Brake system for a wheeled article

Information

  • Patent Grant
  • 6478312
  • Patent Number
    6,478,312
  • Date Filed
    Wednesday, January 24, 2001
    23 years ago
  • Date Issued
    Tuesday, November 12, 2002
    22 years ago
Abstract
An inline skate and brake system including a plurality of skate wheels with a first braking surface and a plurality of brake members with a second brake surface and an actuation mechanism for causing movement of the brake element brake surfaces into and out of braking engagement with the brake surfaces of the wheels.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates generally to a brake system for a wheeled article and more specifically to a brake system or personal wheeled article such as an inline skate or the like. The brake system of the present invention has particular applicability to being mechanically or electronically actuated and/or remotely controlled.




2. Description of the Prior Art




A variety of braking methods and systems have been developed for inline skates. Hand operated brakes such as those exemplified by U.S. Pat. No. 5,349,238, U.S. Pat. No. 5,411,276 and U.S. Pat. No. 3,330,207 utilize a cable between a hand-held brake and actuator and a brake device mounted to one or both of the skates. Other hand operated brakes such as those exemplified by U.S. Pat. No. 5,280,930 and U.S. Pat. No. 5,340,131 utilize a hydraulic conduit or line extending from a hand actuator to a brake on the skate. Although hand operated brakes function satisfactorily, they are not widely used.




Foot mounted brakes typically rely on one or more of several techniques for applying the brake force. One system involves use of various types of skid pads located at the toe or heel of the skate which are simply dragged on the skating surface. A second system involves utilizing an auxiliary wheel or roller which makes contact with a brake pad or a braking surface. A third technique involves forcing a braking surface against one or more of the load bearing wheels.




Various brake systems also exist which exert spring or hydraulic force against the wheels. Examples include those shown in U.S. Pat. No. 5,803,468, U.S. Pat. No. 5,411,276 and U.S. Pat. No. 5,351,974.




Although a wide variety of inline brake systems and techniques currently exist for personal wheeled articles such as inline skates, there is a continuing need for an improved brake system. Further, there is a need for an improved brake system with improved control, which can brake one or more wheels of an inline brake simultaneously and which has particular applicability to being mechanically or electronically actuated and/or remotely controlled.




SUMMARY OF THE INVENTION




The present invention relates to an improved brake system for a personal wheeled article and in particular a skate product such as an inline skate. More particularly, the present invention relates to an improved brake system which is capable of simultaneously braking one or more wheels of such article or inline skate and which has particular applicability to being mechanically or electronically actuated and/or remotely controlled.




More specifically, the brake system of the present invention is designed for use with an inline skate and includes a wheel support frame and one or more brake elements carried by the wheel support frame. Each brake element has a brake surface and is moveable relative to the frame between a brake position in which such brake surface engages a portion of the inline skate wheel and a non-brake position in which such brake surface is disengaged from the inline skate wheel. The brake element is caused to move between its brake and non-brake positions by an actuation member or bar in response to corresponding movement of an actuator.




In the preferred embodiment, the brake elements comprise a pair of pivotable callipers which are associated with each of the wheels of an inline skate. The callipers are twin callipers which include arm portions with brake pads defining a brake surface near their distal ends for engaging a brake surface on the wheel. An opposite end of the callipers includes a cam follower for engagement with a cam surface in the actuator member. The actuator member is in the form of an elongated actuator bar and is common to each of the callipers. Thus, movement of the actuator bar results in corresponding braking or non-braking movement of the callipers, in unison. In the preferred embodiment, the movement of the actuator bar and thus the callipers is driven by an electric, battery-driven solenoid which is in turn remotely controlled by the user.




The brake system of the present invention also preferably uses a single twin calliper to brake more than one wheel. This reduces the weight and complexity of the brake system, while at the same time providing improved braking force.




Accordingly, it is an object of the present invention to provide an improved brake system for a personal wheeled article.




Another object of the present invention is to provide a brake system for an inline skate.




Another object of the present invention is to provide an inline skate braking system for individually braking multiple wheels of the inline skate.




A further object of the present invention is to provide a brake system for an inline skate which is particularly applicable to being remotely controlled.




A still further object of the present invention is to provide a brake system for an inline skate embodying an improved structure for simultaneously braking two or more wheels of the skate. These and other objects of the present invention will become apparent with reference to the drawings, the description of the preferred embodiment and the appended claims.











