Your search keyword '"Kwong, Philip"' showing total 9 results

1. Biochar for electrochemical applications

Author

Rahman, Mohammad Z., Edvinsson, Tomas, Kwong, Philip, Rahman, Mohammad Z., Edvinsson, Tomas, and Kwong, Philip

Abstract

Carbon-rich biochar can be produced by pyrolysis of biomass. Depending on the precise production pathway, the surface chemistry and porosity can be tuned and made compatible for a defined application. This shear benefit has persuaded researcher to explore its suitability in various electrochemical applications related to energy storage and conversion. In this article, we succinctly discuss the potentials of biochar in electrocatalysis, fuel cell, supercapacitors, and rechargeable batteries. We have concluded this article with recommenda-tions for future research.

Published

2020

2. Decoding gas-solid interaction effects on adsorption isotherm shape: I. Non-polar adsorptives

Author

Universidad de Alicante. Departamento de Química Inorgánica, Madani, S. Hadi, Kwong, Philip, Rodríguez Reinoso, Francisco, Biggs, Mark J., Pendleton, Phillip, Universidad de Alicante. Departamento de Química Inorgánica, Madani, S. Hadi, Kwong, Philip, Rodríguez Reinoso, Francisco, Biggs, Mark J., and Pendleton, Phillip

Abstract

A suite of non-polar adsorptives of different kinetic diameters and shape were used to determine adsorption and pore filling mechanism of a well-characterised poly(furfuryl alcohol)-based activated carbon. Triplicate measured Type I adsorption isotherms for each adsorptive were averaged to provide standard deviation in relative pressures and associated amounts adsorbed. Plateau amounts adsorbed for N2, Ar, CH4, and C6H6, provided Gurvitsch volumes averaged to 0.368 ± 0.015 cm3(liq)/g. The calculated Gurvitsch volumes were compared with those derived via the Dubinin-Radushkevich (DR) equation. Additional adsorptives were CO2, iso-butane and SF6. The results of these 7 adsorptives were used to qualitatively analyse and decode a micropore filling adsorption mechanism. The DR equation was also used for further analysis of the pore filling mechanism. Based on the adsorbate-adsorbate and adsorbate-adsorbent interactions, adsorbates were classified into three groups: (a) Non-polar with non-specific interactions (no dipole, no quadrupole, not readily polarizable: Ar, N2, CH4 and iso-butane), adsorbing as a continuous uptake over the observed relative pressure range; (b) Non-polar adsorptives with potential for specific interactions (no dipole, quadrupole moment: CO2 and C6H6), adsorbing as a condensation process over a relatively narrow relative pressure range in a medium pressure range; (c) Halogenated adsorptives (no dipole, no quadrupole, polarizable: SF6), adsorbing with an S-shaped uptake extending over a relatively broad relative pressure range.

Published

2018

3. Decoding gas-solid interaction effects on adsorption isotherm shape: I. Non-polar adsorptives

Author

Universidad de Alicante. Departamento de Química Inorgánica, Madani, S. Hadi, Kwong, Philip, Rodríguez Reinoso, Francisco, Biggs, Mark J., Pendleton, Phillip, Universidad de Alicante. Departamento de Química Inorgánica, Madani, S. Hadi, Kwong, Philip, Rodríguez Reinoso, Francisco, Biggs, Mark J., and Pendleton, Phillip

Abstract

A suite of non-polar adsorptives of different kinetic diameters and shape were used to determine adsorption and pore filling mechanism of a well-characterised poly(furfuryl alcohol)-based activated carbon. Triplicate measured Type I adsorption isotherms for each adsorptive were averaged to provide standard deviation in relative pressures and associated amounts adsorbed. Plateau amounts adsorbed for N2, Ar, CH4, and C6H6, provided Gurvitsch volumes averaged to 0.368 ± 0.015 cm3(liq)/g. The calculated Gurvitsch volumes were compared with those derived via the Dubinin-Radushkevich (DR) equation. Additional adsorptives were CO2, iso-butane and SF6. The results of these 7 adsorptives were used to qualitatively analyse and decode a micropore filling adsorption mechanism. The DR equation was also used for further analysis of the pore filling mechanism. Based on the adsorbate-adsorbate and adsorbate-adsorbent interactions, adsorbates were classified into three groups: (a) Non-polar with non-specific interactions (no dipole, no quadrupole, not readily polarizable: Ar, N2, CH4 and iso-butane), adsorbing as a continuous uptake over the observed relative pressure range; (b) Non-polar adsorptives with potential for specific interactions (no dipole, quadrupole moment: CO2 and C6H6), adsorbing as a condensation process over a relatively narrow relative pressure range in a medium pressure range; (c) Halogenated adsorptives (no dipole, no quadrupole, polarizable: SF6), adsorbing with an S-shaped uptake extending over a relatively broad relative pressure range.

