The popularity of roller skating has continued to grow in this country, and it is estimated by the Roller Skating Association that more than forty million Americans engage in roller skating. Roller skating safety is a paramount concern to both participants and skate providers. Roller skating injuries, while statistically lower and less significant than many team oriented sports like basketball and soccer, still occur at a fairly high frequency. Roughly 3 participants in a thousand will injure themselves to the extent that hospitalization is required. Moreover, many of the injured skaters are experience skaters. Below is a table of injuries sustained by inline roller skaters.
The percentages are calculated for an estimated 6,331 persons treated in emergency departments nationally during the study period. They are based on data from 161 injured skaters, weighted according to the hospital in the NEISS sample in which they were treated.
As the statistics show, the cause of the injuries in many cases come from loss of balance or impact with a stationary object. Both of these conditions are related to a skater's speed, and the ability to brake safety when a hazardous situation arises. For that reason, there has been much work and research into safer braking systems, particularly for inline skates. Specifically, in most skate brakes, the skater must lift three wheels off the ground to make contact with a rear stopper on the back of the skate boot, causing instability in the skater.
U.S. Pat. No. 7,455,305 to Bellehumeur is directed to a skate brake particularly suited for an inline skate includes a braking carriage formed of left and right plates spaced apart by axles that support rollers thereon. The rollers engage the wheels of the skate when the carriage is maneuvered to the appropriate elevation, and the momentum of the wheels is arrested as a result of a frictional bearing of the rollers against the carriage surface. The carriage is raised and lowed by a rocker mounted below the skate and coupled to the carriage plates, where rotation of the rocker drives the plates and the carriage downward such that the rollers contact one or more wheels. The rocker is actuated by a linkage that includes a pushrod and a second rocker that is mounted to the skate boot, allowing the user to control the braking carriage by applying pressure to a rear location of the boot.
U.S. Pat. No. 7,264,091 to Bellehumeur is directed to a brake assembly for inline skates having a boot portion with right and left downwardly directed frame members. The frame members support at least three axles. Right and left carrier plates are positioned along an inner face of the downwardly directed frame members. At least two diabolos are supported by the right and left carrier plates. The diabolos each contact two wheels and are forced outwardly to provide a friction rubbing action against the carrier plates when the carrier plates have moved from a disengaged position to an engaged position.
While the skate brake art has shown advances over earlier braking systems, there is a constant striving to improve the overall effectiveness of the skate brake while minimizing wear on the brakes that result in premature replacement of wheels or other skate components. The present invention is directed to the goal of overall skate brake improvement.
The present invention is an improved skate brake particularly suited for an inline skate, wherein braking can be actuated while all four wheels are engaged with the ground. The system maintains superior control by keeping all four wheels on the ground, as opposed to a traditional rubber stopper which requires lifting the toe of the boot.
Another improvement in the present system is the ability to apply full braking force to the brake pad and frame plates, as opposed to applying the braking force directly to the wheels. The wheels are the trigger in activating the braking power. The braking system prevents slippage of the braking pad on the wheels, and resists “lockup” that could otherwise cause a skater to lose balance and also promotes flattening of that portion of the wheels touching the ground, leading to premature wear.
Braking power is activated by a downward application of force on an axel supporting the brake cones, which in turn forces the cones outward against the frame plates. This, in turn, causes the brake pad to be pressed against the frame plates to provide the friction needed to brake the skate. Braking cones may be serrated, but other forms of cone surface to provide friction, could be substituted.
If the wheel material is of a relatively soft material, no braking cone may be necessary, and the exact structure of the brake pad and brake cone could be constructed entirely of braking material, preventing slippage from occurring on the wheels.
These and other features of the invention will be understood in conjunction with the following description and associated drawings.
The frame 16 secures a plurality of inline wheels 40 using a parallel axel system as is known in the art, and the particular system for mounting the wheels is not critical to the present invention. Mounted on the boot 12 is a flexible cuff 22 that supports the ankle and surrounds the boot 12, where the cuff 22 may have a fastening system 24 to tighten about the boot and provide additional support for the skater. The fastening system can be a strap 24 as shown, laces, hook and loop fasteners, or the like. The cuff 22 is fastened to the pivoting bracket 26, which in turn is secured to a shell 28 that links the cuff 22 to the frame 16. In an alternate embodiment, the bracket may be formed as part of the cuff 22 or the shell 28. The pivoting bracket 26 is secured so that it can pivot about a pin 30 that passes through the plate 26 and the cuff 22, permitting a rearward rocking of the cuff 22 by the skater. This rearward rocking motion causes a clockwise rotation of the bracket 26 about pin 30 as shown in
The pushrods 32 coincide with the side of the skater's foot (as opposed to the back), depending almost vertically between the bracket 26 and the gap between the third and fourth wheels 40 when viewed from the side as seen in
The lower end of the push rod 32 is connected to an axel 34, which may include a tubular bearing spacer 34a over the axel 34 (see
The braking members 36a, 36b are preferably conical (or frustoconical) and cooperate to form a wedge therebetween that can contact and grip the wheels 40, further aided by serrations (see, e.g.,
When the skater applies a downward force on the pushrods 32, causing the axel 34 to lower until the braking members 36a, 36b contact the spinning wheels 40 on their side surfaces, the braking members 36a, 36b initially spin with the wheels 40 to provide little braking force. As more downward pressure is applied, the braking members 36a, 36b are wedged outward by the wheels 40 on the axel 34, causing contact with the free disk 41. The free disk 41 in turn will rotate with the braking members 36a, 36b but also engage the inner surface of the plates 16 (see
As shown in
As shown in
As stated above, one improvement of the just described system is the ability to apply full braking force to the brake pad and frame plates, as opposed to applying the braking force directly to the wheels. The wheels are the trigger in activating the braking power. The braking system prevents slippage of the braking pad on the wheels, and resists “lockup,” that could otherwise cause flattening of that portion of the wheels touching the ground. To effect the braking system, the skater leans his/her leg forward to shift the boot 12 ahead of the cuff 22, rotating the pivoting bracket backwards. Braking is activated by a downward movement of the push rods, and the brake cones, against the side of the wheels of the skate. Additional downward force drives the cones outward against the free disks, which are sandwiched between the brake cones and the skate frame plates. The compression of the free disk between the braking members and the frame retards the rotation of the wheels to brake the skate.
The foregoing description and associated drawings are intended to be illustrative only, and not limiting in any manner. Rather, it is to be understood that various modifications and substitutions would be readily understood and appreciated by one of ordinary skill in the art, and the present invention is intended to cover all such modifications and substitutions. Accordingly, nothing in this specification should be interpreted as limiting the scope of the present invention.
This application claims priority from U.S. Provisional Application No. 61/538,595, filed Sep. 23, 2011 incorporated by reference in its entirety.
Number | Date | Country | |
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61538595 | Sep 2011 | US |