The technical field relates generally to slacklining, more particularly to balance boards adapted for use during slacklining
Slacklining is a sport or physical activity that takes place on a narrow strip of flat webbing extending between two anchor points, such as large trees, rocks or any other suitable anchor points. The webbing is stretched to support the weight of a user standing thereon, although the webbing is not necessarily stretched so as to be rigidly taut like a tightrope.
The webbing on which slacklining is practiced is referred to as a “slackline”. It can be made of synthetic fibers, such as nylon or others, woven to form a strong fabric. A slackline is generally about 1 to 2 inches (2.5 to 5 cm) in width. A slackline is thus considerably larger than a tightrope and this allows the weight of a user to be distributed over a much larger area. A slackline is often positioned horizontally and relatively close to the ground surface, for instance at a height of about 12 to 24 inches (30 to 60 cm). The section extending between the two opposite anchor points is often about 10 to 12 feet (305 to 365 cm) in length. Variants exist. For instance, some users can practice slacklining higher from the ground surface and/or using longer slacklines. Some slacklines may not be set horizontally.
When slacklining, users may be simply standing on the slackline. Others may combine various movements such as walking, standing on only one foot, pivoting, etc. Acrobatic moves or stunts can be done by experienced users. Users may adjust the tension in the slackline to vary the amplitude of the sagging, the bouncing effect and other characteristics. The tension can be adjusted using a ratchet mechanism or the like. Variants are possible as well.
A slackline may be installed outdoors or indoors. Although slacklining is mostly practiced above a ground surface on which the user can stand, a slackline can also extend over a water surface.
Slacklining is currently a sport where users interact with the slackline either with shoes or barefooted. This limits the number of possible actions that can be accomplished on a slackline. More specifically, no additional piece of equipment specifically designed for use between the slackline and the user's feet during slacklining is available.
Some sports or physical activities are part of a category that can be referred to as boardsports. Boardsports involve specialized boards as primary pieces of equipment and their users stand in an upright position above these boards. Surfing, skateboarding, windsurfing and snowboarding, to name just a few, are examples of boardsports. Other examples exist as well. The feet of the users may or may not be strapped onto the board, depending on the kind of boardsport and/or the kind of boards chosen by a particular user.
Balance boards also involve a board as a primary piece of equipment. Balance boards are designed for use on cylindrical or spherical objects. Thus, unlike in boardsports such as surfing, skateboarding, windsurfing and snowboarding, the user does not travel over a given distance but remains essentially at the same location throughout the entire duration of the physical activity. The user's body must stay balanced enough to keep the board's tips from touching the ground surface and to prevent the user from falling off the board. Balance boards are often used for leisure, balance training, athletic training, brain development and physical therapy, to name just a few.
Using a balance board on a slackline has not been suggested yet, even if such equipment would represent a breakthrough in slacklining Also, using a balance board on a slackline has its own challenges since the board must have certain characteristics and features to interact with a slackline, as well the ground surface, in a proper way. For instance, a slackline balance board would need to be relatively stable when the user is on the slackline, easy to use and to position with reference to the slackline, and have a relatively simple and inexpensive construction. It must also be able to engage the ground surface and withstand impacts, if applicable. These desirable characteristics have not been found hitherto. Moreover, one cannot simply use an existing board, for instance one designed for other boardsports, and use it on a slackline as a balance board. The same is also true for existing balance boards. Since they are designed for use on cylindrical or spherical objects, they cannot address the challenges specific to slacklining
The goal of the proposed concept is to provide a slackline balance board that is specifically designed to transform slacklining into a boardsport.
Accordingly, the present concept relates to the introduction of balance boards adapted for use on a slackline and capable of overcoming the challenges of the unique environment which slacklining offers. The slackline balance board allows a user to stand on the slackline by placing the slackline balance board directly thereon, for instance perpendicular or parallel to the slackline to name just a few possible positions. This board has many advantages. With a balance board placed between the user's feet and the slackline, different new balancing and even acrobatic moves may be performed. This can greatly diversify how one uses a slackline and offer numerous new possibilities.
In one aspect, there is provided a slackline balance board for use on a slackline, the slackline balance board including: an elongated deck having an upper surface and a bottom surface, the deck including opposite first and second end sections; and a medial cambered section interposed between the first and second end sections, the medial cambered section being arched upwards with reference to a longitudinal axis; and two spaced-apart slackline guides secured to the bottom surface of the deck.
In another aspect, there is provided a slackline balance board as shown, described and/or suggested herein.
In another aspect, there is provided a method of using a slackline balance board as shown, described and/or suggested herein.
