Cutting tools are used in a variety of applications to cut or otherwise remove material from a workpiece. A variety of cutting tools are well known in the art, including but not limited to knives, scissors, shears, blades, chisels, machetes, saws, drill bits, etc.
A cutting tool often has one or more laterally extending, straight or curvilinear cutting edges along which pressure is applied to make a cut. The cutting edge is often defined along the intersection of opposing surfaces (bevels) that intersect along a line that lies along the cutting edge.
In some cutting tools, such as many types of conventional kitchen knives, the opposing surfaces are generally symmetric; other cutting tools, such as many types of scissors and chisels, have a first opposing surface that extends in a substantially normal direction, and a second opposing surface that is skewed with respect to the first surface.
Complex blade geometries can be used, such as multiple sets of bevels at different respective angles that taper to the cutting edge. Scallops or other discontinuous features can also be provided along the cutting edge, such as in the case of serrated knives.
Cutting tools can become dull over time after extended use, and thus it can be desirable to subject a dulled cutting tool to a sharpening operation to restore the cutting edge to a greater level of sharpness. A variety of sharpening techniques are known in the art, including the use of grinding wheels, whet stones, abrasive cloths, abrasive belts, etc.
Various embodiments of the present disclosure are generally directed to a method and apparatus for sharpening a cutting tool, such as but not limited to a kitchen knife.
In some embodiments, a sharpener has a guide assembly adjacent a moveable abrasive medium. The medium is advanced at a first speed relative to the guide assembly during a coarse sharpening operation in which a user presents the cutting tool against the medium to shape a side of the cutting tool and generate distended material from the cutting edge (e.g., burrs). The medium is subsequently slowed to a lower, second speed for a fine sharpening operation in which the user presents the cutting tool against the medium to remove the distended material and provide a sharpened cutting edge.
These and other features and advantages of various embodiments will be understood from a review of the following detailed description in conjunction with the accompanying drawings.
Multi-stage sharpeners are known in the art to provide a succession of sharpening operations to the cutting edge of a cutting tool, such as but not limited to a kitchen (chef) knife, to produce an effective cutting edge. One example of a multi-stage sharpener is provided in U.S. Pat. No. 8,696,407, assigned to the assignee of the present application and hereby incorporated by reference, which provides a slack belt powered sharpener in which multiple abrasive belts can be successively installed in a sharpener to provide different levels and angles of shaping to obtain a final desired geometry on a cutting tool. Other multi-stage sharpeners are well known in the art that use a variety of abrasive media, including rotatable grinding wheels, carbon rippers, abrasive rods, etc.
These and other forms of multi-stage sharpeners generally enact a sharpening scheme whereby a coarse sharpening stage is initially applied to quickly remove a relatively large amount of material from the cutting tool to produce an initial blade geometry. One or more fine sharpening stages are subsequently applied to refine the geometry and “hone” the blade to a final cutting edge configuration. In some cases, relatively larger grit abrasives are used during coarse sharpening followed by the use of relatively finer grit abrasives to provide the final honed blade. The honing operation can remove striations and other marks in the blade material left by the coarser abrasive, and hone the final cutting edge to a relatively well defined line.
In some embodiments such as taught by the '407 patent, different effective sharpening angles can be applied to further enhance the multi-stage sharpening process. For example, the coarse sharpening can occur at a first bevel angle, such as about 20 degrees with respect to a longitudinal axis of the blade, and the fine sharpening can occur at a different second bevel angle, such as about 25 degrees with respect to the longitudinal axis of the blade.
While these and other forms of sharpeners have been found operable in producing sharpened tools, the use of multiple stages increases the complexity and cost of the associated sharpener. One factor that can increase such complexity and cost is the need to utilize different abrasive media to effect the various sharpening stages. For example, the '407 patent teaches to have the user remove and replace different belts with different levels of abrasiveness and different linear stiffnesses in order to carry out the different sharpening operations. Other sharpeners provide multiple sharpening stages within a common housing with different abrasive media (e.g., rotatable discs, carbon rippers, abrasive rods, etc.) so that the user successively inserts the blade into or against different guide assemblies (guide slots with associated guide surfaces) to carry out the multi-stage sharpening operation against different abrasive surfaces.
Accordingly, various embodiments of the present disclosure provide a number of different, related sharpeners that can carry out multi-stage sharpening operations using a common abrasive medium. In some embodiments, the common abrasive medium is an endless abrasive belt. In other embodiments, the common abrasive medium is a rotatable abrasive disc. Other forms of abrasive medium are envisioned, so that these examples are merely exemplary and not necessarily limiting.
