A programmable range of motion system has a frame, a range of motion device, a controller, a computer and sensors. The frame has a seat to support a rehab patient. The range of motion device is attached to the frame. The actuator, servo or alternate mechanism selectively rotates the range of motion device through a range of motion for a rehab patient's limb. The controller controls the actuator, servo or alternate mechanism. The computer is connected electronically to the controller. The computer has a software, program or application including a plurality of programmable range of motion movements for exercising the limb. The sensor detects movements of the actuator, servo or alternate mechanism and records data back to the computer. The term actuator as used hereafter includes servo or alternate articulating mechanism.

Provided is a chest expander including a pair of operational arms having upper ends rotatably coupled to a head and moving to approach or be spaced apart from each other and a pair of gas springs disposed crosswise between the pair of operational arms. In the operational arm, a longitudinal hole configured to guide one end of the gas spring to move are formed. A guide coupled to the one end of the gas spring are arranged in the longitudinal holes. A Holding device holds the guide at a selected position. Intensity of elastic force provided by the gas spring is adjustable by adjusting a position of the one end of the gas spring.

The invention relates to a rehabilitation device adapted for rehabilitation and/or exercise of the shoulder region, the device being provided with a frame (1), which is connected to a power-generating apparatus (2), a back part (10), a seat part (11), and armrests (21). The rehabilitation device according to the invention is characterised in that it further comprises first support arms (23), second support arms (24), and motion arms (22), which communicate with said corresponding first and second support arms. The rehabilitation device according to the invention is further characterised in that said armrests (21) are articulated in said corresponding motion arms (22), and said power-generating apparatus (2) communicates with said motion arms (22). In addition, the invention relates to the use of the rehabilitation device for exercising the shoulder region.

A weight arm assembly for use with a weight lifting rack is provided, the weight arm assembly including a mounting bracket configured to be attached to a vertical surface in a fixed position, an arm mount configured to be coupled to the mounting bracket so as to be pivotable about a first axis, a stop member coupled to the arm mount and configured to move between an engaged position to prevent pivoting of the arm mount through interaction with the mounting bracket, and a disengaged position to allow pivoting of the arm mount, and a weight arm configured to be coupled to the arm mount, proximate a first end of the weight arm, so as to be pivotable about a second axis substantially orthogonal to the first axis.

An exercising assembly for fitness training and rehabilitation includes a first base, which is positionable on a substantially horizontal surface. An engagement module is selectively engageable to the first base so that the engagement module is positioned proximate to a first end of the first base. A plurality of attachment elements is engaged to the first base, the engagement module, and to a plurality of tensioners. The attachment elements are selectively mutually couplable. A plurality of first interface elements is selectively engageable to the engagement module. Respective attachment elements of the plurality of attachment elements are engaged to each of the first interface elements. Respective tensioners thus are extendable between a respective first interface element and one or more of the first base and the engagement module. The respective tensioners provide resistance to the user moving the first interface elements.

A multi-functional sliding grip exercise device, specifically but not limited to: sliding grip medial pull-ups, sliding grip lateral pull-ups, lower back extension/sit-up assistance exercise. Exercise device will have rotatable rubber pegs attached to horizontal bars to aid in utility. Horizontal bars supporting hand grips will have apertures on its frame; apertures will take on the form of a “T” with arms going vertically down to engage device locking system. Horizontal bar with apertures will have tracks on top surface and bottom surface to support guidance of Hand grips. Horizontal bar with apertures will have a resistance element housed within, preferably but not limited to springs; also housed within bar will be spring caps with an protuberance attached that will make contact with Handgrips appendage to engage springs. Handgrips may have indentations to support lower back bar for lower back extension/sit-up assistance exercise. Device may have adjustable resistance.

A machine for exercising arms and shoulders and reducing abdominal fat. The machine includes a frame of curve shape. Straps extend from the ends of the frame for tightening the machine over the abdomen. The frame includes an upper rail, a middle rail, and a lower rail, the upper rail and middle rail form an upper track and the middle rail and lower rail form a lower track. An upper set of rollers are mounted in the upper track and an upper handle is coupled to the upper set of rollers. A lower set of rollers are mounted to the lower track and a lower handle is coupled to the lower set of rollers. The upper handle and the lower handle are grasped to pull and push the upper set of rollers and the lower set of rollers to roll back-and-forth in the upper track and the lower track respectively.

A weight arm assembly for use with a weight lifting rack is provided, the weight arm assembly including a mounting bracket configured to be attached to a vertical surface in a fixed position, an arm mount configured to be coupled to the mounting bracket so as to be pivotable about a first axis, a stop member coupled to the arm mount and configured to move between an engaged position to prevent pivoting of the arm mount through interaction with the mounting bracket, and a disengaged position to allow pivoting of the arm mount, and a weight arm configured to be coupled to the arm mount, proximate a first end of the weight arm, so as to be pivotable about a second axis substantially orthogonal to the first axis.

An exercise machine for reducing abdominal fat as well as exercising the arms and shoulders. The exercise machine includes a frame that can be of a curved shape to conform to the curves of the abdomen. Straps extend from the ends of the frame for tightening the exercise machine over the abdomen. The frame includes an upper rail, a middle rail, and a lower rail, wherein the three rails run horizontally and parallel to each other along the length of the frame. The upper rail and the middle rail form an upper track and the middle rail and the lower rail forms a lower track. An upper set of rollers are mounted in the upper track and an upper handle is coupled to the upper set of rollers. Similarly, a lower set of rollers can be mounted to the lower track and a lower handle is coupled to the lower set of rollers. The upper handle and the lower handle can be grasped to pull and push the upper set of rollers and the lower set of rollers to roll back-and-forth in the upper track and the lower track respectively.

Provided herein are devices and methods for analysis and/or exercise of a body region of a subject. Such devices may include a guide arm supported by a support frame; a receiving surface supported by the guide arm, the receiving surface for receiving input force from the subject; and a motor assembly in communication with the guide arm, the motor assembly controlling movement of the receiving surface based on received input force. Exercise and/or analysis methods described herein may include steps of instructing the subject to apply an input force to a receiving surface; sensing the applied input force over time; and controlling movement of the receiving surface based on the received input force using a motor assembly, whereby the motor assembly moves the receiving surface in a pre-determined direction, so long as the input force remains within an allowable tolerance, until a pre-set end position is reached.