Exercise Apparatus

Abstract

An exercise apparatus that is adapted for use with a leg exercising machine on a surface, the exercise apparatus includes a support beam having a longitudinal axis, the support beam including a proximal end portion and an opposing distal end portion with the longitudinal axis spanning therebetween, wherein there is also a means for removably engaging the support beam proximal end portion to the leg exercising machine. Further included in the exercise apparatus is a grasping arm having a first end portion and an opposing second end portion with a lengthwise axis spanning therebetween, the first end portion is affixed to the distal end portion, wherein operationally an individual user of the leg exercising machine grasps with their hand the arm for stability and support to effect a soft skeletal joint support wherein the user can engage in upper body exercise as well using the arm.

Description

TECHNICAL FIELD

The present invention generally relates to an apparatus for accomplishing exercise typically in a traditional exercise or working out environment, either in the home or commercial gym. More particularly, the present invention is an exercise apparatus that is adapted to be adjacent to a common treadmill that an individual uses in a home or commercial gym environment to facilitate exercise in a convenient time and place, thus allowing the individual to enjoy the health benefits of exercise when circumstances don't readily allow for the time and expense of exercising in an outdoor environment, such as running, bicycling, and the like, as opposed to using a traditional exercise facility, such as a gym, health club, spa, and so forth.

BACKGROUND OF INVENTION

The health benefits of exercise are well known and applicable to all ages of individuals, including cardiovascular improvement, muscle strengthening, stretching, increased blood circulation, better coordination, sharper motor abilities, flexible joint mobility, bone health, general overall wellness, and the like. One problem as an individual typically moves from being a child to being an adult, their physical activity levels decline just when maintaining good health is at its most important as an individual ages, typically their exercise levels decline that can work against maintaining good health, thus just when an individual should be exercising and being active, their exercise and activity levels tend to decrease.

Children are normally active in going places (i.e. walking or riding a bike), playing active games in their spare time, such as football, soccer, baseball, tag, hide and seek, and the like, plus being in school children are also active in physical education classes and after school hours sports leagues. Thus as children we are normally plenty active and in the best of health due to our young age. However, as we become adults, societal norms tend to drive us into a much more sedentary lifestyle, for instance by having a car, we tend to walk very little, nor ride a bicycle much, and as an office worker we tend to sit at a desk for long periods of time, sit in meetings, sit on airplanes, and then go out for high fat and calorie content meals at high end restaurants, thus as a result most adults tend to gain weight by consuming more calories coupled with a lower activity lifestyle, just when our bodies should be in better shape to compensate for aging we typically get in worse shape.

Although the benefits of exercise especially for adults are acknowledged by most everyone for weight control, maintaining agility, preventing diabetes, preventing joint stain from excessive body weight, preventing higher various internal organ workloads (especially the heart) from excessive body weight, and so on, few adults are active enough to maintain even a recommended weight, typically being only about one-fourth of the adult population is not overweight, thus an overwhelming majority of adults are overweight. So the question to ask is, why don't the majority of adults exercise especially if the health benefits are widely known?

One probable answer is that available time and convenience are a problem for engaging in an exercise program, as most adults have a full time job, a family, and other interests that all together consume most of an adult's time, this is in addition to boredom and the constant obligation of regular exercise placed upon an individual's time. Wherein, even the adults who engage in exercise programs, especially after new years in January-typically lose interest in a short amount of time, wherein this “petering-out” of individual's exercise program is acerbated by the long term slow rate of actual physical shape (endurance, strength, and appearance) improvement. Thus, a potentially helpful solution is to minimize the time, boredom, and convenience obstacles to allow for an exercise program to be more possible for a working adult on a long term basis.

In looking at the prior art in this area of exercise machines that attempt make exercise or physical rehabilitation easier, more effective, involving additional muscles, or less strenuous, for example in U.S. Pat. No. 6,450,923 to Vatti disclosed is an apparatus and methods for enhanced exercises and back pain relief, thus helping to decrease exercise boredom and increase comfort. People suffering from back pain in Vatti would be able to use the apparatus more effectively to relieve the pain. This apparatus in Vatti can also be used by common users for strengthening and stretching exercises that conventional exercising equipment such as treadmills do not provide. Combinations of a general frame in Vatti along with multiple attachments form an effective exercising apparatus. The user of the Vatti apparatus shifts weight from the spine or lower back to the hands while performing exercises.

