A skate blade sharpening system is a specialized type of grinder specifically configured to sharpen ice skates. One key aspect in sharpening ice skates, such as hockey skates, is the accuracy with which a grinding wheel is aligned with a skate blade. Specifically, a mid-plane of the grinding wheel is ideally aligned with the mid-plane of the skate blade. The accuracy of the alignment directly influences the degree to which the outside edges of a sharpened skate blade lie in the same horizontal plane, which in turn affects the predictability and consistent feel of the skate blade to a skater. If the edges are of unequal height, the low edge will feel duller and less certain to the skater, while the high edge will feel sharper. For the side-to-side grip in the ice to feel equal for the skater, the height of the inside and outside edges should be as equal as possible. This need for equal edge height translates to a need for accurate alignment between the grinding wheel and the skate blade when the blade is being sharpened.
The present disclosure is concerned primarily with aspects of alignment, including the manner of gauging alignment.
Known skate sharpening systems have used trial-and-error alignment techniques. A skate blade is sharpened, then a gauge is used to determine how even the resulting edges are. Some known gauges are placed on the skate blade and have pivoting members that rest on the two blade edges. Unevenness is measured as non-perpendicularity of the pivoting member with respect to the longitudinal plane of the skate blade. Measured unevenness is translated to a corresponding value of wheel-blade misalignment. A position adjustment is then made by this amount, and the blade is sharpened again. Typically the blade unevenness is then checked again, and if necessary the process of adjusting, sharpening, and checking is again repeated. This cyclical process is time consuming and not intuitive for an unskilled user. An unskilled user may not know how much material to remove given an amount of adjustment made, and also may not know how much adjustment to make given a certain amount of edge unevenness. Additionally, this cyclical process may unnecessarily accelerate the consumption of the skate blade, and create issues of inconsistency between the left and right skates in a pair.
A variety of mechanisms for adjusting the relative positions of the grinding wheel and skate blade are known. There are three general limitations with known mechanisms. One is problematic mechanical coupling between the position adjustment mechanism and a pivoting mechanism that permits a grinding wheel mounted on a pivoting arm to follow the edge of a skate blade in operation. In some known systems, the problematic coupling interferes with smooth pivoting and thus creates inconsistent grinding forces, with corresponding degraded sharpening results. Known systems also employ locking mechanisms that are used to secure the alignment of the grinding wheel and the skate blade. These locking mechanisms are known to shift the position of a member (e.g., grinding wheel) after it has been adjusted, introducing error in the alignment. Another general issue with known adjustment mechanisms is the placement of user controls used for adjustment. It is known that these mechanisms are often difficult to reach and adjust for the user.
Disclosed herein are apparatus and methods for addressing the above and other shortcomings of known skate sharpening systems, specifically shortcomings pertaining to alignment between a grinding wheel and a skate blade to be sharpened. In particular, a disclosed approach provides for accurately gauging alignment without requiring that a sharpening be performed first. A disclosed position adjustment mechanism provides for smoother adjustment movement and for decoupling of adjustment from the pivoting motion occurring during sharpening, improving positioning accuracy.
In particular, a skate blade sharpening system is disclosed that includes a clamp configured to retain a skate blade in a sharpening position, a centerline of the sharpening position having a first predetermined location relative to a first visual reference feature of the skate sharpening system. The sharpening system further includes a motor-driven rotating shaft, the shaft having a wheel-mounting location at which a grinding wheel is mounted to rotate with the shaft and contact the skate blade in the sharpening position during a sharpening operation. The shaft also accepts an alignment wheel mounted at the wheel-mounting location during an alignment operation, the alignment wheel having a second visual reference feature that, when the alignment wheel occupies the wheel-mounting location, has a second predetermined location relative to a centerline of the grinding wheel when occupying the wheel-mounting location.
The sharpening system further includes an adjustment mechanism for moving the shaft transversely during the alignment operation to vary a relative position between the wheel-mounting location and the sharpening position across a range, the range including an aligned position of the wheel-mounting location in which the centerline of the grinding wheel when occupying the wheel-mounting location is aligned with the centerline of the sharpening position, the aligned position being indicated by alignment of the first visual reference feature with the second visual reference feature during the alignment operation.
Through the use of visual reference features that can be brought into mutual alignment using the adjustment mechanism, the grinding wheel can be aligned with the sharpening position of the skate blade as an initial step prior to performing any sharpening. This avoids the trial-and-error approach of known skate sharpening systems. Additionally, by using an alignment wheel separate from the grinding wheel, the grinding wheel need not incorporate alignment features and thus may be manufactured relatively simply and inexpensively.
In one embodiment, the first visual reference feature is part of an alignment tool having a blade portion that is placed in the sharpening position, temporarily bringing the first visual reference feature into proximity with the second visual reference feature for the alignment process. Then the alignment tool is removed, and the skate blade is placed in the sharpening position for sharpening. Because the blade portion of the alignment tool occupies the same sharpening position as the skate blade, the skate blade has a known location relative to the position of the first visual reference feature of the alignment tool during alignment.
