A portable exercise device provided includes: a base disc, two pulley assemblies, a support plate, and a fan wheel assembly. A support plate is disposed on the base disc, the two pulley assemblies are provided on the base disc, and the fan wheel assembly is provided on the support plate, so that the fan wheel assembly and the two pulley assemblies are vertically arranged on top of each other, thereby reducing the overall volume. More preferably, because the volume is reduced, the user can arbitrarily move and hang the portable exercise device at the desired position, and because the portable exercise device of the invention can be hung at different positions, which allows the user to train different muscles according to the different positions.

Disclosed is a technical training garment configured for use with modular, interchangeable electronics and resistance modules. The garment provides resistance to movement throughout an angular range of motion and tracks biomechanical parameters such as stride length, stride rate, angular velocity and incremental power expended by the wearer. The garment may be low profile, and worn by a wearer as a primary garment or beneath or over conventional clothing. Alternatively, the device may be worn as a supplemental training tool during conventional training protocols.

A mechanical braking system which can provide a brake to a self-powered treadmill, or a dual mode treadmill that can operate in both self-powered and motor-powered modes, that will rapidly halt the motion of the belt or rollers in the event of a power disconnect such as from the removal of a safety key.

In some embodiments, two or more different types of stator structures may be disposed within a gap of an axial flux machine. Such arrangements may be advantageous, for example, for producing a machine optimized for multiple modes of operation, such as mechanical torque generation, conversion of mechanical torque to electrical power, and/or dissipation of mechanical power. Further, in some embodiments, an axial flux machine may include a planar stator having a winding arranged to be positioned within the machine's active region, and may further include at least one switch configured to be selectively closed to establish an electrical connection between respective ends of the winding at a time that the winding is not coupled to an external power source

Exercise machine comprising a user force input element, for example a set of bicycle pedals, a transmission unit, an electric motor, and an electrical circuit connected to the electric motor. The user force input element is connected to the electric motor via the transmission unit such that said electric motor turns at an angular velocity which is different than the velocity or angular velocity of the user force input element and the motor runs as a generator such that when the electric motor is turned, an electrical current is developed in the electrical circuit. The electrical circuit comprises an electrical resistor, a switching element, a Pulse Width Modulation (PWM) controller, and a load reference controller. The electrical resistor is connected to the electric motor via the switching element such that when the switching element is switched on and off, the electrical resistor is electrically connected and disconnected from the electric motor. The switching element is controlled via the PWM controller to change the time the resistor is connected to the motor. The PWM controller has a switching frequency greater than or equal to 200 Hz. The load reference controller controls the PWM controller by sending a load reference to the PWM controller, said load reference controller having a sampling frequency of greater than or equal to 200 Hz. In this way, a flexible, efficient an fast controlled load can be provided to an exercise machine.

A treadmill includes a treadmill frame having a front end and a rear end opposite the front end; a front running belt pulley coupled to the treadmill frame at or near the front end; a rear running belt pulley coupled to the treadmill frame at or near the rear end; a running belt disposed about the front and rear running belt pulleys, the running belt adapted for rotation about the front and rear running belt pulleys and defining a non-planar running surface; and a brake coupled to the running belt and adapted to selectively restrict the speed of rotation of the running belt depending upon an established limit for the speed of the running belt.

A resistance exercise system having, in certain embodiments, a DC power supply system, a DC motor connected to the DC power supply system, a drive section connected to a drive element, a resistance delivery element connected to the drive element, and an extractable exercise resistance delivery section, a predetermined variable resistance section intermediate the DC power supply system and DC motor, an electrical condition sensor, and a variable resistance section control in communication with the electrical condition sensor and the predetermined variable resistance section. In some embodiments, the resistance exercise system includes a computing facility providing the ability to configure the exercise system to provide predetermined static or variable exercise resistance during exercise, and for example, during a positive or negative exercise stroke. Some embodiments allow users to create and, if desired, display varying and complex resistance exercise routines with or without use of resistance weights.

A computer-implemented system for an exercise machine includes a mechanical energy storage device and an apparatus configured to supplement the resistance of the mechanical energy storage device with an added resistance and dissipate the energy of the mechanical energy storage device and an associated athlete. A communication pathway enables the exercise machine to communicate with at least one additional associated exercise machine to duplicate the total resistance in the exercise machine to an associated exercise machine. A central server includes a processor, memory, and a networking interface. A first user device includes a display, a processor, a memory, and a networking interface. The central server receives data from the exercise machine, extracts synchronization performance information from the data, and transmits the synchronization performance data to the first user device where it is used to train an athlete for an athletic endeavor.

This disclosure relates to a torque sensing system. The torque sensing system comprises a rotatable shaft (102) having a first part and a second part, the shaft comprising a spring structure (122) between the first and second part; a first readout structure (130) connected to the first part, the first readout structure (130) comprising first position indicators, and a second readout structure (132) connected to the second part, the second readout structure (132) comprising second position indicators; a detector system for detecting the first and second position indicators and generating a first detection signal indicating respective passing times for the first position indicators and a second detection signal indicating respective passing times for the second position indicators; and a processor. The processor is configured for determining an angular position of the first readout structure (130) occurring at a particular time instance based on a detected passing time of at least one first position indicator on the first readout structure (130) and on a first relation between angular position of the first readout structure (130) and time around said particular time instance; and determining an angular position of the second readout structure (132) occurring at the particular time instance based on a detected passing time of at least one second position indicator on the second readout structure (132) and optionally based on a second relation between angular position of the second readout structure (132) and time around said particular time instance; and, determining an angle of twist at the particular time instance based on the angular position of the first readout structure (130) and the angular position of the second readout structure (132), the angle of twist being associated with a torque applied to the first and/or second part of the rotatable shaft (102).

A weight training equipment includes: a base frame that sits on the ground; a chair provided on the upper portion of the base frame and on which an exercising person may sit; first and second exercise bars that are hinge-coupled to both sides of the front of the chair and formed so as to be pushed or pulled forward and backward by the exercising person; a weight part providing weight and composed of a connection bar, which is connected to one side of the first and second exercise bars, and a weight member formed on the connection bar; and a torsion angle adjusting means for adjusting the torsion angle by rotating the first and second exercise bars.