Wherein, an ordinary upright user position causes more stress on the lower back and the weight of the upper body in motion may make the situation worse, say for instance on a typical treadmill. By suitable placement of hands and selectively distributing upper body weight to hands in Vatti, the user would be able to control the amount of weight reduction on the lower back or spine as needed to achieve the best results and comfort. Basically, Vatti combined a conventional treadmill with a number of attachments for exercising a user's arms and legs for additional exercises plus having upper body support while on the treadmill, however, not teaching any specifics related to adjustment or criterion setting, i.e. amount of upper body support.

Continuing in this area of exercise machine prior art, in U.S. Pat. No. 5,662,560 to Svendsen, et al., disclosed is a therapeutic bilateral weight unloading apparatus which suspends a user to support a selected portion the user's weight while reducing and dampening both vertical and lateral forces that are exerted on the user while standing or exercising. The apparatus in Svendsen, et al., suspends the user between two independently supported boom arms, with the independent action of the boom arms gently counter balances the user's natural weight shifts to reduce and dampen both the vertical and lateral forces exerted on the suspended user while standing or exercising, thus the dampening is applied to the entire user's body from a torso stabilizing harness.

The unloading apparatus Svendsen, et al., includes a frame and two pivoting boom arms that are independently supported by two gas compression springs with the user being completely suspended between the boom arms by a body harness. The boom arms Svendsen, et al., are pivotally connected to a vertically adjustable gantry frame extensibly mounted to a base frame, which allows the boom arms to be raised and lowered. The gas springs Svendsen, et al., provide the upward suspension force used to support a selected portion of the user's weight, further one end of the gas springs is connected to a slide collar shiftably mounted to each of the boom arms. Each slide collar Svendsen, et al., can be selectively positioned along the length of the boom arm to adjust the suspension force for each boom arm, in addition, the base frame may be fitted with casters, which allows the apparatus to be moved by the suspended user, see column 1, lines 43-67.

Svendsen et al., has disadvantages in requiring a user fitted unique harness, plus the discomfort from heavy physical activity, i.e. sweating/chaffing while the user is in the harness, as basically Svendsen, et al., is specifically designed for the user who needs total vertical support while on a treadmill for instance, in other words the user could completely collapse in Svendsen, et al., apparatus and still be completely suspended above the treadmill. Also, as in Vatti, there is no teaching in Svendsen, et al., related to adjustment or criterion setting, i.e. amount of upper body support.

Continuing in this prior art area in U.S. Pat. No. 5,372,561 to Lynch being configured similar to Svendsen et al., Lynch discloses an apparatus for whole user body suspension assisted ambulation to provide a vertically moveable gantry frame in conjunction with a treadmill with attachment points on the gantry frame which allow attachment of an upper-body harness so as to suspend a person so that the person can ambulate with less than gravitational weight on their lower extremities. The exercising device in Lynch comprises a treadmill, a vertical support frame affixed to such treadmill, a gantry frame pivotally attached to the vertical support frame, and an upper-body harness suspended from solid gantry frame; see column 2, lines 47-68. Pneumatic linear actuators are pivotally connected to Lynch in the vertical support frame and the gantry frame and regulated air pressure may be introduced into the pneumatic linear actuators to effect a rotational movement to the gantry frame in relation to the support frame and thus exert an upward force on the upper-body harness.

The magnitude of the vertical force in Lynch exerted on the upper-body harness is a function of the regulated air pressure. By regulating the air pressure in Lynch the user/operator can vary the uplift force applied to meet the requirements of each subject so that individuals who only need to be stabilized can ambulate with near full weight on their feet and where individuals who cannot tolerate full weight on a lower extremity joint may have the joint load reduced by a substantial percentage of their body weight. The use of air pressure in Lynch to actuate the upper-body suspension system allows it to instantly adjust to the vertical translational excursion of the body that occurs during ambulation and thus preclude oscillating shocks being induced to the user.

The control in Lynch of the various parameters of the machine, (belt speed, uplift force, and time) are preferably controlled, monitored and recorded by a computer, see column 3, lines 1-28. Lynch, does finally get into some criterion for upward force on the user's body through the use of regulating air pressure, however, there is a lack of specifics as to what relationship the upward force to have to other parameters of user weight, speed, condition, support type, etc, instead there are just a set of typical or arbitrary percentages of upward force, see column 6, lines 16-36. Further, in Lynch the use of air pressure in a cylinder is not good design, as the ability hold a position of the harness and thus upward force is unreliable due to air leakage and not having a positive suspension lock, i.e. a screw block type, plus if the compressor were to fail, the user would be suddenly dropped, potentially causing injury. Note that Lynch supports the entire user's body through a torso harness also much like Svendsen et al., not allowing for a contemporaneous dampened grasp by the user.

