US20040032099A1 - In-line roller skates having quick-release axle system - Google Patents
In-line roller skates having quick-release axle system Download PDFInfo
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- US20040032099A1 US20040032099A1 US10/408,843 US40884303A US2004032099A1 US 20040032099 A1 US20040032099 A1 US 20040032099A1 US 40884303 A US40884303 A US 40884303A US 2004032099 A1 US2004032099 A1 US 2004032099A1
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- Prior art keywords
- axle
- release
- pair
- central bore
- shafts
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- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63C—SKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
- A63C17/00—Roller skates; Skate-boards
- A63C17/22—Wheels for roller skates
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63C—SKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
- A63C17/00—Roller skates; Skate-boards
- A63C17/22—Wheels for roller skates
- A63C17/226—Wheel mounting, i.e. arrangement connecting wheel and axle mount
Definitions
- the present invention relates generally to in-line roller skates, and more particularly to a quick-release axle system for use in the same.
- the bolt (acting as the axle shaft) passes through the axle aperture in the skate frame, then through the bearings and bearing spacer, and is held in place with a nut which is threaded onto the bolt from the opposite side and tightened against the skate frame.
- a further object, of the present invention is to provide such an axle system, in which a quick release, snap-lock apparatus is used to secure the wheels to the frame on an in-line skate.
- a further object of the present invention is to provide such an axle system, which can accommodate the different axle aperture diameters and bearing spacers most commonly used in in-line roller skates.
- a further object of the present invention is to provide a quick-release type;axle system, in which a pair of axle shafts automatically engage and lock with a bearing spacer within a skate wheel-when a pair of axle release pins are inserted into a central bore formed through each such axle shafts, and the axle shafts automatically disengage from the bearing spacer when the release pins are pulled out slightly from the axle shafts
- a further object of the present invention is to provide a quick-release type axle system, in which a pair of axle shafts automatically engage and lock with each other when an axle release pin is inserted into a central bore formed through one of such axle shaft and the axle shafts automatically disengage with each other when the release pin are pulled out slightly from the axle shaft.
- a further object of the present invention is to provide a quick-release type axle system, in which a pair of axle shafts automatically engage and lock with a bearing spacer within a skate wheel when a pair of axle release pins are inserted into a central bore formed through each such axle shaft, and the axle shafts automatically disengage from the bearing spacer when the release pins are pushed inwardly into the bore formed in the axle shaft.
- a further object of the present invention is to provide a quick-release type axle system, in which a pair of axle shafts automatically engage and lock with each other when an axle release pin is inserted into a central bore formed through one of such axle shafts and the axle shafts automatically disengage with each other when the release pin is pushed inwardly into the bore formed in the axle shaft.
- FIG. 1 is a perspective view of an in-line roller skate, incorporating the quick-release axle system of the first illustrative embodiment of the present invention
- FIG. 2 is an exploded diagram of the quick-release axle system of first illustrative embodiment of the present invention, showing the major subcomponents thereof;
- FIG. 2A is a perspective view of the bearing spacer used i in conjunction with the quick-release axle system of the first embodiment
- FIG. 2B is a perspective view of another type of bearing spacer used in conjunction with the quick-release axle system of the second embodiment
- FIG. 3 is a cross-sectional diagram of the quick-release axle system of the present invention showing both axle shafts of the system the axle haft on the left is in its locked and ready position, while the axle shaft on the right is in the release position as it would appear being either withdrawn or inserted through the axle aperture;
- FIG. 4 is an elevated side view of the bearing spacer used in the first illustrative embodiment of the axle system of the present invention
- FIG. 4A is a cross-sectional view of the bearing spacer of the illustrative embodiment, taken along line 4 A- 4 A of FIG. 4;
- FIG. 5 is an elevated cross-sectional diagram of one of the axle shafts removed from the quick-release axle system of the first illustrative embodiment
- FIG. 6 is an elevated side view of the spring-like lock washer used in conjunction each axle shaft of the quick-release axle system of the first illustrative embodiment
- FIG. 7 is an elevated side view of the release pin, spring and C-clip subassembly that slides along the central bore of each axle shaft of the quick-release axle system of the first illustrative embodiment
- FIG. 8 is an elevated, cross-sectional schematic diagram of the second illustrative embodiment of the quick-release axle system of the present invention, showing a pair of axle portions releasably engaged with a bearing spacer supported within a wheel of an in-line skate;
- FIG. 8A is an elevated side view of the release pin as used in conjunction with the quick-release axle system of the second embodiment of FIG. 8 which utilizes the “pull” method for axle release;
- FIG. 9 is an elevated, cross-sectional schematic diagram of the third illustrative embodiment of the quick-release axle system of the present invention, showing a pair of axle portions releasably engaged with each other while passing through a wheel of an in-line skate;
- FIG. 10 is an elevated, cross-sectional schematic diagram of the fourth illustrative embodiment of the quick-release axle system of the present invention, showing a pair of axle portions;
- FIG. 10A is an elevated side view of the release pin as used in conjunction with the quick-release axle system of the second embodiment of FIG. 10 which utilizes the “push” method for axle release;
- FIG. 11 is a exploded diagram of the fifth illustrative embodiment of the quick-release axle system of the present invention.
- FIG. 11A is an elevated cross-sectional schematic diagram of the fifth illustrative embodiment of the quick-release axle system of FIG. 11, which utilizes the “push” method for axle release.
- a generalized embodiment of an in-line skate of the present invention comprises a number of components, namely: a frame 1 having a pair of spaced apart frame rails 2 A and 2 B; a set of wheels 3 , rotatable supported by way of the quick-release axle system of the present invention, between the frame rails; a brake structure 4 typically made of rubber or hard plastic and mounted on the rear of the skate frame, for use in braking operations; and a boot portion 5 mounted to the frame and adapted for comfortably receiving the foot of its user. Details regarding the general design of prior art in-line skates are disclosed in Applicant's U.S. Pat. No. 5,362,075, incorporated herein by reference.
- FIG. 2 an exploded perspective view of the quick-release axle system of the first illustrative embodiment is shown.
- the system comprises three subcomponents, namely: a bearing spacer 6 installed between the bearing assemblies 7 A and 7 B; first and second axle shafts 8 A and 8 B; and first and second axle-shaft release pins 9 A and 9 B.
- axle shafts 8 A and 8 B are identical, the description of the structure will be made with reference to axle shaft 8 B for purposes of explication.
- Each wheel on the in-line skate consists of a tire portion 10 surrounding an inner core 10 A which has been formed with an inner bore so as to receive bearings 7 A and 7 B with bearing spacer 6 disposed therebetween.
- the bearing spacer 6 has a central portion 6 A and hollow end portions 6 B and 6 C extending therefrom.
- the ends of the bearing spacer 6 are machined with an outer diameter that permits the bearing spacer to fit into the inner bore of the inner race of the bearings 7 A and 7 B.
- the center portion of the spacer 6 A has a larger diameter than the end portions thereof 6 B and 6 C in order to create a shoulder that contacts the inner races of the bearings.
- the bearing spacers are provided with an inner bore 6 D through which each wheel axle shaft 8 A and 8 B is passed enabling the wheel to be attached to the skate frame.
- four equally-spaced indents 11 are formed at a predetermined distance from the end of the bearing spacer.
- the function of these holes is to receive an axle-locking ball (i.e., spherical element) 12 (e.g., 0.09385 inch diameter).
- This arrangement forms a mechanism for locking the axle shaft relative to the bearing spacer.
- the steel material of the axle shaft around these ball bearings is crimped in order to keep them from falling back out of the detents.
- each axle shaft 8 A and 8 B has a hollow bore 13 (of about 0.130 inch diameter) formed centrally therethrough, and an end cap portion 14 .
- the cap portion is about 0.1875 inches at its thickest point.
- a recess, FIG. 2, 18 is machined into one half of the cap portion 14 in order to allow for an access point for the release pin.
- the outer diameter of the axle shaft has an outer diameter of about a 0.25 inch and is adapted for insertion through an aperture 15 formed in the frame rail and the hollow bore 6 D of the end portion of the bearing spacer.
