In this thesis, we study several ODE systems modeling the competition among m species in patchy environments. First, we consider the case of two species and two patches, where both species move between the patches with the same dispersal rate. It is shown that the species with larger birth rates in both patches drives the other species to extinction, regardless of the dispersal rate. The more interesting case is when both species have the same average birth rate but each species has a larger birth rate in one patch. It has previously been conjectured by Gourley and Kuang in 2005 that the species that can concentrate its birth in a single patch wins if the diffusion rate is large enough, and two species will coexist if the diffusion rate is small. In short, the winning strategy is simply to focus as much birth in a single patch as possible. We solve these two conjectures by applying the monotone dynamics theory, incorporated with a complete characterization of the positive equilibrium and a thorough analysis on the stability of the semi-trivial equilibria with respect to the dispersal rate. Our result on the winning strategy for a suffciently large dispersal rate might explain the group breeding behavior that is observed in some animals under certain ecological conditions. Second, we consider two species and two patches, where both species move between the patches with the different dispersal rates. We establish the interesting phenomenon that the slower diffuser always prevails. That is, in a spatially heterogeneous environment, the slower diffuser always wipes out its faster competitor, regardless of the initial conditions as long as both are nonzero. The ODE model we study herein has its continuous-space counterpart. Such a system of PDEs has been studied by Dockery et al. in 1998. Third, the carrying simplex for m competing species is discussed. We conrm that all solutions for m competing species in a spatially homogeneous environment ultimately enter the carrying simplex. Finally, we provide several numerical examples to illustrate the dynamical scenarios.