Your search keyword '"Jong Hoon Cho"' showing total 4 results

1. Effect of Particle Orientation and Porosity on Thermal Conductivity of Petroleum Pitch Polymer-Based Carbon Molded Body

Author

Jong Hoon Cho, Ji Sun Im, and Byong Chol Bai

Subjects

heat sink materials, pyrolyzed fuel oil, binder pitch polymer, needle coke, graphite block, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The present study was conducted to investigate changes in the thermal conductivity of petroleum pitch-based carbon molded bodies prepared by anisotropic (uniaxial) molding under different molding pressures. The carbon molded bodies were prepared using needle coke and petroleum-based binder pitch polymers (softening point: 150 ℃). Green blocks prepared under high molding pressure showed a higher particle orientation value up to 16.4 μm. Graphite blocks, prepared by graphitizing the green blocks at 2800 ℃ showed a similar trend. The pores in the carbon molded body were filled with low boiling point substances, generated by the thermal treatment of the binder pitch polymer or air that could not be discharged during the molding procedure. Therefore, when phonons encountered a pore, phonon scattering, rather than phonon transport, occurred, and thus the heat transport from the hot zone to a cold zone became slow. As a result, although the particle orientation was a little higher in the B_10-G sample than in the B_20-G sample (in the error range), the thermal conductivity was higher in the B_20-G sample, which may be because the B_10-G sample had a higher porosity than the B_20-G sample.

Published

2020

2. The Control of Volume Expansion and Porosity in Carbon Block by Carbon Black (CB) Addition for Increasing Thermal Conductivity

Author

Min Il Kim, Jong Hoon Cho, Byong Chol Bai, and Ji Sun Im

Subjects

Thermal conductivity, volume expansion, carbon black, binder pitch, artificial graphite, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The graphite block as a phase change materials (PCMs) was manufactured by graphitization of a carbon block. Carbon blocks were prepared by filler (cokes or graphite) and binder (pitch). The binder-coated filler was thermally treated for carbonization. The gases generated from the evaporation of low molecular weight components in the binder pitch during the carbonization process were not released to the outside. Consequently, porosity and volume expansion were increased in artificial graphite, and thereby the thermal conductivity decreased. In this study, to prevent the decrease of thermal conductivity in the artificial graphite due to the disadvantages of binder pitch, the carbon block was prepared by the addition of carbon black, which can absorb low molecular weight compounds and release the generated gas. The properties of the prepared carbon blocks were analyzed by SEM, TGA, and thermal conductivity. The addition of carbon black (CB) decreased the porosity and volume expansion of the carbon blocks by 38.3% and 65.9%, respectively, and increased the thermal conductivity by 57.1%. The CB absorbed the low molecular weight compounds of binder pitch and induced the release of generated gases during the carbonization process to decrease porosity, and the thermal conductivity of the carbon block increased.

Published

2020

3. Effect of Particle Orientation and Porosity on Thermal Conductivity of Petroleum Pitch Polymer-Based Carbon Molded Body

Author

Ji Sun Im, Jong Hoon Cho, and Byong Chol Bai

Subjects

Materials science, Softening point, chemistry.chemical_element, 02 engineering and technology, Molding (process), Thermal treatment, 010402 general chemistry, 01 natural sciences, lcsh:Technology, complex mixtures, lcsh:Chemistry, Thermal conductivity, needle coke, General Materials Science, Graphite, Composite material, Porosity, Instrumentation, lcsh:QH301-705.5, Fluid Flow and Transfer Processes, lcsh:T, Process Chemistry and Technology, General Engineering, Petroleum coke, technology, industry, and agriculture, 021001 nanoscience & nanotechnology, lcsh:QC1-999, binder pitch polymer, 0104 chemical sciences, Computer Science Applications, chemistry, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, pyrolyzed fuel oil, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), Carbon, heat sink materials, lcsh:Physics, graphite block

Abstract

The present study was conducted to investigate changes in the thermal conductivity of petroleum pitch-based carbon molded bodies prepared by anisotropic (uniaxial) molding under different molding pressures. The carbon molded bodies were prepared using needle coke and petroleum-based binder pitch polymers (softening point: 150 ℃). Green blocks prepared under high molding pressure showed a higher particle orientation value up to 16.4 &mu, m. Graphite blocks, prepared by graphitizing the green blocks at 2800 ℃ showed a similar trend. The pores in the carbon molded body were filled with low boiling point substances, generated by the thermal treatment of the binder pitch polymer or air that could not be discharged during the molding procedure. Therefore, when phonons encountered a pore, phonon scattering, rather than phonon transport, occurred, and thus the heat transport from the hot zone to a cold zone became slow. As a result, although the particle orientation was a little higher in the B_10-G sample than in the B_20-G sample (in the error range), the thermal conductivity was higher in the B_20-G sample, which may be because the B_10-G sample had a higher porosity than the B_20-G sample.

Published

2020

4. The Control of Volume Expansion and Porosity in Carbon Block by Carbon Black (CB) Addition for Increasing Thermal Conductivity

Author

Ji Sun Im, Min Il Kim, Byong Chol Bai, and Jong Hoon Cho

Subjects

Materials science, carbon black, 020209 energy, volume expansion, Evaporation, chemistry.chemical_element, 02 engineering and technology, engineering.material, lcsh:Technology, lcsh:Chemistry, Thermal conductivity, Filler (materials), 0202 electrical engineering, electronic engineering, information engineering, artificial graphite, General Materials Science, Graphite, Composite material, Porosity, lcsh:QH301-705.5, Instrumentation, Fluid Flow and Transfer Processes, lcsh:T, Carbonization, Process Chemistry and Technology, General Engineering, Carbon black, binder pitch, 021001 nanoscience & nanotechnology, lcsh:QC1-999, Computer Science Applications, lcsh:Biology (General), lcsh:QD1-999, chemistry, lcsh:TA1-2040, engineering, lcsh:Engineering (General). Civil engineering (General), 0210 nano-technology, Carbon, lcsh:Physics

Abstract

The graphite block as a phase change materials (PCMs) was manufactured by graphitization of a carbon block. Carbon blocks were prepared by filler (cokes or graphite) and binder (pitch). The binder-coated filler was thermally treated for carbonization. The gases generated from the evaporation of low molecular weight components in the binder pitch during the carbonization process were not released to the outside. Consequently, porosity and volume expansion were increased in artificial graphite, and thereby the thermal conductivity decreased. In this study, to prevent the decrease of thermal conductivity in the artificial graphite due to the disadvantages of binder pitch, the carbon block was prepared by the addition of carbon black, which can absorb low molecular weight compounds and release the generated gas. The properties of the prepared carbon blocks were analyzed by SEM, TGA, and thermal conductivity. The addition of carbon black (CB) decreased the porosity and volume expansion of the carbon blocks by 38.3% and 65.9%, respectively, and increased the thermal conductivity by 57.1%. The CB absorbed the low molecular weight compounds of binder pitch and induced the release of generated gases during the carbonization process to decrease porosity, and the thermal conductivity of the carbon block increased.

Published

2020