Patent Grant
7150461
The present invention relates to skateboard devices. In particular, the present invention relates to a foldable skateboard.
A conventional skateboard typically consists of a rigid deck with front and rear truck assemblies attached thereto. A user stands upon the deck, and can control the direction in which the skateboard is traveling by shifting weight to certain places about the board. In most cases, the truck assemblies are located directly beneath the deck, which inherently results in the deck being positioned higher than axes of the wheels of the truck assemblies. This raises the user's center of gravity upon mounting the skateboard. By lowering the deck such that it lies in the same plane in which the axes of the wheels lie, the user's center of gravity is kept closer to the ground, resulting in the skateboard becoming more stable and maneuverable.
Conventional skateboards are also by their nature bulky and difficult to carry when not in use. An example of this type of problem is the banning of skateboards at convenience stores not only because the owner's of such stores do not want the skateboards to be ridden in the store, but also because the skateboards can knock items off of shelves and counters if the child is not paying attention to how he or she is carrying the skateboard. The same type of problem exists at households where children are careless when carrying the skateboard, and due to its bulkiness, accidentally knock the skateboard into household objects, which leads either to their damage or destruction.
Another problem associated with conventional skateboards is storage. Due to their bulkiness, conventional skateboards tend to take up considerable storage space. Alternatively, if not stored properly, skateboards may be accidentally stepped on causing an injury to the person.
The present invention includes an articulated skating apparatus positionable between a skating position and a folded position. The articulated skating apparatus includes a forward portion and a rearward portion pivotally attached to a cradle. The cradle includes a foot platform for resting at least one foot of a user thereon. While in the folded position, the forward portion and the rearward portion pivot into and nest within the cradle. Both the forward portion and the rearward portion include a wheel assembly having at least one ground engaging wheel. While in the skating position, an axis of at least one forward ground engaging wheel, an axis of at least one rearward ground engaging wheel and the foot platform all lie substantially within the same plane. A cable assembly attachable to the forward portion and the rearward portion provides semi-rigid support to the articulated skating apparatus. The articulated skating apparatus further comprises a steering dampening assembly for selectively controlling the steering of the articulated skating apparatus.
A preferred embodiment of an articulated skating apparatus according to the present invention is generally indicated at 10 in
The neck portion 12 of the skating apparatus 10 comprises a nose assembly 24, a truck assembly 26, and a steering dampener assembly 28. The nose assembly 24 includes support arms 30 pivotally attached to truss members 32 of the cradle 16. As illustrated in
The truck assembly 26 includes a truck housing 38 for supporting the front axle 18. Attached to opposing ends of the front axle 18 are wheels 40 secured by screws 42. The truck housing 38 further includes a medial aperture 44 therethrough, positioned transverse to the front axle 18, for receiving an attachment means to pivotally secure the truck assembly 26 to the nose assembly 24. Pivotally securing the truck assembly 26 to the nose assembly 24 assists in maneuvering or directing the skating apparatus 10 in a particular direction. Additionally, each forward wheel 40 is independently rotatable, which further assists in turning and maneuvering.
To control the ease at which to steer or maneuver the articulated skating apparatus 10 of the present invention, the steering dampener 28 is provided. The steering dampener 28 includes a nose shaft 46, a damper rod 48, a damper spring 50, a damper bumper 52, a damper spacer 54 and a damper nut 56. The nose shaft 46 nests within the medial aperture 44 of the truck housing 38, pivotally securing the damper rod 48 to the truck housing 38. The damper rod 48 threadably engages the nose shaft 46. The damper bumper 52 and the damper spring 50 slidably engage the damper rod 48. The damper spring 50 urges the damper bumper 52 into engagement with an outside semi-circular surface 53 of the truck housing 38. Securing the damper bumper 52 and the damper spring 50 to the damper rod 48 are the damper spacer 54 and the damper nut 56. The damper nut 56 threadably engages the damper rod 48, and by selectively adjusting the damper nut 56, the force needed to steer the articulated skating apparatus 10 can be modified. Because the truck assembly 26 pivots about the nose shaft 46 inserted through the medial aperture 44 of the truck housing 38, rotating the truck assembly 26 assists in cornering and maneuvering the skating apparatus 10. However, depending upon the desired use of the skating apparatus 10, it may be desirable to modify the amount of force needed to pivot the truck assembly 26.
