The invention relates in general to mobility aid sticks and, more specifically, to a walking stick with a built in a dual flexure spring above the foot of the walking stick.
Walkers, climbers, and other participants can benefit from walking sticks that have the feature of returning kinetic energy that is acquired as the walking stick compresses in contact with the ground. This retained energy has the benefit that the users have to expend less of their own energy moving their legs forward, thus allowing them to walk or climb further and faster more comfortably and with less fatigue. Experiencing this advantage, the user will increase their interest in the activity and become a more active person.
The use of a walking stick with an energy storage spring for returning energy to the walker is well known to those familiar with the art. An example is the use of energy storage springs in foot prosthesis; particularly those used for athletic purposes. Designs include that of U.S. Pat. No. 6,007,582 or that in use in the Flex-Foot®, manufactured by Ossur hf of Reykjavik, Iceland. Examples where a spring mechanism stores and then sequentially dissipates energy for the sole purpose of cushioning a walking stick are described in U.S. Pat. No. 6,131,592, U.S. Pat. No. 5,720,474, and FR2617023. These walking sticks utilize a mechanical device such as a coil spring or cylinder for a spring and do not make use of the compression of a flexure to return the energy from the material compressing as a step is taken.
A published paper entitled “The design of a compliant composite crutch” by D. Shortell et al. discloses two designs of crutches using composite materials. The first design utilizes a metal coil spring embedded in a single unit composite material crutch. The coil spring compresses under the weight of the user with a spring force in the range of 90 to 170 lbs. The spring force, which acts in the vertical direction, is for shock absorption, not as a forward propelling aid. A second crutch design utilizes the flexure of the S curve in the shaft of the crutch in place of the coil spring. The effective springs that are designed using the composite material in place of the coil spring also operate in the vertical direction for shock absorption, not as a forward propelling aid. Another feature of the crutches that are the subject of the Shortell et al. publication is a rigid armrest with a grip. These armrests are oriented in the vertical direction for the purpose of providing the user with more support.
Bio-mimicry is the study and emulation of nature and its processes and elements to draw inspiration in order to solve human problems. The term bio-mimicry takes roots from the Greek words bios, meaning life, and mimesis, meaning to imitate. Nature has many elegant solutions to adapt to difficult and diverse terrains and climates. For example, mountain goats have evolved feet that allow them to maintain sure-footing on steep, rocky slopes and powerful legs that give them the strength to climb these difficult slopes.
Standard walking sticks, hiking poles, and ski poles can only assist a person's capability to negotiate a limited number of landscapes and ground conditions. There has been limited evolution of their tips, oftentimes referred to as “ferrules and baskets.” The ferrule and basket has been the standard up until now, with minimal design modification other than variations in materials, slight changes in shape, addition of hard points and shock absorbers. A walking stick that could readily accept an interchangeable shoe designed to improve traction on varying terrains would be a major improvement over the current art.
Another limitation of the standard walking stick is the pointed tip of the ferrule. This pointed tip cuts into the surface of the terrain the user is traversing. This contributes to deterioration of the terrain surface as the pointed tip slices through and grabs into the surface. It also causes the user to expend excess energy to remove the tip from the terrain surface and places transverse forces across the walking stick which contributes to walking stick failure (breakage). A walking stick that possessed a dual flexure spring configured in an S-shape would cause less damage to terrain as a user traversed the terrain and would not be susceptible to breaking the shaft due to normal wear.
In light of the above, the object of the present invention is to provide a walking stick that takes inspiration from nature to absorb energy in the downward first motion of a walking stride and then return the stored energy to aid in propelling the walker forward in the final forward motion of the walking stride all the while keeping the walker in an ergonomically correct position which minimizes discomfort and reduces wasted energy. The walking stick will add an increase in ability of a person to climb and descend steeper slopes and stairways as the strength and agility of the user's arms are available and therefore increases the capability of a person. It is designed to allow a user to be more aggressive and more positively negotiate more complex terrains and surface conditions than is possible with walking sticks currently available. They are fashioned to be more surefooted through the extraction of principles derived from nature's best examples of foreleg designs. Animals, such a mountain goats, antelope, mountain lions, and tapirs are prime examples of surefooted creatures that rapidly and surefootedly traverse complex terrain.
The walking stick that is the subject of this patent application utilizes a dual flexure spring configured in an S-shape (hereafter referred to as an S-flexure spring) as an extension of the straight shaft of the stick. The shape and location of the S-flexure spring are such that the spring force helps propel the walker forward. The spring constant of the S-flexure spring is in the range of 5 to 100 pounds per inch of deflection. In the preferred embodiment the S-flexure spring is fabricated using composite materials.
The walking stick of the present invention utilizes a hand grip that is large and comfortable and extends nearly perpendicularly from the base of the walking stick inwardly (towards the user) at an angle of approximately 10 to 45 degrees. The natural position that the relaxed hand takes when the arms are held perpendicular to the ground is at an angle of approximately 15 to 30 degrees. In a preferred embodiment the hand grip is fabricated using glass reinforced acrylonitrile butadiene styrene (ABS) plastic covered with a rubberlike material. The handgrip allows a user to keep the wrists in a natural nearly horizontal position which allows for more efficient transfer of force to the S-flexure spring than would be transferred when the wrists are held in a vertical position. In another preferred embodiment the hand grip is fabricated to conform to a user's palm putting the user's hand in an even more natural and relaxed position.