The second visual reference feature may include an alignment notch or protrusion on the alignment wheel, and the first visual reference feature may include an indicator feature placed along a path of the alignment wheel for the alignment operation, such as an alignment tool.
In another respect, a method is disclosed of aligning a grinding wheel to a sharpening position in a skate blade sharpening system, wherein the sharpening position is occupied by a skate blade during sharpening, the sharpening system including a first visual reference feature having a first predetermined location relative to a centerline of the sharpening position. The method includes mounting an alignment wheel at a wheel-mounting location on a motor-driven shaft of the sharpening system, the shaft being movable transversely by an adjustment mechanism to vary a relative position between the shaft and the sharpening position. The alignment wheel has a second visual reference feature having a second predetermined location relative to a centerline of the grinding wheel when subsequently occupying the wheel-mounting location in a sharpening operation. The method further includes operating the adjustment mechanism to bring the second visual reference feature into alignment with the first visual reference feature, thereby bringing the wheel-mounting location of the shaft to an aligned position in which the centerline of the grinding wheel when occupying the wheel-mounting location is aligned with the centerline of the skate blade position.
The foregoing and other objects, features and advantages will be apparent from the following description of particular embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views.
It will be appreciated that the disclosed methods and apparatus may be used with other blade profiles, including flat and V-shaped, for example.
Returning to
It is noted that controls and locations could be reversed in alternative embodiments, so that the communications position would be a far-left position rather than a far-right position.
The above operation may also be used with bare removable skate blades of the type known in the art. In this case a blade holder or other mechanical aid of some type may be used to enable a user to position the bare blade in the slot 24 for clamping and to engage the bumpers 29 of the scoops 28 to permit operation. Alternatively, a bare blade could also be positioned without a blade holder. As described more below, a blade holder may engage limit switches on the slot covers 28 to enable sharpening operation, and enables a user to insert a loose skate blade in clamping jaws.
As shown, the chassis 14 has an S-like cross section defining the frontward platform 22 and a rearward shelf portion (“shelf”) 56 separated by a sloping wall 58. The underside of the shelf 56 includes two rails 60 on which a carriage (not shown) moves, as well as a downward-projecting flange 62. As described more below, a toothed “gear rack” that forms part of a rack-and-pinion mechanism for moving the carriage is attached to the flange 62. On the platform 22 at each end of the slot 24 are rounded projections 64 on which the scoops 28 are slidably mounted. The projections 64, also referred to as “arches” 64 below, have retention grooves 66 that engage with corresponding features in the scoops 28 to retain the scoops 28 on the projections 64 while permitting them to slide left and right.
One important feature of the presently disclosed skate sharpener 10 is use of a compact (small-diameter) grinding wheel 36. Specifically, its diameter is less than the diameter of the grinding wheel motor 80 by which it is rotated. Use of a compact grinding wheel 36 can provide certain advantages including greater precision in operation and lower cost.
Also shown in schematic fashion in
In operation, the grinding wheel 36 is rotated by the grinding wheel motor 80 via the spindle 82, and the carriage assembly 70 is moved back and forth along the rails 60 by action of a rack-and-pinion mechanism that includes a motor-drive pinion gear 87 engaging a toothed rack on the underside of the chassis 14 (described more below). The pinion gear 87 is driven by a carriage motor mounted within the carriage 72, not visible in
As shown, the jaws 90 each include angled slots 104, and in the slots 104 are arranged rectangular guide blocks 106 that retain the jaws 90 at the underside of the platform 22 with spacing to permit the jaws 90 to slide in the long direction of the slots 104. The front jaw 90-F is retained by one guide block 107 in a center slot 104, while the rear jaw 90-R is retained by respective guide blocks 106 in outer two slots 104. This arrangement permits the front jaw 90-F to rotate very slightly about a Z-direction axis extending through the single guide block 106, while the rear jaw 90-F is rotationally fixed. Additional details are provided below.
When the clamp paddle 26 is in the position shown in both
When a skate blade is to be clamped for sharpening, a user rotates the clamp paddle 26 to open the jaws 90. Referring to
The jaw guard 100 protects against the possibility of contact between the grinding wheel 36 and the jaws 90. If the sharpener 10 were to somehow be operated without a skate blade present, then without the jaw guard 100 the wheel 36 would move across the jaws 90 at its upper vertical limit position, potentially damaging the grinding wheel 36 and/or the jaws 90. This is prevented by the jaw guard 100, which would be encountered by the spindle 82 (
Also shown in
The grinding ring 200 has an abrasive outer surface for removing material from a steel skate blade during operation. In one embodiment the abrasive surface may include a diamond or cubic boron nitride (CBN) coating, deposited by electroplating for example. The grinding ring 200 is preferably of steel or similar rigid, strong metal, and it may be fabricated from steel tubing or bar stock. Although in general the grinding ring 200 may be of any size, it is preferably less than about 100 mm in diameter and even more preferably less than about 50 mm in diameter. Its thickness (radially) is substantially less than its radius, e.g., by a ratio of 1:4 or smaller. The ring shape, as opposed to a disk shape as used in more conventional grinding wheel designs, produces a much lighter grinding wheel 36 which can reduce the effects of wheel imbalance, eccentricity, and non-planarity. Reducing such effects can contribute to a smoother finish on a skate blade and a higher performance skate sharpening.