Published

2018

4. Co-firing coal with rice husk and bamboo and the impact on particulate matters and associated polycyclic aromatic hydrocarbon emissions

Author

Chao, Christopher Y.H., Kwong, Philip C.W., Wang, J.H., Cheung, C.W., Kendall, Gail, Chao, Christopher Y.H., Kwong, Philip C.W., Wang, J.H., Cheung, C.W., and Kendall, Gail

Abstract

The potential of co-firing rice husk and bamboo with coal was studied in a bench-scale pulverized fuel combustion reactor. Experimental parameters including biomass blending ratio in the fuel mixture, biomass grinding size, excess air ratio and relative moisture content in the biomass were investigated. Particulate Matters in the forms of PM10, PM2.1, ultra fine particles as well as the associated Polycyclic Aromatic Hydrocarbons (PAHs) emissions were evaluated. An operation range between 10\% and 30\% of biomass to coal ratio was found to be the optimum range in terms of minimum pollutant emissions per unit energy output. Co-combustion of coal with biomass seemed to have the effect of moving the fly-ash in PM2.1 to a larger size range, but increasing the number counts of the ultra fine particles. It was noted that the much higher volatile matter content in the biomass fuels has played a key role in improving the combustion performance in the system. However, slagging, fouling and formation of clinker could be the issues requiring attention when using biomass co-combustion in conventional boilers. (C) 2006 Elsevier Ltd. All rights reserved.

Published

2008

5. Co-firing coal with rice husk and bamboo and the impact on particulate matters and associated polycyclic aromatic hydrocarbon emissions

Author

Chao, Christopher Y.H., Kwong, Philip C.W., Wang, J.H., Cheung, C.W., Kendall, Gail, Chao, Christopher Y.H., Kwong, Philip C.W., Wang, J.H., Cheung, C.W., and Kendall, Gail

Abstract

The potential of co-firing rice husk and bamboo with coal was studied in a bench-scale pulverized fuel combustion reactor. Experimental parameters including biomass blending ratio in the fuel mixture, biomass grinding size, excess air ratio and relative moisture content in the biomass were investigated. Particulate Matters in the forms of PM10, PM2.1, ultra fine particles as well as the associated Polycyclic Aromatic Hydrocarbons (PAHs) emissions were evaluated. An operation range between 10\% and 30\% of biomass to coal ratio was found to be the optimum range in terms of minimum pollutant emissions per unit energy output. Co-combustion of coal with biomass seemed to have the effect of moving the fly-ash in PM2.1 to a larger size range, but increasing the number counts of the ultra fine particles. It was noted that the much higher volatile matter content in the biomass fuels has played a key role in improving the combustion performance in the system. However, slagging, fouling and formation of clinker could be the issues requiring attention when using biomass co-combustion in conventional boilers. (C) 2006 Elsevier Ltd. All rights reserved.

Published

2008

6. Co-firing coal with rice husk and bamboo and the impact on particulate matters and associated polycyclic aromatic hydrocarbon emissions

Author

Chao, Christopher Y.H., Kwong, Philip C.W., Wang, J.H., Cheung, C.W., Kendall, Gail, Chao, Christopher Y.H., Kwong, Philip C.W., Wang, J.H., Cheung, C.W., and Kendall, Gail

Abstract

The potential of co-firing rice husk and bamboo with coal was studied in a bench-scale pulverized fuel combustion reactor. Experimental parameters including biomass blending ratio in the fuel mixture, biomass grinding size, excess air ratio and relative moisture content in the biomass were investigated. Particulate Matters in the forms of PM10, PM2.1, ultra fine particles as well as the associated Polycyclic Aromatic Hydrocarbons (PAHs) emissions were evaluated. An operation range between 10\% and 30\% of biomass to coal ratio was found to be the optimum range in terms of minimum pollutant emissions per unit energy output. Co-combustion of coal with biomass seemed to have the effect of moving the fly-ash in PM2.1 to a larger size range, but increasing the number counts of the ultra fine particles. It was noted that the much higher volatile matter content in the biomass fuels has played a key role in improving the combustion performance in the system. However, slagging, fouling and formation of clinker could be the issues requiring attention when using biomass co-combustion in conventional boilers. (C) 2006 Elsevier Ltd. All rights reserved.