- the bore at once end of the axle shaft is enlarged to a diameter of 0.1875 for a length of about 0.215 inches in order to accommodate a return spring 16 and retaining clip 17 slipped over the end of the release i pin 9 A ( 9 B)
- each axle-shaft release pin 9 A and 9 b has a first cylindrical body portion 19 of a first length, and a second cylindrical body portion 20 of a second (i.e., shorter) length separated by a tapered portion 21 of narrower diameter than the first and second cylindrical portions of the release pin.
- a hole 22 having a 0.0625 inch diameter is drilled through the release pin shaft 19 at about 0.093 inches from one end of the shaft, as shown in FIG. 3. The function of hole 22 is to allow a tool or pin to be used to pull the release pin 9 A, ( 9 B) out of the axle shaft during axle release operations.
- the hole 22 in the release pin is recessed within the end of the axle shaft (as shown in the left side of FIG. 3) and thus, cannot be inadvertently pulled out during roller skating activity.
- a recess or slot 23 (e.g., having dimensions of 0.0312 inch deep ⁇ 0.145 inches long) is machined into the shaft at about 0.100 inches from the end of the axle shaft where the hole 22 has been drilled.
- the function of this slot 23 is to allow for the insertion of a retaining pin or screw 24 through a hole drilled laterally through the side of the cap portion extending therefrom into the inner bore of the axle shaft so that the release pin can be retained within the bore of the axle shaft.
- a small return spring 16 is installed over the end of the release pin shaft 20 and c-clip retainer 17 is pushed onto a machined groove 25 in the axle shaft in order to retain the return spring on the end portion thereof.
- the function of the return spring 16 is to hold the release pin in the locked position within the axle shaft during the vibration encountered while skating. With this arrangement, the return spring 16 is then trapped between the c-clip 17 and the inner flange 26 machined within the bore of the axle shaft, while the retaining screw 24 is inserted into the slot 23 formed in the end of the release pin.
- the release pin 22 is retained within the bore of the respective axle shaft and is permitted to slide therewithin a distance equal to the length of slot 23 formed in the end of the release pin.
- a curved spring steel washer 27 (of 0.017 inches thickness and 0.500 inch outer diameter and inner diameter of about 0.251 inches) is positioned over the axle shaft.
- the spring washer 27 is pressed against the inner surface of the end cap 14 in order to provide tightness when the axle shafts are installed and locked to the bearing spacer.
- a nylon plastic cover may be fashioned to snap-fit over the cap end 14 of the main axle.
- Each bearing 7 A and 7 B is installed into the wheel from opposite sides, separated by bearing spacer 6 A.
- the locking balls 12 held within the shaft by crimpings automatically fall into place into the corresponding holes 11 in the bearing spacer.
- the release pin is then allowed to retract within the inner bore of the axle shaft due to the pressure of the return spring 16 which automatically forces the release pin inward toward the bearing spacer so that the central portion 21 thereof is positioned directly beneath detent holes 11 and contacts the surface of the steel locking balls 12 forcing them to remain locked within the holes 11 (detents) formed in the bearing spacer.
- the cylindrical portion 19 of the release pin 9 A renders it impossible for the ball bearings 12 to move downward, or out of their corresponding detents, and thus provides an extremely strong and efficient locking mechanism.
- Pulling the spring-biased release pin 9 A out from its corresponding axle shaft can be carried out using a small tool, (e.g., a paper clip or an accessory device).
- the tool is slid through the hole 22 formed in the end of the release pin and allows the release pin to be pulled out slightly (against the force of the return spring) so that the balls 12 retaining the axle shaft within the bearing spacer can be allowed to fall out of their corresponding holes, as described hereinabove.
- curved spring steel washer 27 applies pressure to the outside of the skate frame in order to take up any slack and provide a tight fit.
- the fit can be adjusted further, if desired, by using washers of different thicknesses as shims installed over the axle shaft to be positioned between the spring steel washer and the skate frame.
- FIGS. 8 and 8A A second illustrative embodiment of the quick-release axle system of the present invention is shown in FIGS. 8 and 8A. While this embodiment is quite similar to the embodiment of FIG. 3, there are a number of minor differences.
- the bearing spacer 30 in FIG. 8 does not have an outer bore surface that slides into the inner bore of the inner race of the bearing, as in the first embodiment shown in FIG. 3.
- the bearing spacer 30 is shaped like a bushing whose inner and outer diameters are exactly the same as the inner and outer diameters of the inner race of the bearing itself. Therefore, the axle shaft diameter is larger in order to correspond with the diameter of the inner bore of the inner bearing race.
- Circumferential grooves 31 A and 31 B are cut into the inner surface of the inner bore of the bearing spacer 30 (about 0.030 inches deep) in lieu of the equally spaced holes in the bearing spacer of the first illustrative embodiment described above.
- the locking balls lock into place within the recess provided by the groove.
- the groove is positioned so as to create a tight fit between the flange and the skate frame upon installation. Other minor differences will be described below.
- each bearing is installed into the wheel from opposite sides and separated by bearing spacer 30 .
- the axle shafts 6 A and 6 B are inserted into the bore of the bearing spacer, the locking balls 12 held within the shaft by crimpings automatically fall into place into corresponding grooves 31 A and 31 B.
- Releasing the release pin allows pressure from the return spring 16 , which is compressed within the bore of shaft 6 A ( 6 B) between interior flange 34 and circumferential flange 33 , to cause the release pin to slide inward toward the center of the spacer, so that the outer surface of circumferential flange 33 is disposed directly beneath and contacts the surface of the axle-locking balls 12 , forcing them to remain locked within the circumferential groove 31 A ( 31 B) formed in the inner bore of the bearing spacer.
- the end of the release pin will remain recessed within the bore of the axle shaft, while the axle shaft and bearing spacer are securely locked together and the release pin is prevented from being inadvertently pulled out of its locked configuration.
- the release pin 9 A ( 9 B) renders it impossible for the ball bearings 12 to move downward, or out of their corresponding grooves 31 A ( 31 B), and thus provides an extremely strong and efficient locking mechanism.
- Pulling the spring-biased release pin 9 A ( 9 B) out from its corresponding axle shaft can be carried out using a small tool, (e.g., a paper clip or accessory device) that slides through the hole 22 formed in the end of the release pin and allows the release pin to be pulled out slightly (against the a force of the return spring) so that the locking balls 12 retaining the axle shaft within the bearing spacer 30 can be allowed to fall out of their corresponding holes, as described hereinabove.
- a small tool e.g., a paper clip or accessory device
- the bearing spacer is not used as part of the axle-shaft locking mechanism.
- the axle system comprises: a main axle shaft 40 insertable through the first skate frame wall 2 A, the first bearing 7 A, the bearing spacer 41 , the second bearing 7 B, and the second skate frame wall; and a secondary axle shaft 42 for insertion within a central bore 43 formed within the main axle shaft 40 .
- the main shaft axle has head portion 44 formed on one end of its cylindrical body portion, and central bore 43 formed through the end of its body portion opposite head portion 44 . The length of the bore 43 extends about half way across the length of the axle shaft.
- a release pin 45 similar in design as the release pin 9 A ( 9 B) shown in FIG. 8, is provided for insertion through a central bore 46 formed in the secondary axle shaft 42 , to engage with ball bearing 12 .
- a circumferential groove 47 is cut into the inner surface of the inner bore of the main axle shaft 42 .
- the locking portion works exactly the same as in the second embodiment, but the dimensions of the components are smaller.
- the main axle shaft 40 has an outer diameter of about 0.3125 inches and is adapted for insertion through apertures 2 A and 2 B formed in the frame rail 2 A and 2 B.
- Rounded cap portion 44 is about 0.1875 inches at its thickest point.
- a recess 48 0.0625 inches deep and 0.089 inches long is machined into one half of the cap in order to allow for an access point for the release pin 45 .
- a hole 49 having a 0.0625 inch diameter is drilled through the release pin shaft at about 0.093 inches from one end thereof, as shown in FIG. 9.
- the function of hole 49 is to allow a tool or pin to be used to pull the release pin 45 out of the axle shaft during axle release operations.
- the hole in the release pin is recessed within the end of the axle shaft and thus cannot be inadvertently pulled out during roller skating activity.