DESCRIPTION OF THE DRAWINGS





FIG. 1

is an isometric view of an inline skate with the skate brake system of the present invention attached thereto.





FIG. 2

is an isometric view of the skate brake system of the present invention with the skate boot and wheel support frame deleted.





FIG. 3

is an isometric, exploded view of the skate brake system in accordance with the present invention.





FIG. 4

is an enlarged isometric view of the rearward end of the skate brake system of the present invention.





FIG. 5

is a further isometric view of the skate brake system of the present invention with the wheel support frame removed.





FIG. 6

is a view, partially in section, of the structure for pivotally supporting the callipers of the brake system.





FIG. 7

is a view, partially in section, as viewed along a section line


7





7


of FIG.


6


.





FIG. 8

is a view, partially in section, as viewed along the section line


8





8


of FIG.


6


.





FIG. 9

is an elevational bottom view of the actuation means showing the connection between the actuator solenoid and the actuator bar.





FIG. 10

is an isometric view of a portion of the skate brake system and a remote control actuation glove.











DESCRIPTION OF THE PREFERRED EMBODIMENT




The present invention relates generally to a brake system for a personal wheeled article. Although it is contemplated that the brake system of the present invention can be used with a variety of personal wheeled articles such as motorized or non-motorized skate boards, scooters, carts, skates or any multi-wheeled article, it has particular applicability to skates and still more particular applicability to inline skates. Accordingly, the preferred embodiment will be described with respect to an inline skate and more particularly to a brake for braking one or more wheels of an inline skate. Although the brake of the present invention can be used with either a remote control, or a tethered control, or neither, it has particular applicability to a remote control system of the type disclosed, for example only, in U.S. Pat. No. 5,803,468. The substance of Pat. No. 5,803,468 is incorporated herein by reference. Further, as will be described below, the preferred embodiment is provided with an electrically actuated brake in which the brake force is mechanically applied. It is contemplated, however, that the brake systems of the present invention may be hydraulically or pneumatically actuated and/or applied as well.




Reference is made to

FIG. 1

showing an assembled skated with a brake assembly and boot,

FIG. 3

showing an exploded view of the wheel support and brake assembly and

FIGS. 2

,


4


and


5


showing various isometric views of the brake assembly. Specifically, the skate of the present invention includes a boot portion


10


and a wheel support and brake assembly


11


. The wheel support and brake assembly


11


may be connected with the bottom of the boot


10


by any means known in the art such via a plurality of threaded members or other clamp means. As shown best in

FIG. 3

, the wheel support and brake assembly includes a wheel support frame assembly


12


, a plurality of wheel assemblies


14


, a plurality of brake calipers


15


and an actuator bar


16


. The brake assembly also includes an actuator assembly


18


including a remote control signal receiver and a force generating element.




With continuing reference to

FIGS. 1-5

, the wheel support and frame assembly


12


includes a pair of frame side members or skirts


19


and


20


and a bridging frame portion


21


. The bridging frame portion


21


lies in a plane generally parallel to the bottom sole of the skate boot


10


and includes a pair of side edges integrally joined with the top edges of the frame side portions


19


and


20


. The bridging frame portion


21


includes a generally planar member


22


which functions as a support and guide surface for the actuator bar


16


as will be described in greater detail below. A forward brake access opening


24


and a rearward brake access opening


25


are provided in the bridging frame portion


21


to provide access between the actuator bar


16


and the brake assemblies


15


. Secondary openings


26


and


28


are provided to reduce overall weight of the brake system and to facilitate access to the bottom of the boot


10


, if needed.




The frame side portions


19


and


20


are integrally joined with the bridging frame portion


21


and extend downwardly therefrom in generally laterally spaced relationship to one another. Each of the portions


19


and


20


include a plurality of wheel support openings


29


positioned along the length of the portions


19


and


20


near their lower edges. The corresponding openings


29


in the frame sides


19


and


20


are linearly aligned with one another. In the preferred embodiment, each of the frame portions


19


and


20


include four corresponding wheel support openings


29


.




Each of the frame side portions


19


and


20


also include two pairs of caliper access openings, with each pair comprising a forward caliper access opening


30


and a rearward caliper access opening


31


. As will be described in greater detail below, the openings


30


and


31


allow the caliper arms to extend through the openings for braking engagement with the wheel assemblies.