The steering dampening assembly 28 is designed to selectively control the ease at which the truck assembly 26 can be rotated with respect to the nose assembly 24. Upon pivoting from a neutral position, the truck housing 38 urges the damper bumper 52 away from the nose shaft 46. The damper bumper 48, however, is also urged in the opposite direction against the truck housing 38 by the damper spring 50, which is disposed between the damper bumper 52 and the secured damper spacer 54. Increasing the rotation of the truck assembly 26 away from the neutral position requires increasingly greater force as the damper spring 50 exerts greater force onto the damper bumper 52 and subsequently onto the truck housing 38. To selectively modify this force, the damper nut 56 is rotated to urge the damper spacer 52 along the damper rod 48. The force of the damper spring 50 is increased by rotating the damper nut 56 in a clockwise direction, which causes the damper spacer 54 to travel toward the truck housing 38. The force of the damper spring 50 is decreased by rotating the damper nut 56 in a counter-clockwise direction, which causes the damper spacer 54 to travel away from the truck housing 38. It should be understood, though, that this depends upon the threading of the damper rod 48 and the damper nut 56, and reversing the directions by which to increase or decrease the depth of the damper spacer 54 is well within the scope of the present invention.
As described, the tail assembly 14 can pivot about the cradle 16 of the skating apparatus 10. Strut members 58 of the tail assembly 14 pivotally attach to the truss members 32 of the cradle 16. The strut members 58 extend away from the cradle 16, eventually curving toward one another. As best illustrated in
The tail plate 70 includes a support rib 82 centrally disposed along a longitudinal axis of the skating apparatus 10. In conjunction to the support rib 82 providing rigidity to the tail plate 70, the support rib 82, is also utilized in the latching mechanism 62. The tail plate 70 further includes a skid plate 84 also disposed on the underside of the tail plate 70 which can be used as a braking means when contacting the ground. The tail plate 70 and skid plate 84 each include an aperture 86 therethrough which can be used as a handle when carrying the skating apparatus 10, either while in the folded or unfolded position. Additionally, a strap 88 may be attached through the aperture 86, allowing the skating apparatus 10 to become a toting apparatus, as illustrated in
Referring again to
The latching mechanism 62 attaches to the axle support 66 and the strut members 58. The latching mechanism 62 locks the skating apparatus 10 into the first open position by latching the tail assembly 14 to the cradle 16 and prohibiting both the neck assembly 12 and the tail assembly 14 from further pivoting. The latching mechanism 62 includes a finger grip 90, a spring 92 to urge the finger grip 90 into placement, leg covers 94 for cooperatively engaging support plates 96 attached to the deck 22 of the cradle 16, and the support rib 82 for engaging the finger grip 90. Pins or screws 98 insert through the finger grip 90, spring 92 and leg covers 94 to secure the latching mechanism 62 to the axle support 66 and strut members 58. The latching mechanism 62 operates by rotating the tail plate 70 such that the support rib 82, attached thereto, travels toward the finger grip 90. Upon engaging, the finger grip 90 is urged away from the support rib 82 which has a declined surface 99. Upon traveling past the declined surface 99, the finger grip 90 is urged back into position by the spring 92, thus locking the tail plate 70. To release the tailplate 70, the finger grip 90 is urged away from the tail plate 70 by hand, and upon the finger grip 90 disengaging from the support rib 82, the tail plate 70 is unlocked. The latching mechanism 62 works in conjunction with a cable assembly 100 to provide rigidity and lock the skating apparatus 10 while in the unfolded skating position.
As illustrated in
Upon unlatching the tail plate 70 from the rear assembly 14, the tail plate 70 is permitted to rotate about the rear assembly 14. Rotating the tail plate 70 away from the rear assembly 14 permits the cable 102 to become slack because the cable 102 is attached to the tail plate 70. Upon the cable 102 becoming slack, the ferrel 112 can be released from the ferrel guide 118, as illustrated in
To unfold the skating apparatus 10 from the folded position to the skating position, the steps to fold the skating apparatus are simply reversed. First the rear assembly 14, and then the forward assembly 12, are rotated away from the cradle 16 as illustrated in
A second embodiment of the present invention is generally indicated at 200 in
The neck assembly 204 includes neck members 214 and a center arm 216. The neck members 214 pivotally attach to the cradle arms 206, thus allowing the neck assembly 204 to rotate relative to the cradle arms 206. The cradle arms 206 are spaced apart from one another a selected distance which defines the width of the skating apparatus 200. The selected distance between the cradle arms 206 and subsequently the width of the skating apparatus 200 may vary depending upon the size of foot the skating apparatus 200 is designed for. Preferably, the selected distance between the cradle arms 206 will be one which accommodates a range of average foot sizes. Opposing ends of the neck members 214 meet and connect with one another along a longitudinal axis located halfway between the cradle arms 206. The support arm 216 connects to and extends away from the neck members 214 at this juncture 215. Attached to an opposing end of the support arm 216 is a clevis 218 for securing the front wheel assembly 202. The front wheel assembly 202 includes spaced apart, ground engaging wheels 220 connected by and attached to an axle 222. The axle 222 includes a medial aperture (not shown) therethrough for receiving a pin 224, whereby the axle 222 pivotally attaches to the clevis 218 of the center arm 216. Each ground engaging wheel 220 is free to rotate independent of one another, or at differential speeds, which further assists in turning and cornering.
