Priority is claimed in the application data sheet to the following patents or patent applications, each of which is expressly incorporated herein by reference in its entirety:
The present invention generally relates to exercise equipment, and more particularly, to exercise devices in which a user's feet are supported on a pair of pedals and the user may perform one or more movements while supported on the pedals.
The need for physical exercise is especially important in today's world of drive through windows and sitting in front of a computer all day. It is suggested that cardiovascular exercise is most beneficial if the user can obtain an elevated heart rate for at least twenty minutes of sustained exercise. This type of exercise may vary according to the needs and personal preference of the user, but for many people a movement that employs larger muscles, such as those which move the legs and hips may be desirable, as these are capable of doing the most work. For many sedentary individuals the accumulation of excess bodyfat may be a concern. The more work the body does, the more energy the body uses to perform that work. In the human body, most energy storage is in the form of bodyfat. Therefore, using larger muscles to do more work may enable a quicker end result on reducing bodyfat and increasing cardiovascular health. Adding an upper body system to an exercise device may further help by taxing additional muscle groups and increase the work output of the body over time.
It may be beneficial for the user to perform an activity that has a familiar basis to the normal function of the body, such as walking or running. Walking may be preferred for many users, as the impact forces on the legs are less compared to those found in running for the same person, even at the same speed. Using a walking motion may enable some participants to perform the activity that they could not perform under the higher running loads. Also, the lower impact stress may allow some people to perform the activity longer and therefore have a higher cumulative energy expenditure compared to running, even considering the higher energy expenditure per unit of time with running as compared to walking. Increasing the energy expenditure and still maintaining a walking gait may be accomplished by increasing the force required to move the pedals of a machine that simulates walking, or altering the angle to simulate walking up a hill. Either or both may provide a useful alternative to walking on a street or road where the user may be subjected to extreme weather conditions, traffic or physical dangers not found in their home or other controlled environment.
Treadmills have typically been used, but they can be large, expensive and noisy. The noise is due at least partially to the friction between the moving belt and the supporting deck under the belt that occurs with each step. Where there is friction there is wear. The decks must be regularly replaced or lubricated and the belts replaced.
It should, therefore, be appreciated that there is a need for an exercise device that allows the user to simulate walking or other bipedal movement that can be done indoors, with a small footprint and with minimal noise and parts wear. The present invention fulfills this need and others.
The present invention may include a frame and a first crank assembly rotateably coupled to the frame about a first axis and a second crank assembly rotateably coupled to the frame about a second axis. The first crank assembly and the second crank assembly may each provide a first crank arm and a second crank arm displaced from each other such that a user may be positioned there between. The first crank arm and the second crank arm may be positioned 180 degrees out of phase from each other. In addition, the first crank arm of the first crank assembly and the first crank arm of the second crank assembly may be parallel to each other.
A control system may be provided that may be in communication with the first crank assembly and the second crank assembly, the control system may provide a synchronous movement of the first crank assembly relative to the second crank assembly. A pedal arm may have a first end pivotally coupled to the first crank assembly and a pedal positioned on a second end of the pedal arm. In addition, a crank link may have one end coupled to the second crank assembly and a second end coupled to the pedal arm. The first crank link may be movably coupled to a location on the first pedal arm and then moved to a second position on the first pedal arm, thereby changing the path of movement of the pedals.
The control system may include a drive shaft rotateably connected to the frame, which may provide mechanical communication between the first crank arm and the second crank arm of the first crank assembly. The control system may also include a drive member selected from the groups consisting of a belt, roller chain, a synchronous belt, a v-belt and a poly-v belt. The control system may also include a torque linkage including a link rod rotateably coupled to the second crank assembly and the drive shaft. The torque linkage may transfer power between the second crank assembly and the drive shaft operating in cooperation with the drive member. A braking system may be provided that may be in mechanical communication with the drive shaft, which may provide a resistance to movement of first crank arm and the second crank arm of the first crank assembly and the second crank assembly.
