The present application is generally related to wheeled devices, and more particularly to a wheeled device having a general orientation of a ski and comprising wheels oriented to allow for users to have the sensation of skiing on non-ice or snow surfaces.
Skiing is a popular winter sport but relies upon the increasingly fickle coverage of snow or ice. Certainly, we are seeing higher than normal temperatures and lower than normal precipitation resulting in smaller snow pack and shorter skiing seasons. Winter skis, of course, have a generally flat base side that is waxed or coated to make it slick and reduce friction, and on each side of the ski is a sharp metal or composite edge to aid in gripping the snow or ice. This edge allows the skis to properly turn, carve, and stop on the snow and ice, and allows a user to traverse down a hill or over flat land, based on using downhill style skis, telemark style skis, or cross country skis.
Skis have changed in shape over the past few decades, and many modern skis utilizes a side cut design, wherein the center of the ski is narrower than the tips of the ski. Furthermore, the skis are shaped so that there is a camber, having a slight upward curve in the middle of the ski. These elements impact how the ski turns and feels. Designs to mimic these features and the feeling of carving are lacking.
Because of the shorter ski seasons and unreliable snow conditions, consumers that enjoy skiing, and resorts that rely on these consumers face a conundrum in that they skiing seasons are short and unpredictable. Once the ice or snow has melted, grass, dirt, and other dry surfaces, make winter style skiing impossible.
To combat this, composite materials have been created that are nearly as slick as the snow or ice, and in certain locations, small amounts of composite materials are laid onto the ground to enable skiers to use conventional or nearly conventional skis in areas that lack in snow. For example, the United States Olympic Training Center in Lake Placid N.Y. has installed a surface of composite materials on the hills below the ski jumping features, to allow ski jumpers to practice jumping when there is no snow or ice on the ground. However, the composite materials are generally expensive and it would be impractical to install such a material over a large portion of ground to enable use of typical winter skis. In other areas, indoor skiing relies upon chilling a large room and creating snow with a snow gun. However, each of these options have significant limitations.
Other methods of skiing without snow or ice have included placing plastic on a slope and using modified skis to slide down the plastic. Similarly, people have employed wood, such as plywood and have further added slick materials such as wax, paints, and oils to the surface to reduce friction. Typically still, these materials still require the use of non-traditional skis to move down the surface.
Several entities have tried to make summer skiing type products that include wheels or high friction materials to aid in sliding down a grass or other hard surface. For example, U.S. Pat. Nos. 3,827,706, 4,134,598, 4,460,187, 4,744,576, 4,886,298, 4,805,936, 5,125,687, 5,195,781, and 5,975,546 have tried to create a roller ski or snowboard but none have found success in the marketplace.
Typical patents have utilized various strategies to provide wheels that face in the direction of movement of the ski, while providing other wheels or mechanisms to allow the ski to “carve” as if on the edges of a typical winter snow ski.
Additional information and products related to summer style skis include: http://www.nordicskater.com/alpina/#summer; http://www.oxygenfedsport.com/2011/11/in-us-fischer-rollerskis-would-compete-in-a-small-market; and Grasskiusa.com.
Despite these prior art examples, no summer style ski has yet found an appropriate design to engage users of winter skiers, as the summer style skis often fail in the feel of sliding and carving that is found on winter skis. The embodiments described herein provide for a summer style ski that simulates sliding and carving movements, utilizes weight distribution and edge engagement to controls speed, and provides a unique summer skiing experience that seeks to more closely mimic winter style skiing.
An embodiment of the present disclosure comprises a wheeled ski comprising a base, a binding, and three different wheel types, arranged along the length of the ski; wherein the binding is centrally located along the longitudinal axis and the three wheel types have a having a mirror image wheel type on either side of the binding; wherein extending away from the binding along the longitudinal axis in each direction is a pair of fixed wheels having a fixed axle and the wheels extending away from the base along the lateral direction, where the wheels can rotate along a rotational axis and allow the ski to move along the longitudinal axis; extending further to the end of the ski from the fixed wheels are corresponding pairs of moveable axle wheels, having a mount with an axle positioned along the lateral axis and wherein the axle can move horizontally, as compared to the fixed axle wheels which do not move; finally, the outermost wheels are single caster wheels positioned at each end of the ski, and mounted on a Z-shaped mount.
