A device and method that simulates the squatting position for bowel evacuation while sitting on a toilet.

A device and method that simulates the squatting position for bowel elimination while still sitting on a toilet.

A far infrared rolling back healthcare massage device is provided for a user to perform a flexing and extending movement by leg squatting and rising and to back-massage, acupuncture and moxibustion with noninvasive and painless therapy by self-help at the same time, which includes a rolling back apparatus including an upper supporter and a lower supporter spacedly mounted by a support frame, an elongated rolling back massage stem securely and vertically supported between the upper supporter and the lower supporter for the user to perform a flexing and extending movement by leg squatting and rising with the back of the user touching and pushing rearwards against the massaging arrangement, and a far infrared ray generator which is arranged in the rolling back massage stem and configured to generate at least one far infrared ray radiating towards a treatment space around the rolling back massage stem.

A modular passive-to-active exoskeleton system utilizes motor unit modules, an electromagnetic-clutch power transmission system, and biometric control. The passive exoskeleton has a stamina-increasing chairless chair function and optional use of magnetic ball-and-socket joints and knee torsion springs. To convert the exoskeleton system into an active robotic wearable device, modular attachments allow for motor units to be securely connected to the exoskeletal frame. An exoskeleton system may contain a knee motor unit that has a transmission system with an electromagnetic clutch that enables a passive mode, active mode, and/or hybrid mode. The motor units are controlled using wireless biometric motion sensors that measure limb joint angle and muscle activity. These motor units also communicate via wireless transmission with a central processing unit of the exoskeleton. This central processing unit serves as a gateway for user feedback from an Internet-of-Things (IoT) device, such as a smartphone, tablet, computer, etc.

Presented are wearable sensor systems for monitoring user movement, methods for making/using such systems, exoskeletons employing such systems, and wireless-enabled wearable sensor devices for performing biometric measurements. A sensor system for monitoring movement of a user includes a wearable sensor device that is communicatively connectable to a sensor linking node. The sensor linking node wirelessly receives sensor data from the wearable sensor device and wirelessly communicates the received sensor data to a remote computing node. The wearable sensor device includes an expandable device body, such as an elastic compression sleeve or an adjustable strap, that is worn on an appendage of the user. The device body includes a mounting interface, such as mating hook-and-loop fastener pads, that removably mounts thereon a biometric sensor core (BSC) unit. The BSC unit contains a microcontroller assembly that is integral with a microcontroller device, a biometric sensor array, and a wireless communication device.

The present disclosure provides an exoskeleton mechanism for supporting a joint. The exoskeleton mechanism includes a brace having a first arm and a support arm, the support arm pivotably connected to the first arm. The exoskeleton mechanism further includes a spring secured to the first arm, the spring having a first length at an equilibrium position and a second length at a displaced position, a spring force generated by the spring when the spring is in the displaced position. Additionally, the exoskeleton mechanism has a cable having a first end and a second end, the first end coupled to the support arm and the second end coupled to the spring such that rotation of the support arm relative to the first arm causes the spring to move to the displaced position and the spring force is transferred to the support arm.

A modular passive-to-active exoskeleton system utilizes motor unit modules, an electromagnetic-clutch power transmission system, and biometric control. The passive exoskeleton has a stamina-increasing chairless chair function and optional use of magnetic ball-and-socket joints and knee torsion springs. To convert the exoskeleton system into an active robotic wearable device, modular attachments allow for motor units to be securely connected to the exoskeletal frame. An exoskeleton system may contain a knee motor unit that has a transmission system with an electromagnetic clutch that enables a passive mode, active mode, and/or hybrid mode. The motor units are controlled using wireless biometric motion sensors that measure limb joint angle and muscle activity. These motor units also communicate via wireless transmission with a central processing unit of the exoskeleton. This central processing unit serves as a gateway for user feedback from an Internet-of-Things (IoT) device, such as a smartphone, tablet, computer, etc.

Presented are wearable sensor systems for monitoring user movement, methods for making/using such systems, exoskeletons employing such systems, and wireless-enabled wearable sensor devices for performing biometric measurements. A sensor system for monitoring movement of a user includes a wearable sensor device that is communicatively connectable to a sensor linking node. The sensor linking node wirelessly receives sensor data from the wearable sensor device and wirelessly communicates the received sensor data to a remote computing node. The wearable sensor device includes an expandable device body, such as an elastic compression sleeve or an adjustable strap, that is worn on an appendage of the user. The device body includes a mounting interface, such as mating hook-and-loop fastener pads, that removably mounts thereon a biometric sensor core (BSC) unit. The BSC unit contains a microcontroller assembly that is integral with a microcontroller device, a biometric sensor array, and a wireless communication device.