A RETAINER LOCK
Reference to Priority Application
This application claims the benefit of U.S. Provisional Application No. 60/178,935, filed February 1, 2000.
Technical Field of the Invention
The present invention relates to locking devices and in particular to appratus and methods for secuπng components to a bicycle.
Background and Summary of the Invention
Bicycles are susceptible to theft when only the front wheel of the bicycle is secured to a bicycle rack or other object. Conventional bicycles are stolen by using a tool to loosen or remove the retainers holding the front wheel onto the bicycle frame Especially susceptible are bicycles incorporating a quick release mechanism. Quick release mechanisms are popular because they allow bicycle wheels to be easily removed or bicycle seats to be easily adjusted in height However, in order to protect against theft the owner of a bicycle with a quick release mechanism must remove the front wheel from the bicycle and secure both the front wheel and the bicycle frame to an object.
The present invention secures components, such as bicycle wheels or seats, to the frame of a bicycle such that the components cannot be easily removed without either using a corresponding key or by damaging the bicycle
In a first exemplary embodiment, a locking device configured to secure a bicycle wheel having an hub with an axial channel to a bicycle frame comprises a rod adapted to pass through the axial channel of the hub. The rod comprises a first threaded portion and a second threaded portion. The locking device further compnses a first retainer compnsing a body member and a coupler. The body member of the first retainer being configured to be coupled to the first threaded portion of the rod. The coupler of the first retainer compnsing a plurality of receiving portions. The locking device further compnses a second retainer compnsing a body member configured to be coupled to the second threaded portion of the rod and a tab member configured to limit rotation of the second retainer relative to the frame. The locking
device further compnsing a key compnsing a plurality of protruding portions Each one of the receiving portions of the first retainer is configured to couple one of the protruding portions of the key
In a second exemplary embodiment, a locking device configured to secure a bicycle wheel having a hub with an axial channel to a bicycle frame compnses a rod adapted to pass through the axial channel of the hub The rod comprises a first threaded portion and a second threaded portion The locking device further compnses a first retainer compnsing a body member and a coupler The body member of the first retainer being configured to be coupled to the first threaded portion of the rod The locking device further compnses a second retainer compnsing a body member configured to be coupled to the second threaded portion of the rod and a tab member configured to limit rotation of the second retainer relative to the frame The locking device further comprises a key comprising a body member and a coupler configured to couple the coupler of the first retainer The locking device further compnses a sleeve compnsing a body member and a tab member The body member of the sleeve configured to partially receive the first retainer The tab member of the sleeve configured to limit rotation of the sleeve relative to the frame
In a third exemplary embodiment, a locking device configured to secure a bicycle wheel having an axle with a first threaded portion and a second threaded portion to a bicycle frame compnses a first retainer compnsing a body member and a coupler The body member of the first retainer being adapted to be coupled to the first threaded portion of the axle The coupler of the first retainer compnsing a plurality of receiving portions positioned in a first configuration The locking device further compnses a second retainer compnsing a body member adapted to be coupled to the second threaded portion of the axle and a coupler compnsing a plurality of receiving portions positioned in a second configuration The second configuration of the receiving portions of the second retainer matching the first configuration of the receiving portions of the first retainer The locking device further compnses a key compnsing a plurality of protruding portions Each one of the receiving portions of the first retainer configured to couple one of the protruding portions of the key
In a fourth exemplary embodiment, a locking device configured to secure a bicycle wheel having an axle with a first threaded portion and a second threaded portion to a bicycle frame compnses a first retainer compnsing a body member and a coupler The body member
of the first retainer being adapted to be coupled to the first threaded portion of the axle. The locking device further compnses a second retainer comprising a body member adapted to be coupled to the second threaded portion of the axle and a coupler. The locking device further compnses a key compnsing a body member and a coupler. The coupler of the key being configured to couple the coupler of the first retainer and the coupler of the second retainer. The locking device further compnses a sleeve compnsing a body member and a tab member. The body member of the sleeve configured to partially receive the first retainer. The tab member adapted to limit rotation of the sleeve relative to the frame.
