In　unmanned　aerial　vehicle　(UAV)　performing　tasks,　the　UAV　often　faces　electricity　shortages.　The　traditional　scheme　to　charge　a　UAV　needs　to　return　to　the　ground.　Using　the　charging　UAV　(CUAV)　can　avoid　the　waste　of　electricity　caused　by　the　return.　However,　the　existing　works　only　consider　a　fixed　charging　location　for　electricity　replenishment.　Moreover,　fewer　works　focus　on　the　matching　relationship　between　multi-CUAV　and　multi-UAV.　It　is　challenging　to　complete　the　expected　charging　work　due　to　the　mismatch　between　the　electricity　demand　and　supply.　To　address　this　problem,　we　propose　a　two-stage　electricity　scheduling　scheme.　Specifically,　in　the　charging　location　selection　stage,　we　solve　the　Nash　equilibrium　(NE)　of　flight　consumption　between　CUAVs　and　UAVs　through　the　exact　potential　game,　thereby　determining　the　accessible　charging　position.　Then,　in　the　electricity　transaction　stage,　we　adopt　the　Stackelberg　game　model　to　determine　the　Stackelberg　equilibrium　(SE)　between　the　acceptance　rate　of　CUAVs　and　the　rejection　rate　of　UAVs,　ensuring　that　both　CUAVs　and　UAVs　are　satisfied　with　the　unit　electricity　prices　and　electricity　demands.　Based　on　the　above　two　game　stages,　we　propose　a　supply　and　demand　scheduling　(SDS)　algorithm　to　achieve　dynamic　scheduling　between　CUAVs　and　UAVs.　Theoretical　analysis　indicates　the　exits　of　NE　and　SE.　Furthermore,　the　extensive　experiments　show　that　our　scheme　has　significant　advantages　over　the　baselines　in　charging　cost,　charging　price,　and　flight　consumption.