Byung Kyu Park scite author profile

Byung Kyu Park

2Publications

0Citation Statements Received

82Citation Statements Given

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Seoul National University

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Influence of the Foaming Process on the Burning Behavior of the PET–PEN Copolymer

2023

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The manufacturing process can modify the micromechanical structure, usefulness, and functionality of foams. Although one-step foaming is a simple process, controlling the morphology of the foams is difficult compared to the two-step processing method. In this study, we investigated the experimental differences in thermal and mechanical properties, particularly combustion behavior, between PET−PEN copolymers prepared by the two methods. With an increase in foaming temperature T f , the PET−PEN copolymers became more fragile, and the breaking stress of the one-step PET− PEN foamed at the highest T f was only 2.4% of that of the raw material. For the pristine PET−PEN, 24% of the mass was burned, leaving 76% as a molten sphere residue. The two-step MEG PET− PEN had only 1% of its mass remaining as a residue, whereas the onestep PET−PENs had between 41 and 55%. The actual mass burning rates were similar for all the samples except the raw material. The coefficient of thermal expansion of the one-step PET−PEN was about two orders of magnitude lower than that of the two-step SEG.

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Unsteady Heat Flux Measurement and Predictions Using Long Short-Term Memory Networks

Park

Kim

2023

Buildings

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Energy consumption modeling has evolved along with building technology. Modeling techniques can be largely classified into white box, gray box, and black box. In this study, the thermal behavior characteristics of building components were identified through time-series data analysis using LSTM neural networks. Sensors were installed inside and outside the test room to measure physical quantities. As a result of calculating the overall heat transfer coefficient according to the international standard ISO 9869-1, the U value of the multi-window with antireflection coating was 1.84 W/(m2∙K). To understand the thermal behavior of multiple windows, we constructed a neural network using an LSTM architecture and used the measured data-set to predict and evaluate the heat flux through deep learning. From the measurement data, a wavelet transform was used to extract features and to find appropriate control time-step intervals. Performance was evaluated according to multistep measurement intervals using the error metric method. The multistep time interval for control monitoring is preferably no more than 240 s. In addition, multivariate analysis with several input variables was performed. In particular, the thermal behavior of building components can be analyzed through heat flux and temperature measurements in the transient state of physical properties of pre-installed building components, which were difficult to access with conventional steady-state measurement methods.

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Byung Kyu Park

Influence of the Foaming Process on the Burning Behavior of the PET–PEN Copolymer

Unsteady Heat Flux Measurement and Predictions Using Long Short-Term Memory Networks

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