As shown, both the arbor 212 and hub 202 have shaped outer edges which mate with respective edges of the grinding ring 200. The mating between the arbor 212 and ring 200 is a sliding contact mating that permits mounting and dismounting of the grinding wheel 36 while also providing for heat transfer between the grinding ring 200 and the arbor 212. This relatively tight fit is also responsible for the centering of the grinding wheel. The heat transfer helps dissipate frictional heat generated in the grinding ring 200 as it rotates against a skate blade in operation. Specifically this mating is between a portion of an inner annular surface of the grinding ring 200 and an annular outer rim of the arbor 212. Both the hub 202 and arbor 212 have notches or shoulders on which respective portions of the grinding ring 200 rest. Thus the shoulder portion of the hub 202 extends only partway into the grinding ring 200, so that a remaining part of the grinding ring 200 extends beyond the arbor-facing end of the hub 202 and mates with the shoulder portion of the arbor 212.
The arbor 212 may include vanes or other features to increase its surface area and/or enhance air flow for a desired cooling effect, further promoting heat dissipation and helping to maintain a desired operating temperature of the grinding ring 200 in operation.
One important feature of the grinding ring 200 is its relatively small size, as compared to conventional grinding wheels which may be several inches in diameter for example. Both the small size of the ring (outer diameter) as well as its ring geometry (in contrast to disk geometry of conventional grinding wheels) contribute to advantages as well as challenges. Advantages include low cost and ease of manufacture, so that it can be easily and inexpensively replaced to maintain high-quality sharpening operation. The size and geometry also reduce any contribution of the grinding ring 200 to imbalance and related mechanical imperfections of operation. Balance and related operational characteristics are more heavily influenced by the arbor 212, which is preferably precision-formed and precision-mounted. One challenge of the geometry and size of the grinding ring 200 is heat removal, and this is addressed in part by the heat-conducting mating with the arbor 212 and heat-dissipating features of the arbor 212.
The identification tag 204 has a unique identifier such as a manufacturer's serial number, and when packaged with a grinding wheel 36 into an assembly serves to uniquely identify that assembly including the constituent grinding wheel 36. The identification tag 204 also includes memory capable of persistently storing data items, used for any of a variety of functions such as described further below. The identification tag preferably employs a security mechanism to protect itself against tampering and improper use, including improper manipulation of the contents of the memory. Memory protected in such a manner may be referred to as “secure memory”. The serial number should be a read-only value, while the memory is preferably both readable and writeable. As described below, a separate transceiver in the system 10 is capable of exchanging communication signals with the tag 204 for reading and writing data. In one embodiment, so-called “RFID” or radio frequency identification techniques may be employed. Using RFID, the identification tag 204 is read from and written to using radio-frequency electromagnetic waves by an RFID transceiver contained in the sharpening system 10 (described more below). Other types of implementations are possible, including optically interrogated tags and contact-based tags such as an iButton® device.
For security, the identification tag 204 may use an access code that is read by the control unit 32 and validated. The access code can be generated by a cryptographic hash function or other encryption algorithm that takes as input the serial number of the identification tag 204 and a confidential hash key. Using the serial number ensures that the access code created is uniquely paired with a specific identification tag 204. This uniqueness can help prevent misuse that is attempted by copying an access code from one identification tag 204 to another. When the serial number of the other identification tag 204 is encrypted, the result will not match the copied access code, and appropriate action can be taken such as preventing use of the grinding wheel 36 that contains the apparently fraudulent identification tag 204.
As mentioned above, the wheel 36 includes an identification tag 204 on which various data may be stored for a variety of purposes. In the illustrated embodiment this tag employs a wireless communication technique such as Radio Frequency Identification (RFID) communications. The sensor module 222 includes an RFID antenna (not shown) which becomes registered or aligned with the identification tag 204 when the grinding wheel 36 is in the illustrated home position, so that the tag 204 may be read from and written to using RFID communications. Generally the RFID antenna has one or more loops of conductive material such as wire or metal etch, with the loops having a circular or other shape (e.g., rectangular). The RFID communications may operate on any of a number of frequencies. Frequencies in common use include 133 kHz (Low Frequency or LF), 13.56 MHz (High Frequency or HF), and 900 MHz (Ultra High Frequency or UHF).
In the illustrated embodiment the identification tag 204 is within the circumference of the circular RFID antenna of the sensor module 222, e.g., concentric with the antenna, during the reading and writing of data from/to the tag 204 as part of operation. By this arrangement the identification tag 204 can be read from and written to even when the grinding wheel 36 is rotating at full speed, which may be between 5000 and 25000 RPM. Reading and writing at full rotational speed has a distinct advantage of allowing the sharpener 10 to sharpen more quickly, because it is not necessary to slow/stop wheel rotation and then bring rotation back up to speed for each read/write operation. As described more below, in one embodiment reading and writing occurs once during each 2-pass cycle, so the time savings is proportional to the number of cycles in a sharpening operation. Additionally, reading and writing at full rotational speed can discourage any tampering with the grinding wheel 36, because it is always moving during the sharpening process. In some embodiments it may be advantageous to maintain rotation but at a reduced rotational speed to improve the read/write communications with the tag 204.