- a small return spring 16 is installed over the central body portion of the release pin shaft and restrained by an enlarged annular-shaped flange 50 , which is designed to engage balls 12 in the system's locked configuration.
- the function of the return spring is to hold the release pin in the locked position within the axle shaft during the vibration encountered while skating.
- the return spring is then trapped between the annular 50 and the inner flange 51 of the machined groove bore 52 formed in the axle shaft, while the retaining pin 24 is inserted into the slot 53 formed in the end of the release pin, as shown in FIG. 9.
- the release pin 45 is retained within the bore of the secondary axle shaft and is permitted to slide therewithin a distance equal to the length of slot 53 formed in the end of the release pin.
- a curved spring steel washer 27 is positioned over the secondary axle shaft 42 which tightens the axle system in the locked configuration.
- a nylon plastic cover can be snapped over the cap end of the second axle shaft.
- Each bearing 7 A, 7 B is installed into the wheel from opposite sides. Then, the main axle shaft is inserted into the bore of the wheel and thereafter the secondary axle shaft is slid into the bore within the main axle shaft.
- the release pin 45 is slid into the bore of the second axle shaft, the two steel locking balls are automatically forced into place into the circumferential groove 54 formed within the control portion of the bore 52 within the main axle shaft. In this configuration, the end of the release pin will remain recessed within the bore of the primary axle shaft, while the primary axle shaft and second axle shaft are securely locked together and the release pin prevented from being inadvertently pulled out of its locked configuration. In this locked configuration, shown in FIG. 9, the release pin 45 renders it impossible for the axle-locking balls 12 to move downward, or out of their corresponding detents, and thus provides an extremely strong and efficient locking mechanism.
- the release pin 45 When the release pin 45 is pulled outwardly by an amount limited by the length of slot 53 , (i.e. against the outwardly directed biasing forces produced by the return spring), the ball bearings 12 are permitted to fall within the narrow circumferential groove 54 .
- the secondary axle shaft 42 In this unlocked configuration, the secondary axle shaft 42 is released from the primary axle shaft 40 and can be withdrawn therefrom, as well as the wheel assembly and the skate frame.
- the release pin on a particular wheel has been “released” or arranged into its unlocked configuration, then the secondary axle shaft can be withdrawn from the primary axle shaft and the wheel assembly easily removed from the frame of the in-line skate.
- Pulling the spring-biased release pin 45 out from the main axle shaft can be carried out using a small tool, (e.g. a paper clip or accessory device) that slides through the hole 48 formed in the end of the release pin.
- a small tool e.g. a paper clip or accessory device
- FIGS. 10 and 10A a fourth illustrative embodiment of the quick release axle system is shown.
- the release pins are released by a “pushing” operation rather than by a pulling operation.
- each bearing 7 A, 7 B is installed into the wheel 10 from opposite sides and separated by bearing spacer 60 .
- the axle shafts 61 A ( 61 B) are inserted into the bore of the bearing spacer, the locking balls 12 held within the shaft by crimpings, automatically fall into place within corresponding grooves 62 A ( 62 B).
- the end of the release pin will remain recessed within the bore of the axle shaft, while the axle shaft and bearing spacer are securely locked together and the release pin prevented from being inadvertently pulled out of its locked configuration.
- the release pin 68 A 68 (B) renders it impossible for the axle-locking balls 12 to move downward, or out of their corresponding grooves 62 A 62 (B), and thus provides an extremely strong and efficient locking mechanism.
- Pushing the spring-biased release pin 68 A ( 68 B) into its corresponding axle shaft can be carried out using a small tool (e.g., a screw driver or accessory device) that is slid into the open end of the bore in the axle shaft, and pushed against release pin (against the force of the return spring) so that the axle-locking balls 12 retaining the axle shaft within the bearing spacer 60 can be allowed to fall out of their corresponding holes, as described above.
- a small tool e.g., a screw driver or accessory device
- FIGS. 11 and 11A a fifth illustrative embodiment of the quick release axle system is shown.
- the fifth embodiment of the present invention is constructed in the same manner as the second embodiment except that only a single axle shaft 8 B′′ is used instead of two separate axle shafts to support each wheel.
- the axle shaft 6 B′′ does not interlock with the bearing spacer 6 .
- the axle shaft 8 B′′ is made long enough to pass through the skate frame 2 B from one side, through the frame spacer, wheel and bearing assemblies 7 A, 7 B and the axle aperture in the frame portion on the opposite side.
- the interlocking balls 12 then use the outer surface of the other side of the skate frame 2 A itself to lock the axle shaft in place when the release pin 9 B′′ is allowed to slide into position, beneath the locking balls, within the main axle bore 70 formed therein.
- each bearing 7 A, 7 B is installed into the wheel 10 from opposite sides and separated by bearing spacer 6 .
- the axle shaft 8 B′′ is inserted through the bore of the bearing spacer, and bearings 7 A, 7 B and frame rails 2 A, 2 B as shown in FIG. 11A, the locking balls 12 held within the shaft by crimpings, automatically fall into place outside the outer surface of skate frame 2 A, creating a locking mechanism.
- the end of the release pin will remain recessed within the bore of the axle shaft, while the axle shaft is securely locked between the frame rails 2 A and 2 B while the release pin 9 B′′ is prevented from being inadvertently pulled out of its locked configuration.
- the release pin 9 B′′ renders it impossible for the axle-locking balls 12 to move downward, or away from the outer surface of frame unit 2 A, and thus provides an extremely strong and efficient locking mechanism.
- axle-locking balls 12 are permitted to fall within the central bore of the axle shaft.
- the axle shaft is released from the frame rails 2 A and can be withdrawn from the bearing spacer 6 , wheel assembly and skate frame.
- the release pin on a particular wheel has been “released” or arranged into its unlocked configuration, then the associated axle shaft can be withdrawn from the bearing spacer and the wheel assembly easily removed from the frame of he in-line skate.
- a cap can be used to engage with locking balls 12 , outside of the rail frame 2 A.
- the cap will have an inner bore with a diameter which is slightly larger than the diameter of the axle shaft 8 B′′.
- a circumferential groove is then machined at a predetermined distance from one end of the cap within the inner bore.
- the cap is then pressed onto the protruding portion of the axle shaft 8 B′′ from the opposite side of the frame 2 A.
- the locking balls 12 then interlock within the circumferential groove in the cap when the release pin is allowed to slide into position within the bore formed through the axle shaft 8 B′′.
- the axles may be designed so that releasing the axle from the skate is accomplished by pulling the release pin outward slightly, or they may be designed so that the release procedure involves pushing the release pin inward slightly.
Abstract
A quick-release type axle system for in-line skates is disclosed. A pair of axle shafts cooperate with each other to support a wheel between a pair of frames. A release pin is inserted into a central bore formed through the axle shafts to lock the axle shafts relative to each other. In one embodiment, the release pin is pulled outwardly to release the axle shafts from the locked configuration, whereas in another embodiment, the release pin is pushed inwardly to achieve unlocking of the axle shafts. In some embodiments, a pair of release pins are used to achieve the quick-release mechanism of the present invention.
Description
- 1. Field of Invention
- The present invention relates generally to in-line roller skates, and more particularly to a quick-release axle system for use in the same.
- 2. Brief Description of Prior Art
- There are currently a wide variety of prior art axle systems in use for mounting the wheels on in-line roller skates. Each skate manufacturing company has it's own unique design and there are several after-market companies which also manufacture axle kits. Although each one differs somewhat in design, the general configuration invariably involves a threaded portion which is fastened with a nut.
- In the common nut and bolt type axle system, the bolt (acting as the axle shaft) passes through the axle aperture in the skate frame, then through the bearings and bearing spacer, and is held in place with a nut which is threaded onto the bolt from the opposite side and tightened against the skate frame.
- Other systems have the threaded portion on the inside of the axle shaft. A screw is threaded into the axle from the opposite side and tightened to hold it in place. A third popular method involves threading the inside of the bearing spacer itself. A screw is then inserted from each side of the frame and threaded into the bearing spacer forming an axle to support the wheel.