Extending upwardly from the surface portion


22


of the bridging portion


21


are a plurality of connection bracket members functioning primarily to guide movement of the actuator bar


16


in generally linear and reciprocal movement. The connection members include a pair of laterally spaced forward connection bracket members


32


,


32


and a pair of rearward connection bracket members


34


,


34


. Each of the bracket members


32


,


32


and


34


,


34


is provided with opening


33


for connecting the frame


12


to the boot


10


(FIG.


1


).




Each of the wheel assemblies


14


includes a central ground engaging wheel or wheel portion


35


, a pair of central hubs


36


,


36


, a pair of bearings


38


,


38


and a pair of axle portions


39


,


39


. In the preferred embodiment, each of the hubs


36


includes an outer flange portion


40


, a central opening


42


and an outwardly facing surface portion


41


forming a first braking surface. When assembled, the flange portion


40


is positioned inwardly and adjacent to the center wheel


35


, with the braking surface


41


facing outwardly and in a plane generally perpendicular to the rotational axis of the wheel assemblies


14


. Such rotational axis is defined by the axle members


39


,


39


. Each of the bearings


38


,


38


is press fit within the center opening


42


of a respective hub


36


,


36


. The wheel assemblies


14


can be conventional inline skate wheel assemblies except for the provision of the first braking surface


41


. In the preferred embodiment, the hubs


36


,


36


are constructed of aluminum or other light weight and strong material and the center wheel


35


is constructed of a plastic material such as urethane. In the preferred construction, the plastic wheel member


35


is molded over the hubs


36


,


36


.




As shown best in

FIGS. 5-8

, the wheel support frame is provided with means for pivotally supporting the plurality of calipers


15


. One embodiment of this means is shown in

FIG. 5

by a plurality of pivot support members


44


. Each pivot support member


44


is rigidly connected with the wheel support frame


12


. Each side of the bracket


44


includes a pair of support ears


46


,


46


which are spaced in the longitudinal direction of the skate. Each of the ears


46


is provided with a pivot opening


45


. The openings


45


are designed to receive a pivot pin


48


for pivotally supporting the calipers


15


as will be described in greater detail below. The bracket


44


also includes an actuator bar retaining portion


49


extending upwardly past the bridging frame portion


22


. The upper end of each portion


49


includes a retaining groove or recess


50


. The recess


50


receives an outer edge of the actuator bar


16


as shown in

FIG. 5

for the purpose of guiding the reciprocal movement of the bar and limiting its vertical movement relative to the frame portion


22


.




As shown, each bracket


44


includes a pair of laterally spaced retaining members


49


, with each side of the bracket


44


further including a pair of spaced pivot support ears


46


,


46


. In the preferred embodiment, the brake assembly includes two such brackets


44


, one for pivotally supporting the pair of calipers


15


at the forward end of the skate and the other for pivotally supporting the pair of calipers at the rearward end of the skate. The brackets


44


are rigidly connected with the wheel support frame assembly


12


. Thus, they can be integrally formed with the frame


12


or separately formed and connected to the frame such as via a plurality of threaded members or by welding or the like. Although Figure A shows the brackets


44


at both the forward and rearward ends of the skate as including an actuator bar retaining portion


49


with retaining groove


50


, such groove


50


and corresponding retaining portion


49


may be eliminated, if desired, at the forward end of the skate, with the actuator bar


16


being retained by engagement with the bottom surface of the boot


10


.




A further embodiment of the means for pivotally supporting the plurality of callipers


15


is shown in

FIGS. 6

,


7


and


8


. In these figures, a pair of longitudinally spaced brackets


43


are secured to the wheel support frame


12


by a plurality of threaded members


53


extending through the frame sides


19


and


20


into the brackets


43


. Each of the brackets


43


includes a downwardly extending flange


47


having a pair of laterally spaced openings to support the calliper pivot pin


48


. The pivot portions


50


of the callipers are pivotally supported on the pins


48


between the flanges


47


.




The brake assembly of the present invention is preferably provided with four caliper assemblies


15


. These comprise two caliper assemblies (a forward assembly and a rearward assembly) on each side of the skate. As shown best in

FIG. 3

, each caliper assembly includes a pivot portion


50


having a pivot opening


51


extending therethrough. Preferably, the pivot opening


51


extends in the longitudinal direction of the skate so that the pivot member and thus the entire caliper is pivotable about an axis generally parallel to the longitudinal axis of the skate. A caliper follower or actuator pin


52


extends upwardly from the pivot portion


50


for engagement with cam slots


58


in the actuator bar


60


as described below. The pin


52


extends vertically upwardly from the pivot portion


50


and preferably includes a brass sleeve


53


or other durable, low friction portion for engaging the cam slots


58


.