As the adjustment member 244 is turned, it presents different faces of the scalloped lower edge at a rest position of the limit peg 248. When the grinding wheel 36 is clear of the skate blade and the motor arm 78 rotates upward under the action of the spring 84, the upward travel is limited by the limit peg 248 encountering a face of the lower edge of the adjustment member 244. The different faces of the adjustment member 244 are at different radii from the center of rotation of the adjustment member 244, thereby establishing different vertical locations for this rest position of the limit peg 248.
In operation, a user rotates the adjustment member 244 to set a maximum vertical position of the grinding wheel 36. The purpose of this adjustment is to set a vertical travel limit of the grinding wheel 36 when it comes off the edge of the skate blade. This feature helps tailor operation depending on the type of skate being sharpened. Regular ice hockey skates have rounded upturns at each end of the skate blade (e.g. toe or heel), and it is desired that the grinding wheel 36 move upward to follow the upturns. This can be accomplished by having a high maximum vertical position. The blades on so-called “goalie skates” are flatter and it is typically desired that the grinding wheel 36 not move as far upward as it leaves the end of the blade, but rather come off relatively straight. This can be accomplished by adjusting the height limit using the adjustment member 244 to set a lower maximum vertical position.
In
One feature visible in
Another pertinent feature relates to a Y-adjustment mechanism permitting fine adjustment of the position of the grinding wheel 36 to align it with a retained skate blade in the X-Z plane (which is perpendicular to the page of
Use of Identification Tag 204
The grinding wheel 36 utilizes the identification tag 204 to carry important information and provide it to the control unit 32 of the sharpener 10. The information carried by the tag 204 can be used to improve sharpening operation and reduce costs associated with the skate sharpener 10.
Accurate and repeatable skate sharpening is obtained when the grinding wheel 36 is in good condition (e.g. running true, not excessively worn, not damaged). One of the limitations of existing sharpeners is that there is no indicator for the user that alerts them when the grinding wheel is not in good condition. Generally the user must make a judgment call on when to retire a grinding wheel. This may occur, for example, in response to a bad skating experience with skates that were sharpened with a grinding wheel that is no longer in good condition.
The disclosed sharpener 10 can use the data-carrying ability of the grinding wheel 36 to track usage, and employ the usage information in some way to promote delivery of consistent high quality sharpening. Generally this will involve comparing actual usage to a usage limit that has been predetermined as a dividing point between high quality sharpening and unacceptably low quality sharpening. When the usage limit is reached, some action is taken. For example, the control unit 32 may provide an indication to a user via the user interface display panel 34. It may also prevent further use of the grinding wheel 36, i.e., refrain from performing any passes with a wheel whose usage has reached the limit, even if such continued use has been requested by a user.
In one embodiment, the above usage tracking may be realized by initially loading the usage limit value onto the tag 204 and then subtracting or “debiting” the stored value as the grinding wheel 36 is used. The usage limit may be deemed to have been reached when the stored value reaches a predefined number such as zero. Generally the usage tracking and usage limit may be specified in any of a variety of ways, including a count of passes or cycles as has been mentioned, or alternatively by counting operating time (tracking the operating time for each sharpening and accumulating the time values over a period of successive sharpenings). If the usage limit value is specified as a maximum number of passes, then the value is decremented by two for each 2-pass cycle of the grinding wheel 36 over a skate blade during sharpening. In one embodiment, this decrementing can take place once each cycle, with the grinding wheel 36 passing through the home position (
A specific example is now provided for illustration. It is assumed that the useful lifetime of a grinding wheel 36 is on the order of 160 passes. This translates to approximately 10 sessions of sharpening a pair of skates if an average of 4 cycles (8 passes) is used per skate (8*2*10=160).
In a given embodiment, usage may be tracked in units of passes, cycles, blades sharpened (assuming some fixed or limited number of passes per blade), time, or some other scheme. The UI display 34 may be used to display remaining usable life for a grinding wheel 36 to the user. For example, it may be displayed as a fraction or percentage, or as more general ranges which could be indicated by colored indicators, for example—e.g., green for high remaining lifetime, white or other neutral color for intermediate, and red for low remaining lifetime. In one embodiment a linear array of indicators may be used, and indicators successively extinguished from one end as usage increases, and the end-of-life indicated by no indicators being lit.