The tail assembly 210 includes connecting tail members 226, a tail arm 228 and a tail platform 230. The tail members 226 are each pivotally attached to the cradle arms 206. Opposing ends of the tail members 226 meet and connect with one another along the longitudinal axis located halfway between the cradle arms 206. The center tail arm 238 attaches to and extends away from the tail members 226 at the junction where the support arms 226 meet. A terminal end of the tail arm 228 includes an aperture (not shown) for receiving a rear axle 232 of the rear wheel assembly 212.
In addition to the rear axle 222, the rear wheel assembly 212 includes ground engaging wheels 220 positioned on the rear axle 222 such that the tail arm 216 disposes between each wheel 220. Each wheel 220 has a frusto-conical configuration having a greater radius at the center and decreasing outwardly. The slant of the rear wheels 220 works in conjunction with the front wheel assembly 202 to assist in maneuverability of the skating apparatus 200.
The tail platform 230 of the tail section 210 includes mount supports 236 extending downwardly from peripheral edges. Each mount support 236 includes an aperture suitable for accepting and inserting threaded terminal ends of the rear axle 232 therethrough. Caps 238 threadably engage each threaded terminal end of the rear axle 232 to pivotally secure the tail platform 230 to the axle 222, which also secures the rear axle to the tail arm 228. A third aperture (not shown) is positioned near a forward end of the tail platform 230. The third aperture of the tail plate 230 is cooperatively alignable with a medial aperture positioned through the tail arm 238. Upon aligning, a threaded bolt 242 or pin may be inserted through each aperture. A threaded cap engages the threaded bolt 242 to fasten the forward end of the tail platform 230 to the tail section 210. The tail platform 230 supports a non-leading foot of the user thereon. Preferably, the tail platform 230 includes a non-skid surface to prevent the non-leading foot from slipping during use.
The deck 208 is preferably constructed of durable fabric. A support platform 246, tension loop 248 and a tension bar 250 are provided to assist in supporting the weight of the user. The deck 208 may be constructed to include a major axis and a minor axis. Along the minor axis protrudes wings 252 of material. Each wing 252 is folded over itself and sewn so as to form a cylindrical channel 254. Each wing 252 is insertable through an elongated slot 256 contained in the respective cradle arm 206. Upon inserting the cylindrical channel of each wing 252 through the respective slot 256, a rod (not shown) having a diameter greater than the width of each slot 256 is inserted through each channel 254, thus preventing the wings 252 from being removed from the slots 256.
Along the major axis of the deck 208 runs the tension loop 248. The tension loop 248 preferably comprises a continuous loop of wire cable having a selected length. However, it would also be within the scope of the present invention to include two separate tension wires instead of a continuous loop. The tension loop 248 nests within the clevis 218 and is securably positioned by the threaded bolt 242 which also secures the tail plate 230. As illustrated in
The rigid deck platform 246 is positioned upon the durable fabric of the deck 208. The deck platform 246 provides an area for the user to place a leading foot while using the skating apparatus 200. The deck platform 246 attaches to the fabric 208 by means of a fastener 260. The fastener 260 inserts through an aperture in the fabric. Additionally, the fastener 260 also rotatably secures the tension bar 250 to the underside of the deck 208. An aperture in the tension bar permits the fastener to be inserted therethrough. By rotating the tension bar 250, the tension loop 248 can be brought under tension or relaxed.