More details on the various aspects and features of the proposed concept will become apparent in light of the detailed description which follows and the appended figures where some examples of the slackline balance board are shown.
The illustrated slackline balance board 100 is approximately the same size as a standard skateboard. Like a standard skateboard, it includes an elongated deck 102, namely a deck whose length along a longitudinal axis exceeds its width. The bottom surface 106 is designed to engage a slackline. The deck 102 also has an upper surface 104 and a bottom surface 106. However, unlike in a standard skateboard, the deck 102 has a unique shape and is not generally flat, among other things. The longitudinal axis is schematically represented in
The deck 102 can be made of a dense but slightly resilient monolithic material. The deck 102 must resist the weight of the user on the slackline but still be light enough to provide the user with a maximum freedom of movement. It can be manufactured using a similar process as for the manufacturing of skateboards, for instance using multiple thin layers of wood that are glued together and shaped by compression using a mold. The various layers can be configured and disposed so as to vary the level of flexibility of the deck 102 in one or more axes. In some implementations, the deck 102 can include one or more materials to replace or in addition to wood, for instance materials such as plastics, polyvinyl carbonate, carbon fiber, etc. Other variants are also possible.
In the illustrated example, the medial cambered section 114 amounts to about half of the total length of the deck 102. The first and second end sections 110, 112 are also equal in length. Variants are possible as well.
The slackline balance board 100 further includes two spaced-apart slackline guides 130 secured to the bottom surface 106 of the deck 102. The slackline guides 130 extend transversally and are adjacent to a junction of the medial cambered section 114 with reference to a corresponding one among the first and second end sections 110, 112. The slackline guides 130 are positioned under the end sections 110, 112 and their inner transversal edges define the boundaries between the corresponding end sections 110, 112 and the medial cambered section 114. The slackline guides 130 are useful to act as stoppers, thereby limiting movements of the slackline balance board 100 on the slackline and helping the user in keeping the slackline within the same section 110, 112, 114 underneath the board 100.
In the illustrated example, each slackline guide 130 includes two spaced-apart and downwardly-projecting guide members 132. They can be fixed onto the slackline balance board 100 using, for instance, corresponding screws or using bolts attached the threaded inserts passing through the thickness of the slackline balance board 100. Threaded inserts for the guide member fasteners are visible in
Each of the first and second end sections 110, 112 of the deck 102 illustrated in
The slackline balance board 100 of
In use, the slackline balance board 100 can be positioned at various angles on a slackline. Most beginners may start by setting the slackline balance board 100 substantially perpendicular or transversal to a slackline The bottom surface 106 underneath the medial cambered section 114 is arched-shaped. The shaped profile creates a self-centering tendency that will help keeping the slackline at a neutral balanced position when the user tries to maintain balance thereon, thereby greatly improving the overall stability. Moreover, the bottom arched surface allows the slackline balance board 100 to engage the slackline directly from above, even if the slackline balance board 100 is oriented at an angle with reference to the horizontal. The slackline will tend to be positioned at the highest point of the arched surface underneath the slackline balance board 100 and this will help the user staying over the slackline instead of slipping away. More experienced users may use slackline balance boards 100 with less curvature.
A non-slip material can be applied or otherwise provided on at least some of the upper surface 104 of the slackline balance board 100. This will improve grip and, for instance, help the user to stay on the slackline balance board 100 while doing tricks or the like. The non-slip material may be for example a grip tape, Ethylene vinyl acetate (EVA) foam or any other suitable product that can enhance adherence. A grip tape can be generally defined as a sheet of paper or fabric with adhesive on one side and a surface similar to sandpaper on the other. Variants are possible as well.
The slackline balance board 100 illustrated in
In addition to the longitudinal slackline-receiving channel 134, three guiding areas 140, 142, 144 are also created under the bottom surface 106 by the slackline guides 130. The first and second ones are outer guiding areas 140, 142. They are located between the outer side of a corresponding one of the slackline guides 130 and the nearest tip 120. The inner guiding area 144 is located between the inner sides of the two slackline guides 130. These guiding areas 140, 142, 144 are useful when the slackline balance board 100 is placed perpendicular on the slackline or at an angle. The guide members 132 act as stoppers to prevent the slackline balance board 100 from easily sliding off the slackline.
It should be noted that in
When the slackline balance board 100 is placed perpendicular to the slackline and the slackline engages the bottom surface 106 within the inner guiding area 144, the two opposite pairs of guide members 132 will help to keep the slackline inside the inner guiding area 144, particularly when the board 100 is oriented to define an angle with reference to the horizontal. The curved arched surface underneath the slackline balance board 100 is what essentially maintains the slackline centered when the board 100 is horizontal or almost horizontal.
