Effective robot navigation in dynamic environments is a challenging task that depends on generating precise control actions at high frequencies. Recent advancements have framed navigation as a goal-conditioned control problem. Current state-of-the-art methods for goal-based navigation, such as diffusion policies, either generate sub-goal images or robot control actions to guide robots. However, despite their high accuracy, these methods incur substantial computational costs, which limits their practicality for real-time applications. Recently, Conditional Flow Matching(CFM) has emerged as a more efficient and robust generalization of diffusion. In this work we explore the use of CFM to learn action policies that help the robot navigate its environment. Our results demonstrate that CFM is able to generate highly accurate robot actions. CFM not only matches the accuracy of diffusion policies but also significantly improves runtime performance. This makes it particularly advantageous for real-time robot navigation, where swift, reliable action generation is vital for collision avoidance and smooth operation. By leveraging CFM, we provide a pathway to more scalable, responsive robot navigation systems capable of handling the demands of dynamic and unpredictable environments.