Bπef Descnption of the Drawings
Fig. 1 is a partial isometnc view of a bicycle wheel and fork frame member of a bicycle which uses a quick release mechanism including a portion of a first illustrative embodiment of the present invention;
Fig. 2 is an exploded, isometnc view of the components of a first illustrative embodiment of the present invention;
Fig. 3 is a side view of an illustrative embodiment of a first retainer of the present invention;
Fig. 4 is a front view of the first retainer of Fig. 3;
Fig. 5 is a diagrammatical representation of an illustrative placement cπtena for the coupler of the first retainer of Fig. 4;
Fig. 6 is a side view of an illustrative embodiment of a second retainer of the present invention;
Fig. 7 is a front view of the second retainer of Fig. 6;
Fig. 8 is a partial, cutaway, side view of an illustrative embodiment of a key of the present invention;
Fig. 9 is a rear view of the key of Fig. 8;
Fig. 10 is an exploded, cross-sectional view of an exemplary sleeve and a first retainer which are part of a second illustrative embodiment of the present invention;
Fig. 11 us an unexploded view of Fig. 10,
Fig. 12 is an exploded, isometnc view of the components of a third illustrative embodiment of the present invention;
Fig. 13 is a side view of a another illustrative embodiment of a first retainer of the present invention;
Fig. 14 is a front view of the second retainer of Fig. 13;
Fig 15 is a side view of another illustrative embodiment of a key of the present invention; and
Fig. 16 is an exploded, side view of the components of a fourth illustrative embodiment of the present invention;
Detailed Descnption of Exemplary Embodiments
While the invention is susceptible to various modifications and alternative forms, exemplary embodiments thereof have been shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that there is no intent to limit the invention to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spint and scope of the invention as defined by the appended claims.
Refernng to Fig. 1, a bicycle wheel 10 including a hub 20 being configured to function with a quick release mechanism is shown along with a portion of a bicycle frame 60. Bicycle frame 60 includes a fork member 62 having a first fork arm 70 and a second fork arm 72. First fork arm 70 and second fork arm 72 include apertures or receiving portions 74 and 76, respectively First fork arm 70 further includes a pocket 77 formed in fork surface 75. Pocket 77 includes a bottom surface 78 and a wall surface 80. Second fork arm 72 contains a pocket similar to pocket 77.
Bicycle hub 20 includes an axle 30 having a first threaded portion 32 and a second threaded portion 34. Bicycle hub 20 is designed to accept a quick release mechanism for attaching bicycle wheel 10 to bicycle frame 60. In order to accommodate the quick release mechanism, axle 30 includes an axial channel 40 which has a generally circular axial cross section and which is concentnc with axle 30 Channel 40 accepts a rod which couples a first portion of a quick release mechanism positioned proximate to first fork arm 70 to a second portion of a quick release mechanism positioned proximate to second fork arm 72.
Refernng to Fig. 2, an exemplary embodiment of a locking device 100 is shown. Locking device 100 includes a rod 110, a washer 102, a first retainer 120, a second retainer 170, and a key 190. Alternatively, locking device 100 does not include washer 102
Alternatively, when used with a conventional bicycle hub, locking device 100 includes a first retainer 120, a second retainer 170 and a key 190
Rod 1 10 is not required with a conventional bicycle hub because the axle length of a conventional hub extends beyond first fork member 70 and second fork member 72 a length sufficient to directly couple first retainer 120 and second retainer 170. As such, when axle 30 is of sufficient length, first retainer 120 couples with first threaded portion 32 of axle 30, second retainer 170 couples with second threaded portion 34 of axle 30 and rod 110 is not required
In an exemplary embodiment, first retainer 120 and second retainer 170 include the features set forth in connection with Figs. 3, 4, 6 and 7 In another exemplary embodiment, second retainer 170 is configured generally identical to first retainer 120 As such, second retainer 170 includes a coupler and second retainer 170 does not include a tab member
Rod 110 is generally cyhndncal and includes a first threaded portion 112 and a second threaded portion 114 First threaded portion 112 and second threaded portion 114 are configured to threadably couple first retainer 120 and second retainer 170, respectively. In one exemplary embodiment, rod 110 is manufactured from a high grade steel. The length of rod 110 is chose based upon the application. For instance, rod 110 in an exemplary embodiment is longer when a rear wheel is to be secured by locking device 100 as opposed to when a front wheel is to be secured by locking device 100
Refernng to Figs. 2, 3 and 4, first retainer 120 includes a body member 122 and a coupler 124 Body member 122 includes a generally circular first axial surface 126, a generally circular second axial surface 128, a first radial surface 130 and a second radial surface 132 First axial surface 126 and second axial surface 128 have a generally circular configuration to provide a generally cyhndncal configuration for radial surface 130 A generally cyhndncal radial surface is preferred to a faceted surface because a generally cyhndncal surface cannot as easily be gnpped by a tool, such as a wrench One drawback with a cyhndncal configuration is that such a configuration allows for a tool to apply pressure to body member 122 along the axial extent of the radial surface 130
In the exemplary embodiment shown in Figs. 2, 3 and 4, second axial surface 128 has a generally smaller diameter compared to the diameter of first axial surface 126, thereby causing radial surface 130 to have a frusto-conical shape The frusto-conical configuration of
surface 130 reduces the axial e? tent by which a tool having a linear profile can exert pressure. It is preferred that the diameter; of first axial surface 126 and second axial surface 128 be selected such that the angle A, shown in Fig. 3, has a value in the range of 15° to 60°. Even more preferably, angle A should have a value in the range of 20° to 45°. Most preferably the value of angle A should be 20°.
