In response to the demand for high-accuracy mass flowrate measurement in industry, this thesis aims to analyze the operation of dual U-tube Coriolis mass flowmeter by using the commercial software COMSOL that is a finite element simulation package. The dual U-tube Coriolis mass flowmeter contains two identical U-tube connected in parallel. An actuator mounted on the midpoint of the U-tube is used to drive the U-tubes to oscillate normal to the plane of the U-tube. The two U-tubes oscillate symmetrically with the same frequency and amplitude. Two motion sensors mounted symmetrically with respect to the midpoint of the U-tube are used to detect the displacements of the U-tube at the positions of the motion sensors. Due to the symmetrical vibrational mode of the U-tube, when the fluid does not flow, the output signals of the two motion sensors should be the same. When the fluid flows, the Coriolis force induced by the relative motion of the fluid and the oscillatory U-tube will distort the vibration mode and thereby results in the phase difference of the signals output by the two motion sensors. Therefore, one can obtain the mass flow rate through the phase difference of the signals output by the two motion sensors. The author adopts COMSOL to simulate the fluid-structure coupling effects of a dual U-tube Coriolis mass flowmeter and investigates the relationships among the resonant frequencies of the U-tube, the density and viscosity of the fluid, the phase difference of the signals output by the motion sensors, and the fluid flow rate. The author also uses COMSOL’s application development platform to develop a design interface for dual U-tube Coriolis mass flowmeter to facilitate the product development. Furthermore, the influence of the positions of the motion sensors and gravity on the output signals, the influence of the flow splitter on the pressure drop, and the influence of the structure unbalance on the output signals and mass flowrate measurement are discussed as well. The aforementioned simulation results are verified by experiments. A dual U-tube Coriolis mass flowmeter produced by Yokogawa company is used and the experiment is conducted in the standard flow testing factory provided by FineTek Technology Co., Ltd. The experiment shows that the simulation results of the present model agree well with the experiment. Furthermore, to investigate the feasibility of measuring the fluid viscosity by Coriolis mass flowmeter, the author also simulates the effect of the fluid viscosity on the pressure loss of flow tube and on the drive current of the actuator. The result about the pressure loss has the same trend with empirical formula while the relationship of the viscosity and driving force of the actuator is obtained by curve fitting on the simulation results.