The present invention relates to exercise apparatus, and more particularly to variable resistance exercise apparatus.
While many exercise apparatus provide variable resistance for the user during an exercise session, there still remains a problem of exercising arms and legs with resistance in all phases, throughout a range of motion, with little resistance lag during transitions between phases.
Some apparatus use solid weights for resistance. However, these apparatus tend to be bulkier due to the size of the weight stacks employed. Likewise these apparatus have substantially more mechanical parts, which require regular maintenance and are prone to breakage.
As can be seen, there is a need for an improved hydraulic resistance exercise apparatus that provides a greater range of motion (though resistance may not be perfectly regular), with almost no interruption of loading when switching from one movement, or range of movement to the other.
In one aspect of the present invention, a hydraulic resistance exercise apparatus is disclosed. The hydraulic resistance exercise apparatus includes a frame adjustably supporting an upper drum body and a lower drum body. An arm bar is pivotally attached to the upper drum body and a leg bar is pivotally to the lower drum body. A seat is adjustably attached to the frame. A hydraulic vane cylinder is disposed in each of the upper drum body and the lower drum body. The hydraulic vane cylinder has at least one vane coupled to one of the arm bar and the leg bar, and one or more hydraulic channels. Operation of one of the arm bar and the leg bar urges a hydraulic fluid contained within the hydraulic vane cylinder under a resistance by passage of the hydraulic fluid through the one or more hydraulic channels.
In some embodiments, a seatback adjustably carried by the frame. A handle may be disposed at a distal end of the arm bar. An adjustable footrest disposed at a distal end of the leg bar.
In some embodiments, a gearbox assembly is coupled to the upper drum body and the lower drum body. The gearbox assembly is configured to provide a user selectable resistance to movement of one or more of the arm bar and the leg bar. The gearbox assembly may include one or more planetary gear assemblies having a plurality of planetary gears and a sun gear. A clutch selectively engages the one or more planetary gear assemblies.
In some embodiments, the vane cylinder comprises a plurality of in-line hydraulic vane cylinders. Each of the plurality of in-line hydraulic vane cylinders are selectively engageable to adjust the resistance of the hydraulic resistance exercise apparatus.
In other aspects of the invention, a hydraulic resistance exercise apparatus, is disclosed having a frame adjustably supporting at least one drum body. One of an arm bar and a leg bar are pivotally attached to the at least one drum body. A hydraulic vane cylinder is disposed in each the at least one drum body. The hydraulic vane cylinder has one or more hydraulic channels and at least one vane coupled to one of the arm bar and the leg bar, such that operation of one of the arm bar and the leg bar urges a hydraulic fluid contained within the hydraulic vane cylinder under a resistance by passage of the hydraulic fluid through the one or more hydraulic channels.
In some embodiments, a seat is adjustably supported by the frame. A seatback may also be adjustably supported by the frame.
In other embodiments, the hydraulic vane cylinder comprises a plurality of in-line hydraulic vane cylinders. Each of the plurality of in-line hydraulic vane cylinders are selectively engageable to adjust the resistance of the hydraulic resistance exercise apparatus.
In other embodiments, a gearbox assembly is coupled to the at least one drum body. The gearbox assembly is configured to provide a user selectable resistance to movement of one or more of the arm bar and the leg bar. The gearbox assembly may include one or more planetary gear assemblies having a plurality of planetary gears and a sun gear. The gearbox assembly may also include a clutch to selectively engage the one or more planetary gear assemblies.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following drawings, description and claims.
The following detailed description is of the best currently contemplated modes of carrying out exemplary embodiments of the invention. The description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating the general principles of the invention.
Broadly, embodiments of the present invention provides an apparatus and method for exercise that utilizes a variable hydraulic resistance mechanism that maintains muscle loading throughout a range of motion while utilizing the variable hydraulic resistance apparatus. By using a hydraulic liquid, such as water, to impart frictional resistance, the user will feel a load almost immediately after changing motion direction or selecting a desired range of motion.
As shown in reference to the drawings of
A seat assembly 14 includes a vertically adjustable seat 14d that is supported in an interior space within the surrounding frame 12a. The seat 14d is carried on an adjustment rod 14b that is telescopically adjustable relative to a seat adjustment outer cylinder 14a. A seat adjustment pin 14c may be removed to adjust a vertical position of the seat 14d. When a desired seat elevation is achieved, an adjustment pin 14c may be inserted through the outer cylinder 14a.
