In　aerospace　applications,　proton　exchange　membrane　fuel　cells　are　subject　to　high-intensity　vibration.　Vibration　has　a　substantial　effect　on　water　transport　in　fuel　cells.　However,　there　is　a　lack　of　research　on　the　effects　of　multi-directional　and　high-intensity　vibration　conditions　on　fuel　cells.　In　this　study,　the　droplet　transport　characteristics　in　the　gas　channel　under　high-intensity　vibration　conditions　are　investigated　for　the　first　time.　Moreover,　the　effects　of　vibration　direction　and　vibration　frequency　on　the　droplet　dynamic　transport　process　are　specifically　studied.　The　droplet　transport　state,　drainage　performance,　and　pressure　drop　variation　in　the　gas　channel　under　different　vibration　conditions　are　analyzed　and　interpreted.　The　results　show　that　low-frequency　vibration　in　the　longitudinal　direction　is　more　conducive　to　the　droplet　discharge,　and　the　pressure　drop　undergoes　a　periodic　change　corresponding　to　the　vibration　frequency.　Vertical　vibration　promotes　droplet　detachment　from　the　gas　diffusion　layer　surface,　which　contributes　to　the　reduction　in　water　coverage　ratio　on　its　surface,　despite　an　increase　in　the　channel　pressure　drop.　Under　the　influence　of　horizontal　vibration,　droplets　are　more　susceptible　to　adsorption　on　the　channel　sidewalls　and　turn　into　a　liquid　film,　which　leads　to　a　longer　discharge　time　and　a　reduction　in　pressure　drop.