Each of the calliper assemblies


15


are twin callipers which include a pair of caliper arms


54


,


54


extending generally downwardly from the pivot member


50


in a diverging configuration as shown. The distal end of each of the caliper arms


54


,


54


is provided with a brake surface support portion


55


. As shown, each portion


55


is generally arcuately shaped to conform to the curvature of the brake surface


41


on the wheel hub


36


. Each brake surface support member


55


includes an inwardly facing brake surface or a surface to which a brake surface element


56


is connected. In the preferred embodiment, a separate brake surface element


56


is connected with each brake surface support member


55


for making braking engagement with the brake surface portion


41


of the wheel assembly


14


.




As discussed above, and as shown best in

FIGS. 6

,


7


and


8


, each calliper assembly is pivotally connected relative to the wheel support frame


12


via the pivot pins


48


extending through the pivot openings


51


. The arms


54


,


54


of each calliper extend outwardly through respective openings


30


and


31


provided in the frame sides


19


and


20


for each calliper assembly


15


. The brake surface support portions


55


or the brake surface element


56


connected thereto are then free to selectively engage the braking surface


41


. It is contemplated that the brake surface element


56


can be any one of a variety of materials that provides desired braking friction when engaged with the brake surface


41


. Such material can range from relatively hard metals commonly used as braking surfaces to softer rubber or synthetic materials.




The actuator bar


16


is an elongated member having a forward actuator section


59


, a rearward actuator section


60


and a central connecting portion


61


which connects the forward and rearward actuator sections


59


and


60


. Each of the sections


59


and


60


includes a pair of actuator cam slots


57


and


58


for moving the caliper follower pins


52


and thus pivoting the caliper assemblies


15


. Each of the cam slots


57


and


58


includes a braking portion


62


and a release portion


64


. As shown best in

FIG. 4

, the portions


62


diverge slightly from one another as they extend towards the forward end of the skate, while the portions


64


converge more significantly toward one another as they extend toward the rearward end of the skate. In the preferred embodiment, the entire inner edge of the cam slots


57


and


58


is provided with a cam or bearing surface. The actuator bar


16


is positioned to allow the cam pins


52


to extend upwardly through a respective cam slot


57


and


58


. Thus, as the actuator bar and the actuator sections


59


and


60


are moved forwardly and rearwardly relative to the wheel support frame


12


, the cam surfaces of the slots


57


and


58


cause lateral inward and outward cause lateral pivotal movement of the pins


52


about the pivot pin


48


. This inward and outward movement of the pins results in the pivoting of the entire calliper assemblies


15


. This in turn results in corresponding pivotal movement of the caliper arms


54


and thus movement of the brake surface support elements


55


between a braking position in which the brake surface element


56


is engaged with the brake surface


41


and a non-braking position in which the brake surface of the element


56


and the brake surface


41


are disengaged from one another.




Specifically, as the actuator bar


16


is moved forwardly relative to the wheel support frame


12


,the brake release portions


64


of the cam slots


57


and


58


pivot the pins


52


inwardly toward one another, thereby causing the brake surface support elements


55


to pivot outwardly from one another to a non-braking position. Conversely, when the actuator bar


16


is moved rearwardly relative to the wheel support frame


12


, the brake engaging portions


62


of the cam slots


57


and


58


cause the pins


52


to pivot away from one another, thereby causing the brake surface support members


55


to pivot toward one another and thus into braking engagement with the brake surface


41


of the wheels. Accordingly, by moving the actuator bar


16


forwardly and rearwardly relative to the wheel support frame


12


, the caliper assemblies


15


can be moved between non-braking and braking positions respectively.




As shown, the brake the brake surface support members


55


of each caliper assembly are designed to engage a separate wheel. Thus the forward caliper assemblies at the forward end of the brake engage the brake surfaces


41


on opposite sides of each of the two forward wheels


14


, while the brake surface support members


55


of the rearward caliper assemblies


15


engage the brake surfaces


41


on opposite sides of the two rearward wheels


14


.




