A direct-drive bicycle training system and methods of using the same are provided. The system includes a bicycle trainer that rests on a support surface and supports a bicycle frame in an upright manner with respect to the support surface. The bicycle trainer includes a stator, a rotor that rotates with respect to the stator, a cassette affixed to the rotor, a support frame supporting the stator, rotor, and cassette, and a resistance applying mechanism that operatively couples to a portion of a drivetrain of the bicycle frame and applies varying levels of resistance to the portion of the drivetrain. The support frame moves with respect to the support surface in response to a force applied to the drivetrain of the bicycle frame during use of the bicycle training system, generating a more natural movement of the bicycle and simulating on-road use.

An exercise apparatus includes a linear arm portion having an elongate arm member with proximal and distal ends and an elongate support member having proximal and distal ends. The arm member can be slidably mounted to the support member by a sliding joint. A linear arm brake assembly can be coupled to the arm member for resisting linear motion of the arm member. A torso portion can be included to which the linear arm portion is rotatably mounted about a second axis by rotary shoulder joint. The linear arm portion can be configured, and the rotary shoulder joint can be positioned along the length of the support member at a location that substantially balances the linear arm portion about the rotary shoulder joint at least when the arm member is in the retracted position.

Disclosed is a climbing machine including a rotatable rotation shaft (501), a plurality of one-way components (502) capable of achieving one-way transmission, a plurality of transmission units (503) and a plurality of climbing points (300, 400), where the one-way components (502) are connected to the rotation shaft (501) in a sleeving manner, each transmission unit (503) is connected to one climbing point (300, 400), and each transmission unit (503) and the rotation shaft (501) form one-way transmission by means of being connected to one one-way component (502); in one rotating direction, the rotation shaft (501) and the transmission units (503) are capable of being in transmission, and the climbing points (300, 400) descend during transmission; and in the direction opposite to the rotating direction, transmission between the rotation shaft (501) and the transmission units (503) cannot be achieved. By using the climbing machine, a user can experience a vivid feeling of climbing upwards, thereby improving the climbing experience.

A magnetic resistance and brake control structure includes a sleeve, a rotating member, a compound operating member, a movable shaft, and a cable. The rotating member is coaxially disposed in the sleeve in an axial direction, and is rotatable relative to the sleeve. The rotating member has an axial guide groove extending in the axial direction. The rotating member includes an exposed portion extending out of the sleeve. The compound operating member passes through the rotating member coaxially, and is movable relative to the rotating member in the axial direction. The movable shaft is connected to an operating lever, and is movable along the axial guide groove or drives the rotating member to rotate synchronously through the axial guide groove. The cable has a first end that is directly or indirectly fixed to the exposed portion.

A weight training sled having (i) a chassis, (ii) longitudinally spaced rotatable wheels in contact with ground, (iii) a pair of laterally spaced push handles proximate a first longitudinal end of the chassis and (iv) a brake for applying resistance to one of the wheels, characterized by an elevated tow hook.

A reciprocating unidirectional electromagnetic resistance device includes a shaft having a flywheel installed to a first end of the shaft, an electromagnetic braking unit, and a first sensing device. A spring return device and a second sensing device are installed at a second end of the shaft, and a pull rope device is installed at the middle of the shaft. The electromagnetic braking unit and the spring return device are integrated into a single module and provided for an operator to perform a reciprocating motion to pull out a pull rope of the pull rope device and drive the shaft, the flywheel and the spring return device synchronously, and the electromagnetic braking unit acts an electromagnetic resistance onto the flywheel, so that the flywheel has the excellent precise resistance of the electromagnetic braking unit. When released, the pull rope can be retracted to achieve the reciprocating motion effect.

A direct-drive bicycle training system and methods of using the same are provided. The system includes a bicycle trainer that rests on a support surface and supports a bicycle frame in an upright manner with respect to the support surface. The bicycle trainer includes a stator, a rotor that rotates with respect to the stator, a cassette affixed to the rotor, a support frame supporting the stator, rotor, and cassette, and a resistance applying mechanism that operatively couples to a portion of a drivetrain of the bicycle frame and applies varying levels of resistance to the portion of the drivetrain. The support frame moves with respect to the support surface in response to a force applied to the drivetrain of the bicycle frame during use of the bicycle training system, generating a more natural movement of the bicycle and simulating on-road use.

An embodiment of the present invention provides a moving bike device including: a memory configured to store distance information and altitude information; a content implementation unit configured to adjust a reproduction state of content in response to a speed of a wheel depending on pedaling of a user; a controller configured to calculate a road slope from the distance information and the altitude information, and to calculate a travel distance depending on the pedaling of the user; and a road slope implementation unit configured to adjust strength of a brake in proportion to the road slope corresponding to the travel distance.

An exoskeleton fitness device, particularly for exercising a human body, comprises a wearable structure having at least one fastening member, the at least one fastening member configured to fasten the wearable structure to a user's body, at least one mechanical joint having at least one axis of rotation and at least one degree-of-freedom, the at least one mechanical joint fastened to the wearable structure, at least one unit for generating a rotational resistance that counteracts a rotational movement of the at least one mechanical joint, and a controller for controlling the rotational resistance, wherein the controller is configured to control the rotational resistance according to a user setting.

An exercise apparatus includes a linear arm portion having an elongate arm member with proximal and distal ends and an elongate support member having proximal and distal ends. The arm member can be slidably mounted to the support member by a sliding joint positioned at the distal end of the support member. The arm member can be movable along a first axis between retracted and extended positions. The sliding joint can include first and second bearing assemblies which are spaced apart a sufficient distance from each other for constraining portions of the arm member within the sliding joint. The proximal end of the arm member that overlaps with the support member outside of the sliding joint when in retracted positions can be capable of some unconstrained lateral movement relative to the first axis. A linear arm brake assembly can be coupled to the arm member for resisting linear motion of the arm member. A torso portion can be included to which the linear arm portion is rotatably mounted about a second axis by rotary shoulder joint. The linear arm portion can be configured, and the rotary shoulder joint can be positioned along the length of the support member at a location that substantially balances the linear arm portion about the rotary shoulder joint at least when the arm member is in the retracted position.