A system made up of multiple orthopedic components which are coupled to one another, having a first electronic and/or electric device which has a first supply terminal via which the first electric and/or electronic device can be supplied with energy and/or data from a charging station via a plug. At least a second electric and/or electronic device is provided on one of the components which has a separate, second supply terminal and/or a plug connection which can be coupled to the first electronic and/or electric device for transmitting energy and/or data via the first supply terminal or a separate plug connection.

A device for fixing two orthopedic components to one another includes a receiving element arranged on a first orthopedic component, which receiving element has a receptacle and includes a connecting element arranged on a second orthopedic component. The connecting element has a connector. The connector can be inserted into the receptacle and is coupled with the receiving element in a tensile force, compressive force, and torque-transmitting manner. At least one flow- and/or data-transmitting contact is arranged on the connecting element and the receiving element so as to correspond to one another, which form an electrical and/or data-transmitting connection with one another in a fixed state of the orthopedic components.

A system consisting of at least one orthopaedic component, having at least one stored energy source and multiple electrical and/or electronic devices, and at least one operator control device and/or feedback device, which is assigned to the electrical and/or electronic devices and is coupled to them.

A method for distributing a limited amount of electrical power from an energy source to a plurality of electrical loads includes sensing and/or encoding the available electrical power of the energy source, monitoring a power balance of the loads by sensing and/or encoding the drawn power in the individual loads, and reducing the drawn power in the loads if the available power is not sufficient for supplying all the loads with the required power.

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 supply system for at least one orthopedic technology component, which has at least one electronic and/or electrical device and has a supply connection and/or a radio device for receiving data and/or electrical energy. The supply system also includes a holder for the orthopedic technology component, which has a supply device, and which is compatible with the supply connection and/or the radio device, for supplying the orthopedic technology component with data and/or energy. The invention further relates to a system consisting of a supply system and an orthopedic technology device, and to a method for supplying the system with data and/or energy.

An orthopedic device with a hydraulic damping device, a valve with a valve seat and a valve body that is subjected to a closing force. The closing force is applied via a valve spring that is pre-loaded towards the valve seat. A fluid connection between the hydraulic damping device and the valve seat is provided. The valve features an adjustment device for adjusting the preload of the valve spring.

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 grasp control system assists an operator with a grasping movement task. A movement intention signal is monitored for a grasping movement muscle of the operator. A volitional operator input for the grasping movement task is identified from the movement intention signal. One or more movement motors are operated based on the volitional operator input to perform the grasping movement task as a chain of motion primitives, wherein each motion primitive is a fundamental unit of grasping motion defined along a movement path with a single degree of freedom.

A hand-held electromechanical surgical device is configured to selectively connect with a surgical accessory. The surgical device includes a power-pack, an outer shell housing, and a gasket. The power-pack is configured to selectively control a surgical accessory. The outer shell housing includes a distal half-section and a proximal half-section, the distal half-section and the proximal half-section together defining a cavity configured to selectively encase substantially the entire power-pack therein. The gasket is located between the distal half-section and the proximal half-section of the outer shell housing. The gasket is configured to create a seal between the distal half-section and the proximal half-section and to provide a sterile barrier between the power-pack and an outside environment outside the outer shell housing.