The hydraulic resistance apparatus 10 may also include a lower drum stabilizer assembly 16. The lower drum stabilizer assembly is configured to adjustably mount a lower drum body 16c within the frame 12a. A lower drum stabilizer tube 16a, extending from the base 12b, adjustably couples to a drum stabilizer rod 16b. The lower drum stabilizer assembly 16 may be adjusted to set a desired height of the lower drum body 16c so that it may be positioned relative to a user seated on the seat 14d. The lower drum body 16c has a pivot shaft 18d about which the hydraulic resistance vane drum of the lower drum body 16c pivots.
A body height adjustment assembly 18 is coupled to the frame 12a. The body height adjustment assembly 18 permits adjustment of the upper drum body 12c relative to the occupant seated on the seat 14d. The body height adjustment assembly 18 includes an outer cylinder arm 18a that is adjustably carried by the inner cylinder arm 18b. A body height adjustment pin 18c is received through the outer cylinder arm 18a and inner cylinder arm 18b. The upper drum body 16c has a pivot arm 18d about which the hydraulic resistance vane drum of the lower drum body 16c.
A backrest adjustment assembly 20 is coupled to the frame 12a at an aft end of the hydraulic resistance exercise apparatus 10 via an upper frame connector 20e. The backrest adjustment assembly 20 adjustably carries a backrest 20a within the frame 12a. The back rest 20a is carried on a backrest rod 20b that is adjustable relative to a backrest tube 20c. A backrest adjustment pin 20d retains the backrest rod 20b and the backrest tube 20c at a selected position to set the backrest 20a at a desired lateral displacement relative to the frame 12a and the seat 14d.
A proximal end of an arm bar 22 is coupled to the pivot shaft 18e of the upper drum body 12c. A hand grip 24 is disposed at a distal end of the arm bar 22. The arm bar is operable in a back and forth motion to enable the user to exercise their upper body and arms.
A proximal end of a leg bar 26 is coupled to the pivot arm 18d of the lower drum body 16c. A footrest 28 is adjustably attached to a distal end of the leg bar 26 via a slidable footrest adjustment 28a. Toe loops 30 extend above an upper surface of the footrest 28 to secure the wearer's toes while exercising their lower legs. The footrest 28 and leg bar 26 are operable in a back and forth motion to enable the user to exercise their legs.
A gear assembly 32 may be operatively coupled to each of the upper drum body 12c and the lower drum body 16c. The gear assembly 32 is configurable to adjust a resistance of the hydraulic resistance exercise apparatus 10. Each of a plurality of in-line hydraulic vane cylinders 50 are selectively engageable to adjust the resistance of the hydraulic resistance exercise apparatus. The gear assembly 32 may include a plurality of planetary gear sets 34, 36 comprised of a sun gear 34a and one or more planetary gears 34b, 36b. A driven variable gear cluster 36c may also be provided. A clutch 36a, such as a dog clutch, may be provided to allow the user to shift to select a planetary gear 36b from among one of the plurality of planetary gear sets 34, 36 to select a desired resistance while exercising.
As seen in reference to
Various non-limiting embodiments of the hydraulic vane cylinders are shown in reference to
As will be appreciated, differing frame 12a configurations and dispositions of the upper drum body 12c and the lower drum body 16c to target differing muscle groups and exercises. In the embodiment shown, the user can adjust one or more of the seat 14d, the back rest 20a, footrest 28, or the upper drum body 12c and lower drum body 16c to adjustably configure the hydraulic resistance exercise apparatus to the anthropomorphic measurements of the user and a desired exercise regimen.
Once adjusted the user can manipulate one or more of the arm bar 22 and the leg bar 26 to perform an exercise regimen. As indicated previously, operation of the arm bar 22 and the leg bar 26 against the resistance of the hydraulic fluid 44 contained within the hydraulic vane cylinders provides a convenient, contained workout system.
It should be understood, of course, that the foregoing relates to exemplary embodiments of the invention and that modifications may be made without departing from the spirit and scope of the invention as set forth in the following claims.
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