As explained below, a coarse sharpening operation is generally carried out by presenting the tool to be sharpened via a guide assembly against a moveable abrasive medium. A coarse mode of operation is selected so that the medium moves at a first relative speed with respect to the tool. It is contemplated although not necessarily required that the first relative speed is a relatively high rate of speed in terms of unit of distance transversed adjacent the tool with respect to time (e.g., X feet per minute, fpm).
A fine (honing) mode of operation is subsequently selected so that the medium moves at a different, second relative speed with respect to the tool. It is contemplated that the second speed will be significantly less than the first speed (e.g., Y fpm where Y<X).
In some embodiments, the first rate of removal is selected to be high enough to form a burr, which as explained below is a displaced extent of material from the cutting edge. The second rate of material is selected to be high enough to remove the burr but low enough such that the lower rate of speed does not significantly alter the underlying geometry of the blade.
In some cases, both coarse and fine grinding are carried out with the medium moving in the same direction with respect to the tool. In other cases, the coarse grinding may take place with the medium moving in one direction and the fine grinding taking place with the medium moving in an opposite direction. In further cases, the final pass of the fine grinding operation is carried out with the abrasive surface of the medium moving toward the cutting edge rather than away from the edge. For example, using a substantially horizontal blade with the cutting edge along a lowest point thereof, toward the cutting edge may be a direction that is generally upwardly, while away from the cutting edge may be in a direction that is generally downwardly. These relative directions may be reversed.
These and other features, advantages and benefits of various embodiments can be understood beginning with a review of
The exemplary sharpener 100 is configured as a powered sharpener designed to rest on an underlying base surface, such as a table top, and to be powered by a source of electrical power such as residential or commercial alternating current (AC) voltage, a battery pack, etc. Other forms of tilted sharpeners can be implemented, including non-powered sharpeners, hand-held sharpeners, etc.
The sharpener 100 includes a rigid housing 102 that may be formed of a suitable rigid material such as but not limited to injection molded plastic. A user switch, power and control circuitry module 104 includes various elements as required including user operable switches (e.g., power, speed control, etc.), power conversion circuitry, control circuits, sensors, user indicators (e.g., LEDs, etc.).
An electrical motor 106 induces rotation of a shaft or other coupling member to a transfer assembly 108, which may include various mechanical elements such as gears, linkages, etc. to in turn impart rotation to one or more drive rollers 110. As explained below, the respective module 104, motor 106 and linkage 108 are variously configured such that, responsive to user inputs, the drive roller 110 is rotated in two separate and distinct rotational velocities. In some cases, three or more separate and distinct rotational velocities may be used. While not necessarily required, changes in rotational direction can also be imparted to the drive roller by such mechanisms.
An endless abrasive belt 112 extends about the drive roller 110 and at least one additional idler roller 114. In some cases, multiple rollers may be employed by the sharpener, such as three or more rollers to define a multi-segmented belt path. A tensioner 116 may impart a bias force to the idler roller 114 to supply a selected amount of tension to the belt. A guide assembly 118 is configured to enable a user to present a cutting tool such as a knife against a segment of the belt 112 between the respective rollers 110, 114 along a desired presentation orientation, as discussed below.
A schematic representation of one exemplary belt path is provided in
The belt 112 has an outer abrasive surface denoted generally at 122 and an inner backing layer denoted generally at 124 that supports the abrasive surface. These respective layers are generally represented in
The exemplary arrangement of
Each segment 126, 128 is further shown to be unsupported by a corresponding restrictive backing support member against the backing layer 124. This allows the respective segments to remain aligned along the respective neutral planes in an unloaded state and to be rotationally deflected (“twisted”) out of the neutral plane during a sharpening operation through contact with the knife. It is contemplated that one or more support members can be applied to the backing layer 128 in the vicinity of the segments 126, 128, such as in the form of a leaf spring, etc., so long as the support member(s) still enable the respective segments to be rotationally deflected away from the neutral plane during a sharpening operation.
An abrasive belt axis is represented by broken line 138 and represents a direction of travel and alignment of the belt 112 during operation. The abrasive belt axis 138 is nominally orthogonal to the respective roller axes 110A, 114A of rollers 110, 114 in
A pair of edge guide rollers are represented at 140, 142. The edge guide rollers form a portion of the aforementioned guide assembly 118 (see
Generally, the edge guide rollers 140, 142 provide a retraction path 144 for the blade 134 as the user draws the cutting edge across the belt 112 via the handle 132. As shown in
While not limiting to the scope of the claimed subject matter, the presence of a non-orthogonal tilt angle A as in
During a sharpening operation, in some embodiments the module 104 (see
Thereafter, the user provides an input to module 104, which causes the sharpener 100 to rotate the belt 112 in a second direction and at a second speed. The second direction may be the same as, or opposite of, the first direction. The second speed will be slower than the first speed. Again the user presents the blade via the guide assembly 118 as before, drawing the blade across the belt 112 a selected number of times, such as 3-5 times. As before, the user may alternate the sharpening on both sides of the blade.
