Revealing the long-range elastic interaction and short-range core reaction between intersecting dislocations is crucial for understanding dislocation-based strain hardening mechanisms in crystalline solids. Phase field model (PFM) has shown great potential in modeling dislocation dynamics with employing the continuum microelasticity theory to describe the elastic interactions and incorporating the -surface into the crystalline energy to enable the core reactions. Since the crystalline energy is approximately formulated by linear superposition of interplanar potential of each slip plane in the previous PFM, it does not fully account for the reactions between dislocations gliding in intersecting slip planes. In this study, an improved PFM of dislocation intersections is proposed through updating the crystalline energy by coupling the potential of two intersecting planes, and then applied to study the collinear interaction compared with the previous PFM model. Collinear annihilation captured only in the improved PFM is found to strongly affect the junction formation and plastic flow in multislip systems. The results indicate that the improvement is essential for PFM of dislocation intersections.