- All of these methods involve a tightening sequence using allen wrenches, screw drivers, or wrenches of some type making installation or removal of the wheels a tedious and time-consuming process.
- In addition, it is a common problem to have the keyed slot, whether it be for an allen key or screwdriver, strip out making it extremely difficult, if not impossible, to remove the axle with the standard designated tools. Usually these can only be removed by drilling or cutting the axle and replacing it with a new-one.
- It is also possible for cross-threading to occur during assembly which makes removal extremely difficult as well.
- Thus, there is a great need in the art for an improved axle system for use in connection with in-line roller skates, while avoiding the shortcomings and drawbacks of prior art axle systems and wheel mounting methodologies.
- Accordingly, it is a primary object of the present invention to provide an improved axle system for use in connection with in-line roller skates, while avoiding the shortcomings and drawbacks of prior art axle systems and wheel mounting methodologies.
- A further object, of the present invention is to provide such an axle system, in which a quick release, snap-lock apparatus is used to secure the wheels to the frame on an in-line skate.
- A further object of the present invention is to provide such an axle system, which can accommodate the different axle aperture diameters and bearing spacers most commonly used in in-line roller skates.
- A further object of the present invention is to provide a quick-release type;axle system, in which a pair of axle shafts automatically engage and lock with a bearing spacer within a skate wheel-when a pair of axle release pins are inserted into a central bore formed through each such axle shafts, and the axle shafts automatically disengage from the bearing spacer when the release pins are pulled out slightly from the axle shafts
- A further object of the present invention is to provide a quick-release type axle system, in which a pair of axle shafts automatically engage and lock with each other when an axle release pin is inserted into a central bore formed through one of such axle shaft and the axle shafts automatically disengage with each other when the release pin are pulled out slightly from the axle shaft.
- A further object of the present invention is to provide a quick-release type axle system, in which a pair of axle shafts automatically engage and lock with a bearing spacer within a skate wheel when a pair of axle release pins are inserted into a central bore formed through each such axle shaft, and the axle shafts automatically disengage from the bearing spacer when the release pins are pushed inwardly into the bore formed in the axle shaft.
- A further object of the present invention is to provide a quick-release type axle system, in which a pair of axle shafts automatically engage and lock with each other when an axle release pin is inserted into a central bore formed through one of such axle shafts and the axle shafts automatically disengage with each other when the release pin is pushed inwardly into the bore formed in the axle shaft.
- For a more complete understanding of the Objects of the Present Invention, the following Detailed Description of the Illustrative Embodiments of the Present Invention should be read in conjunction with the accompanying Drawings, wherein:
- FIG. 1 is a perspective view of an in-line roller skate, incorporating the quick-release axle system of the first illustrative embodiment of the present invention;
- FIG. 2 is an exploded diagram of the quick-release axle system of first illustrative embodiment of the present invention, showing the major subcomponents thereof;
- FIG. 2A is a perspective view of the bearing spacer used i in conjunction with the quick-release axle system of the first embodiment;
- FIG. 2B is a perspective view of another type of bearing spacer used in conjunction with the quick-release axle system of the second embodiment;
- FIG. 3 is a cross-sectional diagram of the quick-release axle system of the present invention showing both axle shafts of the system the axle haft on the left is in its locked and ready position, while the axle shaft on the right is in the release position as it would appear being either withdrawn or inserted through the axle aperture;
- FIG. 4 is an elevated side view of the bearing spacer used in the first illustrative embodiment of the axle system of the present invention;
- FIG. 4A is a cross-sectional view of the bearing spacer of the illustrative embodiment, taken along line4A-4A of FIG. 4;
- FIG. 5 is an elevated cross-sectional diagram of one of the axle shafts removed from the quick-release axle system of the first illustrative embodiment;
- FIG. 6 is an elevated side view of the spring-like lock washer used in conjunction each axle shaft of the quick-release axle system of the first illustrative embodiment;
- FIG. 7 is an elevated side view of the release pin, spring and C-clip subassembly that slides along the central bore of each axle shaft of the quick-release axle system of the first illustrative embodiment;
- FIG. 8 is an elevated, cross-sectional schematic diagram of the second illustrative embodiment of the quick-release axle system of the present invention, showing a pair of axle portions releasably engaged with a bearing spacer supported within a wheel of an in-line skate;
- FIG. 8A is an elevated side view of the release pin as used in conjunction with the quick-release axle system of the second embodiment of FIG. 8 which utilizes the “pull” method for axle release;
- FIG. 9 is an elevated, cross-sectional schematic diagram of the third illustrative embodiment of the quick-release axle system of the present invention, showing a pair of axle portions releasably engaged with each other while passing through a wheel of an in-line skate;
- FIG. 10 is an elevated, cross-sectional schematic diagram of the fourth illustrative embodiment of the quick-release axle system of the present invention, showing a pair of axle portions; and
- FIG. 10A is an elevated side view of the release pin as used in conjunction with the quick-release axle system of the second embodiment of FIG. 10 which utilizes the “push” method for axle release;
- FIG. 11 is a exploded diagram of the fifth illustrative embodiment of the quick-release axle system of the present invention; and
- FIG. 11A is an elevated cross-sectional schematic diagram of the fifth illustrative embodiment of the quick-release axle system of FIG. 11, which utilizes the “push” method for axle release.
- Referring to the figures in the Drawings, the illustrative embodiments of the in-line roller skate of the present invention, and the quick-release axle systems incorporated therein, will be described in great detail. In connection with this detailed description, like structures being indexed with like reference numbers.
- As shown in FIG. 1, a generalized embodiment of an in-line skate of the present invention, comprises a number of components, namely: a
frame 1 having a pair of spaced apartframe rails wheels 3, rotatable supported by way of the quick-release axle system of the present invention, between the frame rails; abrake structure 4 typically made of rubber or hard plastic and mounted on the rear of the skate frame, for use in braking operations; and aboot portion 5 mounted to the frame and adapted for comfortably receiving the foot of its user. Details regarding the general design of prior art in-line skates are disclosed in Applicant's U.S. Pat. No. 5,362,075, incorporated herein by reference. It is understood that the design of the boot and the frame structure of the in-line skate hereof may differ from embodiment to embodiment thereof without departing from the scope or spirit of the present invention. Any of the illustrative embodiments of the quick-release axle system of the present invention described below can be incorporated in such in-line skate designs. - In FIG. 2, an exploded perspective view of the quick-release axle system of the first illustrative embodiment is shown. As illustrated, the system comprises three subcomponents, namely: a
bearing spacer 6 installed between thebearing assemblies second axle shafts 8A and 8B; and first and second axle-shaft release pins axle shafts 8A and 8B are identical, the description of the structure will be made with reference to axle shaft 8B for purposes of explication. Each wheel on the in-line skate consists of atire portion 10 surrounding aninner core 10A which has been formed with an inner bore so as to receivebearings spacer 6 disposed therebetween. - As shown in FIGS. 3 and 4, the bearing
spacer 6 has acentral portion 6A andhollow end portions 6B and 6C extending therefrom. The ends of the bearingspacer 6 are machined with an outer diameter that permits the bearing spacer to fit into the inner bore of the inner race of thebearings spacer 6A has a larger diameter than the end portions thereof 6B and 6C in order to create a shoulder that contacts the inner races of the bearings. The bearing spacers are provided with an inner bore 6D through which eachwheel axle shaft 8A and 8B is passed enabling the wheel to be attached to the skate frame. In the illustrative embodiment, four equally-spaced indents 11 (e.g., holes of 0.0940 inch diameter) are formed at a predetermined distance from the end of the bearing spacer. The function of these holes is to receive an axle-locking ball (i.e., spherical element) 12 (e.g., 0.09385 inch diameter). This arrangement forms a mechanism for locking the axle shaft relative to the bearing spacer. The steel material of the axle shaft around these ball bearings is crimped in order to keep them from falling back out of the detents. - As shown in FIGS. 3 and 5, each
axle shaft 8A and 8B has a hollow bore 13 (of about 0.130 inch diameter) formed centrally therethrough, and anend cap portion 14. In the illustrative embodiment, the cap portion is about 0.1875 inches at its thickest point. A recess, FIG. 2, 18 is machined into one half of thecap portion 14 in order to allow for an access point for the release pin. The outer diameter of the axle shaft has an outer diameter of about a 0.25 inch and is adapted for insertion through anaperture 15 formed in the frame rail and the hollow bore 6D of the end portion of the bearing spacer. The bore at once end of the axle shaft is enlarged to a diameter of 0.1875 for a length of about 0.215 inches in order to accommodate areturn spring 16 and retainingclip 17 slipped over the end of therelease i pin 9A (9B) - As shown in FIG. 7, each axle-