The second radial surface 132 of body member 122 has a generally cyhndncal configuration and has a smaller axial extent than radial surface 130. The axial extent of radial surface 132 should be minimized in order to prevent the gnpping of surface 132 with a tool. Ideally second radial surface 132 would not be present in first retainer 120 and radial surface 130 would terminate at first axial surface 126. However, the addition of radial surface 132 reduces the manufactunng cost of first retainer 120. Preferably the axial extent of radial surface 132 is in the range of 0.005" (0.13 mm) and 0.060" (1.52 mm). More preferably the axial extent of radial surface 132 is not larger than 0.030" (0.76 mm).
Body member 122 further includes a channel 136 and a pocket 138. Channel 136 is defined by a radially, inward-facing surface 140 that is concentnc with radial surfaces 130 and 132 and which extends from first axial surface 126 through to second axial surface 128. Channel 136 includes a threaded portion configured to couple with first threaded portion 112 of rod 110. Pocket 138 is defined by a third axial surface 142 and a second radially, mward- facing surface 144. Pocket 138 is configured to provide clearance for axle 30 when first retainer 120 is adjacent axle 30
An exemplary embodiment of coupler 124 of first retainer 120 is shown in Figs. 2, 3, and 4. Coupler 124 includes three apertures or receiving portions 146a, 146b, and 146c formed within body member 122. The receiving portions 146a, 146b, and 146c extend from second axial surface 128 into body member 122. The placement of receiving portions 146a, 146b, and 146c can be vaned on second axial surface 128 to provide unique embodiments of first retainer 120. An illustrative embodiment of the parameters used in determining the location of receiving portions 146a, 146b, and 146c is shown in Fig. 5. Additionally the number of receiving portions can be vaned to include two portions, three portions, four portions, or higher number of portions.
Refernng to Fig. 5, a representative view of second axial surface 128 is shown. Axial surface 128 is defined into three segments 150a, 150b, and 150c. Each segment 150a. 150b,
7 and 150c is an equal sector of second axial surface 128 defined by lines I, II, and III. Alternatively, segments 150a, 150b, and 150c could be unequally sized sectors or could define amorphous non-overlapping regions. As shown in Fig. 5, receiving portions 146a, 146b, and 146c are positioned in a respective segment 150a, 150b, and 150c. By requinng that each receiving portion 146a, 146b, and 146c be located in a different segment 150a, 150b, and 150c, the general disbursement of receiving portions 146a, 146b, and 146c over second axial surface 128 is maintained.
