引用本文:
吴云英, 莫志兰, 周雪, 袁羽, 马云飞, 陈婧, 唐刚. 传感技术赋能有机化学实验数字化转型——以常压蒸馏、减压蒸馏和分馏为例[J]. 大学化学,
2025, 40(11): 310-317.
doi:
10.12461/PKU.DXHX202503078
Citation: Yunying Wu, Zhilan Mo, Xue Zhou, Yu Yuan, Yunfei Ma, Jing Chen, Gang Tang. Empowering the Digital Transformation of Organic Chemistry Experiments with Sensing Technology: A Case of Atmospheric Distillation, Vacuum Distillation and Fractionation[J]. University Chemistry, 2025, 40(11): 310-317. doi: 10.12461/PKU.DXHX202503078
Citation: Yunying Wu, Zhilan Mo, Xue Zhou, Yu Yuan, Yunfei Ma, Jing Chen, Gang Tang. Empowering the Digital Transformation of Organic Chemistry Experiments with Sensing Technology: A Case of Atmospheric Distillation, Vacuum Distillation and Fractionation[J]. University Chemistry, 2025, 40(11): 310-317. doi: 10.12461/PKU.DXHX202503078
传感技术赋能有机化学实验数字化转型——以常压蒸馏、减压蒸馏和分馏为例
English
Empowering the Digital Transformation of Organic Chemistry Experiments with Sensing Technology: A Case of Atmospheric Distillation, Vacuum Distillation and Fractionation
Abstract:
Compared with the experiments in existing textbooks, digital experiments are characterized by a high degree of comprehensiveness, innovativeness, and intuitiveness. This paper incorporates digital sensing technology into the basic operations of organic chemistry experiments. By means of temperature sensors and pressure sensors, explorations on the improvement and innovation of atmospheric distillation, vacuum distillation, and fractional distillation experiments are carried out. The research findings indicate that by optimizing the experimental setup with temperature sensors and pressure sensors, it is feasible to monitor in real - time the variations in temperature and pressure during fundamental operation processes such as atmospheric distillation, vacuum distillation, and fractional distillation. Moreover, the time - temperature curves and time - pressure curves can be automatically collected and recorded. This integration initiative has realized the digital transformation of organic chemistry experiments, enhanced the depth and breadth of students’ learning, and is worthy of being promoted and implemented in undergraduate organic chemistry experimental teaching.
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Key words:
- Temperature sensor
- / Pressure sensor
- / Basic operation
- / Experimental improvement
- / Curve
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