A particular embodiment of the summer style ski comprises a base, a binding, a pair of caster wheels, two pairs of moveable axle wheels, and two pairs of fixed axle wheels each arranged along the longitudinal axis of the base; (a) wherein the base has a length, a width, a left edge, a right edge, a top, a bottom, a front and rear tip, and two cutout portions; (b) wherein connected to each of the front and rear tip is a caster support member that is roughly a Z shaped member, wherein one side of the Z shaped member is connected to a portion of the base at the front and rear tips, and the other end of the Z shaped member is positioned above the base and extends past the tip to be about parallel to the base; the end extending past the tip comprises a pivot member; attached to the pivot member is a caster wheel, which is positioned below the Z shaped member; (c) adjacent to the Z shaped member and positioned towards the center of the base along the longitudinal axis on each end, is a pair of adjustable axle wheels; wherein the adjustable axle is connected to the base and the axle extending along the lateral axis; wherein wheels are attached to each side of the axle and extend beyond the left and right edges of the base; (d) positioned within the two cutout portions of the base are two pairs of fixed axle wheels, wherein the fixed axle is secured to the base and positioned such that the axle is along the lateral axis; wherein the wheels are engaged to the axle and extend to be about even with the left and right edges of the base; and (e) about centrally positioned on the base, and between the fixed axle wheels, is a binding; and (f) wherein the three different types of wheels have varying vertical clearance with respect to the bottom base; wherein the fixed wheels have the smallest clearance between the bottom of the wheel and the bottom of the base; the adjustable wheels having the next smallest clearance; and the caster wheels on each end having the greatest distance between the bottom of the wheel and the bottom of the base; whereby when the ski is placed on a surface, only the caster wheels are necessarily touching the surface.
A further embodiment of the present disclosure comprises a wheeled ski comprising three types of wheels, a binding, and a base; (a) wherein the first type of wheel is a freely rotating wheel; with one wheel attached to a support member at each end of the longitudinal axis of the base; (b) attached adjacent to the freely rotating wheels on each end are a pair of movable axle wheels, wherein the axle is oriented in the lateral axis and having a rotational axis such that a wheel attached to the axle will propel the ski along the longitudinal axis; (c) attached between the pair of movable axle wheels on each end is a pair of fixed axle wheels, which are mounted closer to the center line of the base than the movable axle wheels, with the axle aligned along the lateral axis; (d) and centrally located is a binding that is situated between the two pairs of fixed axle wheels, and (e) wherein each of the three types of wheels has a different ground clearance, wherein the caster wheels touch the ground first, the adjustable wheels touch the ground next and finally the fixed axle wheels come into contact with the ground upon a force flexing the base and engaging the wheels. The wheel placement with regard to the longitudinal positioning of each of the types of wheels, and the vertical orientation of each of the wheels mimics the camber and side cut of a traditional snow ski.
The embodiments of the invention and the various features and advantages thereto are more fully explained with references to the non-limiting embodiments and examples that are described and set forth in the following descriptions of those examples. Descriptions of well-known components and techniques may be omitted to avoid obscuring the invention. The examples used herein are intended merely to facilitate an understanding of ways in which the invention may be practiced and to further enable those skilled in the art to practice the invention. Accordingly, the examples and embodiments set forth herein should not be construed as limiting the scope of the invention, which is defined by the claims.
As used herein, terms such as “a,” “an,” and “the” include singular and plural referents unless the context clearly demands otherwise.
As used herein, the term “about” means within 10% of a stated number.
The terms “summer ski” and “land ski,” are used interchangeably to mean a ski of the present disclosure that does not require snow or ice to move and includes wheels. In comparison a “winter ski” is intended for snow and ice use and does not have wheels, but has a low friction base and edges on each side of the base for turning on the snow or ice surface.
The embodiments described herein pertain to summer skis having a plurality of wheels that are aligned to create a ski that can be used on dry surfaces such as grass, cement, pavement, dirt, etc., and that simulate the sliding and carving movements of a winter ski. The summer ski utilizes weight distribution and edge engagement through the various wheels arranged on the length of the ski to control speed and engage in turning on a surface.