Published

2008

7. Co-combustion performance of coal with rice husks and bamboo

Author

Kwong, Philip C.W., Chao, Christopher Y.H., Wang, J.H., Cheung, C.W., Kendall, Gail, Kwong, Philip C.W., Chao, Christopher Y.H., Wang, J.H., Cheung, C.W., and Kendall, Gail

Abstract

Biomass has been regarded as an important form of renewable energy due to the reduction of green house gas emission such as carbon dioxide. An experimental study of co-combustion of coal and biomass was performed in a laboratory-scale combustion facility. Rice husks and bamboo were the selected biomass fuels in this study due to their abundance in the Asia-Pacific region. Experimental parameters including the biomass blending ratio in the fuel mixture, relative moisture content and biomass grinding size were investigated. Both energy release data and pollutant emission information were obtained. Due to the decrease in the heating value from adding biomass in the fuel mixture, the combustion temperature and energy output from the co-firing process were reduced compared with coal combustion. On the other hand, gaseous pollutant emissions including carbon monoxide (CO), carbon dioxide (CO2), nitrogen oxides (NOx) and sulfur dioxide (SO2) were reduced and minimum energy-based emission factors were found in the range of 10-30\% biomass blending ratio. With an increase in the moisture content in the biomass, decreases in combustion temperature, SO2, NOx and CO2 emissions were observed, while an increase in CO emissions was found. It has also been observed that chemical kinetics may play an important role compared to mass diffusion in the co-firing process and the change in biomass grinding size does not have much effect on the fuel burning rate and pollutant emissions tinder the current experimental conditions. (C) 2007 Elsevier Ltd. All rights reserved.

Published

2007

8. Co-combustion performance of coal with rice husks and bamboo

Author

Kwong, Philip C.W., Chao, Christopher Y.H., Wang, J.H., Cheung, C.W., Kendall, Gail, Kwong, Philip C.W., Chao, Christopher Y.H., Wang, J.H., Cheung, C.W., and Kendall, Gail

Abstract

Biomass has been regarded as an important form of renewable energy due to the reduction of green house gas emission such as carbon dioxide. An experimental study of co-combustion of coal and biomass was performed in a laboratory-scale combustion facility. Rice husks and bamboo were the selected biomass fuels in this study due to their abundance in the Asia-Pacific region. Experimental parameters including the biomass blending ratio in the fuel mixture, relative moisture content and biomass grinding size were investigated. Both energy release data and pollutant emission information were obtained. Due to the decrease in the heating value from adding biomass in the fuel mixture, the combustion temperature and energy output from the co-firing process were reduced compared with coal combustion. On the other hand, gaseous pollutant emissions including carbon monoxide (CO), carbon dioxide (CO2), nitrogen oxides (NOx) and sulfur dioxide (SO2) were reduced and minimum energy-based emission factors were found in the range of 10-30\% biomass blending ratio. With an increase in the moisture content in the biomass, decreases in combustion temperature, SO2, NOx and CO2 emissions were observed, while an increase in CO emissions was found. It has also been observed that chemical kinetics may play an important role compared to mass diffusion in the co-firing process and the change in biomass grinding size does not have much effect on the fuel burning rate and pollutant emissions tinder the current experimental conditions. (C) 2007 Elsevier Ltd. All rights reserved.

Published

2007

9. Co-combustion performance of coal with rice husks and bamboo

Author

Kwong, Philip C.W., Chao, Christopher Y.H., Wang, J.H., Cheung, C.W., Kendall, Gail, Kwong, Philip C.W., Chao, Christopher Y.H., Wang, J.H., Cheung, C.W., and Kendall, Gail

Abstract

Biomass has been regarded as an important form of renewable energy due to the reduction of green house gas emission such as carbon dioxide. An experimental study of co-combustion of coal and biomass was performed in a laboratory-scale combustion facility. Rice husks and bamboo were the selected biomass fuels in this study due to their abundance in the Asia-Pacific region. Experimental parameters including the biomass blending ratio in the fuel mixture, relative moisture content and biomass grinding size were investigated. Both energy release data and pollutant emission information were obtained. Due to the decrease in the heating value from adding biomass in the fuel mixture, the combustion temperature and energy output from the co-firing process were reduced compared with coal combustion. On the other hand, gaseous pollutant emissions including carbon monoxide (CO), carbon dioxide (CO2), nitrogen oxides (NOx) and sulfur dioxide (SO2) were reduced and minimum energy-based emission factors were found in the range of 10-30\% biomass blending ratio. With an increase in the moisture content in the biomass, decreases in combustion temperature, SO2, NOx and CO2 emissions were observed, while an increase in CO emissions was found. It has also been observed that chemical kinetics may play an important role compared to mass diffusion in the co-firing process and the change in biomass grinding size does not have much effect on the fuel burning rate and pollutant emissions tinder the current experimental conditions. (C) 2007 Elsevier Ltd. All rights reserved.

Published

2007