The exact location of receiving portions 146a, 146b, and 146c is determined by selecting both an angular coordinate and a radial coordinate. Receiving portion 146a is positioned at the intersection of a radial line 152 and a circumferential line 158. Receiving portion 146b is positioned at the intersection of a radial line 154 and a circumferential line 162. Receiving portion 146c is positioned at the intersection of a radial line 156 and a circumferential line 158. Radial lines 152, 154 and 156 and circumferential lines 158, 160 and 162 are provided only for clanftcation. It should be noted that receiving portions 146a, 146b, and 146c can be placed at any angular coordinate and any radial coordinate within the respective sector 150a, 150b, and 150c. However, it preferred to define an acceptable range on both the angular coordinate and radial coordinate. For example, a minimum angle should be maintained from each sector line I, LT, III dependent upon the size of receiving portions 146a, 146b, and 146c. The angle chosen should ensure that each of the receiving portions 146a, 146b, and 146c do not overlap with a second one of receiving portions 146a, 146b, and 146c. Additionally, each sector can be configured to include discrete angular coordinates, such as every two degrees. The radial coordinate should be constrained such that receiving portions 146a, 146b, and 146c do not interfere with channel 136 and are completely contained within the bounds of second axial surface 128. As shown, in Fig. 5 a minimum radial coordinate 164 and a maximum radial coordinate 166 are illustrated. An exemplary minimum radial coordinate is 0.200" (5 08 mm) clearance from channel 136. An exemplary example gnd spacing of radial coordinates and angular coordinates is angular coordinates defined at every 2° and radial coordinates every 0 010" (0.25 mm).
As stated earlier, the placement of receiving portions 146a, 146b, and 146c should be chosen to produce a diffenng configuration from a first first retainer and a second first retainer. By varying the placement of receiving portions 146a, 146b, and 146c, the chance
that an unauthonzed user would have a key 190 with a matching configuration is reduced. If all first retainers had the same configuration then an unauthorized user would need to only purchase a second locking device in order to remove a first locking device. Refernng back to Fig. 5, receiving portions 146a, 146b, and 146c are positioned at their respective coordinate points. Receiving portion 146a is positioned at the intersection of radial line 152 and circumferential line 158. Receiving portion 146b is positioned at the intersection of radial line 154 and circumferential line 162. Receiving portion 146c is positioned at the intersection of radial line 156 and circumferential line 158. In order to create a second first retainer having a configuration diffenng from the first first retainer, one or more of the locations of receiving portions 146a, 146b, and 146c should be changed. For example, receiving portion 146a could be moved to coordinate location 168. Although it would be impractical to design all first retainers 120 to have a unique configuration, by having a sufficient number of different configurations the likelihood is reduced that a locking device purchased by an unauthonzed user would match a locking device assembled to a bicycle.
The axial configurations of receiving portions 146a, 146b, and 146c are generally cyhndncal in configuration. However it is within the scope of the present invention to have receiving portions with different configurations. For example, receiving portions 146a, 146b, and 146c can be tnangular or quadnlateral in configuration. Alternatively, the configurations of each receiving portion 146a, 146b, and 146c is different than at least one of the configurations of the other receiving portions. Alternatively, the size of each receiving portion 146a, 146b, and 146c could be different than at least one of the other receiving portions. By varying the size and configuration of receiving portions 146a, 146b, and 146c, the number of unique combinations of receiving portions is greatly increased over the number that can be created by simply varying the radial and angular coordinate locations of receiving portions 146a, 146b, and 146c.
Refernng to Figs. 2, 6, and 7, an exemplary embodiment of second retainer 170 includes a body member 172 and a tab member 174. Body member 172 includes a first axial surface 176, a second axial surface 178, a first radial surface 180, and a second radial surface 182. First axial surface 176, second axial surface 178, radial surface 180, and radial surface 182 are configured similar to first axial surface 126. second axial surface 128, first radial surface 130, and second radial surface 132 of first retainer 120. The similar configuration
between body member 172 of second retainer 170 and body member 122 of first retainer 120 is for aesthetic purposes. As is explained below the inclusion of tab member 174 eliminates the requirement that body member 172 be configured to reduce the ability to engage body memberl72 with a tool. Body member 172 further includes a channel 184 and a pocket 186 configured similar to the channel 136 and pocket 138 of first retainer 120.
Tab member 174 extends outward from first axial surface 176. Tab member 174 has a generally rectangular cross section on three sides and is bounded by second radial surface 182 on the fourth side. The general shape of tab member 174 is not constrained by any factors. However, in an exemplary embodiment tab member 174 has a longitudinal extent roughly equivalent to the opening of the respective fork member 74, 76, in order to reduce rotation of the second retainer 170 with respect to the respective fork member 74, 76. Additionally, the axial extent of tab member 174 should be large enough to ensure that tab member 174 extends within opening 76 of second fork arm 72.