Further continuing in this prior art area U.S. Pat. No. 5,273,502 to Kelsey, et al. again is a harness type support for the entire user's body weight, see Lynch and Svendsen et al., in Kelsey et al., disclosed is a therapeutic apparatus and method including a frame to which a winch is mounted. A spring in Kelsey, et al., is attached at one end to the winch and at the other end to a support harness; also a load cell is connected to the winch so that the winch automatically maintains a set load while the load varies back and forth from more than to less than the set load. Cables interconnect the winch, spring and harness in a preferred embodiment in Kelsey, et al. Further, the support frame in Kelsey, et al. is preferably comprised of a pair of oppositely positioned strength beams, wherein these beams are interconnected by means of a transverse support within which is an opening from which the harness cable descends so that when a user wears the harness the user is supported from the transverse support from above; see column 2, lines 6-22.

The support harness in Kelsey, et al. includes a waist encircling abdominal strap that “grasps” the user very snugly so that there is no shifting of the abdominal strap as strain is taken on the support cable, i.e. as the user is “unloaded.” A pair of arm loops in Kelsey, et al. is attached at opposite sides to the waist encircling abdominal strap and from those arm loops a corresponding pair of harness cable connectors is attached and these two connectors are attached to a single harness bar at the bar's opposite ends. The center of the bar is connected to the harness cable at the mid-point of the bar so that as the user is “unloaded,” weight is lifted evenly on both sides of the user through the encircling abdominal strap, as a result the user is lifted precisely, evenly, and accurately, see column 2, lines 37-50. Kelsey et al., through the use of a kinematic system including a magnetic clutch and low spring constant change spring attempts to have a constant upward force exerted upon the user in a physical rehab type environment, although this system would seem to have a “pogo-stick” effect by not having any dampening, i.e. constantly yanking the user up and down due to reactionary changes in the winch movement that are amplified by the clutch and spring, i.e. leading to undesirable mechanical dynamic resonance of the system that would be discomforting to the user by being continually oscillating vertically.

Nest, in the exercise machine arts for a combination of exercise movements in U.S. Pat. No. 5,171,196 to Lynch discloses the dispensing of the user harness, that the previous Lynch '561 had, wherein Lynch '196 discloses a treadmill with variable upper body resistance loading to provide two, or more, sets of upper body exercising levers, in conjunction with an inclinable treadmill, each set of levers being independently moveable and with independently variable resistance from the other, note that this is resistance and not dampening, see column 1, lines 54-68. The first set of handlebars in Lynch '196 are placed at about waist height and the second set is placed at a height which would be about shoulder height or higher, furthermore, the upper set of handlebars enables the operator to lift the load by pushing in an upward position (pressing) as opposed to lifting or pulling upward which is done with the lower set of handlebars. Means in Lynch '196 are also provided to prevent the handlebars from dropping below essentially a horizontal position. In Lynch '196, hydraulic/pneumatic cylinders, springs, elastic bands or other suitable devices may be used as the resistance means and are selectively variable for both the upper and lower sets of levers independently, see column 2, lines 24-36. Primarily designed to be used in a weightless environment the multiple handlebar sets in Lynch '196 are operational to provide resistance through cylinders 60, 62, 94, and 96, however, as in Lynch '561 the exercise criterion are arbitrary as opposed to experimental relationships tied to definitive results, also there is no dampening disclosed for a grasp by the user.

There exists a need to provide an exercise apparatus that can facilitate the dynamically selective loading/unloading of the user's static and dynamic weight load force placed upon their back, legs, and feet. This would entail an added feature to a treadmill for example, however, not being limited to just a treadmill with any type of lower body portion or leg exercise machine could be utilized as well, wherein a grasping arm would be available to the user for instantaneously adjusting the load split as between their upper and lower body portions while using the leg exercise machine for instance. Furthermore, it would be desirable for the grasping arm to have a crankshaft type shape for converting reciprocating energy/movement of the user's upper body, arms, and hands into rotational movement of the grasping arm to add another exercise option for the exercise apparatus. In summary, the primary feature would be to allow the user of the leg exercise machine, preferably a treadmill to use the grasping arm at will and to also vary the amount of force loading split as between the user's upper and lower body portion, or to have no split in loading at all as between the upper and lower body portions, also at will.