The exercise device may also include a support frame which may support the first crank assembly and the second crank assembly. The support frame may be movably mounted to a base frame, such that the orientation of the first axis or the second axis may be altered with respect to the base frame and thereby vary the path of the pedals.
The system may include a pair of drive handles pivotally coupled to the frame, each one of the pair of drive handles may include a hand grip on a first end and a drive lever on a second end. A handle link may also be provided with a first end pivotally coupled to the first crank assembly and a second end pivotally coupled to the drive lever.
For purposes of summarizing the invention and the advantages achieved over the prior art, certain advantages of the invention have been described herein. Of course, it is to be understood that not necessarily all such advantages can be achieved in accordance with any particular embodiment of the invention. Thus, for example, those skilled in the art will recognize that the invention may be embodied or carried out in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other advantages as may be taught or suggested herein.
All of these embodiments are intended to be within the scope of the invention herein disclosed. These and other embodiments of the present invention will become readily apparent to those skilled in the art from the following description of the preferred embodiments and drawings, the invention not being limited to any particular preferred embodiment(s) disclosed.
Embodiments of the present invention will now be described, by way of example only, with reference to the following drawings, in which:
With reference to the illustrative drawings, and particularly to
It may be desirable for the first crank assembly 28 and the second crank assembly 32 to move in a synchronous manner with respect to one another. This may be accomplished by the use of a control system 44. The control system 44 may be comprised of a roller chain, a drive belt, a gearing system or any other mechanical transmission elements known in the art. In that the first axis 30 and the second axis 34 may not allow a direct communication between the right and left portions of the first crank assembly 28 or the second crank assembly 32, the control system 44 may also be in mechanical communication with the driveshaft 42. In that the driveshaft 42 may be located in position to mechanically span the entire width of the exercise device 20, the driveshaft 42 with the control system 44 may then act to connect the left and right portions of each of the first crank assembly 28 and the second crank assembly 32 as well as provide for synchronous rotation of the first crank assembly 28 with respect to the second crank assembly 32.
A pedal arm 46 may be rotatably coupled to the first crank assembly 28 on a first end 48 of the pedal arm 46. On a second end 50 of the pedal arm 46 a pedal 52 may be provided, which may be adapted to support the weight of the user 36. Between the first end 48 and the second end 50 of the pedal arm 46, a crank link pin 54 may be provided. The crank link pin 54 may be pivotally coupled to a crank link 56 and the crank link 56 may also be coupled to the second crank assembly 32, thereby connecting the pedal arm 46 to the second crank assembly 32.
It is important to note that in these preferred embodiments of the exercise device 20, the drive shaft 42 is positioned such that it is not in line with the first axis 30 or the second axis 34. That is because both the first axis 30 and the second axis 34 may be positioned to potentially interfere with the movement of the user 36. As such, the drive shaft 42 may be moved to a position that is unlikely to interfere with the movement of the legs of the user 36. It is possible that the second axis 34, and the second crank assembly 32, could be moved far enough forward to avoid the legs of the user 36. If that were done, the drive shaft 42 could directly connect the second crank assembly 32. The crank link 56 may then be increased in length in accordance with the increase in dimension of the relocation of the second axis 34 relative to the current position. This would eliminate the need for some components in the system. The applicant recognizes this could be done and hereby includes this as a variation to the disclosed embodiments even though this is not shown in any of the Figures.
With reference to
To provide a smooth movement of the pedals 52 a flywheel 74 may be coupled to the driveshaft 42, whereby rotation of the driveshaft 42 about the bearings 72 may cause a similar rotation of the flywheel 74. It may also be desirable to include a braking system to resist the movement of the pedals 52. A braking system may include a friction strap 76 mounted to a screw 78, which may be mounted to the support frame 26. Therefore, as the screw 78 is advanced this may increase the tension in the friction strap 76, which may increase the drag and therefore increase the resistance to movement of the flywheel 74. This may increase the work necessary to be provided by the user 36, thus increasing the intensity of the exercise. In a similar manner, any magnetic form of resistance known to the art, such as an electric motor, an eddy current brake or any other braking system may be used in place of the combination of the friction strap 76 and screw 78.
