The rapid development of smart industries has led to the widespread integration of intelligent sensing systems into modern flow meters to achieve quick production and real-time monitoring. Among these, the rotameter (variable area flow meter) is favored due to its simple structure, ease of installation, low pressure loss, relatively low cost, and minimal requirement for straight pipe lengths. It finds extensive application across industries. This work starts with theoretical equations and derives the dimensionless parameters of the rotameter using dimensional analysis. Computational fluid dynamics software, COMSOL, was utilized to simulate the flow field behavior within the measuring tube at different float heights. The impact of float shape on the sensitivity and measuring range of the rotameter was analyzed. The results indicate that the relative error between simulation and literature values is less than 5%, while the average relative error between theoretical and simulation values is 6.49%. The float shape significantly affects the performance of the flow meter; for instance, a float with a characteristic angle of 26.57° shows a sensitivity decrease of approximately 30% compared to one with an angle of 90°. However, the measuring range increases by about 41%. Hence, balancing the trade-off between measuring range and sensitivity is a critical design aspect. Additionally, a magnetically induced measurement design for the rotameter is proposed. This design uses magnets within the float and an external magnetic induction rotation system to measure the float position accurately. Experiments validated the effectiveness of the prototype and the simulations.