To evaluate the thermal-hydraulic characteristics and mechanism of the bubble absorption process inside a solution in a vacuum environment

we design an experimental device for measuring the bubble absorption and transport characteristics of solutions in a pressurized vertical tube and introduce the structure and work of the device. Its reliability is verified by system vacuum pressure experiments

and its accuracy is verified by bubble flow and energy conservation experiments. The results show that pressurization technology achieves bubble absorption in a vacuum environment. The vacuum increase rate of the system is only 2.33% after 12 h of idling

corresponding to a gas leakage rate of 2.4 mL/h. The device exhibited good reliability. The behavior of bubble generation

rising

collision

coalescence

and rupture during the experiment was consistent with the bubble flow behavior reported in the literature. The maximum relative deviations in the outlet temperature and outlet concentration of the solution and cooling water were 0.08%

0.02%

and 0.01%

respectively. The maximum errors of the energy calibration experiment of the different solution inlet temperatures and solution flow rates are 10.4 J and 12.5 J

respectively

and thereby the device has good accuracy. The experimental device provides a good experimental foundation for evaluating the transport characteristics of bubble absorption and the heat transfer characteristics of bubble absorption in a vacuum environment and revealing its transfer mechanism.