The brake assembly in accordance with the present invention also includes means for actuating the actuator bar


16


or for moving the actuator bar


16


forwardly and rearwardly as described above to move the caliper assemblies


15


between braking and non-braking positions. In the preferred embodiment, this means includes a solenoid


66


or other motion generating or force exerting device. More specifically, as shown in

FIG. 9

, the means for moving the actuator bar


16


and thus the calipers


15


between a brake and non-brake position includes a rotation member


67


connected to the solenoid


66


for rotational movement in the direction of the directional arrow


72


. The rotation member


67


includes one or more motion transfer openings and a corresponding pin


68


connected with an actuator link


69


. The link


69


in turn is connected via a motion transfer pin


70


to the actuation bar


16


via the pin


70


extending through a hole


72


in a rearward connecting tab


71


of the actuation section


60


. As can be seen, as the solenoid


66


rotates the member


67


in the direction of the arrow


73


, the actuator bar


16


moves in the direction of the arrow


74


to move the caliper assemblies


15


between their respective brake and non-brake positions.




The solenoid


66


or other means for moving the actuator bar


16


can be controlled by any appropriate device such as, but not limited to, an actuator cord or cable tethered from the user or by a remote control transmitter such as that shown in U.S. Pat. No. 5,803,468. Preferably, the brake assembly of the present invention is designed for a remote control use. This would require the solenoid assembly


66


to include a receiver for receiving a signal from a remote control transmitter and a means for converting the received signal to a signal for actuating the solenoid


66


. In the present embodiment, the solenoid is an HS-815BB Hitec electronic sero.





FIG. 10

shows the brake system in combination with a remote control device for remotely controlling the brake system. Specifically, the remote control device preferably includes a glove


75


or other means that would commonly be carried by the hand or arm of the user so that the control could be performed by the user's thumb or one or more of the user's fingers. As shown in

FIG. 10

, the glove


75


includes a wrist or forearm portion


76


which is designed for selective connection with and removal from the wrist or forearm of the user and a palm portion


77


which carries a transmitter


78


. The transmitter


78


includes a depressible actuation or control button


80


which may be depressed by the user's thumb


79


. When the button


80


is depressed, the transmitter transmits a radio frequency or other signal to the receiver in the solenoid assembly


66


for actuating the brake assembly, specifically, as the button


80


is depressed by the user's thumb in the direction of the arrow


81


, a braking signal is transmitted to the receiver in the solenoid


66


which causes movement of the actuator bar


16


to activate the brake system. Release of the button


80


will result in a release of the braking force. Preferably, the transmitter and receiver are designed so that the more the button


80


is depressed, the greater the braking force.




Accordingly, it can be seen that the inline skate and brake system of the present invention includes a wheel support frame


12


and a plurality of wheels or wheel assemblies


14


linearly spaced from one another and rotatably supported by the frame. Each of the wheel assemblies includes a brake surface


41


positioned on the hubs on each side of the wheel assemblies. The brake system also includes a plurality of brake elements associated with the wheels and carried by the frame


12


. Each of these brake elements or calipers


15


includes a second brake surface, with each of those surfaces being moveable relative to the frame between a brake position in which the brake surfaces of the wheel assemblies and the caliper assemblies are engaged and a non-brake position in which the brake surfaces of the wheel assemblies and the brake surfaces of the caliper assemblies are disengaged. The system also includes an actuator member operatively connected with the caliper assemblies


15


to move its respective brake elements between such brake and non-brake positions.




Although the description of the preferred embodiment has been quite specific, it is contemplated that various modifications could be made without deviating from the spirit of the invention. Accordingly, it is intended that the scope of the present invention be dictated by the appended claims rather than by the description of the preferred embodiment.



