In recent years, there has been a significant increase in demand for thermal dispersion gas flow meters due to the rise of the precision industry. This is because thermal dispersion flow meters do not cause pressure loss in pipelines and have the advantage of being able to detect gases. As a result, they are widely used in industries such as electronics, steel, semiconductor, and others. Currently, all thermal dispersion gas flow meter products are imported from foreign countries, and they are quite expensive, costing around 80,000 to 150,000 NTD. Furthermore, there are no relevant patents for this technology domestically. Therefore, this research aims to develop this product as the goal, hoping to lay the foundation for product development through this study. This study utilizes COMSOL Multiphysics to simulate thermal dispersion flow meters, investigating the relationship between the temperature of the heating element and the fluid velocity. The accuracy of the model will be validated through experimental verification. To design the prototype of the thermal dispersion flow meter, the Taguchi method will be utilized. Geometric parameters for the prototype will be determined, and a flexible printed circuit board for the sensing end will be designed. Finally, the flow velocity will be visualized using Arduino and an LCD screen. The experimental results of the thermal dispersion flow meter prototype indicate that the error is less than 5% for wind speeds ranging from 7.6m/s to 16.5m/s.