Collaborative robots offer new possibilities to use robots in workspaces shared with humans. These robots can interact with their environment and assist human beings in their task in a safer way compared to standard industrial robots. These robots are required to be fast, precise, and efficient during the accomplishment of their tasks. However, their strength can make them dangerous tools around people. Therefore, to ensure safety there are often used in a sub-optimal way. The aim of this work is to ensure the safety of a human interacting with a robot performing a set of tasks. It is more specifically focused on the case of undesired contact with the robot. An undesired contact can either come from of an impact between the robot and an obstacle or from the robot pushing the obstacle against a fixed object. This work shows that in both cases the dangerousness of the robot can be linked to the robot variation of kinetic energy. These robots are also submitted to a set of constraints coming either from their intrinsic design or from the environment. When a human enters in the robot workspace, the robot environment become partially unknown. The robot should be able to adapt to its environment and reactively compute a safe control solution satisfying its constraints while performing its tasks in an optimal way. To that aim, this work formulates the control problem as a constrained optimization one and solves it using Linear Quadratic Programming. The robot variation of kinetic energy is constrained within the quadratic programming problem. This constraint prevents the robot from reaching a dangerous amount of kinetic energy. It also indirectly prevents the robot from exerting too much forces when in contact with an obstacle. This work also shows that it is possible to use the robot redundancy to minimize its perceived mass in the direction of an obstacle. This indirectly reduces its kinetic energy for a given task. The proposed controller is implemented on a 7 dof serial robotic manipulator. This work, realised in collaboration with General Electric Healthcare, features several experiments with this controller in the context of medical imaging. Using external sensors it is shown that it is possible to realise tasks in an optimal way while limiting the robot dangerousness in case of an undesired contact.