The remediation of groundwater uranium pollution has been successfully researched and implemented. However, the cost-effectiveness remains challenging to evaluate. Numerical modeling presents a potential solution, while the coupling of multi-physics in uranium pollution remediation has been a global challenge. This study developed a multi-physics coupled model to simulate the evolution of groundwater uranium plumes in composite remediation system, which was composed of permeable reactive barrier (PRB) and electrokinetic remediation (EKR). Meanwhile, pH changes are also taken into account. The research revolved around sandbox dynamic migration experiments, where key parameters were measured for model building. Based on this, a mathematical model for achieving multi field coupling has been proposed. Substitute equations were used to unify the calculation of flow field and electric field into the same dimension. The results showed that the pH variations induced by electrolysis propagate towards the center of the electric field. Medium adsorption of uranium reached its peak when the pH was between 4 and 5. The driving force of groundwater flow in the coupled field was about 3.5 times that of electroosmosis, occupying a dominant position. Electric fields can serve as auxiliary means to delay the migration of uranium. Under ensuring the effective operation of the system for 360 days, the system can save 25 % of PRB thickness with the EKR assistance. The model can not only predict evolution of uranium plume in groundwater, but also calculate the performance and lifespan of composite remediation systems, providing guidance and recommendations for the design of real-site remediation systems.