Claims
  • 1. A brake system for a wheeled article comprising:a frame; a plurality of wheels linearly spaced from one another and rotatably supported by said frame, at least one of said wheels including a first brake surface; a brake element associated with said at least one wheel, said brake element carried by said frame, having a second brake surface and being moveable relative to said frame between a brake position in which the first brake surface of said at least one wheel and the second brake surface of its associated brake element are engaged and a non-brake position in which the first brake surface of said at least one wheel and the second brake surface of its associated brake element are disengaged; and an actuator member operatively connected with said brake element to move said brake element between said brake and non-brake positions, said brake element including a cam follower surface and said actuator member including a cam slot having a cam surface.
  • 2. The system of claim 1 including the brake element associated with a plurality of said wheels.
  • 3. The system of claim 2 wherein said actuator member is operatively connected with each of said brake elements.
  • 4. The system of claim 2 including a brake element associated with each of said wheels.
  • 5. The system of claim 4 wherein said actuator member is operatively connected with each of said brake elements.
  • 6. The system of claim 1 wherein said brake element is pivotally connected with said frame and pivotally moveable between said brake and non-brake positions.
  • 7. The system of claim 6 including a longitudinal axis extending generally in the direction of said plurality of wheels and wherein said actuator member is moveable reciprocally in a direction parallel to said longitudinal axis to pivot said brake element between said brake and non-brake positions.
  • 8. The system of claim 1 including a first brake surface on each side of said wheel and a pair of brake elements each having a second brake surface, each of said brake element being moveable between a brake position in which said first brake surface on one side of said wheel is engaged with said second brake surface of one of said pairs of brake elements and said first brake surface on the other side of said wheel is engaged with said second brake surface on the other of said pair of brake elements.
  • 9. The system of claim 8 including a pair of wheels each having a first brake surface on each side and wherein one of said pair of brake elements includes a pair of second brake surfaces for braking engagement with the first brake surface and one side of each of said pair of wheels.
  • 10. The system of claim 1 including an actuator operatively connected to said actuator member to move said actuator member between brake and non-brake positions.
  • 11. The system of claim 10 wherein said actuator is electrically powered and is remotely controlled.
  • 12. The system of claim 1 wherein said at least one wheel includes a central hub and a peripheral ground engaging portion and said hub includes said first brake surface.
  • 13. The system of claim 1 including a skate boot connected to said frame.
  • 14. The system of claim 1 wherein said wheeled article is an inline skate.
  • 15. A brake system for a wheeled article comprising:a frame; a plurality of wheels linearly spaced from one another and rotatably supported by said frame, at least one of said wheels including a first brake surface; a brake element associated with said at least one wheel, said brake element carried by said frame, having a second brake surface and being moveable relative to said frame between a brake position in which the first brake surface of said at least one wheel and the second brake surface of its associated brake element are engaged and a non-brake position in which the first brake surface of said at least one wheel and the second brake surface of its associated brake element are disengaged, wherein said brake element is pivotally connected with said frame and pivotally moveable between said brake and non-brake positions; and an actuator member operatively connected with said brake element to move said brake element between said brake and non-brake positions and wherein one of said actuator member and said brake element includes a cam surface and the other of said actuator member and said brake element includes a cam follower surface and wherein said actuator member and said brake elements are operatively connected by said cam surface and said cam follower surface; and a longitudinal axis extending generally in the direction of said plurality of wheels and wherein said actuator member includes a cam surface and is moveable reciprocally in a direction parallel to said longitudinal axis to pivot said brake element between said brake and non-brake positions, wherein said brake element includes a cam follower surface and wherein said cam surface is provided on a cam slot in said actuator element.
  • 16. A brake assembly for a skate having a skate boot and a plurality of wheels each having a first brake surface and a wheel support frame rotatably supporting said wheels and connected with said skate boot, said assembly comprising:a pair of opposing brake elements pivotally connected to the skate frame, each of said brake elements including a second brake surface and a first cam surface, said second brake surface of one of said pair of brake elements adapted for selective braking engagement with said first brake surface on one side of said wheel and said second brake surface of the other of said brake elements adapted for selective braking engagement with said first brake surface on the other side of said wheel and a brake actuator having a second cam surface, at least one of said first and second cam surfaces being defined by a cam slot.
  • 17. The assembly of claim 16 including a pair of linearly aligned wheels, each having a first brake surface on each side thereof and wherein each of said pair of brake elements includes a pair of second brake surfaces, said pair of second brake surfaces of one of said brake elements adapted for selective braking engagement with said first brake surfaces on one side of said pair of wheels and said pair of second brake surfaces of the other of said brake elements adapted for selective braking engagement with said first brake surfaces on the other side of said pair of wheels.
  • 18. The assembly of claim 17 wherein each of said wheels includes a central hub and a peripheral ground engaging portion and wherein said hub includes said first brake surfaces.
  • 19. The assembly of claim 16 wherein said brake actuator is remotely controlled.
  • 20. The assembly of claim 19 in combination with a user control wherein said user control includes a transmitter and said brake actuator includes a receiver to receive a control signal from said transmitter.
  • 21. The assembly of claim 16 wherein said brake actuator is operatively connected with said brake elements,said brake actuator moveable to a brake position to cause movement of said brake elements to a brake position in which said second brake surfaces are engaged with their respective first brake surfaces.
Parent Case Info

This application claims the benefit of Provisional Application No. 60/213,645 filed Jun. 23, 2000.

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Provisional Applications (1)
Number Date Country
60/213645 Jun 2000 US