The operating performance of proton exchange membrane fuel cells (PEMFC) depends on the water production inside the cells. In this study, array piezoelectric ceramic transducers were surface adhered to flow field plate mockups made of aluminum alloy and used to generate and detect guided acoustic waves propagating along the flow channels. In-situ inspection of water distribution in PEM fuel cells is feasible by the presented method. The phase velocities for guided acoustic waves and their corresponding mode shapes were determined using finite element analysis (FEA). Besides the A0 and S0 modes, several additional bending modes caused by transverse vibrations of the stiffeners in flow field plate were found in the lower frequency range. In experiment, the acoustic wave signals were detected by two piezoelectric array sensors and laser Doppler interferometer for various amounts of water production. The fact of directly propagating guided waves interfered with multiply reflected echoes results in deviation of both measured and numerically predicted phase velocities of guided acoustic waves. The insertion loss between transmitted and received piezoelectric arrays was measured as a function of the quantity of water production. The results indicate that the attenuation of guided acoustic wave increases as the water content increases. The insertion loss is a significant index for monitoring water production in the flow field plate of PEM fuel cells.