In an exemplary embodiment, first retainer 120 and second retainer 170 are coupled to the first threaded portion of a conventional axle and the second threaded portion of a conventional axle, respectively. Second retainer 170 is configured to be generally identical to first retainer 120. As such, second retainer 170 includes a coupler generally identical to coupler 124 of first retainer 120 and second retainer 170 does not include a tab member 174. Alternatively, the coupler on second retainer 170 contains a different configuration compared to the coupler 124 on first retainer 120.
Refernng to Figs. 2, 8, and 9, an exemplary embodiment of key 190 includes a body member 192, a tool engagement member 194, and a coupler 196. Body member 192 includes a generally cylindrical configuration defined by radial surface 198 and includes a first axial surface 199. Tool engagement member 194 includes a hexagonally shaped portion 200 sized to be engaged by a wrench tool or socket tool. Alternatively, tool engagement member 194 includes a pocket for receiving the drive of a socket wrench Alternatively, tool engagement member 194 is configured to engage with a screwdnver. Alternatively, tool engagement member 194 includes a handle similar to a screwdnver
Coupler 196 includes three protruding portions 202a, 202b, and 202c sized, shaped and positioned to correspond to receiving portions 146a, 146b, and 146c on first retainer 120 By placing each receiving portion 146a, 146b, and 146c on first retainer 120 in a separate
segment 150a, 150b, and 150c tht load placed on each of protruding portions 202a, 202b, and 202c is more balanced. However the configurations of coupler 196 and coupler 124 should be chosen to mate with each other, in one exemplary embodiment, protruding portions 202a, 202b, and 202c are cyhndncal and are 0.094" (2.39 mm) in diameter. In another exemplary embodiment, protruding portions 202a, 202b, and 202c are cyhndncal and are 0.063" ( 1.6 mm) in diameter. In yet another exemplary embodiment, protruding portions 202a, 202b, and 202c are cyhndncal and are 2 mm in diameter. In yet another exemplary embodiment, protruding portions 202a, 202b, and 202c are cyhndncal and are a non-standard diameter.
As shown in Figs. 2 and 8, the protruding portions 202a, 202b, and 202c of coupler 196 extend outward from a second axial surface 204 of body member 192. Second axial surface 204 defines a pocket 206 in body member 192. A radial surface 208 extends between first axial surface 199 and second axial surface 204. Radial surface 208 is configured to generally match first radial surface 130 of first retainer 120. Pocket 206 ensures that key 190 fits squarely on first retainer 120. Alternatively, body member 192 does not include pocket 206 and protruding portions 202a, 202b, and 202c extend from first axial surface 199. The cost of manufactunng is lower when protruding portions 202a, 202b, and 202c extend from first axial surface 199.
In one exemplary embodiment body member 192 is manufactured out of brass and protruding portions 202a, 202b, 202c are steel pins. To assemble key 190, holes are dnlled into body member 192 to accept protruding portions 202a, 202b, 202c. Protruding portions 202a, 202b, 202c are then fixably secured to body member 192.
Refernng to Figs. 1 and 2 the operation of locking device 100 is descnbed below. Rod 110 is placed within channel 40 of axle 30 such that first threaded portion 1 12 extends beyond first threaded portion 32 of axle 30 and such that second threaded portion 114 extends beyond second threaded portion 34 of axle 30. Next, second retainer 170 is partially threaded onto second threaded portion 114 of rod 110. Alternatively, second retainer 170 is permanently assembled to second threaded portion 114 of rod 110 using an adhesive, such as Loctite® 721, manufactured by the Loctite Corporation. By permanently assembling second retainer 120 to rod 110, the overall assembly of locking device 100 is easier. Next, bicycle wheel 10 is positioned such that tab member 174 of second retainer 170 is positioned within opening 76 of second fork member 72, first axial surface 176 is generally flush against second
fork member 72 and such that first threaded portion of rod 110 is positioned within opening 74 or first fork member 70 Next, first retainer 120 is partially threaded onto the first threaded portion 112 of rod 110. Alternatively, before first retainer 120 is partially threaded onto rod 1 10 channel 104 in washer 102 is positioned around first threaded portion 112 of rod 1 10 and washer 102 is flush against surface 78 of first fork member 70. Next, key 190 is positioned such that coupler 194 of key 190 engages coupler 124 of first retainer 120 Next, a tool is engaged with tool engagement member 194 of key 190 such that the tool tightens first retainer 120 against surface 78 of first fork member 70 or washer 102 if washer 102 is included. It should be noted that the tab member 174 of second retainer 170 prevents the rotation of second retainer 170 while first retainer 120 is tightened with the tool. As such, to disassemble locking device 100 only one tool and key 190 is required. Finally, key 190 is uncoupled from first retainer 120 and stored until required again.
