to be around 20.11%. It decreases to 16.66% when the temperature rises up to 280oC and then increases slightly to 17.13% at 310oC. Further slight increase in hydrogen percentage (i.e. 17.70%) was observed when the temperature increases up to 340oC. The maximum hydrogen percentage (20.11%) was obtained at 250oC while at high temperature (340oC) the maximum percent of hydrogen was still below that of 250oC. The variation of peak height of other evolved gases with the temperature is plotted in Figure 7. The peek height starts from 18447.79 µV at 250oC then exponentially decreases to 17133.28 µV at 310oC where it increases rapidly at 340oC to reach the same peak level (i.e.18447.79µV) as that of 250oC. Figure 8 depicts the impacts of temperature variations on the peak area to peak height ratio of hydrogen. It has been noticed that this ratio decreases rapidly from 2.68s at 250oC to 2.08s at 280oC, and then increases to a value of 2.38s at 310oC where it slightly Engineering, Technology & Applied Science Research Vol. 6, No. 6, 2016, 1269-1273 1272 www.etasr.com El-Sinawi: Production of Hydrogen from Poly Ethylene Terephthalate (PET) using CT 434 ZSM-5... decreases again to 2.34s at 340oC. Although there is little decrease in the peak height (i.e. 2.37s) at 310oC , but still it is very close to the originally obtained value (i.e. 2.38s); Thus, the curve follows approximately a similar trend as that of hydrogen among the collected evolved gases except a minor decrease in peak area to height ratio at temperature of 340oC. Fig. 6. Variation of hydrogen percentage of the evolved gases with increasing temperature Fig. 7. Variation of peak height with the temperature of the evolved gases Fig. 8. Peak area/height ratio with increasing reactor temperature. IV. CONCLUSION The production of hydrogen from Poly Ethylene Terephthalate (PET) using CT 434 ZSM-5 as a catalyst was experimentally investigated. Hydrogen samples of the gases evolved from the reactor at different reactor temperatures were collected and analyzed. A gas chromatography machine with a thermal conductivity detector was used to detect hydrogen in the collected gas samples. Hydrogen is observed in the spectra of gas samples at temperatures of 250oC, 280oC, 310oC and 340oC respectively. The presence of hydrogen is confirmed by comparing the spectra of evolved gas samples with the reference spectrum of pure hydrogen. The peak height values at 18430 µV and 18447.79 µV were noticeably very close to the values of the gas samples taken at 250oC and 340oC respectively. A similar trend is observed for peak area/height ratio and hydrogen percentage with increasing temperature of the evolved gases except a minor decrease in peak area/height ratio at the temperature of 340oC. Maximum hydrogen percentage, around 20.11%, was found in the evolved gases at temperature of 250oC. The recorded retention time (i.e. 2.015 min) for the collected sample at 340oC was very close to the reference retention time (i.e. 2.014 min) of pure hydrogen. This process can be developed and utilized for the production of hydrogen from solid wastes to be used as a source of green energy. ACKNOWLEDGMENT The author would like to thank King Abdulaziz City for Science and Technology (KACST) for funding this ongoing strategic research project under the number ‘10-ENV1149-06’. The author would also gratefully acknowledge King Faisal University (KFU) for furnishing the necessary research labs with cut of the edge technology and support to accomplish this work. REFERENCES [1] P. D. Vaidya, A. E. Rodrigues, “Insight into steam reforming of ethanol to produce hydrogen for fuel cells”, Chem. Eng. J., Vol. 117, pp. 39-49, 2006 Engineering, Technology & Applied Science Research Vol. 6, No. 6, 2016, 1269-1273 1273 www.etasr.com El-Sinawi: Production of Hydrogen from Poly Ethylene Terephthalate (PET) using CT 434 ZSM-5... [2] S. Ahmed, M. Krumpelt, “Hydrogen from hydrocarbon fuels for fuel cells”, Int. J. Hydrogen Energy, Vol. 26, pp. 291-301, 2001 [3] A. N. Fatsikostas, D. I. Kondarides, X. E. 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