The tension loop 248 has a fixed selected length and is secured to the neck assembly 204 and the tail assembly 210 as described. Preferably, the selected length of the tension loop 248 depends upon the length between the attaching points on both the neck assembly 204 and the tail assembly 210 while the skating apparatus 200 is in the first open position. This selected length permits the tension loop 248 to be somewhat slack in a natural state, for example, when the tension bar 250 is not acting upon the tension loop 248. When the tension bar 250 is positioned along the major axis of the skating apparatus 200, the tension bar 250 does not come into contact with the tension loop 248, and the tension loop 248 is in the relaxed state. When the tension bar 250 is positioned along the minor axis of the skating apparatus 200, the tension bar 250 comes into contact with both cables of the tension loop 248, and urges the cables apart from one another, as illustrated in
As described, folding and unfolding of the skating apparatus 200 is accomplished by rotating the neck assembly 204 and the tail assembly 210 in relation to one another and the cradle arms 206. To fold the skating apparatus 200 from the first open position to the second folded position, the threaded bolt 242 is unfastened, thus unfastening the tail plate 230 and tension loop 248 from the tail arm 228. The neck assembly 204 is rotated into the cradle 206 such that the front wheel assembly 202 is positioned proximate the deck 208. The tail assembly 210 is rotated into the cradle 206 such that the tail assembly 210 is positioned proximate the neck assembly 204 and the deck 208. The tail plate 230 is then positioned substantially parallel to the deck 208. Upon rotating the neck assembly 204, the tail assembly 210 and the tail plate 230 as described, the skating apparatus 200 is in the second folded position. It should be noted, however, that it is within the scope of the present invention to modify the design of either the neck assembly 204 or the tail assembly 210 so as to rotate either assembly ahead of the other to place the skating apparatus 200 into the folded position. To unfold the skating apparatus 200, the process as just described is reversed. When the skating apparatus 200 is in the unfolded skating position, the front axle 222, the rear axle 232 and the deck 208 are all positioned substantially within the plane B—B, as illustrated in
A third embodiment of the articulated skating apparatus according to the present invention is generally indicated at 300 in
The neck assembly 304 includes neck members 312 connected to nose members 314. Disposed between and attached to the nose members 314 is a nose core 316 which contains an aperture 318 for positioning a retaining bolt (not shown) therethrough. The retaining bolt (not shown) secures the front wheel assembly 302 to the neck assembly 304. The front wheel assembly 302 includes ground engaging wheels 322 connected by and attached to terminal ends of a front chassis member 324. The front chassis member 324 includes an aperture (not shown) therethrough for receiving the retaining bolt to secure the front wheel assembly 302 to the neck assembly 304. The front chassis 324 is pivotally secured to the neck assembly 304 which allows the front wheel assembly 302 to be rotatable with respect to the neck assembly 304. Additionally, each ground engaging wheel 322 may rotate independent of one an-other, or at differential speeds, which further assists in turning and cornering.
The rear wheel assembly 310 includes an axle 326, a ground engaging wheel 328, a tail plate 330 and a rear deck attachment 332. The wheel 328 is medially positioned on the axle 326. Tail arms 334 of the rear deck attachment 332 are positioned on the axle 326 proximate to opposing sides of the wheel 328. Positioned proximate the rear deck attachment 332 are downwardly extending members 336 of the tail plate 330. The wheel 328, rear deck attachment 332 and the tail plate 330 are all rotatable about the axle 326. Positioned on opposing terminal ends of the axle 326 are the tail arms 334. Each tail arm 334 secures to the respective opposing terminal ends of the axle 326, thus securing the wheel 328, rear deck attachment 332 and the tail plate 330 to the axle 326. Opposing ends of the tail arms 334 rotatably attach to the respective neck arms 334.
The deck 306 is preferably constructed of flexible material, and is attached to the neck assembly 302 by means of a front deck attachment 340, and is attached to the tail assembly by means of the rear deck attachment 332. A forward deck support 342 and a rearward deck support 344 are included to assist in supporting the weight of the user. Attachment of the flexible deck 306 to the front deck attachment 340 and the rear deck attachment 332 may be accomplished by any suitable means including, but not limited to, rivets, bolts, screws or adhesion. The front deck attachment 340 is pivotally anchored to the neck assembly 304. The front deck attachment 340 is also pivotally secured to the neck portion 304 and the rear deck attachment 332 is pivotally secured to the rear wheel assembly 310, thus allowing the deck 306 to flex more easily upon folding the skating apparatus 300. Rotatably mounting the front and rear deck attachments 340 and 332 also enhances conformity when placing a foot of the user thereon.
