A mobile robot including a mobile base element and at least one multi-jointed manipulator, wherein the robot includes several telemedical devices. The invention also relates to a robot for performing a movement sequence together with a limb of a human with the help of a manipulator.

Upper arms are fixed to drive shafts of a pair of drive sources at or near respective left and right hip joints. The upper arms are coupled to an upper body trunk harness by first passive rotary shafts via third passive rotary shafts, and are mounted to a lower body trunk harness by a mounting device. Lower arms are fixed to drive source bodies, and are coupled to thigh harnesses by second passive rotary shafts via fourth passive rotary shafts. The first and second passive rotary shafts and third and fourth passive rotary shafts are angularly displaceable about axial lines in a lateral direction of the wearer and axial lines in an anteroposterior direction of the wearer, respectively. An acceleration/angular speed sensor fixed to the lower body trunk harness detects an acceleration of the body trunk in a vertical direction by landing of a foot.

A robotic assistant includes a wheeled base, a storage unit including drawers, a foldable arm connected to a top of the storage unit and including an end of arm tooling (EOAT) connected to a distal end of the foldable arm, an elevation mechanism positioned on the wheeled base and used to move the storage unit up and down, and a control system that receives command instructions. In response to the command instructions, the control system is configured to move the wheeled base, open or close the one or more drawers, actuate movement of the foldable arm and the EOAT to pick up and place external objects from/to a determined location, and control the storage unit to move up/down.

An automated nursing robot is disclosed, including a main body unit, a wastewater bucket, a clean water bucket, a water injection and wastewater discharge unit for discharging and flushing the wastewater bucket and adding water into the clean water bucket, a mobile base disposed under the wastewater bucket and clean water bucket for carrying both to move between the main body unit and the water injection and wastewater discharge unit, and a connecting side plate arranged on one side of the mobile base. The main body unit and the water injection and wastewater discharge unit are each equipped with a positioning and fixing plate. Each positioning and fixing plate is provided with a pipe joint A, and the connecting side plate is correspondingly provided with a pipe joint B, and the pipe joint A and the pipe joint B are mutually attracted and connected by a magnetic attraction assembly.

The disclosure relates to a lower limb structure, comprising: a hip joint assembly comprising a hip joint support, a hip joint driver fixed to the hip joint support, and a hip joint transmission handle driven by the hip joint driver; a thigh rod connected to the hip joint transmission handle and driven by the hip joint driver; a knee joint assembly comprising a knee joint fixing base, a knee joint driver fixed on the knee joint fixing base, and a knee joint transmission handle driven by the knee joint driver, wherein the knee joint fixing base comprises a sleeve and a connector which is connected to the knee joint driver, and the sleeve is slidably fixed on the thigh rod along an extension direction of the thigh rod; and a lower leg rod connected to the knee joint transmission handle and driven by the knee joint driver, wherein the thigh rod does not coincide with a line connecting centers of the hip joint driver and the knee joint driver, such that a movement range of the knee joint on the thigh rod regulator is larger. The disclosure also relates to an exoskeleton robot having the lower limb structure.

A robotic medical system can include a patient platform. The patient platform includes a tilt mechanism. The tilt mechanism can include a lateral tilt mechanism and a longitudinal tilt mechanism. The lateral tilt mechanism can include a tilt plate and a pivot housing. A linear actuator mounted on the tilt plate can apply a linear force to the pivot housing. The lateral tilt mechanism can also include a first linear guide that extends along a first axis, and the pivot housing can translate along the first linear guide. Application of the linear force to the pivot housing tilts the tilt plate by causing the pivot housing to translate along the first linear guide.

Upper arms are fixed to drive shafts of a pair of drive sources at or near respective left and right hip joints. The upper arms are coupled to an upper body trunk harness by first passive rotary shafts via third passive rotary shafts, and are mounted to a lower body trunk harness by a mounting device. Lower arms are fixed to drive source bodies, and are coupled to thigh harnesses by second passive rotary shafts via fourth passive rotary shafts. The first and second passive rotary shafts and third and fourth passive rotary shafts are angularly displaceable about axial lines in a lateral direction of the wearer and axial lines in an anteroposterior direction of the wearer, respectively. An acceleration/angular speed sensor fixed to the lower body trunk harness detects an acceleration of the body trunk in a vertical direction by landing of a foot.

An automated nursing robot is disclosed, including a main body unit, a wastewater bucket, a clean water bucket, a water injection and wastewater discharge unit for discharging and flushing the wastewater bucket and adding water into the clean water bucket, a mobile base disposed under the wastewater bucket and clean water bucket for carrying both to move between the main body unit and the water injection and wastewater discharge unit, and a connecting side plate arranged on one side of the mobile base. The main body unit and the water injection and wastewater discharge unit are each equipped with a positioning and fixing plate. Each positioning and fixing plate is provided with a pipe joint A, and the connecting side plate is correspondingly provided with a pipe joint B, and the pipe joint A and the pipe joint B are mutually attracted and connected by a magnetic attraction assembly.

A robotic medical system can include a patient platform. The patient platform includes a tilt mechanism. The tilt mechanism can include a lateral tilt mechanism and a longitudinal tilt mechanism. The lateral tilt mechanism can include a tilt plate and a pivot housing. A linear actuator mounted on the tilt plate can apply a linear force to the pivot housing. The lateral tilt mechanism can also include a first linear guide that extends along a first axis, and the pivot housing can translate along the first linear guide. Application of the linear force to the pivot housing tilts the tilt plate by causing the pivot housing to translate along the first linear guide.

Disclosed is a robotic mobile support system configured to autonomously follow a subject with impaired mobility from a close but safe distance behind the subject and react to movements of the subject's torso and upper body to provide dynamic support for the subject and stop the subject from falling. The system comprises a mobile base vehicle, a robotic arm installed on the mobile base vehicle, and a LIDAR sensor for detecting the distance to a subject and the direction/speed of the subject. The robotic arm comprises one or more adjustable rear and side soft supports configured to support the subject and stop the subject from falling. The system can also comprise an onboard computer configured to process LIDAR data to control the movement of the mobile base vehicle and the robotic arm to stop the subject from falling.