SUMMARY OF THE INVENTION

Broadly the present invention is an exercise apparatus that is adapted for use with a leg exercising machine on a surface, the exercise apparatus includes a support beam having a longitudinal axis, the support beam including a proximal end portion and an opposing distal end portion with the longitudinal axis spanning therebetween, wherein there is also a means for removably engaging the support beam proximal end portion to the leg exercising machine.

Further included in the exercise apparatus is a grasping arm having a first end portion and an opposing second end portion with a lengthwise axis spanning therebetween, the first end portion is affixed to the distal end portion, wherein operationally an individual user of the leg exercising machine grasps with their hand the arm for stability and support to effect a soft skeletal joint support wherein the user can engage in upper body exercise as well using the grasping arm.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an upper perspective view of the exercise apparatus that is adapted to attach to the leg exercising machine showing specifically the support beam with the proximal and distal end portions, the means for removably engaging the proximal end portion to the leg exercising machine, the grasping arm in the form of a crank shaft type configuration that is rotationally coupled to the distal end portion to axially retain the crankshaft along the lengthwise axis and facilitate free rotation about the lengthwise axis;

FIG. 2 is a side elevation view of the exercise apparatus adapted to attach to the leg exercising machine showing specifically the support beam with the proximal and distal end portions, the means for removably engaging the proximal end portion to the leg exercising machine, the grasping arm, further shown is the user with the user's arms, hands, upper body, height, and reciprocating exercise motion of the user's upper body;

FIG. 3 is an upper perspective view of the exercise apparatus that is adapted to attach to the leg exercising machine showing specifically the support beam with the proximal and distal end portions, the means for removably engaging the proximal end portion from the leg exercising machine, also shown is the means for lockably adjusting a selected distance between the proximal and distal end portions, plus the grasping arm with the first and second end portions; and

FIG. 4 is an end elevation view of the exercise apparatus that is adapted to attach to the leg exercising machine showing specifically the support beam with the proximal and distal end portions, the means for removably engaging the proximal end portion from the leg exercising machine, also shown is the means for lockably adjusting a selected distance between the proximal and distal end portions, plus the grasping arm with the first and second end portions.

REFERENCE NUMBERS IN DRAWINGS

• 50 Exercise Apparatus
• 55 Leg exercising machine
• 60 User
• 65 Arms of the user 60
• 70 Hands of the user 60
• 75 Left hand of the user 60
• 80 Right hand of the user 60
• 85 Upper body of the user 60
• 90 Movement of the user's 60 arms 65 and hands 70
• 95 Grasping by the user 60
• 100 Different user 60 heights
• 105 Surface
• 110 Support beam
• 115 Longitudinal axis of the support beam 110
• 120 Proximal end portion of the support beam 110
• 125 Distal end portion of the support beam 110
• 130 Means for removably engaging the proximal end portion 120 to the leg exercising machine 55
• 135 Bar clamp for the means 130
• 140 Grasping arm
• 145 First end portion of the grasping arm 140
• 150 Second end portion of the grasping arm 140
• 155 Lengthwise axis of the grasping arm 140
• 160 Affixed of the first end portion 145 to the distal end portion 125
• 165 Selected distance between the proximal 120 and distal 125 end portions
• 170 Means for lockably adjusting the selected distance 165
• 175 Telescoping section
• 180 Inner telescoping element
• 185 Outer telescoping element
• 190 Partially disposed inner telescoping element 180 in the outer telescoping element 185
• 195 Pin
• 200 Plurality of matched holes disposed in the inner 180 and outer 185 telescoping elements
• 205 Crank shaft type configuration for the grasping arm 140
• 210 Grasping points
• 215 Opposing radial position of the grasping points 210 relative to the lengthwise axis 155
• 220 Reciprocating exercise motion of the user's 60 upper body 85
• 225 Rotational motion of the grasping arm 140
• 230 Rotational couple of the first end portion 145
• 235 Free rotation of the grasping arm 140
• 240 Precluding movement axially along the lengthwise axis 155
• 245 First offset arm
• 250 First crank throw
• 255 Left hand grasping point
• 260 Axis of the first crank throw 250
• 265 Parallel position of the first crank throw axis 260 to the lengthwise axis 155
• 270 Second offset arm
• 275 Substantially equal and opposite position of the second offset arm 270 to the first offset arm 245
• 280 Intermediate section
• 285 Intermediate axis of the intermediate section 280
• 290 Co-incident position of the intermediate axis 285 and the lengthwise axis 155
• 295 Third offset arm
• 300 Second crank throw
• 305 Right hand grasping point
• 310 Axis of the second crank throw 300
• 315 Parallel position of the second crank throw axis 310 the lengthwise axis 155
• 320 Substantially equally radially opposed position as between the first crank throw 250 and the second crank throw 300

