Certain types of individuals have medical conditions that cause exaggerated muscle behaviors. For example, individuals with imbalanced muscle tone, often as a result of an anoxic birth injury, cerebral palsy or an acquired/traumatic brain injury, may display strong patterns of either flexion or extension, for example, in the muscles of the hip. This can occur numerous times during a day, often triggered by intention or mood change (excitement, anger, etc.). When the extension is initiated by hip movement (hip extension), the angle between the individual's upper legs and back changes. When this pattern is met by resistance from a traditional seating system, the tone pattern is exaggerated and continued. However, it has been discovered that when there is some “give” or lack of resistance of the support surfaces, the tone pattern is reduced, thus relaxing the muscles that are firing. Tone changes or movement in the lower extremities (i.e., below the hip) are also common. As noted above, the extensor pattern displayed can be lessened when the extension pattern is not met with resistance. Once the resistance is eliminated, the tone pattern is compelled to relax.
Many individuals with mental disabilities, often times along with diagnoses of cerebral palsy, exhibit the need to participate in self-stimulatory behaviors. These are driven by the individual's internal drive to gain certain types of vestibular, proprioceptive and tactile input. As a result, many individuals participate in rocking behaviors. The rocking motion can be limited to head movement or can include total body rocking while seated. When seated in a traditional wheelchair with a fixed seat-to-back angle, this movement often causes damage to the wheelchair, making it unsafe for use. Excessive wear and tear on the wheelchair may cause failure of some parts. Often, rear canes or seat rails shear, making the chair unusable.
Individuals that display any of the above or similar conditions are often, by the nature of their disability, confined to wheelchairs. However, these conditions make the use of traditional wheelchairs (i.e., those having static seating components) less than desirable. Any of these static components may be subject to premature failure because of the involuntary abusive use caused by the individual's exaggerated, often violent, movements. It is not uncommon to have the backrest structure broken off of a wheelchair, rendering the wheelchair unusable. Standard wheelchair footrests and their mounting components are often bent outward by the user who experiences extension thrusting. When the hip extensor tone is fired, the user will exert tremendous force on opposite ends of the wheelchair, pushing against the top of the seat back and against the footplates. The force on the footplates is typically both outward and upward.
When a wheelchair is damaged to the point that it is unusable, the cost goes far beyond the obvious financial cost of repairing or replacing the wheelchair. The inconvenience of not having a wheelchair or having an inappropriate temporary replacement has an impact on the user and their caregivers. In today's medical funding environment, it is also difficult to have a wheelchair repaired. The facility doing the repair work almost always needs approval from the funding source (Medicare, Medicaid, or private insurance) prior to doing the repairs. The repair process typically involves sending a technician to the field to evaluate the problem and report to the medical billing department for the paperwork process to be initiated. Thereafter, quotes are required for parts and must be submitted for prior approval for the repairs. When approval is given, and it may occasionally be withheld at least temporarily, the parts must be ordered. Upon receipt of the parts, an appointment must be made to pick up the wheelchair, then repair and return the wheelchair to the customer. The entire process can take a lengthy period of time, often weeks or months.
In one aspect, the technology relates to a dynamic foot plate for a wheelchair, the dynamic foot plate including: a base plate adapted to be secured to a wheelchair; at least one flexible element secured at a first end to the base plate; a foot plate secured to a second end of the at least one flexible element, such that in a neutral position, the foot plate is substantially parallel to the base plate and such that when a force is applied to the foot plate, the flexible element deflects so as to allow the foot plate to be oriented at an angle to the base plate. In an embodiment, the base plate and the foot plate are secured to the flexible element with a fastener that passes through the flexible element. In another embodiment, the at least one flexible element includes a plurality of flexible elements. In yet another embodiment, the at least one flexible element includes four flexible elements, wherein the four flexible elements are disposed substantially centrally on the foot plate.
In another aspect, the technology relates to a telescoping footrest for a wheelchair, the telescoping footrest including: a tube defining an interior; an elongate element slidably received within the interior of the tube; and a deformable element for controlling sliding movement of the elongate element within the interior of the tube. In an embodiment, the deformable member includes a compressible element. In another embodiment, the elongate element includes an elongate flat guide surface, and wherein the telescoping footrest further includes a guide adapted to slide relative to and along the elongate flat guide surface so as to prevent an axial rotation of the elongate element relative to the tube. In yet another embodiment, the footrest includes a foot support element secured to at least one of the tube and the elongate element.
In another aspect, the technology relates to a pivotable mechanism for a wheelchair, the pivotable mechanism including: an axle including at least one axle projection projecting from an outer surface of the axle; an annular hub including at least one hub projection projecting from an inner surface of the hub, wherein the axle is located within the hub; a biasing element located between the axle projection and the hub projection, such that rotation of at least one of the hub and the axle causes at least one of a compression and an extension of the biasing element. In an embodiment, the axle includes a plurality of axle projections, and wherein the hub includes a corresponding plurality of hub projections. In another embodiment, the pivotable mechanism further includes a plurality of biasing elements corresponding to the plurality of axle projections and the plurality of hub projections. In yet another embodiment, the biasing element is a compressible element.
