This invention relates generally to wheelchair handrims and, in particular, to an adjustable wheelchair handrim with a moveable friction band.
Manual wheelchair users control and propel their wheelchairs with the handrims, also commonly called pushrims, handrings, and handrails. Handrims enable the user to propel forward, turn and brake. Unfortunately, there is a high occurrence of upper extremity injuries as a result of the repetitive stresses experienced by the user when gripping and pushing their handrims.
When propelling forward, the typical wheelchair user reaches back, grips both handrims and pushes forward until their arms are almost fully extended. The user then releases the handrim and prepares for the next push if needed. Another technique sometimes used when starting from rest or climbing a steep incline is to grab both the wheel and handrim to push. Positioning the palm of the hand on the tire and wrapping the fingers around the handrim, this provides addition torque and gripping surface area than just gripping the handrim.
Breaking is done by lightly gripping the handrim as it rotates and slides through the user's hands, decelerating the rotation of the wheels. The greater the gripping force, the higher amount of friction between the hands and handrims, and ultimately the greater the deceleration. Since wheelchair users rely on their upper extremities in this manner, pain and injuries to their arms and shoulders can significantly affect their mobility, and consequently, their independence and quality of life.
The typical handrim used by the manual wheelchair population is substantially equivalent to U.S. Pat. No. 4,687,218 (issued to Okamoto on Aug. 18, 1987), which is incorporated herein in its entirety by specific reference for all purposes. This design presents a hand rim that uses rigid standoffs spanning between the wheel rim and the handrim. Machine screws fasten the handrim to the wheel rim. Another known prior art is to attach the handrim to the wheel rim by welding rigid mounting flange members to the wheel rim and handrim.
Although effective, there are some drawbacks and inconveniences that are inherent with these designs. One drawback is that these handrims have a limited gripping surface for the user's hand to engage during pushing and breaking. An increase in contact area would cause an increase in propulsion efficiency.
Another drawback is that the offset between the handrim and the wheel is not adjustable, providing a standard spanning distance for all users regardless of their hand size and gripping limitations. This makes it impossible for users with smaller hands to use the previously discussed technique of grabbing both the wheel and handrim for climbing hills or starting from rest. In addition, quad users are sometimes not provided with sufficient space to push down on the handrim because of its proximity to the wheel.
It is also known that the user's fingers can get caught in the area between the wheel and handrim or jammed by the rigid standoffs as the wheel rotates.
Another characteristic of typical handrims is that most are generally made of a smooth metal with poor frictional properties. This results in the users needing to grip on the rim with considerable force in order to prevent slippage. Some designs have used friction coatings or materials, such as vinyl or foam, to reduce slipping and minimize the needed gripping force. While these designs are effective in improving the frictional propertied of the handrim, the coating tends to burn the hand of the user during braking.
As an alternative, other handrim designs have placed high friction materials in selected locations, which provide smooth surfaces for the user to grip during braking. While these designs are better than the typical handrim, one problem they possess is that the location of the high friction is permanent. Depending on the condition of the user and their grip limitations, the proximity of the high friction with respect to the wheel rim and tire, and with respect to the handrim contour itself, should be individualized to maximize its benefits.
This leads to the need for a wheelchair manual handrim that allows users to have the ability to move the handrim and high friction material to locations that they desire. The ability to adjust these allows users to reduce the amount of gripping force needed to push, thus relieving existing pain and reducing the potential of developing repetitive stress injuries.
In various exemplary embodiments, the present invention comprises an improved wheelchair handrim assembly that employs an adjustable offset and movable elastomeric friction band to improve the effectiveness and efficiency of the user's pushes by reducing slippage and the needed gripping force between the user's hand and the handrim. In one embodiment, the handrim assembly consists of an ergonomically shaped, tubular handrim with a continuous drive surface. The surface spans the gap between the tubular handrim and the wheel rim, mounting to the wheel rim with numerous rigid tabs that extrude from drive surface. Screw fasteners pass through elongated circle shaped slots in the rigid tabs and attach the handrim to the inner surface of the wheel rim.
The ergonomic handrim profile allows for maximum surface area for the user's fingers to contact, reducing the required gripping force during propulsion. The drive surface presents addition surface area from the user's palm and thumb to engage when pushing. The combination of the drive surface and ergonomic handrim provides maximum gripping surface. Additionally, the continuous drive surface protects the fingers of the users from getting caught between the handrim and wheel rim, as well as blocks them from jamming into the rigid tabs or wheel spokes.
The elongated circles slotted in the rigid tabs allow for variable offset distance between the wheel rim and the ergonomic handrim. The adjustable offset distance allows for users to position the handrim at the ideal distance from the tire depending on their hand size and grip limitations. This means a user with small hands can move the handrim as close to the wheel as possible, allowing them to grab the tire and handrim for starts and climbs. Quads are also able to move the handrim as far from the tire as allowed to reduce the obstruction of the wheel during pushes. The aforementioned embodiment is a fully functional, adjustable, ergonomic handrim with no improved frictional properties.