The walking stick of the present invention has a foot at its base. The foot is angled away from the user at an angle of approximately 10 to 45 degrees. The angling of the foot away from the user helps to keep the user from striking his leg against the walking stick as it moves past the user's leg. It also provides the user a wider foundation providing the user a lowered center of gravity which gives the user more balance when traversing difficult (uneven or slippery) terrain. The foot may be bifurcated which allows for improved stability. The user's arms are held closer to the frame of his body than would be possible with walking sticks of the current art, which place the arms in a more natural position and allows for a more relaxed motion. The foot may optionally be fitted with a shoe covering the foot. The shoe is designed to be specific to particular terrain conditions and provides for improved traction and surety of placement when navigating difficult terrain such as slippery stream beds, steep hill sides, glaciers, deserts, forests, mud flats, and the like. As an example, when traversing over icy terrain, the user could attach a shoe with an icy terrain shoe which keeps the walking stick from sliding on the ice.
The location of the S-flexure spring is a key feature of the present invention. The first flex point of the S-flexure spring mimics the flexibility of a human ankle. This spring is angled away from the user and angles the forces away from the center of the body for added stability and absorbs the downward forces to release on the rebound.
The second flex point of the S-flexure spring, the less flexible arch, controls direction of forces. The angle the foot is aligned relative to straight ahead varies from zero degrees for the medical versions of the walking stick to 45 degrees for the extreme sports or military versions of the walking stick.
There is an additional flex point in the foot. This mimics the motion of the “ball of the foot” of a human which keeps the foot flat when it makes contact with the ground while in use. On rebound it helps propel the walking stick forward to its next location.
The walking stick of the present invention may be used in a wide number of applications. Examples include a walking and climbing stick for hikers and combat troops, an ambulatory aid for a person recovering from surgery or otherwise limited in ability to walk, a substitute for a ski pole for cross country skiing, a pole for use in roller blading, a hiking stick that will also function as a canoe paddle, or a walking stick for snow shoeing. It may be a molded single unit or assembled out of multiple components. As a molded single unit the flexure spring is integral to the molded stick. As a stick built of multiple components, the flexure spring is attached to the straight shaft of the stick and may be interchangeable depending upon the size and weight of the user, or depending on one of the specific uses listed above.
The invention, and its objects and advantages, will become more apparent in the detailed description of the preferred embodiment presented below.
In the detailed description of the preferred embodiments of the invention presented below, reference is made to the accompanying drawings, in some of which the relative relationships of the various components are illustrated, it being understood that orientation of the apparatus may be modified. For clarity of understanding of the drawings, relative proportions depicted or indicated of the various elements of which disclosed members are comprised may not be representative of the actual proportions, and some of the dimensions may be selectively exaggerated.
Referring to
An overhead view of the walking stick 10 is provided in
Referring again to
The shoe is fitted over the foot and remains connected until user decides to change it out. Alternatively, a single non-removable she may be fitted over the foot.
Many animals have feet with an opposable dewclaw located near the ankle. This dewclaw provides the animal additional traction when walking, especially when the animal is walking down a slope, as the dewclaw can grab into the surface. The replaceable shoe may be constructed with a dewclaw attached. There are several readily available methods for adding a dewclaw to the replaceable shoe which are well known to those skilled in the art. These methods include, but are not limited to, molding a dewclaw in a single piece molded shoe or fastening a dewclaw to the shoe via a rivet or screw and nut or other readily available fastener.
Another embodiment of the walking stick of the present invention is shown in
For some applications, such as hill climbing, stair climbing, and trekking, an adjustable length walking stick is preferred. Referring to
The first flex point of the S-flexure spring mimics the flexibility of a human ankle. This spring is angled away from the user and angles the forces away from the center of the body for added stability and absorbs the downward forces to release on the rebound.
The second flex point of the S-flexure spring, the less flexible arch, controls direction of forces. The angle the foot is aligned relative to straight ahead varies from zero degrees for the medical versions of the walking stick to 45 degrees for the extreme sports or military versions of the walking stick.
There is an additional flex point in the foot. This mimics the motion of the “ball of the foot” of a human which keeps the foot flat when it makes contact with the ground while in use. On rebound it helps propel the walking stick forward to its next location.
The multi-part embodiments of the walking stick of the present invention, as illustrated in
Referring to
An additional embodiment of the present invention is presented in
As the patient transfers from a sitting position to a standing position, the patient's upper body and weight compresses (loads) the spring; this stores energy. As the patient transfers to a standing position, stored energy is released providing additional lift to the patient.
During the loading process, a stop is reached. The stop is momentary and realized when the upper back of the foot, which acts as a fifth contact point, is engaged providing stability for the patient. The preferred range for the stop is 10 percent to 40 percent of the spring's working range and more preferably 15 percent to 25 percent of the spring's working range.
A shoe to cover the foot may have outer spring tips, embedded in the over-molded shoe, which spread the applied forces evenly and effectively across the base of the walking stick to the ground.
The personalisible grips are angled to fit the persons relaxed out reached hands with thumbs facing slightly upward about 15 degrees + or −5 degrees relative to the walking surface.
Detailed points of a preferred embodiment of the grip depicted in
Emplacements are available for a variety of sensors to collect data about the environment or the physical condition of the user.
An additional embodiment of the present invention would be a walking stick similar to that of walking stick 10 of
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
Priority for this patent application is based upon provisional patent application 61/821,198 (filed on May 8, 2013). The disclosure of this United States patent application is hereby incorporated by reference into this specification.
Number | Date | Country | |
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61821198 | May 2013 | US |