A method of mechanical-to-electrical energy conversion utilizes a mechanical spring in combination with a rapid-action variable inductance magnetic flux switch to convert a spring-loaded mechanical energy into a change in magnetic flux captured by an electrical coil element within the magnetic flux switch. The change in coil inductance and magnetic flux induces a current to flow through the electrical coil in the form of a a pulse of electrical energy that may be stored. The electrical coil is coupled to the mechanical spring so that each time the spring is released, the coil moves with respect to a magnetic core and a change in flux is created. The application of an external mechanical force (such as human locomotion) functions to compress and subsequently unlock the mechanical switch, allowing for the electrical energy associated with the application of aperiodic forces to be harvested.

Exemplary embodiments relate to techniques for supplying increased power to an augmentation device without increasing battery size. For example, the load may be a motor that provides augmentation power to a joint of a prosthetic ankle, and which is generally powered by a battery. A reconfigurable electrical circuit may connect a supercapacitor in series with the battery to boost the power from the battery at times when a pulse of increased power is demanded. For instance, states of one or more switches of the electrical circuit may be changed in order to briefly disconnect the motor from the circuit just prior to a powered plantarflexion phase of a gait cycle of the ankle, and then to reconnect the motor to a reconfigured circuit to provide a power boost. The circuit may also be reconfigured to allow the battery to recharge the supercapacitor during periods of nominal power demand.

A system for powering a prosthetic arm is disclosed. The system includes at least one internal battery located in the prosthetic arm, at least one external battery connected to the prosthetic arm, and a master controller configured to connect either the at least one internal battery or the at least one external battery to a power bus to power the prosthetic arm.

A prosthetic ankle includes a pair of prosthetic members movably coupled together to allow movement of the pair of prosthetic members with respect to one another. A hydraulic actuator or damper including hydraulic fluid in a hydraulic chamber is coupled to one of the pair of prosthetic members. A hydraulic piston is movably disposed in the hydraulic chamber and coupled to another of the pair of prosthetic members. A hydraulic flow channel is fluidly coupled between opposite sides of the chamber to allow hydraulic fluid to move between the opposite sides of the chamber as the hydraulic piston moves therein. A voice coil valve is coupled to the hydraulic flow channel to vary resistance to flow of hydraulic fluid through the flow channel, and thus movement of the piston in the chamber, and thus influencing a rate of movement of the pair of prosthetic members with respect to one another.

A method of mechanical-to-electrical energy conversion utilizes a mechanical spring in combination with a rapid-action variable inductance magnetic flux switch to convert a spring-loaded mechanical energy into a change in magnetic flux captured by an electrical coil element within the magnetic flux switch. The change in coil inductance and magnetic flux induces a current to flow through the electrical coil in the form of a a pulse of electrical energy that may be stored. The electrical coil is coupled to the mechanical spring so that each time the spring is released, the coil moves with respect to a magnetic core and a change in flux is created. The application of an external mechanical force (such as human locomotion) functions to compress and subsequently unlock the mechanical switch, allowing for the electrical energy associated with the application of aperiodic forces to be harvested.

A system for powering a prosthetic arm is disclosed. The system includes at least one internal battery located in the prosthetic arm, at least one external battery connected to the prosthetic arm, and a master controller configured to connect either the at least one internal battery or the at least one external battery to a power bus to power the prosthetic arm.

A method for controlling an orthopaedic joint device of a lower extremity. The joint device has an upper part and a lower part mounted in a hinged manner on the latter. Arranged between the upper part and the lower part is an energy converter by which, during walking, kinetic energy from the relative movement between the lower part and the upper part is converted or stored and supplied again to the joint in order to support the relative movement, wherein kinetic energy within one movement cycle is converted and/or stored and, within the same movement cycle, is supplied again as kinetic energy to the joint device in a controlled manner and staggered in time.

A series elastic robotic limb may include an energy generator, an energy storage element, and a link assembly. The link assembly may include a plurality of links coupled, via one or more joints, at one or more pivot locations. The energy generator may output a first force that causes an accumulation of energy in the energy storage element while the link assembly is in a first configuration and transitions the link assembly from the first configuration to a second configuration. The energy storage element may release the energy accumulated in the energy storage element when the link assembly is in the second configuration. The link assembly in the second configuration may trigger a motion of the series elastic robotic limb by at least amplifying the first force output by the energy generator and a second force associated with the energy released from the energy storage element.

A system for powering a prosthetic arm is disclosed. The system includes at least one internal battery located in the prosthetic arm, at least one external battery connected to the prosthetic arm, and a master controller configured to connect either the at least one internal battery or the at least one external battery to a power bus to power the prosthetic arm.

The invention relates to a method for controlling an orthopaedic joint device of a lower extremity. The joint device has an upper part (2) and a lower part (3) mounted in a hinged manner on the latter. Arranged between the upper part (2) and the lower part (3) is an energy converter (5) by which, during walking, kinetic energy from the relative movement between the lower part (3) and the upper part (2) is converted or stored and supplied again to the joint in order to support the relative movement, wherein kinetic energy within one movement cycle is converted and/or stored and, within the same movement cycle, is supplied again as kinetic energy to the joint device (1) in a controlled manner and staggered in time.