In another aspect, the technology relates to a wheelchair having a pivotable mechanism as described above, wherein the pivotable mechanism allows for a pivoting movement about an axis defined by an interface between at least one of (a) a seat member and a back member, (b) a seat member and a footrest, (c) a foot rest and a footplate support, (d) a baseplate and a footplate, and (e) a back member and a headrest.
In another aspect, the technology relates to a wheelchair having: a first dynamic component including a first pivotable mechanism for allowing a pivoting movement about a first axis defined by an interface between a seat member and a back member, wherein the first dynamic component includes a biasing element for biasing the first dynamic component into a rest position; and a second dynamic component including a second pivotable mechanism for allowing a pivoting movement about a second axis defined by an interface between at least one of (a) a seat member and a back member, (b) a seat member and a footrest, (c) a foot rest and a footplate support, (d) a baseplate and a footplate, and (e) a back member and a headrest, wherein the second dynamic component includes a biasing element for biasing the second dynamic component into a rest position. In an embodiment, the wheelchair further includes a third dynamic component including a telescoping element for allowing an axial movement of a first footrest element relative to a second footrest element, wherein the third dynamic component includes a biasing element for biasing the third dynamic component into a rest position. In another embodiment, the wheelchair further includes a fourth dynamic component for allowing a pivoting movement about an axis substantially orthogonal to a baseplate. In yet another embodiment, the second axis is substantially orthogonal to the first axis.
There are shown in the drawings, embodiments which are presently preferred, it being understood, however, that the technology is not limited to the precise arrangements and instrumentalities shown.
Adaptive or dynamic components act as shock-absorbing devices, receive the energy exerted by the user and absorb it into the device, thus alleviating or eliminating the above-mentioned problems attendant with fixed components. Absorbing the energy into the dynamic component reduces the energy absorbed into the wheelchair itself, thereby minimizing the potential for breakage of the wheelchair components. Additionally, dynamic components in the wheelchair can help control or lessen the user's condition or behavior which causes the damage. Dynamic seating components for wheelchairs are needed to prevent or eliminate damage to wheelchairs resulting from severe usage, typically involving involuntary and sometimes violent movements of the wheelchair user. Dynamic components may be used in numerous locations on the wheelchair. Any standard component subjected to abnormally high forces exerted by the user may be replaced with dynamic components.
Exemplary components of a wheelchair upon which excessive forces may be exerted include the headrest, backrest, seat frame, footrest, and the footplate.
A number of components are described herein that help limit the forces exerted by an individual against a wheelchair, thus reducing the stresses against both the individual and the wheelchair. This helps reduce the movements and behaviors of the wheelchair user and can also prolong the operational life of the wheelchair. These components include dynamic footplates (as depicted in
Additionally, these components may be used in wheelchairs used for individuals that lack the above-identified medical conditions, but who may benefit from the increased comfort attendant with the dynamic components described herein. These individuals may be obese or have extremities that extend in atypical directions and would benefit from improved component positioning. Additionally, dynamic components may be used in wheelchairs used by paraplegics or quadriplegics, allowing the chair components to conform to the position of the body, not vice versa. In short, the components depicted and described herein allow the wheelchair to better fit the individual, whether that individual moves or not. Accordingly, the components may also be considered adaptive in that they adapt to the particular position of the user. Of course, these components may also be incorporated into stationary or semi-mobile chairs or physical therapy equipment or any type of seating device in which an individual spends time. The components disclosed herein may incorporate different technologies to better conform to the needs of the individual. They may be used independently or any combination and are described in further detail below.
The technologies described herein improve, e.g., the lower extremity support surfaces of a wheelchair, commonly known as footrest or legrest. Footrests typically are attached to the wheelchair seat frame member in a fixed angular position, usually at 90°, 70°, or 60° to the horizontal axis or wheelchair seat frame. Legrests are similar to footrests except that they start at an angle to the seat frame similar to a footrest and then have the ability to elevate to a point where the legrest extends more or less straight out from the seat, becoming an extension of the seat and capable of supporting the full weight of the legs.
A pivotable connection 500 depicted in
The two pivotable connections of
The benefits to the individual as a result of the above technology can be categorized as mechanical, economic and therapeutic. The mechanical benefits include improved durable and reduced failure. The economic benefits include a reduction in breakage and failure of the wheelchair, thus providing a repair cost savings the purchaser of the wheelchair. The savings is realized as a result of fewer repairs and extended life of the wheelchair. The therapeutic benefits include a reduction or change in the behavior or condition.
While there have been described herein what are to be considered exemplary and preferred embodiments of the present technology, other modifications of the technology will become apparent to those skilled in the art from the teachings herein. The particular methods of manufacture and geometries disclosed herein are exemplary in nature and are not to be considered limiting. It is therefore desired to be secured all such modifications as fall within the spirit and scope of the technology. Accordingly, what is desired to be secured by Letters Patent is the technology as defined and differentiated herein, and all equivalents.
This application claims priority to and the benefit of U.S. Provisional Patent Application No. 61/547,315, filed Oct. 14, 2011, entitled “Dynamic Seating Components for Wheelchairs,” the disclosure of which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | |
---|---|---|---|
61547315 | Oct 2011 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13649826 | Oct 2012 | US |
Child | 14543682 | US |