As mentioned above, the final direction of sharpening may be selected such that the belt is moving up and across the blade during all or a portion of the fine mode of sharpening (e.g., in a substantially vertical direction toward upper roller 114 as seen in
The linear stiffness and abrasiveness level (e.g., grit level) of the belt can be selected depending on the requirements of a given application. Without limitation, in some embodiments it has been found that a grit value of from about 80-200 can be selected for the abrasive belt and effective coarse and fine sharpening can be carried out using the same common belt as described herein. In other embodiments, the grit value may be from about 100-400. The respective rotational rates can vary as well; for example, a suitable high speed (coarse grind) rotational rate may be on the order of from about 800-1500 revolutions per minute (rpm) at the rollers and a suitable low speed (fine grind or honing) rotational rate may be on the order of about 300-500 rpm at the rollers.
In further cases, the lower speed may be approximately 50% or lower than 50% of the higher speed. In still further cases, the lower speed may be approximately 75% or lower than 75% of the higher speed. Other suitable values may be used so these are merely exemplary and are not limiting. The speed of the medium may be expressed in any suitable way, including linear travel past the cutting edge (e.g., feet per second, fps, etc.).
As noted above, more than two different speeds, such as three speeds or more, may be used. A high speed may be used initially, followed by a lower, medium speed, followed by a lowest speed lower than the medium speed.
The sharpener 200 includes a rigid housing 202, a user switch, power and control circuit module 204, an electrical motor 206, a transfer assembly 208 and a drive spindle 210. As before, these elements cooperate to enable a user to select, via user input, at least two different rotational speeds for the drive spindle 210. In some embodiments, different directions of rotation may also be effected.
The drive spindle 210 supports a rotatable abrasive disc 212. A guide assembly 218 is positioned adjacent the disc 212 to enable a user to present a tool thereagainst during a multi-stage sharpening operation using the same disc 212.
While not necessarily limiting, in some embodiments the abrasive disc 212 may be characterized as a flexible abrasive disc, as shown in
The flexible disc can be formed of any suitable materials, including the use of abrasive media on a fabric or other flexible backing layer. In some cases, abrasive material may be provided on both sides of the disc; in other cases, the abrasive material will only be supplied on a single side of the disc.
As before, a multi-stage sharpening operation is carried out using the same rotatable disc 212 by rotating the disc at different effective speeds. A coarse sharpening operation is carried out at a relatively high speed of the disc, followed by a fine sharpening operation carried out at a relatively low speed of the disc. Suitable guides can be provided so that each side of the knife 230 is sharpened using the same side of the disc 212 (such as by presenting the blade 234 in opposite directions against layer 214 in
The blade in
It will be appreciated that at least one traditional multi-stage sharpening operations tend to enhance the refinement of the cutting edge, such as through the application of progressively finer abrasives to further refine the cutting edge to the point that it is burr free and substantially linear. While such techniques can provide a very sharp edge, it has been found that such refined edges also tend to dull quickly, sometimes after a single use. As discussed above in
The resulting cutting edge of
As shown by step 252, a powered multi-directional abrasive medium is provided along with an adjacent guide assembly, such as discussed above for the abrasive belt sharpener 100 of
A user presents a cutting tool for sharpening into the guide assembly at step 254, such as the exemplary knives 130, 160 and 230 discussed above. It will be appreciated that other forms of cutting tools can be utilized in accordance with the routine.
The user draws the cutting edge of the tool across the medium while the medium is moving at a first speed, step 256. As discussed above, this can be carried out multiple successive times, including passes on opposing sides of the cutting tool. It is contemplated that the guide assembly includes at least a first surface that supports a side surface of the blade opposite the medium to establish a desired bevel angle for the sharpening operation that can be repeated through reference to this side surface.
A plunge depth of the cutting edge can further be established through the use of one or more stationary or rotatable edge guides against which a portion of the cutting edge contactingly engages as the blade is drawn across the medium. The operation of step 256 will produce a coarse shaped cutting edge such as exemplified in
As shown by 258, once the coarse sharpening operation is completed, the user subsequently draws the cutting tool across the same medium, this time moving at a different second relative speed with respect to the tool. As discussed above, this can be carried out including by providing a suitable input to a motor or other mechanism to slow down the linear or rotational movement rate of the medium with respect to the tool. This effects a fine shaped cutting edge such as exemplified in
In some embodiments, different speeds and directions may be effected through the application of different control voltages and/or currents to the motor. In other embodiments, different gearing ratios or other linkage configurations may be effected via the transfer assemblies. As noted above, user selectable switches, levers or other input mechanisms can be utilized to generate the various input values. In some cases, the user can place the system in coarse or fine mode, and then proximity switches can be utilized to determine placement of the tool into the associated guide and a suitable movement direction for the medium can be selected accordingly.