As can be seen, the base 4 provides for the main support for the summer ski 1, and the various wheels aligned along the longitudinal axis of the ski. The axles for the adjustable wheels 3 and 8 and their mounts 22 and 29 provide that the axle supporting these wheels is positioned along the lateral axis. The front and rear fixed wheels are secured to the front and rear fixed axles 14 and 15, which too are aligned along the lateral axis. Accordingly, the four axles are positioned so as to be perpendicular to one another, whereby wheels attached to the axles can rotate along a rotational axis to propel the ski generally along the longitudinal axis. However, by imparting forces onto the base 4, and carving, or apply pressure to one side of the ski as compared to another, the base 4, flexes, and the adjustable wheels and the movable axle moves with the force, and the fixed wheels, with the fixed axle, are engaged to the ground. This allows the feel of sliding along the ground similar to that of turning or carving as if on the snow.
Situated behind the caster wheel 2 is a pair of adjustable wheels 3. The adjustable wheels can use any of several axle systems to allow for this adjustment including a skateboard style rigid axle connected to a rubber grommet (See
Moving more centrally, towards the binding 6, the next sets of wheels are the fixed wheels 5 and 7. As compared to the adjustable wheels 3 and 8, these fixed wheels 5 and 7 also extend away from the base 4, but do not have as great of outboard distance as the adjustable wheels 3 and 8. In view of
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A typical rider often provides pressure through inclination or tipping of the ski to set an edge. This provides that the base 4 of the summer ski 1 is not parallel to the ground, but at an angle, and thus engages first the wheels on one side of the base, that is angled towards the ground. The adjustable wheels 3 and 8 engage first, creating a turning radius, and allows the rider to turn the ski. Additional pressure then can engage the fixed wheels 5 and 7, and achieves a tighter turning radius. Such radius and ability to turn is further achieved through the flexibility of the base in connection with the vertical displacement and the outboard displacement of the various wheel sets.
As is quite common, by increasing the speed of the rider, the summer ski operates more efficiently, due to increased balance and stability. Additionally at higher speeds, the rider has a greater ability to provide pressure to the skis.
Therefore, upon a mass being placed on the summer ski 1, the caster wheels 2 and 9 will contact the ground. Upon a sufficient mass or force, the adjustable wheels 3 and 8 will contact the ground. The adjustable wheels 3 and 8 imitate the ski edges at the tip or tail of a traditional winter ski. The adjustable wheels 3 and 8 rotate only in the direction of the ski and allow the skier to turn or carve the ski, much like a traditional winter ski. These adjustable wheels 3 and 8 provide further resistance to sliding motion and are particularly engaged during turning and stopping.
Turning to the innermost fixed wheels 5 and 7, under most circumstances the fixed wheels 5 and 7 will not touch the ground until a significant lateral force is applied by the user to turn or create and edge, as if skiing on winter skis or carving a skateboard. Accordingly, the fixed wheels 5 and 7 will then contact the ground and are engaged only during this hard carving, turning, or stopping. These fixed wheels 5 and 7 imitate the ski edges of a winter ski underfoot. The fixed wheels 5 and 7 rotate only in the direction of the centerline of the ski, whereas the caster wheels 2 and 9 can rotate and move in any direction, regardless of the position of the ski.
Further bindings are contemplated being a hybrid style binding using both a winter ski style binding and a snowboard style binding. The typical winter ski style binding comprises a firm boot that secures to a toe clip and a heel clip. Whereas the snowboard style binding typically uses a more flexible boot and a compression plate over the front of the foot to secure the foot and boot to a sole plate and heel plate attached to the base of the ski or board. A hybrid binding/attachment system would incorporate a variable stiffness tongue from a ski boot with a compression plate from the snowboard binding. The goal is to allow a user to wear regular athletic footwear with easy entry/exit, while maintaining the stiffness of a traditional ski binding. Other suitable bindings may include a downhill ski binding, a slalom binding, a cross-country ski binding, or a snowboard binding.
Although the present invention has been described in considerable detail, those skilled in the art will appreciate that numerous changes and modifications may be made to the embodiments and preferred embodiments of the invention and that such changes and modifications may be made without departing from the spirit of the invention. It is therefore intended that the appended claims cover all equivalent variations as fall within the scope of the invention.
Number | Date | Country | |
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62094357 | Dec 2014 | US |