Locking device 100 is disassembled to allow bicycle wheel 10 to be removed from bicycle frame 60 by an authonzed user in the following manner. Key 190 is positioned such that coupler 194 of key 190 engages coupler 124 of first retainer 120 Next, a tool is engaged with tool engagement member 194 of key 190 such that by turning the tool key 190 moves first retainer 120 away from surface 78 of first fork member 70 or washer 102 if washer 102 is included Once first retainer 120 is backed away, bicycle axle 30 is free to exit from fork openings 74 and 76. It should be noted that the tab member 174 of second retainer 170 prevents the rotation of second retainer 170 while first retainer 120 is back away with the tool. As such, to disassemble locking device 100 only one tool and key 190 is required Alternatively, key 190 is configured to include a lever arm which would eliminate the need for a separate tool Finally, key 190 is uncoupled from first retainer 120 and stored until required again
In an exemplary embodiment, second retainer 170 is generally identical to first retainer 120 As such, second retainer 170 includes a coupler similar to coupler 124 and second retainer 170 does not include a tab member 174 Dunng assembly, both first retainer 120 and second retainer 170 are threaded onto the axle of a bicycle and tightened against the bicycle frame 60 with key 190 Alternatively, two keys are used to tighten first retainer 120 and second retainer 170 against bicycle frame 60 Alternatively, first retainer 120 and second retainer 170 comprise couplers having diffeient configurations As such first retainer 120 and
12 second retainer 170 are tightened against bicycle frame 60 with two keys, one having a coupler configured to match the coupler of first retainer 120 and one having a coupler configured to match the coupler of second retainer 170.
When locking device 100 is assembled to hold bicycle wheel 10 onto bicycle frame 60, pocket 77 on first fork member 70 reduces the likelihood that first retainer 120 will be removed by an unauthonzed user. Pocket surface 80 at least partially prevents access to second radial surface 132 of first retainer 120. As such, if first fork member 70 includes a pocket 77, the axial extent of second radial surface 132 can be chosen to generally be less than or equal to the axial extent of pocket surface 80 Alternatively to pocket 77, first fork member 70 can include a wall protruding outward from fork surface 75 which obstructs a tool from engaging first radial surface 130 and second radial surface 132 of first retainer 120.
A second illustrative embodiment 300 of a locking device is partially shown in Figs 10 and 11 Embodiment 300 includes a threaded rod (not shown in Figs. 10 and 11) being generally identical to threaded rod 110, a first retainer 320 being generally identical to first retainer 120, a second retainer (not shown in Figs 10 and 1 1) being generally identical to second retainer 170, a key (not shown in Figs. 10 and 11) being generally identical to key 190, and a sleeve member 360.
Sleeve member 360 includes a body member 362 and a tab member 364. Body member 362 includes a first axial surface 366, a second axial surface 368 and a first radial surface 370 Body member 362 further includes a pocket 372 and a channel 374. Pocket 372 is defined by a third axial surface 376 and a second radial surface 378. Channel 374 extends axially though sleeve 360 and is defined by a third radial surface 379. Channel 374 is sized such that the first threaded portion of the rod is able to pass therethrough
Pocket 372 is sized to receive first retainer 320 The axial separation between second axial surface 368 and third axial surface 376 is chosen such that second radial surface 332 of first retainer 320 is completely overlapped by body member 362 of sleeve 360 when assembled, as shown in Fig. 11. By overlapping second radial surface 332, sleeve 360 prevents an unauthonzed user from engaging second radial surface 332 with a tool Alternatively, the axial separation between second axial surface 368 and third axial surface 376 is chosen such that both first radial surface 330 of first retainer 320 and second radial surface 332 of first retainer 320 are completely overlapped by body member 362 of sleeve
13
360. By overlapping both first radial surface 330 and second radial surface 332, sleeve 360 prevents an unauthonzed user from engaging either first radial surface 330 or second radial surface 332 with a tool.