shaft release pin 9A and 9 b has a first cylindrical body portion 19 of a first length, and a second cylindrical body portion 20 of a second (i.e., shorter) length separated by a taperedportion 21 of narrower diameter than the first and second cylindrical portions of the release pin. A hole 22 having a 0.0625 inch diameter is drilled through the release pin shaft 19 at about 0.093 inches from one end of the shaft, as shown in FIG. 3. The function of hole 22 is to allow a tool or pin to be used to pull therelease pin 9A, (9B) out of the axle shaft during axle release operations. When the release pin is retained within the axle shaft, during the axle locked configuration, the hole 22 in the release pin is recessed within the end of the axle shaft (as shown in the left side of FIG. 3) and thus, cannot be inadvertently pulled out during roller skating activity. - In the illustrative embodiment, a recess or slot23 (e.g., having dimensions of 0.0312 inch deep×0.145 inches long) is machined into the shaft at about 0.100 inches from the end of the axle shaft where the hole 22 has been drilled. The function of this
slot 23 is to allow for the insertion of a retaining pin or screw 24 through a hole drilled laterally through the side of the cap portion extending therefrom into the inner bore of the axle shaft so that the release pin can be retained within the bore of the axle shaft. - As shown in FIGS. 3 and 7, a
small return spring 16 is installed over the end of the release pin shaft 20 and c-clip retainer 17 is pushed onto a machinedgroove 25 in the axle shaft in order to retain the return spring on the end portion thereof. The function of thereturn spring 16 is to hold the release pin in the locked position within the axle shaft during the vibration encountered while skating. With this arrangement, thereturn spring 16 is then trapped between the c-clip 17 and theinner flange 26 machined within the bore of the axle shaft, while the retainingscrew 24 is inserted into theslot 23 formed in the end of the release pin. As shown in FIG. 3, the release pin 22 is retained within the bore of the respective axle shaft and is permitted to slide therewithin a distance equal to the length ofslot 23 formed in the end of the release pin. - As shown in FIG.3, a curved spring steel washer27 (of 0.017 inches thickness and 0.500 inch outer diameter and inner diameter of about 0.251 inches) is positioned over the axle shaft. The
spring washer 27 is pressed against the inner surface of theend cap 14 in order to provide tightness when the axle shafts are installed and locked to the bearing spacer. Also, a nylon plastic cover may be fashioned to snap-fit over thecap end 14 of the main axle. - Each
bearing spacer 6A. As the axle shaft is inserted into the bore of the bearing spacer, the lockingballs 12 held within the shaft by crimpings automatically fall into place into the correspondingholes 11 in the bearing spacer. The release pin is then allowed to retract within the inner bore of the axle shaft due to the pressure of thereturn spring 16 which automatically forces the release pin inward toward the bearing spacer so that thecentral portion 21 thereof is positioned directly beneath detent holes 11 and contacts the surface of thesteel locking balls 12 forcing them to remain locked within the holes 11 (detents) formed in the bearing spacer. In this locked configuration, shown in the left side of FIG. 3, the cylindrical portion 19 of therelease pin 9A renders it impossible for theball bearings 12 to move downward, or out of their corresponding detents, and thus provides an extremely strong and efficient locking mechanism. - When the
release pin 9A is pulled outwardly from theaxle shaft 6A by an amount limited by the length ofslot 23, (i.e., against the outwardly directed biasing forces produced by return spring 16), theball bearings 12 are permitted to fall within the narrowcircumferential groove 21 formed in the portions of the release pin, as shown in the right side of the figure of FIG. 3. In this unlocked configuration, the axle shaft is released from the bearing spacer and can be withdrawn from the bearing spacer, wheel assembly and skate frame. When both release pins on a particular wheel have been “released” or arranged into their unlocked configuration, then the associated axle shafts can be withdrawn from the bearing spacer and the wheel assembly easily removed from the frame of the in-line skate. - Pulling the spring-biased
release pin 9A out from its corresponding axle shaft can be carried out using a small tool, (e.g., a paper clip or an accessory device). The tool is slid through the hole 22 formed in the end of the release pin and allows the release pin to be pulled out slightly (against the force of the return spring) so that theballs 12 retaining the axle shaft within the bearing spacer can be allowed to fall out of their corresponding holes, as described hereinabove. - In the locked configuration, curved
spring steel washer 27 applies pressure to the outside of the skate frame in order to take up any slack and provide a tight fit. The fit can be adjusted further, if desired, by using washers of different thicknesses as shims installed over the axle shaft to be positioned between the spring steel washer and the skate frame. - A second illustrative embodiment of the quick-release axle system of the present invention is shown in FIGS. 8 and 8A. While this embodiment is quite similar to the embodiment of FIG. 3, there are a number of minor differences. In particular, the bearing
spacer 30 in FIG. 8 does not have an outer bore surface that slides into the inner bore of the inner race of the bearing, as in the first embodiment shown in FIG. 3. Instead, the bearingspacer 30 is shaped like a bushing whose inner and outer diameters are exactly the same as the inner and outer diameters of the inner race of the bearing itself. Therefore, the axle shaft diameter is larger in order to correspond with the diameter of the inner bore of the inner bearing race. -
Circumferential grooves 31A and 31B are cut into the inner surface of the inner bore of the bearing spacer 30 (about 0.030 inches deep) in lieu of the equally spaced holes in the bearing spacer of the first illustrative embodiment described above. When the axle shaft is pushed into place, the locking balls lock into place within the recess provided by the groove. The groove is positioned so as to create a tight fit between the flange and the skate frame upon installation. Other minor differences will be described below. - As in the case of the first illustrative embodiment, each bearing is installed into the wheel from opposite sides and separated by bearing
spacer 30. As theaxle shafts 6A and 6B are inserted into the bore of the bearing spacer, the lockingballs 12 held within the shaft by crimpings automatically fall into place into correspondinggrooves 31A and 31B. Releasing the release pin allows pressure from thereturn spring 16, which is compressed within the bore ofshaft 6A (6B) between interior flange 34 andcircumferential flange 33, to cause the release pin to slide inward toward the center of the spacer, so that the outer surface ofcircumferential flange 33 is disposed directly beneath and contacts the surface of the axle-lockingballs 12, forcing them to remain locked within thecircumferential groove 31A (31B) formed in the inner bore of the bearing spacer. In this configuration, the end of the release pin will remain recessed within the bore of the axle shaft, while the axle shaft and bearing spacer are securely locked together and the release pin is prevented from being inadvertently pulled out of its locked configuration. In this locked configuration, shown in the right side of the figure of FIG. 8, therelease pin 9A (9B) renders it impossible for theball bearings 12 to move downward, or out of theircorresponding grooves 31A (31B), and thus provides an extremely strong and efficient locking mechanism. - When the
release pin 9A (9B) is pulled outwardly by an amount limited by the length ofslot 23, (i.e., against the outwardly directed biasing forces produced by return spring), the lockingballs 12 are permitted to fall within the narrowcircumferential recess 35 formed between the outer surface of the end portions of the release pin, as shown in the left side of the figure of FIG. 8. In this unlocked configuration, the axle shaft is released from the bearing spacer and can be withdrawn from the bearingspacer 30, wheel assembly and skate frame. When both release pins on a particular wheel have been “released” or arranged into their unlocked configuration, then the associated axle shafts can be withdrawn from the bearingspacer 30 and the wheel assembly can be easily removed from the frame of the in-line skate. - Pulling the spring-biased
release pin 9A (9B) out from its corresponding axle shaft can be carried out using a small tool, (e.g., a paper clip or accessory device) that slides through the hole 22 formed in the end of the release pin and allows the release pin to be pulled out slightly (against the a force of the return spring) so that the lockingballs 12 retaining the axle shaft within the bearingspacer 30 can be allowed to fall out of their corresponding holes, as described hereinabove. - In FIG. 9, a third alternative embodiment of the present invention is shown. In this embodiment, the bearing spacer is not used as part of the axle-shaft locking mechanism. Instead, the axle system comprises: a
main axle shaft 40 insertable through the firstskate frame wall 2A, thefirst bearing 7A, the bearingspacer 41, thesecond bearing 7B, and the second skate frame wall; and asecondary axle shaft 42 for insertion within acentral bore 43 formed within themain axle shaft 40. As shown in FIG. 8, the main shaft axle hashead portion 44 formed on one end of its cylindrical body portion, andcentral bore 43 formed through the end of its body portion oppositehead portion 44. The length of thebore 43 extends about half way across the length of the axle shaft. Arelease pin 45, similar in design as therelease pin 9A (9B) shown in FIG. 8, is provided for insertion through a central bore 46 formed in thesecondary axle shaft 42, to engage withball bearing 12. As shown in FIG. 9, acircumferential groove 47 is cut into the inner surface of the inner bore of themain axle shaft 42. The locking portion works exactly the same as in the second embodiment, but the dimensions of the components are smaller. The main andsecondary axle shafts - In the illustrative embodiment, the