With particular attention to
With regard to
It may be desirable to change the resistance of the exercise device 20. Any number of users may have different physical capabilities and therefore it may be desirable to have the exercise device conform to those varying capabilities. In addition, as a person uses an exercise device, it is likely the person's physical fitness level will improve. As such, in order to continue to make physiological gains from the exercise, it may be desirable for the exercise device to increase in its ability to stress the body of the user by increasing the workload.
As noted, one method to increase the workload in the present exercise device 20 is by providing resistance to rotation of the flywheel 74 by way of the friction strap 76 or any other form of resistance, such as any number of electromagnetic braking systems. An alternative may be to increase the angle of the pedal path. A solution to do so is illustrated in
With regard to
It may be desirable to enable the user to change the stride length of the pedal path. An example of how this may be accomplished is shown in
A spring may obey “Hook's Law” in that the force needed to deform a spring by some distance is proportional to that distance. Therefore in this example, if a force is applied to cause the distance “x” to decrease, as depicted by the compression arrows 110 shown in
The result is the movable crank link 96 may allow for the dimension “x” to be increased or decreased by forces applied to the movable crank link 96, but the action of the first spring 104 and the second spring 106 may provide a pair of forces that may be balanced optimally when the dimension “x” is at a predetermined value. This combination may allow for displacement of the first link 98 relative to the second link 100 of the movable crank link 96 to allow the value of “x” to vary, but yet provide a bias to return the orientation of the movable crank link 96 to that so the dimension “x” may be a predetermined value.
When used on the exercise device 20″, the force applied to the movable crank links 96 may be applied by the user to the pedals 52. This may be illustrated in more detail in
In a similar but opposite manner, if the user wishes to extend the pedal 52 supporting the back foot farther back than what may be illustrated by the trace of the pedal path 82, the user may apply a force to the rear pedal 52, (right one in
Another option to vary the stride length of the pedals 52 is presented in
With regard to
The horizontal displacement of multiple stride lengths of the pedals 52 that may be provided by varying the position of the movable link pin 118 is illustrated in
If the movable link pin 118 is used with a constant length crank link 56, as shown, the adjustment in the stride length may provide a series of set pedal paths (82, 128, 130) or any infinite number of variations to those shown. Each path may be a result of the settings of the exercise device 20′″ and therefore stable to the user, as the user may not be able to alter the pedal paths without making an adjustment to the position of the movable link pin 118. This stability may be desirable to some users in that their body may be fully supported on the pedals 52 of the exercise device 20′″. Using the movable crank link 96 with the adjustable stride length system as provided by the movable link pin 118 together may provide a system which allows for the user to vary their stride length where the path of the pedals 52 comply with that of the user, and an adjustable baseline path of the path of the pedals 52 may be provided by the movable link pin 118 and set in accordance with the desire or some physical characteristics of the user.
Another embodiment of the exercise device 20″″ is shown in
A drive pulley 135 may be mounted to the drive shaft 42. The drive pulley 135 may be in mechanical communication with the flywheel 74 by way of a drive belt 137. A braking system may be coupled to the flywheel 74 so that resistance provided to the flywheel 74 may offer a resistance to movement of the drive shaft 42, which in turn may offer a resistance to movement of the pedals 52. This combination may offer a form of exercise resistance to the user.
