In Situ Changes in Mechanical Properties Based on Gas Saturation Inside Pressure Vessels

Authors
Kim, Kwan HoonKim, Jae HooLim, Dong HwanKwon, Byung ChulHong, JinYoon, Ho SubCha, Sung Woon
Issue Date
2024-05
Publisher
MDPI Open Access Publishing
Citation
Polymers, v.16, no.9
Abstract
In previous studies, difficulties were encountered in measuring changes within high-pressure vessels owing to limitations such as sensor connectors and sensor failures under high-pressure conditions. In addition, polymer-gas mixtures experience instantaneous gas desorption upon exiting high-pressure vessels owing to pressure differentials, leading to measurement errors. In this study, a device using magnetic sensors was developed to measure the real-time changes in gas-saturated polymers inside pressure vessels. Experiments on polymethyl methacrylate gas adsorption were conducted with parameters including pressure at 5 MPa and temperatures ranging from -20 to 40 degrees C for 60 and 180 min. It was observed that at -20 degrees C, the maximum magnetic field force density and deflection were 391.53 mu T and 5.83 mm, respectively, whereas at 40 degrees C, deflection did not occur, with a value of 321.79 mu T. Based on gas saturation experiments, a new model for deflection in high-pressure atmospheres is proposed. Additionally, an ANSYS analysis was conducted to predict the changes in Young's modulus based on gas saturation. In previous studies, mechanical properties were measured outside the pressure vessel, resulting in an error due to a pressure difference, while the proposed method is characterized by the ability to directly measure polymer behavior according to gas saturation in high-pressure vessels using a magnetic sensor in real time. Therefore, it is possible to predict polymer behavior, making it easy to control variables in high-pressure polymer processes.
Keywords
GLASS-TRANSITION TEMPERATURE; POLYMERS; BATCH; BEHAVIOR; CO2; polymer-gas mixture; batch process; magnetic sensor; polymer deflection; elastic modulus
URI
https://pubs.kist.re.kr/handle/201004/149881
DOI
10.3390/polym16091276
Appears in Collections:
KIST Article > 2024
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