Preferably, the forward deck support 342 is pivotally attached at the juncture where the neck arms 312 pivotally attach to the tail arms 334, and the rearward deck support 344 is pivotally attached to the tail arms 334 proximate the rear wheel assembly 310. However, the position of either deck support 342 or 344 may be repositioned and still be within the scope of the present invention. Both deck supports 342 and 344 are pivotally attached such that they collapse upon folding the skating apparatus 300. When the skating apparatus 300 is in the unfolded skating position, the chassis member 324, the rear axle 326 and the deck 308 are all positioned substantially within plane C—C, as illustrated in
A fourth embodiment of the articulated skating apparatus of the present invention is generally indicated at 400 in
The neck assembly 404 includes neck members 414 which eventually meet to form a neck support arm 416. The neck members 414 are each pivotally attached to the respective cradle members 406. Each neck member 414 initially has an approximate quarter-circular shape but, upon meeting and engaging one another, each arm 414 straightens and continues on a downward slant, forming the structure of the neck arm 416. Positioned about the neck is a circular member 418 and support braces 420. The circular outer member 418 assists in supporting the front wheel assembly 402.
As illustrated in
The dampening system 432 includes compressible washers 444 and 446 positioned between proximal ends of the bushings 440 and 442 and the neck support 416. The axles 422 and 424 each contain a cylindrical channel therethrough for receiving and accepting extensible shafts 448 and 450. The extensible shafts 448 and 450 engage the compressible washers 444 and 446, respectively, which engage the neck arm 416. The extensible shafts 448 and 450 may be lengthened or shortened by set screws 452 and 454 located within a hub 456 and 458 of each wheel 426 and 428. Extending the shafts 448 and 450 compresses the washers 444 and 446 against the neck arm 416, Which in turn decreases the ease at which the front wheel assembly 402 may be rotated. To increase the ease at which the front wheel assembly 402 may be rotated, the extensible shafts 448 and 450 are drawn away from the washers 444 and 446, which in turn does not provide as great a force upon the neck support arm 416.
Referring back to
The tail assembly 410 includes a tail plate 468 and axle arms 470. The support arms 470 each include an aperture therethrough for receiving a bolt to pivotally attach the rear wheel assembly 412 to the cradle arms 406. The axle arms 470 are positioned such that the outer spacers are positioned between the respective axle arms 470 and the respective wheels 466. The tail plate pivotally attaches to the cradle members 406 by securing pin 472. Additionally, the tail plate includes a center downwardly extending member (not shown) positionable between the ground engaging wheels 466 whereupon the downwardly extending member rests upon the center spacer positioned between the wheels 466. The tail platform 468 supports a non-leading foot of the user thereon. The tail platform 468 may by coated with a non-skid surface to prevent the non-leading foot from slipping during use. A rear portion of the tail platform may also include a handle 474 for which the user can grab to carry the skating apparatus 400, whether the skating apparatus 400 be in the first open position or the second folded position.
The deck portion 408 includes a flexible deck 478, a front deck attachment 480, a rear deck attachment 482 and a deck support brace 484. Opposing ends of the flexible deck 403 attach to the front and rear deck attachments 480 and 482. Attachment of the flexible deck 470 to the front deck attachment 480 or the rear deck attachment 482 may be accomplished by any suitable means including, but not limited to, rivets, bolts, screws or adhesion. The front deck attachment 480 pivotally anchors to the neck 404 while the rear deck attachment 482 pivotally secures to the cradle members 406, preferably on the same pin 472 which attaches the tail plate 468 to the cradle members 406. Both the front deck attachment 480 and the rear deck attachment 482 are pivotally mounted to the neck portion 404 and the tail portion 410 such that the deck 478 flexes more easily upon folding the skating apparatus 400. Pivotally mounting the front and rear deck attachments 480 and 482 also enhances conformity of the flexible deck 478 when placing a leading foot upon the deck.
The deck support brace 484 is positioned towards the forward end of the skating apparatus 400, preferably more proximate the neck assembly 404 as opposed to the tail assembly 410. However, the position of the deck support brace 484 can be positioned either way and still be within the scope of the present invention. Preferably, the deck support brace 484 pivotally attaches to the cradle members 406. The deck support brace 484 is such that it collapses between the cradle members 406 upon folding the skating apparatus 400 as illustrated in
A fifth embodiment of the articulated skating apparatus according to the present invention is generally indicated at 500 in
As illustrated in
The neck assembly 504 includes neck members 524 and a steering dampening assembly 526. The neck members 524 are each pivotally attached to the cradle 506. Opposing ends of the neck members 524 each include a rectangular notch 528 to receive the housing 520 of the front wheel assembly 502. Spaced between the opposing ends of the neck members 524 is the steering dampening assembly 526. The steering dampening assembly 526 comprises a control bolt 530, mateable sleeve 532, a pusher 534, a compressible spring 536 and a positionable block 538, all encased within a neck core 540. The neck core 540 contains a first rectangular cavity 542 which houses the positionable block 538, compressible spring 536 and pusher 534. The neck core 540 also contains a second circular cavity 544 which seats the mateable sleeve 532. The neck core 540 secures to the neck members 524 by means of bolt attachments 546. The front wheel assembly 502 is attached to the neck assembly 504 by a center pin 548 inserted through the neck core 540 and the medial apertures 522 of the housing 520 and solid body core 514.