In one embodiment, a high friction, soft elastomeric band is stretched around the top of the drive surface. This band is held in place by the elasticity of the material from which it is made being stretched to a greater radius than its undeformed dimension. The friction between the bottom surface of the band and the top surface of the rigid standoff prevents circumferential movement when the user grips and applies a torque to the handrim during pushes. The location of the high friction band is not permanent, therefore making the distance between the band and the wheel rim and its position on the handrim assembly adjustable. This allows each individual wheelchair user to provide increased friction properties to their handrims in a desired location that will most benefit their tendencies and disabilities and a braking area that they feel it is best suited.
In another embodiment, the cross sectional shape of the high friction band can be adjusted to provide a greater area of increased friction. Also, the elastomeric band can be permanently affixed with glue or similar securing means to the handrim assembly in the desired location to prevent further movement of the band.
Ultimately, the combination of adjustable offset distance and variable shape, size, and position of the movable high friction band allows for a customizable handrim configuration for each individual manual wheelchair user. This customization will increase propulsion efficiency while reducing strain on the upper extremities of the user.
In one exemplary embodiment, as shown in
The adjustable wheelchair handrim with movable friction band 10 is comprised of an ergonomic tubular handrim 22 which transforms directly into a drive surface 24, as can be seen in
A plurality of the aforementioned rigid attachment tabs 26 extrude or extend from the terminal end of the drive surface 24. Individual rigid attachment tabs 26 angle inward before bending horizontal, providing a level top surface 28 to mate with the inner-flat surface of the wheel rim 14. The tabs have elongated circle slots 30 through which fasteners 32 can be used to affix the handrim to the wheel rim 14. The handrim, comprising the ergonomic tubular handrim 22, drive surface 24, and rigid attachment tabs 26, is made of a metal material for durability and rigidity.
As shown in
The elastomeric friction band 34 is held in place when the user is not gripping the handrim by the elastic properties of the band material, and the tendency of the band to contract to its undeformed dimension when stretched. The band resists circumferential movement relative to the handrim during a push through the friction between the bottom surface of the band 36 and the top surfaces of the drive surface 24 and ergonomic tubular handrim 22. The downward force of the user's hand also contributes to prevent movement.
Furthermore, the elongated circle slots 30 allow adjustability of the position of the ergonomic tubular handrim 22 relative to the wheel rim 14 and tire 12. As seen in
In another embodiment, because the elastomeric friction band 34 is held in place by its elastic deformation and is not permanently affixed to the handrim, it can be moved outward perpendicular to the plane of the wheel. When moved, more of the band rests on the ergonomic tubular handrim 22 in order to provide higher friction in a different location on the handrim. The movability of the elastomeric friction band 34 allows individual users to position the increased frictional properties in the location that is most advantageous. This movability, coupled with the adjustable offset distance, provides the user with flexibility and allows them to customize their handrim to maximize their propulsion efficiency.
Further, due to the mobility of the elastomeric friction band 34, it can be removed from the handrim. In this exemplary embodiment, the user is presented with a metal handrim with an adjustable offset distance between the ergonomic tubular handrim 22 and the wheel. Even without any added frictional properties, this embodiment still improves efficiency by providing greater contact surface area for gripping.
In other embodiments, the position of the handrim relative to the wheel rim 14 and tire 12 can be adjusted to any desired location, thus varying the offset distance. In yet other embodiments, the position of the elastomeric friction band relative to the wheel rim 14 and handrim can be adjusted to any desired location.
The contour of the elastomeric band can be changed in order to provide the best configuration for each individual wheelchair user. Also, the position of the band, regardless of its profile, can be permanently affixed to the handrim if the configuration is found to be ideal and permanence of band location is advantageous. The method of mounting can be by chemical adhesives, rigid fasteners, or any other means.
Thus, it should be understood that the embodiments and examples described herein have been chosen and described in order to best illustrate the principles of the invention and its practical applications to thereby enable one of ordinary skill in the art to best utilize the invention in various embodiments and with various modifications as are suited for particular uses contemplated. Even though specific embodiments of this invention have been described, they are not to be taken as exhaustive. There are several variations that will be apparent to those skilled in the art.
This application is a continuation of U.S. patent application Ser. No. 13/409,400, filed Mar. 1, 2012, which claims benefit of and priority to U.S. Provisional Application No. 61/447,989, filed Mar. 1, 2011, by W. Mark Richter, and is entitled to those filing dates for priority. The specifications, figures and complete disclosures of U.S. Provisional Application No. 61/447,989 and U.S. patent application Ser. No. 13/409,400 are incorporated herein by specific reference for all purposes.
Number | Date | Country | |
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61447989 | Mar 2011 | US |
Number | Date | Country | |
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Parent | 13409400 | Mar 2012 | US |
Child | 14325626 | US |