Since there will be user-to-user variability in how many passes are done for a skate sharpening, the system may alert a user when the number of cycles needed to complete a sharpening exceed the number of cycles of remaining life of the grinding wheel 36. The alert may be provided, for example, by dimming or flashing a set of indicators, and/or by stopping a sharpening that is in progress or preventing a new sharpening from beginning Generally, it is desired that the display technique enable a user to accurately plan for use and avoid running out of usable grinding wheel lifetime in the middle of a sharpening
Beyond the usage tracking information, the tag 204 may also be used to carry system setup parameters that the control unit 32 can read and then apply to operation. This programming-type approach can enable a single sharpener 10 having a generalized design to be used in a wide variety of ways. For example, the tag 204 may contain parameters for the rotational speed of the grinding wheel motor 80; the speed of translation of the carriage assembly 70 across the skate blade; and the magnitude of a normal grinding force (i.e., the force applied by the grinding wheel 36 in a direction normal to the bottom face of the skate blade 40). Employing customizable settings in this manner can support variability in the materials, diameters, and grits used for different grinding wheels 36. Larger wheel diameters for different skates, or different grits for different skate steels or surface finishes, will generally require different system settings (grinding wheel RPM and translation speed) for optimized use. In operation, the control unit 32 can read the parameters from the tag 204 and then apply the parameters prior to beginning a sharpening operation, such as by programming the appropriate controllers 132 (
The identification tag 204 may also store user-specific settings to be used for sharpening operations, such as a default number of passes for a skate sharpening. The control unit 32 can read such values and then use them unless they are overridden by a specific current selection by the user. One user may sharpen relatively frequently and typically use a small number of passes, such as two, while another user may sharpen less frequently and typically use a larger number of passes, such as eight. The user interface preferably would enable a user to modify or update any such persistently stored values. Saving user-specific values on the grinding wheel 36 also enhances “portability” of the customization. A user can carry their own grinding wheel 36 and mount it for use in different sharpener systems 10 at different locations while still obtaining the same user-specific operation. For example, an organization such as a hockey club or rink operator can provide access to a sharpener system 10 and allow users to swap grinding wheels 36, so that each user receives a desired user-specific experience.
The sharpener system 10 may also have features for defeating counterfeiting or certain tampering with tags 204. For example, it might record the unique tag identifiers (e.g., tag serial numbers) for every tag 204 that has been used over some interval on that sharpener, as well as recording the number of passes that were last seen on the tag 204. If there is ever a time when a sharpener 10 sees a grinding wheel 36 that it has seen before but having remaining pass count greater than the number of remaining passes last seen on that wheel, the sharpener 10 could deem the grinding wheel 36 to be a counterfeit or tampered with and prevent its use. This might be done to insure that only grinding wheels 36 of sufficient quality are used, to obtain good sharpening results and avoid any unsafe conditions that could occur by using a defective or inferior grinding wheel 36. The system 10 may store the most recent passes remaining count as individual numbers or as percentages similar to the way the system displays the grinding wheel remaining life to the user.
Yet another possibility is for the tag 204 to store system fault data, i.e., data describing fault conditions that have occurred during a sharpening operation. This can help users interact with technical service to diagnose problems they may be having with their machine. A manufacturer or service organization might request that the user send a grinding wheel 36 to that organization for review. The grinding wheel is smaller and thus far cheaper and convenient to send than is the entire system 10. At the manufacturer or service organization, technicians can read fault data such as fault codes from the wheel 36. In another embodiment, the identification tag 204 may be compatible with readers such as near-field communications (NFC) readers such as used on smart phones and similar small computing devices. When the user experiences a system fault, the user can remove the grinding wheel 36 and place it near the computing device. The device might immediately launch an application or navigate to a particular web site to provide information to the user about the particular fault that is identified by the fault data stored on the tag 204. Another use for this type of interface is for repurchasing grinding wheels 36. The application or website launched by the device may provide product ordering functionality, enabling a user to easily obtain replacement grinding wheels 36 as existing grinding wheels are used up.
At 272, the system 10 tracks usage of the grinding wheel 36 for sharpening operations and writes updated usage tracking values to the usage location as the grinding wheel 36 is used for the sharpening operations. Usage may be tracked by counting passes, for example, in which case it may be convenient for the usage tracking value to be expressed as a pass count. The usage value may directly indicate an amount of usage that has occurred, e.g., as an increasing count of passes, or it may be directly indicate an amount of usage remaining, e.g., as a decreasing count of passes.
At 274, the system 10 reads a current usage tracking value from the usage location and selectively enables and disables sharpening depending on whether a usage limit has been reached, as indicated by a relationship between the current usage tracking value and a predetermined usage limit value. When a decreasing or decremented usage value is used to indicate an amount of usage remaining, then the predetermined usage limit value can be used as the starting usage value, and the usage limit is reached when the usage value is decremented to zero.
Referring first to the slot cover 28, the button 27 is mounted for rocking on a horizontal axis and has a downward-extending rack 300 at the rear. The rack 300 engages a pawl 302 attached to the arch 64. A spring (not shown) biases the button 27 so that its top is co-planar with the top of the slot cover 28 and the rack 300 engages the pawl 302, locking the slot cover 28 in place. In use, a user depresses a front part of the button 27 (see
Referring next to the blade clamping mechanism, a vertex portion of the U-shaped pull rod fork 92 is shown, along with a pin 304 securing it to the pull rod 102. The pull rod 102 extends through the clamp cylinder 94, terminating at a piston head 306. The pull rod 102 is disposed within bushings 307, 308. A spring 310 is disposed between one end of the body of the clamp cylinder 94 and an external retaining ring 312 on the pull rod 102.
