STAIR STEP EXERCISE MACHINE

Abstract

A manual stair step exerciser that simulates the exercise derived from climbing stairs including a support frame with a chain sprocket assembly having multiple equal spaced deployable steps thereon. A drive shaft pulley and belt assembly interconnects to an adjustable magnetic resistant fly wheel for sustained user step input of kinetic energy for sustaining self-propelled tread induced motion during exercise.

Claims

1. An exercising stair step device comprising, an integral stationary frame having a pair of spaced parallel support legs, a pair of upstanding handrails with interconnecting support rail, an upper drive shaft and a lower drive shaft supported on respective bearing sets between said support frame legs, a pair of upper chain engagement sprockets on opposite ends of said upper drive shaft, a pair of lower chain engagement sprockets on opposite ends of said lower drive shaft, a pair of step drive chains, each chain extending around opposite ends of said upper and lower chain sprockets, a plurality of interconnected step assemblies connected between said chains, a flywheel drive shaft and support bearing assembly on and extending between said frame support legs in spaced relation to said upper chain drive shaft, a weighted flywheel on said flywheel drive shaft, pulleys on opposite ends of flywheel drive shaft, a sprocket and pulley assembly registerably engaged with one of said step drive chains, a drive belt in communication with the flywheel pulley, a drive belt engagement tensioner assembly on the upper drive shaft, a pair of electromagnetic resistant brake assemblies positionally engaged with the weighted flywheel for selective electronic activation via control input levers on said handrails.

2. The exercise stair step device set forth in claim 1 wherein said movable step assemblies, each comprise, a tread, a riser and interconnecting plate hinged there between.

3. The exercise stair step device set forth in claim 1 wherein said belt engagement tensioner assembly comprises, a belt pulley, a tensioning belt, and an adjustment idler pulley in communication with said tensioning belt.

4. The exercise stair step device set forth in claim 1 wherein said electromagnetic resistant brake assembly control input levers are in electronic communication with an electronic informational control and display on the handrail interconnecting support rail.

5. The exercise stair step device set forth in claim 1 further comprises, a safety brake having a direct engagement with said weighted flywheel.

6. An exercise stair step device comprising, integral stationary frame having a pair of spaced parallel support legs, a handrail extending from each of said leg assemblies with an interconnecting support rail, an upper and lower drive shaft and bearing assemblies, pairs of chain sprockets on opposite ends of said upper and lower drive shafts, a pair of step drive chains extending around opposite ends of said respective chain sprockets, a plurality of step assemblies connected between and driven by said step drive chains, a flywheel drive shaft having a flywheel on one end, extending between said leg assemblies in spaced relation between said pair of chain sprockets, a drive belt engagement tensioner assembly on the upper drive shaft and bearing assembly, electromagnetic resistant brake assemblies positionally engaged with the flywheel, control input levers on said respective handrails in electronic communication with an information control display and respective electromagnetic resistant brake assemblies.

7. The exercise stair step device set forth in claim 6 wherein said movable step assemblies, each comprise, a tread, a riser and interconnecting plate hinged there between.

8. The exercise stair step device set forth in claim 6 wherein said belt drive tensioner assembly comprises, a belt pulley, a tensioning belt, and an adjustment idler pulley in communication with said tensioning belt.

9. The exercise stair step device set forth in claim 6 wherein said informational control display is positioned on interconnecting support rail.

10. The exercise stair step device set forth in claim 6 wherein said electromagnetic resistant braking assemblies comprises, a pair of movable electromagnets.

11. The exercise stair step device set forth in claim 6 further comprises a safety brake for direct engagement with said flywheel.

Description

DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 is a front and side perspective view of the step exercise device of the invention.

[0011] FIG. 2 is a rear, top and side perspective view thereof.

[0012] FIG. 3 is a side elevational view of the step exercise device of the invention.

[0013] FIG. 4 is a front elevational view thereof.

[0014] FIG. 5 is a front, top and side partial perspective exploded view of the step exercise device with portions broken away for visual clarity.

[0015] FIG. 6 is a rear, top and side perspective exploded view of the step exercise device of the invention with portions broken away.

[0016] FIG. 7 is a front, top and side partial exploded perspective view of an alternate fly wheel positioning on a stair exercise device.

[0017] FIG. 8 is an exploded perspective view of the primary form of the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0018] Referring to FIGS. 1-4 of the drawings, a stair step exercise device 10 of the invention can be seen having a main support frame 11 defined by a pair of spaced parallel tubular L-shaped support legs 12 and 13 with an endless step assembly 14 supported there between. A pair of upstanding tubular handrail members 15 and 16 extend respectively therefrom with an interconnecting cross support rail portion 17. Each of the hand rail members 15 and 16 have an angular post support 15A and 16A extending therefrom to the main frame 11 defining a pair of sturdy hand engagement surfaces with a pair of resistance control input levers 18 and 19 for user weight input and desired resistant levels respectively, as will be described in greater detail hereinafter.