The front wheel assembly 502 pivots about the bolt 548 inserted through the medial apertures 522. As discussed, pivoting the front wheel assembly 502 assists in cornering and maneuvering the skating apparatus 500. However, depending on the type of use the skating apparatus 500 is to be put through, it may be desirable to modify the amount of force needed to pivot the front wheel assembly 502. The steering dampening assembly 526 is designed to selectively control the ease at which the front wheel assembly 502 can be rotated with respect to the neck 504. The front wheel assembly 502 is allowed to pivot about the central pin 548. The positionable block 538 of the dampening assembly 526 abuts a top surface 550 of the housing 520. The positionable block 538 is urged against the housing 520 by the compressible spring 536, which is disposed between the positionable block 538 and the pusher 534. In a like manner, the spring 536 urges the pusher 534 against the control bolt 530 which threadably engages the mateable sleeve 532. Upon pivoting the front wheel assembly 502 in either direction, the positionable block 538 is urged deeper within the rectangular cavity 542 against the force of the compressible spring 536. The more the front wheel assembly 502 is rotated, the greater the force the compressible spring 536 exerts onto the positionable block 538 and subsequently onto the housing 520 of the front wheel assembly 502. To selectively modify this force, the depth of the control bolt 530 is either increased or decreased. The depth of the control bolt 530 is increased by rotating the control bolt 530 in a clockwise direction, while the depth is decreased by rotating the control bolt 530 in the counter-clockwise direction. It should be understood, though, that this depends upon the threading of the mateable sleeve 532, and reversing the directions by which to increase or decrease the control bolt 530 depth is well within the scope of the present invention. Increasing the depth of the control bolt 530 urges the pusher 534 deeper within the rectangular cavity 542, which compresses the spring 536, resulting in a greater force upon the positionable block 538, which decreases the ease at which the front wheel assembly 502 pivots. By decreasing the depth of the bolt 530, the compressible spring 536 urges the pusher 534 away, resulting in a lesser force upon the positionable block 538, which increases the ease at which the front wheel assembly 502 pivots.
The rear wheel assembly 510 includes an axle 552, a center spacer (not shown) and ground engaging wheels 556. The wheels 556 are positioned on the axle 552 such that the center spacer (not shown) is positioned between each wheel 556. Each wheel 556 has a frusto-conical configuration having a greater radius at the center and decreasing outwardly. The slant of the rear wheels 556 works in conjunction with the front wheel assembly 502 to assist in the maneuverability of the skating apparatus 500. When the skating apparatus 500 is in the unfolded skating position, the front axle 516, the rear axle 552 and the cradle 506 are all positioned substantially within plane E—E, as illustrated in
The tail assembly 508 includes tail arms 558, a tail platform 560 and a locking mechanism 562. The tail arms 558 are each pivotally attached to the cradle 506. Opposing ends of the tail arms 558 each include an aperture therethrough for receiving the rear axle 552. The tail platform 560 includes mount supports 566 extending downwardly from peripheral edges. Each mount support 566 pivotally attaches to terminal ends of the rear axle 552. Each mount support 566 is positioned between the respective wheel 556 and tail arm 558. Caps (not shown) threadably engage each terminal end of the axle 552 to secure the tail platform 560 and the tail arms 558 thereto.
The locking mechanism 562 works in conjunction with the tension cable 572 to lock and provide rigidity to the skating apparatus 500 while in the first open position. The tension cable 512 removably attaches to the neck portion 504 and the tail assembly 508, whereupon locking the tail platform 560 in position, the tension cable 514 becomes taut. As best illustrated in
Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention. Workers skilled in the art will further recognize that interchanging certain elements of one embodiment with elements of another embodiment are well within the scope of the present invention.
Applicant claims priority of U.S. Provisional Application No. 60/346,695, filed Jan. 7, 2002, and U.S. Provisional Application No. 60/400,447, filed Aug. 1, 2002.
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