The mobility and stability of the knee joint are controlled by a complex interaction between articular surfaces and surrounding connective tissues including ligaments and muscles. Among these force-bearing structures, ACL injuries happen most often. ACLD patients may change their types of gait to compensate for ACL injuries. Several mathematical models have been applied to study kinematics and kinetics of human knee joint. However, studies on the knee joint in the literature have been based on isolated knee joint models or below knee models. The influence of the hip joint position on the lines of action of the bi-articular knee muscles has been largely ignored. The purposes of the study are to develop a three-dimensional lower limb model considering all major joints and use it to study the mechanical interactions between force-bearing structures of the knee joint in ACLD patients during gait. A detailed knee model was integrated into an existing locomotor system. A two-phase numerical procedure was developed and incorporated with the new lower limb model for better prediction of the forces transmitted in the muscles, ligaments and articular surfaces at the knee during gait. Kinematic geometry of the knee and its surrounding structures were determined initially by the three-dimensional knee model assuming inextensible ligaments and rigid articular surfaces. By iteratively changing the displacement components of the joint, the forces developed in the ligaments and contact surfaces were calculated until the equilibrium equations were satisfied. The detailed lower limb model was applied in normal, ACLD and ACLR subjects during level walking. We found the extension moment in stance phase in the ACLD subjects. It was so-called “quadriceps-avoidance gait”. In the first half of the stance phase, the hamstrings generated larger forces in the ACLD subjects, which was considered as a compensation of the ACL deficiency. This special type of gait was not found in the ACLR subjects. However, the quadriceps forces and the flexion moment in the ACLR subjects were smaller to those in the normal ones. The lower limb will be applied in different functional activities to investigate clinical problems and to overcome limitations of current knee joint studies in the future.