[0019] The tubular cross support rail 17 provides a central mounting position for an upstanding electronic informational controller and input display screen 19A. As noted, the endless step assembly 14 is supported within and between the respective main frame leg support members 12 and 13 in an angular inclination orientation, best seen in FIG. 2 of the drawings.

[0020] Referring now to FIGS. 5, 6 and 8 of the drawings, the step drive assembly 14 includes upper drive shaft 22, rotatably supported on end shaft support bearing sets 23A and a lower drive shaft 24 supported by respective end shaft support bearings 24A as will be understood by those skilled in the art.

[0021] Pairs of chain engagement sockets 25 and 26 are mounted on the respective drive shafts 22 and 24. Endless chains 27 extend around the respective upper and lower socket pairs 25 and 26 interlinking same. The plurality of equal spaced movable step assemblies 28 are disposed between and interengaged by the respective chains 27. Each of the step assemblies 28 comprises a tread 30 and a riser 31 with an interconnecting plate 32 there between. The tread 30 and riser 31 are hinged to provide a continuous moving step engagement surface for the user, not shown, to simulate climbing a set of fixed stairs. Such movable inclined step assemblies achieve an endless step configuration for the user by essentially folding each stair step for return to the upper drive shaft 22's position.

[0022] The main support tubular frame has a pair of upper end U-shaped extensions of 33 and 34 that extend in spaced parallel relation about a fly wheel drive shaft 35 and bearing assembly 36. The fly wheel drive shaft 35 has a weighted fly wheel 37 secure to one end and a drive pulley 38 to its oppositely disposed end. The drive pulley 38 is in turn connected by a drive belt 39 to a stair chain engagement pulley 40 in communication with a dual pulley and belt assembly 40A via a shaft 40A′ which engages the upper drive shaft 22. A belt engagement tension 40B′ pivots from the stair frame to maintain flywheel sprocket engagement, as will be understood in the art, best seen in FIGS. 5 and 8 of the drawings.

[0023] The fly wheel 37 has a set of electromagnetic resistant brake assemblies 40D and 40D′ that will impart independent adjustable magnetic induced resistance to the fly wheel 37 by varying the magnetics' positional relationship to the fly wheel 37. Such magnetic induced resistance is well known in the art to achieve an adjustable frictionless drag on a fly wheel by increasing or reducing rotational resistance coupled with the inherent gyroscopic rotation of the weighted fly wheel in such environments. The selective engagement of the brake assembly 40D and 40D′ pairs provide imparted control as to user, not shown, weight and step speed via variances thereof by control input levers 18 and 19 respectively.

[0024] It should be noted, that an optional safety mechanical brake 40E may also be incorporated into the fly wheel design dependent on the manufacturing requirements as indicated by broken lines in FIG. 5 of the drawings for illustration only.

[0025] Referring now to FIG. 7 of the drawings, an alternate form of the invention 41 can be seen having essentially the same frame and endless step assembly disclosed in the primary form of the invention hereinbefore with a relocation of a kinetic energy fly wheel 42′. In this example, the kinetic energy fly wheel 42′ with its magnetic induction resistant brake assembly 43 is repositioned onto a stair chain engagement drive engagement shaft 44 of a pulley assembly as hereinbefore described in the primary form midway on the stair step assembly. This direct engagement to the endless step assembly provides for a more compact footprint and eliminates the reduction rotation ratio that is achieved additionally by the multiple pulley and belt assembly 40A and engagement fly wheel assembly, the primary form of the invention as disclosed above.

[0026] It will be seen that the manual stair step device 10 of the invention utilizing a stepping engagement configuration of a moving step drive train on an integrated welded tubular frame 11. As noted, the main advantage of such a unit is that it requires no electricity to be driven and functional. The stair step exercise devices 10 and 41 with their magnetic resistant fly wheels 37 and 42′ induces a simulation of perpetual motion which allows the unit to be “self-propelled” like and balanced with the user's body weight. Such magnetic resistance fly wheel induced operational configurations provides for the advantage of reduced friction effectively making for a consistent and smooth operational performance which is variable from very light to heavy resistance controllable by user's input via the control levers 18 and 19, noted above.

[0027] It will thus be seen that a new and novel stair step exercise device 10 of the invention has been illustrated and described having a resistant adjustment endless stair step assembly with a magnetic adjustment resistant fly wheel to maintain optimum steps per minute emulating prior art motorized units.

[0028] As such, the user level resistant controls provided and combined with an input control display parameters for calculating specific workout limits based on user's desired exercise level can be achieved. It will therefore be seen that various changes and modifications may be made therein without departing from the spirit of the invention.