A treadmill includes a deck having a continuous track, and a plurality of slats fixedly connected to the track. The treadmill also includes a first post extending from the deck, a second post extending from the deck opposite the first post, and a first arm supported by the first post and including a first rotary control. The treadmill further includes a second arm opposite the first arm and supported by the second post. The second arm includes a second rotary control separate from the first rotary control. The first rotary control is configured to control a first function of the treadmill and the second rotary control is configured to control a second function of the treadmill different from the first function.

A cordless treadmill including a frame, a belt system. and a drop-in cartridge is disclosed. The cartridge includes a plurality of staggered rollers configured to provide tactile feedback to the user. The frame is adapted to receive the belt system and the cartridge as they are lowered into the frame, and the frame is adapted to place the belt of the belt system into tension as the belt system is lowered into the frame. An integrated flywheel generator system provides smooth operation of the treadmill and generates electricity to power additional systems.

In various embodiments, provided herein are systems, methods, processes, and devices for providing locomotive rehabilitation to a subject via one or more gait motions that substantially accurately mimic motions performed in healthy, natural gait cycles. The system may mimic natural gait motions via footplates and handles, and one or more linkage systems. In particular embodiments, the system may further include a motor unit and/or clutch for providing controlled forces assisting or resisting motions of a linkage system. Further, the system may include a tower for operating in a standing or seated position. In at least one embodiment, the system includes a body weight support system that provides offloading forces to a subject.

A system for controlling use of an exercise course by a person in a climbing park has a guiding element, which extends along a longitudinal direction and along which a person can move between a connecting section of the guiding element and a disconnecting section of the guiding element. A securing device is movably attachable along the guiding element between the connecting section and the disconnecting section. The securing device is connectable to the guiding element in the connecting section and is disconnectable from the guiding element in the disconnecting section. An identification device is configured such that, by the identification device, at least a connecting of the securing device within the identification section is identifiable, such that an occupancy of the guiding element with another person is identifiable therewith. An actuating device of the securing device is controllable with the identification device, such that the actuating device of the securing device is adjustable in a clearance position and, upon identification of the occupancy of the guiding element by another person, in a blocking mode. The actuating device of the securing device is coupled with the securing device, such that, in the blocking mode, a connecting of the securing device in the connecting section and/or a displacing of the securing device along the guiding element is blocked.

A motor resistance control structure for an exercising apparatus comprises a motor, a drawing member, a control unit, and a sensing element. The control unit controls the motor to generate a resistance and outputs a first instruction to allow an output shaft to rotate by a first present revolution along a first sense of rotation. The drawing member receives an applied force and pulls the output shaft to rotate by a training revolution along the first sense of rotation. The sensing element senses the applied force and gets a sensing result. By the comparison of the applied force with the resistance, the control unit controls the output shaft to rotate by a second preset revolution along a second sense of rotation or release the resistance of the motor, which avoids a problem in an ordinary exercising apparatus that a counterweight may fall freely to injure a user.

A soft-inflatable exosuit for knee rehabilitation is fabricated in two different beam-like structures (I and O cross-section actuators) and mechanically characterized for their torque performance in knee-extension assistance. The fabrication procedure of both types of actuators is presented as well as their integration into a light-weight, low-cost and body-conforming interface. To detect the activation duration of the device during the gait cycle, a soft-silicone insole with embedded force-sensitive resistors (FSRs) is used. In evaluation studies, the soft inflatable exosuit device is tested for its ability to reduce muscle activity during the swing phase of the knee. Using sEMG (surface electromyography) sensors, the rectus femoris muscle group of a healthy individual is recorded while walking on a treadmill at a constant speed, with and without the soft device.

A treadmill system includes a deck, an endless tread belt covering at least a portion of the deck, a position sensor that senses a position of a user when the user is on the tread belt, and a control module that adjusts a speed of the tread belt in response to an output of the position sensor.

A stair exerciser apparatus includes a frame having a pair of inclined supports, a drive mechanism, and a plurality of stairs coupled to the drive mechanism for traveling around the pair of inclined supports. The driving mechanism has an upper shaft, a lower shaft and at least one drive chain mounted around the upper shaft and the lower shaft. A clutch mechanism is coupled to the upper shaft or the lower shaft of the drive mechanism. A flywheel is operationally coupled to the clutch mechanism, where the clutch mechanism couples the motion of the stairs to the rotation of the flywheel when the stairs are driven in a downward direction, and where the clutch mechanism decouples the motion of the stairs from the rotation of the flywheel when the stairs cease to be driven in the downward direction.

A brake controller for spinner bikes has a frame body engaging a pair of connecting pieces, a shaft engaging a first block through a top end thereof and a second block through a bottom end thereof, and a magnetic encoder that has a PCB with coding circuit for detecting rotation of a magnet disposed under the second block. Thereby the brake controller controls two kinds of braking forces by a single button for spinner bikes.

A tower may support a horizontal track and a vertical climbing wall therebelow. A trolley, movable along the track, may be selectively driven toward and away from the tower by belay lines, line and capstan, positive drive, or some combination. Belay lines reeved over pulleys on the trolley may be taken up and paid out independently from the trolley, while fixed or moving. A rider may climb, be lifted, or both to near the intersection of the tower and track, from there to fall or jump into a controllable trajectory such as swinging or simulating a parachute landing. Swinging may be rapidly attenuated almost entirely by “bumps,” lifting a rider to remove momentum and kinetic energy as a rider moves toward a pivot point overhead. Control may be simplified based on sensing and using timing past bottom dead center (BDC).