DETAILED DESCRIPTION

With initial reference to FIG. 1 shown is an upper perspective view of the exercise apparatus 50 that is adapted to attach to the leg exercising machine 55 showing specifically the support beam 110 with the proximal 120 and distal 125 end portions and the means 130 for removably engaging the proximal end portion 120 to the leg exercising machine 55. Further FIG. 1 shows the grasping arm 140 in the form of a crank shaft type configuration 205 that is rotationally coupled 230 to the distal end portion 125 to axially retain 240 the crankshaft 205 along the lengthwise axis 155 and facilitate free rotation 235 about the lengthwise axis 155.

Continuing, FIG. 2 is a side elevation view of the exercise apparatus 50 adapted to attach to the leg exercising machine 55 showing specifically the support beam 110 with the proximal 120 and distal 125 end portions and the means 130 for removably engaging the proximal end portion 120 to the leg exercising machine 55. Also FIG. 2 shows the grasping arm 140, further shown is the user 60 with the user's arms 65, hands 70, upper body 85, height 100, and reciprocating exercise motion 90, 220 of the user's upper body 85.

Next, FIG. 3 is an upper perspective view of the exercise apparatus 50 that is adapted to attach to the leg exercising machine 55 showing specifically the support beam 110 with the proximal 120 and distal 125 end portions and the means 130 for removably engaging the proximal end portion 120 from the leg exercising machine 55. Also shown in FIG. 3 is the means 170 for lockably adjusting a selected distance 165 between the proximal 120 and distal 125 end portions, plus the grasping arm 140 with the first 145 and second 150 end portions.

Further, FIG. 4 is an end elevation view of the exercise apparatus 50 that is adapted to attach to the leg exercising machine 55 showing specifically the support beam 110 with the proximal 120 and distal 125 end portions and the means 130 for removably engaging the proximal end portion 120 from the leg exercising machine 55. In addition FIG. 4 shows the means 170 for lockably adjusting a selected distance 165 between the proximal 120 and distal 125 end portions, plus the grasping arm 140 with the first 145 and second 150 end portions.

Broadly the present invention is the exercise apparatus 50 that is adapted for use with the leg exercising machine 55 on a surface 105, see FIGS. 1 and 2. The exercise apparatus 50 includes the support beam 110 having the longitudinal axis 115, the support beam 110 including the proximal end portion 120 and the opposing distal end portion 125 with the longitudinal axis 115 spanning therebetween, as best shown in FIGS. 3 and 4. Wherein there is also the means 130 for removably engaging the support beam 110 proximal end portion 120 to the leg exercising machine 55, see FIGS. 1 and 2.

Further included in the exercise apparatus 50 is the grasping arm 140 having the first end portion 145 and the opposing second end portion 150 with the lengthwise axis 155 spanning therebetween, the first end portion 145 is affixed 160 to the distal end portion 125, as best shown in FIGS. 2, 3, and 4. Wherein operationally the individual user 60 of the leg exercising machine 55 grasps 95 with their hand 70 the arm 140 for stability and support to effect a soft skeletal joint support wherein the user 60 can engage in upper body exercise 85 as well using the arm 140, see in particular FIG. 2.

As an option for the exercise apparatus 50, the means 130 for removably engaging is preferably constructed of a bar clamp 135, as seen in FIGS. 1 to 4.

A further option for the exercise apparatus 50, wherein the support beam 110 can have the means 170 for lockably adjusting the selected distance 165 as between the proximal 120 and distal 125 end portions to operationally accommodate different user 60 heights 100, see FIG. 2 in particular, plus FIGS. 1, 3, and 4. Further, on the means 170 for lockably adjusting is preferably constructed of a telescoping section 175 having an inner 180 and an outer 185 telescoping element such that the inner telescoping element 180 is partially disposed 190 within the outer telescoping element 185 wherein a pin 195 is removably received into a plurality of matched holes 200 that that are disposed in both of the inner 180 and outer 185 telescoping elements to operationally removably lock the selected distance 165, as best shown in FIGS. 3 and 4, also see FIGS. 1 and 2.