Tab member 364 of sleeve 360 extends from first axial surface 366 on body member 362 and is generally identical to tab member 174 on second retainer 170 of embodiment 100. Tab member 364 extends outward from first axial surface 366 up to fourth axial surface 380. The separation between first axial surface 366 and fourth axial surface 380 is chosen such that tab member 364 extends into opening 74 on first fork member 72 shown in Fig. 1.
Coupler 324 of first retainer 320 may include protruding portions protruding outward from second axial surface 328 as opposed to apertures or receiving portions 346 or coupler 324 may include both receiving portions and protruding portions. Preferably coupler 324 includes receiving portions as opposed to protruding portions because two or more protruding portions could be easier to gnp with a tool. Additionally the number of receiving portions or protruding portions can be vaned to include two portions, three portions, four portions, or higher number of portions.
Refernng to Figs. 1, 10 and 11 the operation of locking device 300 is descnbed below. The rod is placed within channel 40 of axle 30 such that the first threaded portion of the rod extends beyond first threaded portion 32 of axle 30 and such the second threaded portion of rod extends beyond second threaded portion 34 of axle 30. Next, the second retainer is partially threaded onto the second threaded portion of the rod. Alternatively, the second retainer is permanently assembled to the second threaded portion of the rod using an adhesive, such as Loctite® 721, manufactured by the Loctite Corporation. By permanently assembling the second retainer to the rod, the overall assembly of locking device 300 is easier. Next, bicycle wheel 10 is positioned such that the tab member of the second retainer is positioned within opening 76 of second fork member 72, the second retainer is generally flush against second fork member 72 and such that the first threaded portion of the rod is positioned within opening 74 or first fork member 70. Next, sleeve 360 is placed over the first threaded portion of the rod such that tab member 364 of sleeve 360 is positioned within opening 74 of first fork member 70. Next, first retainer 320 is partially threaded onto the first threaded portion of the rod. Next, the key is positioned such that the coupler of the key engages coupler 324 of first retainer 320. Next, a tool is engaged with the tool engagement
member of the key such that by timing the key first retainer 320 is tightened against sleeve 360 and hence against surface 78 of first fork member 70 Finally, the key is uncoupled from first retainer 320 and stored until required again.
The tab member on the second retainer and tab member 364 on sleeve 360 prevent the rotation of the second retainer and the sleeve, respectively, when either the second retainer or the sleeve is attempted to gnpped with a tool. In order to compromise locking device 300, an unauthonzed user would either have to dislodge tab member 364 or the tab member on the second retainer or break the second retainer or sleeve 360
It should be noted that the inclusion of sleeve 360 permits first retainer 320 to have vanous radial configurations and still function properly. For example, first retainer 320 could have a smooth, cyhndncal radial surface, as long as the diameter of the radial surface is smaller than the diameter of radial surface 378 of sleeve 360 The radial configuration of first retainer 320 could also be hexagonal, as long as, the separation between the hexagonal surfaces and radial surface 378 is small enough to prevent the introduction of a socket or other tool between first retainer 320 and radial surface 378 of sleeve 360
In an exemplary embodiment, the second retainer is generally identical to first retainer 320 As such, the second retainer includes a coupler similar to coupler 324 and the second retainer does not include a tab member Dunng assembly, both first retainer 320 and the second retainer are threaded onto the axle of a bicycle and tightened against the bicycle frame 60 with key 190 Alternatively, a first sleeve 360 is inserted between first retainer 120 and bicycle frame 60 and a second sleeve 360 is inserted between second retainer 170 and bicycle frame 60 Alternatively, two keys are used to tighten first retainer 120 and second retainer 170 against bicycle frame 60 or first and second sleeves 360 Alternatively, first retainer 120 and second retainer 170 compnse couplers having different configurations As such first retainer 120 and second retainer 170 are tightened against bicycle frame 60 or first and second sleeves 360 with two keys, one having a coupler configured to match the coupler of first retainer 120 and one having a coupler configured to match the coupler of second retainer 170
Locking device 300 is disassembled to allow bicycle wheel 10 to be removed from bicycle frame 60 by an authonzed user in the following manner The key is positioned such that the coupler of the key engages coupler 324 of first retainer 320 Next, a tool is engaged with the tool engagement member of the key such that by turning the key first retainer 320 is
moved away from surface 78 of first fork member 70. Once first retainer 320 is backed away, bicycle axle 30 is free to exit from fork openings 74 and 76. Finally, the key is uncoupled from first retainer 320 and stored until required again.