main axle shaft 40 has an outer diameter of about 0.3125 inches and is adapted for insertion throughapertures frame rail Rounded cap portion 44 is about 0.1875 inches at its thickest point. A recess 48, 0.0625 inches deep and 0.089 inches long is machined into one half of the cap in order to allow for an access point for therelease pin 45. - A
hole 49 having a 0.0625 inch diameter is drilled through the release pin shaft at about 0.093 inches from one end thereof, as shown in FIG. 9. The function ofhole 49 is to allow a tool or pin to be used to pull therelease pin 45 out of the axle shaft during axle release operations. When thesecondary axle shaft 42 is retained within the main axle shaft, during the axle locked configuration, the hole in the release pin is recessed within the end of the axle shaft and thus cannot be inadvertently pulled out during roller skating activity. - As shown in FIG. 9, a
small return spring 16 is installed over the central body portion of the release pin shaft and restrained by an enlarged annular-shapedflange 50, which is designed to engageballs 12 in the system's locked configuration. The function of the return spring is to hold the release pin in the locked position within the axle shaft during the vibration encountered while skating. Within this arrangement, the return spring is then trapped between the annular 50 and theinner flange 51 of the machined groove bore 52 formed in the axle shaft, while the retainingpin 24 is inserted into theslot 53 formed in the end of the release pin, as shown in FIG. 9. As such, therelease pin 45 is retained within the bore of the secondary axle shaft and is permitted to slide therewithin a distance equal to the length ofslot 53 formed in the end of the release pin. As shown in FIG. 9, a curvedspring steel washer 27 is positioned over thesecondary axle shaft 42 which tightens the axle system in the locked configuration. Also, a nylon plastic cover can be snapped over the cap end of the second axle shaft. - Each
bearing release pin 45 is slid into the bore of the second axle shaft, the two steel locking balls are automatically forced into place into thecircumferential groove 54 formed within the control portion of the bore 52 within the main axle shaft. In this configuration, the end of the release pin will remain recessed within the bore of the primary axle shaft, while the primary axle shaft and second axle shaft are securely locked together and the release pin prevented from being inadvertently pulled out of its locked configuration. In this locked configuration, shown in FIG. 9, therelease pin 45 renders it impossible for the axle-lockingballs 12 to move downward, or out of their corresponding detents, and thus provides an extremely strong and efficient locking mechanism. - When the
release pin 45 is pulled outwardly by an amount limited by the length ofslot 53, (i.e. against the outwardly directed biasing forces produced by the return spring), theball bearings 12 are permitted to fall within the narrowcircumferential groove 54. In this unlocked configuration, thesecondary axle shaft 42 is released from theprimary axle shaft 40 and can be withdrawn therefrom, as well as the wheel assembly and the skate frame. When the release pin on a particular wheel has been “released” or arranged into its unlocked configuration, then the secondary axle shaft can be withdrawn from the primary axle shaft and the wheel assembly easily removed from the frame of the in-line skate. - Pulling the spring-biased
release pin 45 out from the main axle shaft can be carried out using a small tool, (e.g. a paper clip or accessory device) that slides through the hole 48 formed in the end of the release pin. - FIGS. 10 and 10A, a fourth illustrative embodiment of the quick release axle system is shown. In this embodiment, wherein the release pins are released by a “pushing” operation rather than by a pulling operation. As in the case of the second illustrative embodiment, each bearing7A, 7B is installed into the
wheel 10 from opposite sides and separated by bearingspacer 60. As the axle shafts 61A (61B) are inserted into the bore of the bearing spacer, the lockingballs 12 held within the shaft by crimpings, automatically fall into place within corresponding grooves 62A (62B). Then as therelease pin 68A (68B) is slid within the inner bore of the axle shaft and the retainingpin 24 inserted within theslot 64 formed therein, thereturn spring 16, retained between circumferential flange 65 and c-clip 66 (in circumferential groove 70) will automatically force the release pin outwards (away from the center of the bearing spacer) so thatcircumferential flange 67 is disposed directly beneath and contacts the surface of the axle-lockingballs 12, forcing them to remain locked within the circumferential groove 62(A), 62(B) formed in the bearing spacer. In this configuration, the end of the release pin will remain recessed within the bore of the axle shaft, while the axle shaft and bearing spacer are securely locked together and the release pin prevented from being inadvertently pulled out of its locked configuration. In this locked configuration, shown in the right side of the figure of FIG. 10, therelease pin 68A 68(B) renders it impossible for the axle-lockingballs 12 to move downward, or out of their corresponding grooves 62A 62(B), and thus provides an extremely strong and efficient locking mechanism. - When the
release pin 9A (9B) is pushed inwardly by an amount limited by the length ofslot 64, (i.e., against the outwardly directed biasing forces produced by return spring), the axle-lockingballs 12 are permitted to fall within the narrowcircumferential recess 69 formed between the outer surface and end portions of the release pin, as shown in the right side of the figure of FIG. 10. In this unlocked configuration, the axle shaft is released from the bearing spacer and can be withdrawn from the bearingspacer 30, wheel assembly and skate frame. When both release pins on a particular wheel have been “released” or arranged into their unlocked configuration, then the associated axle shafts can be withdrawn from the bearingspacer 30 and the wheel assembly easily removed from the frame of he in-line skate. - Pushing the spring-biased
release pin 68A (68B) into its corresponding axle shaft can be carried out using a small tool (e.g., a screw driver or accessory device) that is slid into the open end of the bore in the axle shaft, and pushed against release pin (against the force of the return spring) so that the axle-lockingballs 12 retaining the axle shaft within the bearingspacer 60 can be allowed to fall out of their corresponding holes, as described above. - FIGS. 11 and 11A, a fifth illustrative embodiment of the quick release axle system is shown. The fifth embodiment of the present invention is constructed in the same manner as the second embodiment except that only a single axle shaft8B″ is used instead of two separate axle shafts to support each wheel. In this configuration, the axle shaft 6B″ does not interlock with the bearing
spacer 6. Instead, the axle shaft 8B″ is made long enough to pass through theskate frame 2B from one side, through the frame spacer, wheel andbearing assemblies balls 12 then use the outer surface of the other side of theskate frame 2A itself to lock the axle shaft in place when therelease pin 9B″ is allowed to slide into position, beneath the locking balls, within the main axle bore 70 formed therein. - As in the case of the second illustrative embodiment, each bearing7A, 7B is installed into the
wheel 10 from opposite sides and separated by bearingspacer 6. As the axle shaft 8B″ is inserted through the bore of the bearing spacer, andbearings balls 12 held within the shaft by crimpings, automatically fall into place outside the outer surface ofskate frame 2A, creating a locking mechanism. Then as therelease pin 9B″ is slid within the inner bore of the axle shaft (or the side offrame rail 2A) and the retainingpin 24 inserted within theslot 64 formed therein, thereturn spring 16, retained between circumferential flanges 65′ and 67′ will automatically force the release pin outwards (away from the center of the bearing spacer) so thatcircumferential flange 67′ is disposed directly beneath and contacts the surface of the axle-lockingballs 12, forcing them to remain lockedoutside frame rail 2A. In this configuration, the end of the release pin will remain recessed within the bore of the axle shaft, while the axle shaft is securely locked between the frame rails 2A and 2B while therelease pin 9B″ is prevented from being inadvertently pulled out of its locked configuration. In this locked configuration, shown in the right side of the figure of FIG. 11A, therelease pin 9B″ renders it impossible for the axle-lockingballs 12 to move downward, or away from the outer surface offrame unit 2A, and thus provides an extremely strong and efficient locking mechanism. - When the
release pin 9B″ is pulled automatically outwardly by an amount limited by the length ofslot 64, (i.e., against the outwardly directed biasing forces produced by return spring), the axle-lockingballs 12 are permitted to fall within the central bore of the axle shaft. In this unlocked configuration, the axle shaft is released from the frame rails 2A and can be withdrawn from the bearingspacer 6, wheel assembly and skate frame. When the release pin on a particular wheel has been “released” or arranged into its unlocked configuration, then the associated axle shaft can be withdrawn from the bearing spacer and the wheel assembly easily removed from the frame of he in-line skate. - In the alternative embodiment of the axle system shown in FIGS. 11 and 11A, a cap can be used to engage with locking
balls 12, outside of therail frame 2A. In such an embodiment, the cap will have an inner bore with a diameter which is slightly larger than the diameter of the axle shaft 8B″. A circumferential groove is then machined at a predetermined distance from one end of the cap within the inner bore. The cap is then pressed onto the protruding portion of the axle shaft 8B″ from the opposite side of theframe 2A. The lockingballs 12 then interlock within the circumferential groove in the cap when the release pin is allowed to slide into position within the bore formed through the axle shaft 8B″. - As in the previous examples, the axles may be designed so that releasing the axle from the skate is accomplished by pulling the release pin outward slightly, or they may be designed so that the release procedure involves pushing the release pin inward slightly.