Yet a further another option for the exercise apparatus 50, wherein the grasping arm 140 can be sized and configured as the crankshaft type shape 205 with a pair of grasping points 210 that are at substantially opposing radial positions 215 relative to the lengthwise axis 155, further the first end portion 145 is rotatably received into the distal end portion 125 such that operationally reciprocating exercise motion 220 of the user's 60 upper body 85 translates into rotational motion 225 of the grasping arm 140, see in particular FIG. 1 and then FIG. 2.

Continuing, for the crank shaft type shape 205 for the exercise apparatus 50, the crankshaft type shape 205 can include a first end portion 145 rotational couple 230 that is rotationally engaged to the distal end portion 125 such that the grasping arm 140 freely rotates 235 about the lengthwise axis 155 while precluding movement axially 240 along the lengthwise axis 155, see in particular FIG. 1. The rotational couple 230 is affixed to a first offset arm 245 that is affixed to a first crank throw 250 for a left hand 75 grasping point 255, a first crank throw 250 axis 260 is positioned parallel 265 to the lengthwise axis 155 separated by the first offset arm 245, further the first crank throw 250 is affixed to a second offset arm 270 that is equal and opposite 275 to the first offset arm 245 that is affixed to an intermediate section 280 that has an intermediate axis 285 that is co-incident 290 to the lengthwise axis 155, again see FIG. 1. The intermediate section 280 is affixed to a third off set arm 295 that is affixed to a second crank throw 300 for a right hand 80 grasping point 305, a second crank throw 300 axis 310 is positioned parallel 315 to the lengthwise axis 155 separated by the third offset arm 295, wherein the first crank throw 250 and the second crank throw 300 are substantially equally radially opposed 320 to one another about the lengthwise axis 155.

CONCLUSION

Accordingly, the present invention of an exercise apparatus and method of using the same has been described with some degree of particularity directed to the embodiments of the present invention. It should be appreciated, though, that the present invention is defined by the following claims construed in light of the prior art so modifications the changes may be made to the exemplary embodiments of the present invention without departing from the inventive concepts contained therein.

Claims

1. An exercise apparatus that is adapted for use with a leg exercising machine on a surface, said exercise apparatus, comprising: (a) a support beam having a longitudinal axis, said support beam including a proximal end portion and an opposing distal end portion with said longitudinal axis spanning therebetween;(b) means for removably engaging said proximal end portion to the leg exercising machine; and(c) a grasping arm having a first end portion and an opposing second end portion with a lengthwise axis spanning therebetween, said first end portion is affixed to said distal end portion, wherein operationally an individual user of the leg exercising machine grasps with their hand said arm for stability and support to effect a soft skeletal joint support wherein the user can engage in upper body exercise as well using said arm.

2. An exercise apparatus according to claim 1 wherein said means for removably engaging is constructed of a bar clamp.

3. An exercise apparatus according to claim 1 wherein said support beam has a means for lockably adjusting a selected distance as between said proximal and distal end portions to operationally accommodate different user heights.

4. An exercise apparatus according to claim 3 wherein said means for lockably adjusting is constructed of a telescoping section having an inner and an outer telescoping element such that said inner telescoping element is partially disposed within said outer telescoping element wherein a pin is removably received into a plurality of matched holes that that are disposed in both of said inner and outer telescoping elements to operationally removably lock said selected distance.

5. An exercise apparatus according to claim 4 wherein said grasping arm is sized and configured as a crankshaft type shape with a pair of grasping points that are at substantially opposing radial positions relative to said lengthwise axis, further said first end portion is rotatably received into said distal end portion such that operationally reciprocating exercise motion of the user's upper body translates into rotational motion of said grasping arm.

6. An exercise apparatus according to claim 5 wherein said crankshaft type shape includes a first end portion rotational couple that is rotationally engaged to said distal end portion such that said grasping arm freely rotates about said lengthwise axis while precluding movement axially along said lengthwise axis, said rotational couple is affixed to a first offset arm that is affixed to a first crank throw for a left hand grasping point, a first crank throw axis is positioned parallel to said lengthwise axis separated by said first offset arm, further said first crank throw is affixed to a second offset arm that is equal and opposite in position to said first offset arm that is affixed to an intermediate section that has an intermediate axis that is co-incident to said lengthwise axis, said intermediate section is affixed to a third off set arm that is affixed to a second crank throw for a right hand grasping point, a second crank throw axis is positioned parallel to said lengthwise axis separated by said third offset arm, wherein said first crank throw and said second crank throw are substantially equally radially opposed to one another in position about said lengthwise axis.