A joint device of an orthosis or prosthesis or for an orthosis or prosthesis with an upper part, a lower part, a joint that comprises a joint axis, about which the upper part is mounted such that it can be swivelled relative to the lower part, and an actuator, which is designed to influence a swivelling of the upper part relative to the lower part. The actuator is mounted at an upper part fixing point on the upper part and at a lower part fixing point on the lower part. At least two joints are arranged between the upper part fixing point and the lower part fixing point, wherein the joints enable a swivelling of the actuator relative to the upper part fixing point and the lower part fixing point, and the joints each form at least one joint axis, at least one of which is not oriented parallel to the joint axis.

An active suspension system with body wearable device integration is disclosed. The system includes a prosthetic having a shock assembly with at least one active valve and a controller communicatively coupled with the at least one active valve of the shock assembly, the controller configured to communicate damping adjustment information to the at least one active valve of the shock assembly, the damping adjustment information used by said at least one active valve to modify a damping characteristic of the shock assembly.

Methods, devices, and systems are described for a foot suspension system configured to offload weight from a foot of a user. The foot suspension system includes a boot shaped to receive at least a part of the foot of the user, the boot including a bottom inner surface. The foot suspension system further includes a sleeve configured to secure to a lower appendage of the user to assist with suspending at least the part of the foot above the bottom inner surface of the boot. The foot suspension system further comprises at least one vertical bar with a first end positioned adjacent to the boot and a second end of the at least one vertical bar positioned

A robotic joint comprises a first link, a middle link, a torque generator, a second link, and a locking mechanism. Different ends of the middle link are rotatably coupled to the first link and the second link. The torque generator is coupled to the first link and the middle link and is configured to produce torque between these links. The locking mechanism is switchable between a locking state and an unlocking state. In the unlocking state, the locking mechanism allows free rotation of the second link relative to the middle link in the first and second rotation directions. In the locking state, the locking mechanism is configured to impede rotation of the second link relative to the middle link in the first rotation direction and to allow rotation of the second link relative to the middle link in the second rotation direction opposite of the first rotation direction.

Embodiments herein discloses an orthotic knee control device providing ease of movement. The orthotic knee control device includes a hydraulic piston connected with a hydraulic chamber, accumulator spring(s) connected with an accumulator chamber, a non-return valve connected in between the hydraulic chamber and the accumulator chamber. The non-return valve allows the flow of an oil from the accumulator chamber to the hydraulic chamber and does not allow the flow of the oil from the hydraulic chamber to the accumulator chamber. Further, the orthotic knee control device includes a motorized valve connected between the hydraulic chamber and the accumulator chamber. Further, the accumulator springs apply pressure to the hydraulic piston, to resist flexion of a knee joint and to aid extension of the knee joint.

A powered orthotic device for use with a limb having at least two joints includes at least two brace sub-assemblies. The first brace sub-assembly includes a first powered actuator assembly that receives a first sensor signal from a sensor selected from a group consisting of an electromyographic sensor, an inertial measurement unit, and combinations thereof. The first powered actuator assembly applies a first force for driving sections positioned with respect to a first joint to move relative to one another. The second brace sub-assembly includes a second powered actuator assembly that is configured to receive a second sensor signal from a sensor selected from a group consisting of an electromyographic sensor, an inertial measurement unit, and combinations thereof. The second powered actuator assembly applies a second force for driving sections positioned with respect to a second joint to move relative to one another. The first force and the second force are based on the first sensor signal or the second sensor signal.

Various orthotic joint devices, components, and methods are provided. These include orthotic joint alignment devices for adjusting a neutral or fixed angle of an orthotic joint device independently of other parameters, orthotic joint devices providing staged resistance through staged recruitment of separate springs or initiation of staged spring-rate behavior of a single spring retained in a joint body, adapters for converting non-staged resistance orthotic joint devices into orthotic joint devices, and low-noise orthotic joint devices with intermittent normal force-transmitting contact associated with resistive or assistive forces provided by the devices, and methods of using the devices and components.

A robotic joint comprises a first link, a middle link, a torque generator, a second link, and a locking mechanism. Different ends of the middle link are rotatably coupled to the first link and the second link. The torque generator is coupled to the first link and the middle link and is configured to produce torque between these links. The locking mechanism is switchable between a locking state and an unlocking state. In the unlocking state, the locking mechanism allows free rotation of the second link relative to the middle link in the first and second rotation directions. In the locking state, the locking mechanism is configured to impede rotation of the second link relative to the middle link in the first rotation direction and to allow rotation of the second link relative to the middle link in the second rotation direction opposite of the first rotation direction.

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 joint for an orthopedic device which has a first articulated arm and a second articulated arm, which are mounted about a swivel axis such that they can be swiveled relative to one another, and a blocking device which can be moved into a release position and a blocking position. The blocking device, when in the blocking position, blocks the swiveling of the first articulated arm relative to the second articulated arm in the first swivel direction, independently of a swivel angle between the first articulated arm and the second articulated arm, insofar as the swivel angle is in a predetermined range, and allows the swiveling in the first swivel direction, insofar as the swivel angle is outside of the predetermined range.