- While the present invention has been exemplified by the illustrative embodiment thereof described above, it is understood that such embodiments can be readily modified without departing from the shape and spirit of the present invention set forth by the appended claims to invention.
Claims (21)
1. An axle system for use in an in-line skate having a plurality of wheels rotatably supported by a pair of wheel bearings disposed between a pair of spaced apart frame rails, said axle system having a locked configuration and an unlocked configuration and comprising:
a pair of axle shafts for passage through said frame rails and one of said wheels for rotatable supporting said wheel between said frame rails along a rotational axis, and at least one of said pair of axle shafts having a bore formed therethrough along said rotational axis; and
a release pin for insertion into said bore and releasably locking said axles shafts relative to each other when arranged in said locked configuration to prevent said axle shafts from disengaging from said wheel during skating, and for releasing said axle shafts from said wheel when arranged in said unlocked configuration.
2. The axle system of claim 1 , wherein said release pin is spring biased within said bore to a predetermined locking position which locks said axle shafts relative to each other when arranged in said locking configuration.
3. The axle system of claim 2 , which further comprises a plurality of balls arranged within at least one said axle shaft for engagement with said release pin so as to interlock said axle shafts in said locked configuration.
4. The axle system of claim 1 , wherein at least one said axle shaft has a cap portion with a hole formed therethrough in communication with said bore, and said release pin has a notch formed in said release pin so that when a retaining pin is inserted through said hole, said retaining pin is engaged within said notch and delimits the amount that said release pin is permitted to slid within said bore.
5. The axle system of claim 4 , which further comprises a bearing spacer disposed between said wheel bearings and said axle shafts engage said bearing spacer by way of said locking balls.
6. The axle system of claim 1 , wherein each said axle shaft has a bore formed along said rotational axis and a plurality of balls arranged within said axle shaft, and one said release pin is inserted through each said bore in order to engage said locking balls and lock said axle shaft within said wheel.
7. The axle system of claim 1 , wherein said release pin is pulled out of said bore by a predetermined amount in order to unlock said axle shafts in said unlocked configuration.
8. The axle system of claim 1 , which further comprises a curved spring washer to produce equalizing forces upon said frame rails.
9. The axle system of claim 2 , wherein at least one said axle shaft has a cap portion with a hole formed therethrough in communication with said bore, and said release pin has a notch formed in said release pin so that when a retaining pin is inserted through said hole, said retaining pin is engaged within said notch and delimits the amount that said release pin is permitted to slid within said bore.
10. A quick-release type axle system for use in an in-line skate, comprising:
a bearing spacer for spacing a pair of wheel bearings within a skate wheel in said in-line skate;
a pair of axle shafts for rotatably supporting said skate wheel on said wheel bearings about a rotational axis, and each said axle shaft having a central bore and engaging with said bearing spacer along said rotational axis; and
a pair of axle release pins for insertion into said central bores of said pair of axle shafts, respectively, and causing said axle shafts to automatically lock with said bearing spacer when said release pins are pushed into said central bores of said axle shafts to a first predetermined position within said central bore, and automatically unlock from said bearing spacer when said release pins are pulled outwardly from said central bores of said axle shafts to a second predetermined position.
11. A quick-release type axle system for use in an in-line skate, comprising:
a bearing spacer for spacing a pair of wheel bearings within a skate wheel in said in-line skate;
a pair of axle shafts for rotatably supporting said skate wheel on said wheel bearings about a rotational axis, and each said axle shaft having a central bore and engaging with said bearing spacer along said rotational axis; and
a pair of axle release pins for insertion into said central bores of said pair of axle shafts, respectively, and causing said axle shafts to automatically lock with said bearing spacer when said release pins are pushed into said central bores of said axle shafts to a first predetermined position within said central bore, and automatically unlock from said bearing spacer when said release pins are pushed inwardly into said central bores of said axle shafts to a second predetermined position.
12. A quick-release type axle system for use in an in-line skate, comprising:
a pair of axle shafts for rotatably supporting a skate wheel on a pair of wheel bearings about a rotational axis, and each said axle shaft having a central bore; and
a pair of axle release pins for insertion into said central bores of said pair of axle shafts, respectively, and causing said axle shafts to automatically lock relative to each other when said release pins are pushed into said central bores of said axle shafts to a first predetermined position within said central bore, and automatically unlock when said release pins are pulled outwardly from said central bores of said axle shafts to a second predetermined position.
13. A quick-release type axle system for use in an in-line skate, comprising:
a pair of axle shafts for rotatably supporting a skate wheel on a pair of wheel bearings about a rotational axis, and each said axle shaft having a central bore; and
a pair of axle release pins for insertion into said central bores of said pair of axle shafts, respectively, and causing said axle shafts to automatically lock relative to each other when said release pins are pushed into said central bores of said axle shafts to a first predetermined position within said central bore, and automatically unlock when said release pins are pushed inwardly into said central bores of said axle shafts to a second predetermined position.
14. A quick-release type axle system for use in an in-line skate, comprising:
a primary axle shaft for rotatably supporting a skate wheel on a pair of wheel bearings about a rotational axis, and said primary axle shaft having a first central bore formed through at least a portion thereof;
a secondary axle shaft for insertion into said primary central bore along said rotational axis, and having a second central bore extending along said rotational axis; and
an axle release pin for insertion into said second central bore of said secondary axle shaft, and causing said primary and secondary axle shafts to automatically lock with each other when said release pin is pushed into said second central bore of said secondary axle shaft to a first predetermined position within said second central bore, and automatically unlock said primary and secondary axle shafts from each other when said release pin is pulled outwardly from said second central bore of said secondary axle shaft to a second predetermined position.
15. A quick-release type axle system for use in an in-line skate, comprising:
a primary axle shaft for rotatably supporting a skate wheel on a pair of wheel bearings about a rotational axis, and said primary axle shaft having a first central bore formed through at least a portion thereof;
a secondary axle shaft for insertion into said primary central bore along said rotational axis, and having a second central bore extending along said rotational axis; and
an axle release pin for insertion into said second central bore of said secondary axle shaft, and causing said primary and secondary axle shafts to automatically lock with each other when said release pin is pushed into said second central bore of said secondary axle shaft to a first predetermined position within said second central bore, and automatically unlock said primary and secondary axle shafts from each other when said release pin is pushed inwardly into said second central bore of said secondary axle shaft to a second predetermined position.