When the clamp paddle 26 is in the position shown, the cam 96 presents a lower-radius face to the piston 306, and the spring 310 urges the pull rod 102 to a maximum retracted position, to the left in
A user opens the clamp jaws 90 by pushing downward on an outer part of the paddle 26, rotating it counterclockwise in the view of
As shown in
The above motion reverses when the jaws 90 are opened. As the rear jaw 90-R is pushed in the X direction, clamping tension is released and it slides downward in the Z direction, closing the space 347 and returning to the position of
In the illustrated embodiment as described above with reference to
In the illustrated embodiment the jaws 90 are urged against a lower or bottom surface of the spacer blocks 343, which are fixedly secured to the underside of the platform 22 of the chassis 14. More generally the jaws 90 are urged against a surface that is in some manner referenced to the chassis 14, i.e., having a fixed position with respect to the chassis 14. In an alternative embodiment, the jaws 90 might be secured directly to a surface of the chassis 14 itself, such as the bottom surface.
In the illustrated embodiment, the bumper 29 is attached to the body of the slot cover 28 (at lower left corner in this view). The attachment is with a pin or similar fastener 320 that permits the bumper 29 to rotate. A face portion 322 contacts a skate blade holder in operation as described above (
In operation, the limit switch 328 is electrically open by default, due to the mechanical biasing action of the spring 330. When the face portion 322 of the bumper 29 is depressed, the bumper 29 rotates (clockwise in this view) and the arm 324 depresses the limit switch lever 326, electrically closing the limit switch 328. The state of the limit switch 328 as open or closed is sensed by the controller 32. In one embodiment, sharpening operation is permitted only when the limit switch 328 is sensed as closed, which normally occurs when a skate blade is clamped in position and the slot covers 28 have been moved inward to contact the skate blade holder. In these operating positions the slot covers 28 cover the outer ends of the slot 24 that would otherwise be open. This prevents the introduction of any objects through the outer ends of the slot 24, where such objects might harmfully contact the rotating grinding wheel 36 as it moves along the slot 24 during a sharpening operation. If the limit switch 328 of either slot cover 28 is sensed as open, which normally occurs when either a skate or skate blade holder is not present or both slot covers 28 have not been moved inward to their operating positions, the controller 32 prevents sharpening operation, i.e., provides no electrical drive to the grinding wheel motor 80 and the carriage motor 260. With these motors not rotating, it is safer to introduce objects (such as a skate blade during mounting, for example) into the slot 24.
There are various alternatives to the configuration described above. An alternative to the bumper 29 may be a piston-like mechanism that moves linearly to actuate a switch, instead of rotating about a fixed pivot point as in the above. It is not necessary to use a limit switch with an actuation lever—in an alternative arrangement the bumper 29 (or analogous member) may directly push on the button of a limit switch. Also, in some embodiments a separate spring 330 may not be required. It may be possible to rely on the spring of a limit switch to provide a bias or return force. However, it may be desirable to use a separate spring to provide for adjustment of either/both the range of motion and actuation force of the bumper.
In yet another alternative, a contactless switch such as an optical emitter-detector pair could be used, with the skate or skate blade holder breaking the optical path to trigger the switch.
In the illustrated embodiment the slot covers 28 are affixed and always present, but in an alternative embodiment they could be separate components that are placed and locked onto the ends of the skate or skate blade holder by the user prior to sharpening. Also, while in the illustrated embodiment the slot covers 28 move by sliding, they could alternatively move by rotating on a hinge, telescoping, or rolling out (like a breadbox or garage door).
The pivot spindle 240 is secured at each end to the carriage 72. A pivot section 400 of the motor arm 78 is mounted on the pivot spindle 240 by a combination of bearings 402, 404 and bushings 406, 408. Shown on the right in this view is a spring 410 disposed in compression between the front wall of the carriage 72 and an inner race 412 of the bearing 404. Shown on the left is the spindle gear 252 which is disposed on a hub or nut 414 having screw threading engaging corresponding screw threading on the pivot spindle 240. It will be appreciated that the gear and threading features may be integrated into a single component as an alternative. Arranged between the nut 414 and an inner race 416 of the bearing 402 is a washer 418 and a collar portion 420 of the bushing 406, including a detent mechanism as described below.
The mounting of the motor arm 78 on the bearings 402, 404 permits the motor arm 78 to pivot about the pivot spindle 240 so that the grinding wheel 36 can follow the profile of the bottom face of the skate blade during sharpening (as described above with reference to
The transverse or Y-direction (left to right in
The nut 414 and washer 418 are co-configured to form a detent mechanism providing several detent locations for a rotation of the nut 414, helping prevent undesired transverse movement of the motor arm 78 after an alignment operation has been performed and a sharpening operation has begun. Specifically, the front face (rightward in
In use, a user opens the jaws 90 and inserts the alignment tool 440, locating it so that the shoulder portions 450 sit on top of the endward clamping portions 436 of the jaws 90 and the protrusions 452 are received by the notches 438. The user then closes the jaws 90 so that the alignment tool 440 is retained with the blade-like portion 442 in the same position as a skate blade 40 is retained during sharpening. The carriage 70 is then moved to bring the grinding wheel 36 to the position shown in
In one embodiment the movement of the grinding wheel 36 into the alignment position of
The process further includes at 462 operating an adjustment mechanism while visually observing the area where the visual reference features are located to bring them into alignment with each other. This brings the grinding wheel and the retained skate blade into an aligned position in which the centerline of the grinding wheel is aligned with the centerline of the retained skate blade. In one embodiment the adjustment mechanism may be configured and used such as described above, but the adjustment mechanism may be realized in different ways in alternative embodiments.
Referring again to
It is noted that the placement of the notch 454 toward an edge of the grinding wheel 36 has significance. Proper grinding occurs at the center of the grinding wheel 36, so if the alignment mark were placed at the center of the grinding wheel 36 then it would be affected by grinding and potentially lose its ability to function as an alignment mark. It might even be erased completely before the end of the usable lifetime of the grinding wheel 36. When formed as a notch or similar feature, it might also compromise the quality of the sharpening. By placing the alignment mark in the form of the notch 454 nearer the edge or face of the grinding wheel 36 it is not affected by the normal wearing of the abrasive over a period of use, and it does not interfere with grinding.
The process of
The process further includes, at 522, operating the adjustment mechanism to bring the first visual reference feature into alignment with the second visual reference feature, thereby bringing the wheel-mounting location of the spindle to an aligned position in which the centerline of the grinding wheel when occupying the wheel-mounting location is aligned with the centerline of the skate blade position. The alignment may be achieved by visually monitoring relative positions of the visual reference features while operating the adjustment mechanism.
Although the alignment processes and apparatus as described herein contemplate a human user who looks through the magnifying lens 446 and rotates the adjustment knob 242, it will be appreciated that in alternative embodiments a more automated process may be used. For example, some manner of machine vision or other apparatus may be used to monitor relative position between the grinding wheel 36 and alignment tool or between the alignment wheel 502 and the alignment tool, and the adjustment mechanism may be driven by an adjustment motor provided with an electrical adjustment signal. In an embodiment employing automation, a controller can then perform the process of
While various embodiments of the invention have been particularly shown and described, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
1219004 | Kalanquin | Mar 1917 | A |
2114967 | Myers | Apr 1938 | A |
2438543 | Custin et al. | Mar 1948 | A |
2563018 | Fello | Aug 1951 | A |
2599952 | Strayer | Jun 1952 | A |
2722792 | Harrington | Nov 1955 | A |
2775075 | McMaster et al. | Dec 1956 | A |
2819568 | Kasick | Jan 1958 | A |
2990661 | Hackett | Jul 1961 | A |
3118256 | De Witt | Jan 1964 | A |
3259959 | Tobey | Jul 1966 | A |
3574975 | Liss | Apr 1971 | A |
3650073 | Weisman | Mar 1972 | A |
3735533 | Salberg | May 1973 | A |
3742655 | Oliver | Jul 1973 | A |
3756796 | Miller | Sep 1973 | A |
3789551 | Norris et al. | Feb 1974 | A |
3800632 | Juranitch | Apr 1974 | A |
3839828 | Arnold | Oct 1974 | A |
3881280 | Thompson | May 1975 | A |
3988124 | Babcock | Oct 1976 | A |
3988865 | Weisman | Nov 1976 | A |
4055026 | Zwicker | Oct 1977 | A |
4078337 | Chiasson | Mar 1978 | A |
4094101 | Robinson | Jun 1978 | A |
4235050 | Hannaford et al. | Nov 1980 | A |
4235052 | Guidry | Nov 1980 | A |
4271635 | Szalay | Jun 1981 | A |
4516357 | Gach | May 1985 | A |
4534134 | Consay et al. | Aug 1985 | A |
4549372 | Sexton et al. | Oct 1985 | A |
4558541 | Consay | Dec 1985 | A |
4570387 | Unno et al. | Feb 1986 | A |
4615144 | Peacock et al. | Oct 1986 | A |
4615149 | Yoneda et al. | Oct 1986 | A |
4722152 | Ek et al. | Feb 1988 | A |
4756125 | Kadnar | Jul 1988 | A |
4967515 | Tsujiuchi et al. | Nov 1990 | A |
5009039 | Lager et al. | Apr 1991 | A |
5127194 | Jobin | Jul 1992 | A |
5129190 | Kovach et al. | Jul 1992 | A |
5177901 | Smith | Jan 1993 | A |
5259148 | Wiand | Nov 1993 | A |
5547416 | Timms | Aug 1996 | A |
5562526 | Yoneda et al. | Oct 1996 | A |
5591069 | Wurthman | Jan 1997 | A |
5601473 | Strain et al. | Feb 1997 | A |
5823854 | Chen | Oct 1998 | A |
5897428 | Sakcriska | Apr 1999 | A |
5989114 | Donahue et al. | Nov 1999 | A |
6116989 | Balastik | Sep 2000 | A |
6422934 | Blach et al. | Jul 2002 | B1 |
6602109 | Malkin et al. | Aug 2003 | B1 |
6626745 | Bernard | Sep 2003 | B1 |
7118466 | Laney | Oct 2006 | B2 |
7220161 | Eriksson | May 2007 | B2 |
7473164 | Sunnen | Jan 2009 | B2 |
D603432 | Wilson et al. | Nov 2009 | S |
7934978 | Wilson et al. | May 2011 | B2 |
D665830 | Wilson et al. | Aug 2012 | S |
8246425 | Schudel | Aug 2012 | B2 |
8277284 | Wilson et al. | Oct 2012 | B2 |
8316742 | Craig et al. | Nov 2012 | B2 |
D681077 | Wilson et al. | Apr 2013 | S |
8430723 | Moon | Apr 2013 | B2 |
8827768 | Allen | Sep 2014 | B2 |
8888567 | Allen | Nov 2014 | B2 |
9114498 | Layton, Jr. et al. | Aug 2015 | B1 |
9242330 | Layton, Jr. et al. | Jan 2016 | B1 |
9339911 | Eriksson | May 2016 | B2 |
9352437 | Layton, Jr. et al. | May 2016 | B2 |
9352444 | Layton, Jr. et al. | May 2016 | B2 |
9475175 | Layton, Jr. | Oct 2016 | B2 |
20020009964 | Wolf et al. | Jan 2002 | A1 |
20030156401 | Komine et al. | Aug 2003 | A1 |
20040209547 | Hatano et al. | Oct 2004 | A1 |
20050130571 | Sunnen | Jun 2005 | A1 |
20060159533 | Zeiler et al. | Jul 2006 | A1 |
20060183411 | Moon | Aug 2006 | A1 |
20060223419 | Moon | Oct 2006 | A1 |
20070054598 | Uchida et al. | Mar 2007 | A1 |
20080176496 | Tasi | Jul 2008 | A1 |
20080280548 | Wilson et al. | Nov 2008 | A1 |
20100125362 | Canora et al. | May 2010 | A1 |
20110169233 | Wilson et al. | Jul 2011 | A1 |
20120108151 | Swist | May 2012 | A1 |
20120190279 | Ficai | Jul 2012 | A1 |
20120302147 | Trautner et al. | Nov 2012 | A1 |
20130344774 | Allen | Dec 2013 | A1 |
20140179201 | Proulx | Jun 2014 | A1 |
20150367224 | Schatz | Dec 2015 | A1 |
20160114450 | Layton, Jr. et al. | Apr 2016 | A1 |
20160114451 | Layton, Jr. et al. | Apr 2016 | A1 |
20160114452 | Layton, Jr. et al. | Apr 2016 | A1 |
20160114454 | Layton, Jr. et al. | Apr 2016 | A1 |
20160114461 | Layton, Jr. et al. | Apr 2016 | A1 |
20160114464 | Layton, Jr. et al. | Apr 2016 | A1 |
Number | Date | Country |
---|---|---|
1118514 | Feb 1982 | CA |
1229985 | Dec 1987 | CA |
2260531 | Aug 1999 | CA |
2309222 | Nov 2000 | CA |
2323321 | Apr 2002 | CA |
WO 2016065237 | Apr 2016 | WO |
Entry |
---|
Invitation to Pay Additional Fees issued in International Application No. PCT/US2015/057078, mailed on Feb. 24, 2016. |
International Search Report & Written Opinion of the International Searching Authority issued in International Application No. PCT/US2015/057078, mailed on May 2, 2016. |
“CAG One Service AB”, downloaded from www.cagone.pl/dokumenty/cag-one-users-manual.pdf, 32 pages, Sep. 2009. |
“CAG Profiler Manual”, downloaded from www.cagone.com/img/profiler.pdf, 23 pages, Sep. 2010. |
“Dupliskate Users Manual”, downloaded from www.dupliskate.com/pdf/Dupliskate-User-Manual.pdf, 11 pages, Aug. 2013. |
“Prosharp AS2001 Allpro, AS1001 Portable, Skatepal Pro3 Instructions”, downloaded from www.prosharp.net/file/broschyroriginalinstructions-eng.pdf, 40 pages, Apr. 2013. |
“Skatepal Pro Instructions”, downloaded from www.prosharp.net/file/instruction-skatepal-pro2-eng.pdf, 12 pages, Oct. 2010. |
“Spareparts Skatepal Pro 3”, downloaded from www.prosharp.net/file/schematicssp13a1.pdf, 6 pages, Mar. 2013. |
“SSM Catalog”, downloaded from www.skyice.org/ssm—catalogue—2011.pdf, 12 pages. |
CAG One Skate Sharpeners, “CAG One New Evolution Sharpening Machine”, URL: http://cagone.com/evolution/, pp. 1-4, (Date Unknown). |
Craig Forsythe, “CAG Speed III Sharpener Manual”, Teflone Publications MMV, downloaded from www.cagone.com/img/speed.pdf, 14 pages, Aug. 2009. |
Prosharp, “Grinding Wheels—SkatePals”, 2015 ProSharp AB, URL: http://prosharp.com/products/grinding-wheels/grinding-wheels, pp. 1-9. |
Number | Date | Country | |
---|---|---|---|
20160346893 A1 | Dec 2016 | US |