Butterflies uniquely use the body postures to maneuver their flight directions and speeds, but the method how butterflies utilize to control their body pitching in the air is unclear. Experiment recording the real flight of butterflies indicate that butterflies fly with significant wing lead-lag motion, the wing motion that deviate from the stroke plane. In this research, we create a simulation of butterflies in free flight to investigate how butterflies utilize this motion to achieve different flight modes by controlling their body pitching. The wing lead-lag motion change the distance between the center of pressure (COP) of wing and the center of rotation (COR) of butterflies, and largely affect the direction and magnitude of aerodynamic torque. When the position of COP is fixed ahead of COR, the variations of pitching angle is similar to that of real butterflies in free flight, and the butterfly is able to perform a stable flight in the simulation. Increasing the lead-lag angle further increases the pitching moment and rotational amplitude, and the butterfly performs the flight motion close to vertical take-off. When the position of COP is fixed behind of COR, the variations of pitching angle is completely different from the real butterflies in free flight, and the flight is unstable and the butterfly falls down .When the lead-lag angle is considered as a function, and the trajectory of the wing-tip is an oval similar to that of a real butterfly. The distance between COP and COR is continually changing throughout the downs and upstroke. The average pitching angle decreases while slightly decreasing the pitching amplitude, and butterflies perform the forward flight. The lead-lag motion affects the generation of aerodynamic torque and force and plays an important role in the flight control of a butterfly. Our results might provide a new flight control method for designing high maneuverability aerial vehicle in the future.