16. An in-line skate having a quick-release type axle system, comprising:
a bearing spacer for spacing a pair of wheel bearings within a skate wheel in said in-line skate;
a pair of axle shafts for rotatably supporting said skate wheel on said wheel bearings about a rotational axis, and each said axle shaft having a central bore and engaging with said bearing spacer along said rotational axis; and
a pair of axle release pins for insertion into said central bores of said pair of axle shafts, respectively, and causing said axle shafts to automatically lock with said bearing spacer when said release pins are pushed into said central bores of said axle shafts to a first predetermined position within said central bore, and automatically unlock from said bearing spacer when said release pins are pulled outwardly from said central bores of said axle shafts to a second predetermined position.
17. An in-line skate having a quick-release type axle system, comprising:
a bearing spacer for spacing a pair of wheel bearings within a skate wheel in said in-line skate;
a pair of axle shafts for rotatably supporting said skate wheel on said wheel bearings about a rotational axis, and each said axle shaft having a central bore and engaging with said bearing spacer along said rotational axis; and
a pair of axle release pins for insertion into said central bores of said pair of axle shafts, respectively, and causing said axle shafts to automatically lock with said bearing spacer when said release pins are pushed into said central bores of said axle shafts to a first predetermined position within said central bore, and automatically unlock from said bearing spacer when said release pins are pushed inwardly into said central bores of said axle shafts to a second predetermined position.
18. An in-line skate having a quick-release type axle system, comprising:
a pair of axle shafts for rotatably supporting a skate wheel on a pair of wheel bearings about a rotational axis, and each said axle shaft having a central bore; and
a pair of axle release pins for insertion into said central bores of said pair of axle shafts, respectively, and causing said axle shafts to automatically lock relative to each other when said release pins are pushed into said central bores of said axle shafts to a first predetermined position within said central bore, and automatically unlock when said release pins are pulled outwardly from said central bores of said axle shafts to a second predetermined position.
19. An in-line skate having a quick-release type axle system, comprising:
a pair of axle shafts for rotatably supporting a skate wheel on a pair of wheel bearings about a rotational axis, and each said axle shaft having a central bore; and
a pair of axle release pins for insertion into said central bores of said pair of axle shafts, respectively, and causing said axle shafts to automatically lock relative to each other when said release pins are pushed into said central bores of said axle shafts to a first predetermined position within said central bore, and automatically unlock when said release pins are pushed inwardly into said central bores of said axle shafts to a second predetermined position.
20. An in-line skate having a quick-release type axle system comprising:
a primary axle shaft for rotatably supporting a skate wheel on a pair of wheel bearings about a rotational axis, and said primary axle shaft having a first central bore formed through at least a portion thereof;
a secondary axle shaft for insertion into said primary central bore along said rotational axis, and having a second central bore extending along said rotational axis; and
an axle release pin for insertion into said second central bore of said secondary axle shaft, and causing said primary and secondary axle shafts to automatically lock with each other when said release pin is pushed into said second central bore of said secondary axle shaft to a first predetermined position within said second central bore, and. automatically unlock said primary and secondary axle shafts from each other when said release pin is pulled outwardly from said second central bore of said secondary axle shaft to a second predetermined position.
21. An in-line skate having a quick-release type axle system, comprising:
a primary axle shaft for rotatably supporting a skate wheel on a pair of wheel bearings about a rotational axis, and said primary axle shaft having a first central bore formed through at least a portion thereof;
a secondary axle shaft for insertion into said primary central bore along said rotational axis, and having a second central bore extending along said rotational axis; and
an axle release pin for insertion into said second central bore of said secondary axle shaft, and causing said primary and secondary axle shafts to automatically lock with each other when said release pin is pushed into said second central bore of said secondary axle shaft to a first predetermined position within said second central bore, and automatically unlock said primary and secondary axle shafts from each other when said release pin is pushed inwardly into said second central bore of said secondary axle shaft to a second predetermined position.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US10/408,843 US20040032099A1 (en) | 1997-08-26 | 2003-04-04 | In-line roller skates having quick-release axle system |
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US91880897A | 1997-08-26 | 1997-08-26 | |
US09/935,295 US6607198B2 (en) | 1997-08-26 | 2001-08-22 | In-line roller skates having quick-release axle system with safety retaining pin mechanism |
US10/408,843 US20040032099A1 (en) | 1997-08-26 | 2003-04-04 | In-line roller skates having quick-release axle system |
Related Parent Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US09/935,295 Continuation US6607198B2 (en) | 1997-08-26 | 2001-08-22 | In-line roller skates having quick-release axle system with safety retaining pin mechanism |
Publications (1)
Publication Number | Publication Date |
---|---|
US20040032099A1 true US20040032099A1 (en) | 2004-02-19 |
Family
ID=25440999
Family Applications (2)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US09/935,295 Expired - Fee Related US6607198B2 (en) | 1997-08-26 | 2001-08-22 | In-line roller skates having quick-release axle system with safety retaining pin mechanism |
US10/408,843 Abandoned US20040032099A1 (en) | 1997-08-26 | 2003-04-04 | In-line roller skates having quick-release axle system |
Family Applications Before (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US09/935,295 Expired - Fee Related US6607198B2 (en) | 1997-08-26 | 2001-08-22 | In-line roller skates having quick-release axle system with safety retaining pin mechanism |
Country Status (1)
Country | Link |
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US (2) | US6607198B2 (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20030187697A1 (en) * | 2001-12-31 | 2003-10-02 | Bonissone Piero Patrone | Process for case-based insurance underwriting suitable for use by an automated system |
US9788591B2 (en) | 2007-04-16 | 2017-10-17 | Riddell, Inc. | Quick release connector |
Families Citing this family (10)
Publication number | Priority date | Publication date | Assignee | Title |
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EP1314463A1 (en) * | 2001-11-26 | 2003-05-28 | Andreas Greber | Inline rollerskate with quick release wheel fastening system |
US6805363B2 (en) * | 2002-08-20 | 2004-10-19 | Bbc International, Ltd. | Convertible shoe |
US6902160B1 (en) * | 2003-01-22 | 2005-06-07 | Zaytran, Inc. | Locating pin with integrated clamp |
US6931980B1 (en) * | 2003-03-21 | 2005-08-23 | Zaytran, Inc. | Pneumatic device with cushioning mechanism |
US7125024B1 (en) * | 2003-04-25 | 2006-10-24 | Kelly Keith B | Quick-release axle assembly for in-line skate |
US20090140570A1 (en) * | 2004-12-20 | 2009-06-04 | Jeff Houkal | Removable wheel system |
US7419168B2 (en) * | 2006-09-28 | 2008-09-02 | Felty Paul G | Skateboard wheel and axle assembly |
US20140035352A1 (en) * | 2012-08-02 | 2014-02-06 | Jonathan Michael Waller | Quick release skateboard wheel |
US9320962B2 (en) * | 2012-08-21 | 2016-04-26 | Brian J. Krell | Apparatus and methods for quickly releasing a hub-and-wheel assembly |
KR101668920B1 (en) * | 2014-11-12 | 2016-10-25 | 형성산업(주) | Retractable golf cart |
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US20030187697A1 (en) * | 2001-12-31 | 2003-10-02 | Bonissone Piero Patrone | Process for case-based insurance underwriting suitable for use by an automated system |
US9788591B2 (en) | 2007-04-16 | 2017-10-17 | Riddell, Inc. | Quick release connector |
US10856600B2 (en) | 2007-04-16 | 2020-12-08 | Riddell, Inc. | Quick release connector |
Also Published As
Publication number | Publication date |
---|---|
US6607198B2 (en) | 2003-08-19 |
US20020070512A1 (en) | 2002-06-13 |
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Legal Events
Date | Code | Title | Description |
---|---|---|---|
STCB | Information on status: application discontinuation |
Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION |