Serially connected manipulators have been used in many applications. Force analysis with regard to serially connected manipulators are discussed thoroughly in the past. However, force analysis of statically balanced manipulator using springs has not been widely addressed because spring forces and motions do not share an immediate association. For the statically balanced manipulators, the torque equilibrium regarding the pre-connected joint of a typical link should be zero; and the torque contributed by gravity force and spring force can be formed as function of accumulative joint angles. Based on compatibility between torques with the same accumulative joint angle, the spring attachment parameters are constrained by given link properties. However, the spring affecting joint reaction forces of the joints crossed by the spring. It is necessary to derive the torque equilibrium equations on all joints, then attachment parameters of springs solved by these parameters simultaneously satisfying equations. Thus, spring forces and joint reaction force can be sequentially determined by a chosen set of stiffness and attached lengths of springs. The results of four-link illustrative example show that joint reaction forces are reduced by 22.6%, 40.1% and 75.7% at joint 1, 2 and 3, respectively than those without springs. And for the statically balanced manipulator, a portion of the torques caused by springs countering each other lead to an imbalance in gravitational torques and, therefore, are deemed as waste torques for springs to achieve static balance. It just like motor-torque is not used to drive the manipulator and seemed as waste energy. For the aforementioned statically balanced manipulator, the torque w.r.t the joint should be zero; in which, there are only gravitational torque and torque caused by springs. The torque contribution of spring can be classified as gravity-balancing torque and counter-torque. And the internal counter-torque is defined as the possible maximum value of these counter-torques at each joint. Because of the number of spring attachment parameters more than the number of equations in a system, the solution of parameters is not unique; some parameters can be chosen. Thus, the internal counter-toque can be minimized by adjusting the spring attachment parameters. The results of a three-DOF manipulator shows that there are 28% and 50% reductions in the internal counter-torque at joints 2 and 3, respectively, through the adjustment of spring attachment parameters. Furthermore, several static balance methods have been proposed for a spanning-spring arrangement in a statically balanced mechanism (SBM) with auxiliary elements; in which, the extra space is required for the arrangement and the auxiliary elements, and there may have interference between springs, auxiliary elements and mechanism. To avoid these disadvantages, the spring is installed in the prismatic joint; and the direction of its elongation is parallel to the moving direction of the prismatic joint. This installation method can avoid aforementioned two disadvantages, using extra space and interference with mechanism during motions. To achieve the perfect static balance, in the design, two prismatic joints are required for a closed-loop, planar four-link SBM by deriving the formulation of potential energy. And these two prismatic joints should be adjacent and perpendicular to each other. Then, the one-DOF six-link mechanism can be expended from the four-link SBM. The six-link mechanism has two types, Watt-type and Stephen-type mechanism; the former is formed by two four-link mechanism and the letter formed by one four-link mechanism and one five-link mechanism. For Watt-type mechanism, the ground-link is assumed as the ternary link to avoid redundant loop and enhance the rigidity of the mechanism. The one of prismatic joints is assumed as ternary joint to reduce the number of prismatic joints to avoid friction problem. For Stephen-type mechanism, an extra rule is applied which is there are not more than two revolute joints in the five-link mechanism except ternary joint because there are just two revolute joints in the four-link mechanism. Examples of one-DOF four-link mechanism and Stephen-type six-link mechanism show that the mechanisms reached perfectly static balance without using extra space for installing springs.