The control system 44 may include a drive member 138, which may take the form of a belt, roller chain, a synchronous belt, a v-belt, a poly-v belt or any other power transmission system known in the art. The drive member 138, as shown here in the form of a belt, may be tensioned by the idler 80. A drive pulley 140 may be secured to the first crank assembly 28 and the second crank assembly 32 on both the first drive 132 and the second drive 134. The drive member 138 may be limited to a belt or other power transmission system alone. Alternatively it may be advantageous to provide a secondary power transmission system in the form of a torque linkage 142. This may include a link rod 144 that may be coupled to the second crank assembly 32 and the drive shaft 42 by way of a pair of clamp links 146. This torque linkage 142 may be used to supplement the drive member 138 when high torque is applied to the second crank assembly 32 by the user. The braking system may be applied to the flywheel 74, as such, the highest load may be seen between the second crank assembly 32 and the drive shaft 42. The use of the torque linkage 142 may allow the drive member 138 to be designed for the lower torque associated with extended use by a user and when high forces are applied by the user, such as during sprinting or high incline “hiking” movements, the torque linkage 142 may supplement the power transmission, taking any excessive stress off the drive member 138. This may help eliminate the possibility of drive member 138 jumping a tooth of one of the drive pulleys 140 without the need to over engineer the drive member 138 and drive pulleys 140 for stresses that are only seen occasionally and for short durations.
The torque linkage 142 is shown here to connect the second crank assembly 32 to the drive shaft 42, which may be connected to the braking system. This combination may experience the highest forces and that is why it is shown in this configuration. It is understood that one or more torque linkages 142 may connect any one or more combinations between the first crank assembly 28, the second crank assembly 32 and the drive shaft 42.
The transfer of the higher forces that may be added by the user to the torque linkage 142 may be generated by the user by positioning the exercise device 20″″ in a configuration so as to simulate walking up a hill. In this embodiment, this may be accomplished by altering the position of the support frame 26″ and all the elements supported by the support frame 26″ with respect to the base frame 24. One method of doing this is illustrated in
To reduce production costs, compared to using linear actuators in place of the counterbalance springs 148, the gas springs may be used as the counterbalance springs 148 with an incline adjustment 150. The incline adjustment 150 may include a first support 152, which may articulate with a second support 154, and a locking pin 156 to releasably secure the first support 152 to the second support 154 at desired positions. This may securely alter the dimension between a support frame pin 158 and a base frame pin 160. By increasing the dimension between the support frame pin 158 and the base frame pin 160, exercise device 20″″ may produce an inclined pedal angle from flat (as shown in
In this embodiment the drive handles 58 of previous embodiments have been removed and a set of stationary leaning handles 162 are shown. These handle types are not mutually exclusive to any embodiment. The leaning handles 162 may be desirable in some angular orientations of the exercise device 20 and the moving drive handles 58 may be desirable in other orientations, or as a personal preference in any orientation. Either form of handles (moving drive handles 58 or stationary leaning handles 162) may be interchangeably used or in combination together on any embodiment.
A method of altering the pedal path by varying the position of the crank link 56 on the pedal arm 46 has been disclosed. This embodiment of the exercise device 20″ illustrates a manually adjustable version to accomplish this task. An adjustment bracket 164 may be releasably secured to the pedal arm 46 at one or more positions on the pedal arm 46. A leg lock pin 166 may be used to releasably secure the adjustment bracket 164 to a position on the pedal arm 46. The crank link 56 may be pivotally secured to the adjustment bracket 164 at the movable lock pin 118, and as noted before, also to the second crank arm 40. Therefore, by adjusting and securing the adjustment bracket 164 at different positions on the pedal arm 46, the path of the pedals 52 may be altered to achieve more than one pedal path, as previously disclosed.
The foregoing detailed description of the present invention is provided for purposes of illustration, and it is not intended to be exhaustive or to limit the invention to the particular embodiment shown. The embodiments may provide different capabilities and benefits, depending on the configuration used to implement key features of the invention.
Number | Date | Country | |
---|---|---|---|
Parent | 17405347 | Aug 2021 | US |
Child | 18299017 | US | |
Parent | 15609910 | May 2017 | US |
Child | 17405347 | US |