Fig. 12 shows a third illustrative embodiment 400 of a locking device. Locking device 400 includes a rod 410 having a first threaded portion 412, a first retainer 420 fixably coupled to rod 410 and being generally identical to first retainer 120, a second retainer 470 generally identical to second retainer 170. and a key generally identical to key 190 (not shown if Fig. 12). Alternatively, locking device 400 further includes a sleeve (not shown in Fig. 12) generally identical to sleeve 360.
Figs. 13 and 14 provide an additional exemplary embodiment of a first retainer 520 First retainer 520 includes a body member 522 and a coupler 524. Body member 522 includes a generally circular first axial surface 526, a generally circular second axial surface 528, a first radial surface 530 and a second radial surface 532. First axial surface 526 and second axial surface 528 have a generally circular configuration. Second axial surface 528 has a generally smaller diameter compared to the diameter of first axial surface 526, thereby causing radial surface 530 to have a frusto-conical shape. The axial tapenng of the frusto- conical configuration reduces the axial extent of first retainer 520 to which a tool having a linear profile can exert pressure.
Body member 522 further includes a channel 536 and a pocket 538 Channel 536 is defined by a radially, inward-facing surface 540 that is concentnc with radial surfaces 530 and 532 and which extends from first axial surface 526 through to second axial sui face 528 Channel 536 includes a threaded portion configured to couple with the first threaded portion of the rod of locking device 500 Pocket 538 is defined by a third axial surface 542 and a second radially, mward-facing surface 544 Pocket 538 is configured to provide clearance for axle 30 when first retainer 520 is coupled to axle 30
Coupler 524 of first retainer 520 includes three apertures or receiving portions 546a, 546b, and 546c formed within body member 522 The receiving portions 546a, 546b, and 546c extend from either second axial surface 528 or first radial surface 530 into body member 522. By allowing receiving portions 546a. 546b, and 546c to intersect with radial surface 530 instead of only axial surface 528, as in locking device 100, the overall radial extent of first retainer 520 is reduced
16
The placement of receiving portions 546a, 546b, and 546c is vaned on second axial surface 528 and first radial surface 530 to provide unique embodiments of first retainer 520. The placement cntena of receiving portions 546a, 546b, and 546c on second axial surface 528 and first radial surface 530 is similar to the angular and radial coordinates shown in Fig. 5.
Refernng to Fig. 15, key 590 of locking device 500 includes a body member 592, a tool engagement member 594, and a coupler 596. Body member 592 includes a generally cyhndncal configuration defined by radial surface 598 and includes a first axial surface 599. Tool engagement member 594 includes a hexagonally shaped portion 600 sized to be engaged by a wrench tool or socket tool. Coupler 596 includes three protruding portions 602a, 602b, and 602c sized, shaped and positioned to correspond to receiving portions 546a, 546b, and 546c The configurations of coupler 596 and coupler 524 are chosen to mate with each other
As shown m Fig. 15, the protruding portions 602a, 602b, and 602c of coupler 596 extend outward from a second axial surface 604 of body member 692. Second axial surface 604 defines a pocket 606 in body member 592 A radial surface 608 extends between first axial surface 599 and second axial surface 604 and is configured to generally match first radial surface 530 of first retainer 520. Alternatively, body member 592 does not include pocket 506 and protruding portions 602a, 602b, and 602c extend from first axial surface 599.
Referring to Fig. 16, another illustrative embodiment of locking device 700 is shown Locking device 700 includes a rod 710 generally similar to rod 110 of locking device 100, a first retainer 720 generally similar to first retainer 120 of locking device 100, a second retainer 170 generally similar to first retainer 120 of locking device 100, and a key (not shown in Fig. 16). Locking device 700 is used in applications wherein there is not an opening, such as fork openings 74 and 76. to receive the tab member on the second retainer or the sleeve For example, locking device 700 may be used to secure a seat to the bicycle frame
While the invention has been illustrated and descnbed in detail in the drawings and foregoing descnption, such illustration and descnption is to be considered as exemplary and not restrictive in character, it being understood that only exemplary embodiments have been shown and descnbed and that all changes and modifications that come within the spint of the invention are desired to be protected