• Title/Summary/Keyword: 피열온도

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Scientific Analysis for Furnace Walls of the Joseon Dynasty Excavated in Southern Region of the Korean Peninsula (한반도 남부지역 출토 조선시대 노벽의 과학적 분석)

  • Jang, Won Jin;Han, Min Su
    • Journal of Conservation Science
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    • v.37 no.6
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    • pp.807-820
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    • 2021
  • A study on the Joseon Dynasty's furnace walls, excavated from south Korea, was conducted to identify the correlations and differences of the furnace walls found in Jeolla and Gyeongsang regions. Three ruins in the Jeolla region and two in the Gyeongsang region were selected for the analysis. The results showed a layer change depending on the degree of plasticity and difference in the number of layers and particle phase. Furthermore, although the temperature to be subjected to heat was divided into 1300℃ and 1100℃, it was not a phenomenon that appeared according to the region. Additionally, analysis result of major components revealed that the TiO2 content of most samples does not exceed 1wt%, This means that the furnace did not smelt iron sand or smelted it into low-titanium sand. This study indicated a slight similarity between the furnace walls found in the two regions, and the correlation was determined based on the nature of the ruins, raw materials of the metals ores, and composition of the raw materials constituting the furnace walls.

Scientific Analysis of Firing Characteristics for Walls and Rooftiles Excavated from Jeseoksa Dump-site, Iksan (익산 제석사지 폐기유적 벽체 및 기와의 피열특성)

  • Ahn, Kyoung Suk;Lee, Min Hye;Han, Min Su
    • Journal of Conservation Science
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    • v.37 no.5
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    • pp.567-578
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    • 2021
  • In this study, the physicochemical properties of 21 wall fragments and rooftile pieces excavated from Jeseoksa Dump-site were analyzed, and the possibility of heat exposure, such as the fire reported in the literature, was investigated by estimating the firing temperature. From the results, it was estimated that the rooftiles were composed of refined materials, and the walls were composed of materials having different particle sizes depending on the layer. Unlike ordinary rooftiles and walls, they exhibited an uneven surface with traces of bloating phenomenon in the cross section. It was estimated from the blackening of some portions that firing was not performed in a controlled state in a constant firing environment. In addition, the estimated firing temperature showed that the non-overfired rooftiles had endured a firing temperature of 900℃ or less, but the over-fired samples were subjected to a temperature of 1,000℃ or higher and were fired at a temperature higher than the manufacturing temperature at that time. Additionally, the rooftiles probably became defective during firing or molding at the time of production, but the non-overfired rooftiles exhibited an intact shape and showed the possibility of heat exposure due to fire. Therefore, the analytical results of this study confirm that the defective architectural components damaged by the fire, as reported in the literature, were discarded in the Jeseoksa dump-site.

Analysis on the Temperature Distribution for the Billet in a Furnace (가열로내 피열재의 온도분포 해석)

  • Kwon, O.B.;Kim, M.K.;Chang, K.Y.;Kwon, H.C.;Bae, D.S.
    • Journal of Power System Engineering
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    • v.8 no.2
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    • pp.24-30
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    • 2004
  • In this paper, the optimal heating pattern of the furnace is sought to reduce the unnecessary energy loss. A finite difference method was used to estimate the transient temperature field of the billet in a furnace. Heat conduction equations were used in the interior nodes of the billet, while energy balances for conduction, convection, and radiation were considered in the boundary nodes. Several heating patterns for the furnace were tested and subsequently compared each other. The results showed that the temperature in the preheating zone should be set to relatively low. The temperature distributions of the billet are quite different from each other when different heating pattern are used, even though the heating patterns have the same amount of energy consumption. It reveals that there exists an optimal heating pattern to save the energy loss.

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