When the slackline balance board 100 is placed perpendicular to the slackline and the slackline engages the bottom surface 106 in one of the two outer guiding areas 140, 142, the nearest pair of guide members 132 will help to prevent the slackline from easily going into the inner guiding area 144. Finally, when the slackline balance board 100 is placed parallel to the slackline, the longitudinal slackline-receiving channel 134 will help to keep the slackline balance board 100 in alignment with the slackline.
The slackline guides 130 can be made of different materials. Examples of materials include thermoplastic, polyurethane, thermoplastic rubber, wood, etc. Other materials can be used as well.
The material can be chosen to absorb shocks and impacts, for instance when the guide members 132 hit the ground surface. The material can also be chosen to increase or decrease the friction coefficient with the slackline.
Alternatively, as aforesaid, the slackline guides 130 can also be made integral with the deck 102, for instance if the deck 102 is manufactured using a composite construction process or using a plastic injection process. The slackline guides 130 are thus secured to the bottom surface 106 of the deck 102 when the two are made integral with one another.
In
Also, as best shown in
It should be noted that the longitudinal slackline-receiving channels 134, although very useful, could be omitted in some implementations.
The foot retaining system 150 allows the user's feet to remain attached to the slackline balance board 100 during the different moves (jumps, rotations, etc.). The foot retaining system 150 may be integral (much like snowboard bindings where parts must be detached or otherwise opened to release a foot) or partial (allowing the foot to be slid out more easily if desired). The illustrated foot retaining system 150 is a partial type. Variants are possible as well.
The illustrated foot retaining system 150 has two sides, namely one for the right foot and one for the left foot. Each side includes a pair of adjustable straps 152. One end of these straps 152 is secured to the upper surface 104 of the deck 102, for instance using screws 154 or similar kinds of fasteners that were attached to preinstalled inserts provided on the deck 102. Variants are possible as well. These straps 152 of each pair form a loop and the size of the loop can be adjusted, in the illustrated example, using corresponding buckles 156. Velcro bands can also be used. Other variants are possible as well. The straps 152 are generally oriented parallel to the longitudinal axis 116 in the example and the user will insert his or her feet from the side of the slackline balance board 100. The user's feet will be substantially parallel to one another (flat stance).
Even if one does not provide a complete foot retaining system on a board 100, it is possible to manufacture the deck 102 of the board 100 with preinstalled threaded inserts at various locations. These preinstalled threaded inserts are made integral with deck and are opened on the upper surface for solidity. The inserts can be made, for instance, of metal or plastics. Other materials are possible as well. They may allow a user to purchase a board 100 without a foot retaining system and to select a foot retaining system later and/or to use a foot retaining system that the user had on a previous board 100. Straps and other binding elements can be easily installed with the preinstalled threaded inserts.
As can be seen in
In
As can be seen, the slackline balance board 100 of
It should be noted that preinstalled inserts for the foot retaining system 150 can be seen in
Overall, the slackline balance board 100 of the proposed concept gives users new possibilities. It is somewhat a mix between a bouncing board for use with a trampoline, and a traditional balance board. Creative boarders will soon unveil the full potential of this new sport.
The present detailed description and appended figures are only examples. A person working in this field will be able to see that variations can be made while still staying within the framework of the proposed concept. For instance, the medial cambered section 114 of the deck 102 could be partially opened instead of being an uninterrupted solid surface. The upper surface 104 and the bottom surface 106, in such medial cambered section 114, would be provided by the upper and bottom surfaces of elongated and narrow rigid members attaching the two opposite end sections 110, 112. The slackline guides 130 can also include a flanged portion projecting into the inner guiding area 144. These flanged portions could face one another and act as hooks for further holding the board 100 on the slackline 210. The exact shape of the deck 102 can be different from what is shown. The slackline guides 130 could be disposed in a non-parallel manner with reference to one another in some implementations. Different other kinds of foot retaining systems can be used. The angle of the straps or of other kinds of foot retaining devices can be different to what is shown and described. As users become more experienced, they can experiment with different stances to find what is best for them.
The present case claims the benefit of U.S. Patent Application No. 62/055,274 filed on 25 Sep. 2014,which application is hereby incorporated by reference in its entirety.
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Number | Date | Country |
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202011108718 | Mar 2012 | DE |
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Machine translation in English of DE 20 2011 108 718 U1. |
Number | Date | Country | |
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20160089577 A1 | Mar 2016 | US |
Number | Date | Country | |
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62055274 | Sep 2014 | US |