A weighted pivot arm apparatus attached to a weight rack component, comprising: a body having an upper end and a lower end and extending along longitudinal axis; an attachment point disposed on the body comprising at least one wing with a hole therethrough and wherein the attachment point is rotatably mounted to the weight rack component; and, an impact bumper disposed on a lower end of the body.

A pedal-type vibrational apparatus includes a seat body, a pedal assembly, a gear plate assembly, a drive assembly and an eccentric assembly, like a lever structure. By treading the pedal assembly, the gear plate assembly drives the drive assembly to rotate. The drive assembly is connected with the eccentric assembly. The user can fully exercise the muscles of the body during exercise, and the vibrational effect generated by the eccentric assembly can stimulate the acupuncture points of the body to improve the blood circulation. The left and right pedals can be treaded in turn to continuously drive a gear to rotate in the same direction so as to achieve the effect of acceleration and to enhance vibrations.

A peg (3) is placed on a peg board (2) by a subject. A detection unit (32) detects a contact state between a peg body (31) and a body portion of the subject. A signal transmission unit (33) transmits a signal indicative of a detection result from the detection unit (32).

A vibration elastic rope assembly includes a vibrating unit having a cylindrical shell and a vibrator disposed in the cylindrical shell, and an elastic unit having a connecting member mounted on the cylindrical shell of the vibrating unit and an elastic rope connected to the connecting member and detachably connected to a user's body or an exercise equipment. Thus, the user can perform a stretching exercise by using the elastic unit and a vibration exercise by using the vibrating unit.

A pulsatile resistive exerciser control system. The control system changes the resistance that a muscle feels in the millisecond time frame. The control systems comprising a stationary or elliptical bike having a drive belt secured to an electric alternator that is modified to allow for the modulation of the alternator output thereby allowing for the pulsation of resistance. The device can be set to exert a rapid increase in the resistance on the pedal at a specified point in the rotation of a stationary bike, or the gliding pedal of an elliptical bike, thus exerting a force on a specific muscle.

A vibrating fat eliminating device includes a vibrating mainbody, a chair body and a positioning unit. The vibrating mainbody includes a fixing notch and an upper surface, wherein the fixing notch is disposed on the upper surface. The chair body is detachably disposed on the vibrating mainbody and includes a supporting frame and a cushion, wherein the supporting frame is disposed on the upper surface, the cushion is disposed on the supporting frame, and the supporting frame includes a connecting portion having a through hole. The positioning unit passes through the through hole and is connected to the fixing notch correspondingly, wherein the chair body is detachably disposed on the upper surface via the positioning unit.

A vibrational rehabilitation device includes two drive assemblies, an eccentric assembly, and two half housings. Each drive assembly includes a driving wheel assembly and a driven wheel assembly. The driving wheel assembly has a driving wheel and a driving shaft. The driving shaft is mounted to a center of the driving wheel. A grip member is provided at one side of the driving shaft opposite the driving wheel. The driven wheel assembly includes a first driven wheel and a second driven wheel. The first driven wheel is connected with the driving wheel and driven by the driving wheel. The second driven wheel is coaxially disposed with the first driven wheel. The eccentric assembly includes two transmission wheels at two sides thereof and an eccentric block sandwiched between the two transmission wheels. The drive assemblies and the eccentric assembly are mounted in the housings.

A respiratory treatment device comprising at least one chamber, a chamber inlet configured to receive exhaled air into the at least one chamber, at least one chamber outlet configured to permit exhaled air to exit the at least one chamber, and an exhalation flow path defined between the chamber inlet and the at least one chamber outlet. A restrictor member positioned in the exhalation flow path is moveable between a closed position, where a flow of exhaled air along the exhalation flow path is restricted, and an open position, where the flow of exhaled air along the exhalation flow path is less restricted. A vane in fluid communication with the exhalation flow path is operatively connected to the restrictor member and is configured to reciprocate between a first position and a second position in response to the flow of exhaled air along the exhalation flow path.

A running device and method of using the device are disclosed. The device may include a moveable material within an inner chamber of the running device's housing. In operation, a running device may be held in each hand and the runner may thrust both hands downward prior to landing and quickly bring the devices to a vertical stop after landing. Bringing the devices to a vertical stop may cause the moveable material to collide with the housing and increase the force exerted by the runner on the ground. A delay component may delay the peak force exerted by the material against the housing so that the translation of that force to the ground coincides with the peak force that the runner would have exerted against the ground in the absence of the devices.

An explosive strength training device is provided. The explosive strength training device includes a cable set, a power box, a resistance motor and a controller. The cable set includes a rubber belt and a movable pulley block connected with one end of the rubber belt, the movable pulley block has a first main pulley disposed opposite to the rubber belt, and allows the pulling force of the rubber belt to pass through the center of the first main pulley. Through the labor-saving structure of the first main pulley, the middle section of the power belt is wound on the upper side of the first main pulley and fixedly sleeved on the positioning rod with the fixed side to form a fulcrum.