Such changes in tensioner bias forces can be provided in addition to, or in lieu to, the changes in rotational/movement rate of the medium. It will be appreciated that the changes in the respective surface pressures of the medium effect the generation of the burr and relatively large scale shaping of the coarse grind, and the fine grind operation (at low pressure) sufficient to remove the burring and produce the final desired geometry. Accordingly, further embodiments can utilize other mechanisms apart from speed control to effect higher and lower amounts of surface pressure to achieve the disclosed coarse and fine shaping using the same medium.
A number of different types of sensors and other electrically based circuit elements can be arranged as required to supply inputs to the control circuit 280. These can include one or more of a proximity circuit 286, a contact sensor 288, an electrical resistance sensor 290, an optical sensor 292, a timer 294 and/or a counter circuit 296. Control outputs from the control circuit are directed to the electrical motor 106, as well as a user light emitting diode (LED) panel 298. While each of these elements shown in
The various sensors can be used to detect operation by the user to contact and draw the cutting tool across the medium. It is contemplated that the various sensors may be respectively placed in suitable locations, such as integrated within or adjacent to the guides 168 (see
While these and other types of sensors are well known in the art, it will be helpful to give a brief overview of each type. The proximity sensor 286 may take the form of a Hall effect sensor or similar mechanism configured to sense the adjacent proximity of the cutting tool, such as through changes in the field strength of a magnetic field that encompasses portions of the cutting tool as the tool is moved through the guide. The contact sensor 288 may utilize a pressure activated lever, spring, pin or other member that senses the application of contact imparted by a portion of the cutting tool.
The electrical resistance sensor 290 may establish a low current pathway that can be used to detect changes in electrical resistance of the cutting tool. The sensor may form a portion of the edge guide surface (see e.g., surface 170 in
The timer 294 may take the form of a resettable countdown timer that operates to count to a desired value to denote desired elapsed time intervals. The counter 296 may be a simple incremental buffer or other element that enables a running count of operations, such as sharpening strokes, to be accumulated and tracked. The user LED panel 298 may provide one or more LEDs or other identifiers that provide a visual indication to a user to carry out various operations.
As noted above, one or more sensors such as depicted in
A greater or lesser number of speeds may be selected based on the initial condition of the blade so that the control circuit generates a unique sharpening sequence. The condition of the blade may also be monitored by the sensor(s) with the control circuit changing from one speed to the next as appropriate to continue the sharpening process.
In still further embodiments, a sharpness tester device is contemplated that utilizes selected combinations of the various elements in
Generally, the sharpener 300 is similar to the sharpener 100 discussed above and includes a multi-speed abrasive belt arranged along a triangular belt path that passes over three internally disposed rollers, in a manner similar to that discussed above in
With specific reference to
An endless abrasive belt 308 is routed along a plurality of rollers, including an upper idler roller 310 and a lower right drive roller 312. Opposing guide slots 314, 316 operate to enable a user to carry out slack-belt sharpening on opposing distal extents of the belt. An interior motor drive shaft 318 transfers rotational power to the drive roller 312 via a drive belt 320. A number of user visible LEDs are provided on a user LED panel 322 in front of the sharpener, which may be selectively activated during a sharpening sequence.
As shown by step 402, the process begins with initiated movement of a powered abrasive medium (e.g., the belt 310) in a selected direction at a first, higher speed. This may be carried out by the user activating the sharpener or by some other action on the part of the user. The belt is arranged adjacent first and second guide slots, such as the guides 314, 316, which are adapted to support the knife during a double sided sharpening operation.
At step 404, the counter 296 is initialized and, as desired, a user indication is made to signal the user to place the knife in the first guide slot. This may be performed in a variety of ways, such as flashing or solid colored LEDs adapted for this purpose. In one embodiment, one LED may be placed under each slot to signal to the user which slot to use in turn.
The user proceeds at step 406 to draw the cutting edge of the knife across the moving medium multiple times to carry out a coarse sharpening operation to a first side of the knife in a manner as discussed above. In
At step 408, the counter is reinitialized and, as desired, a second user indication may be supplied to signal the user to use the second slot. This can be carried out by a different LED or by some other mechanism. It will be appreciated that the use of user indications such as LEDs is merely exemplary and helps to make the sharpening process user-friendly, repeatable and effective. Nevertheless, such user indications are not necessarily required.
At step 410, the user places the knife into the second slot and repeats the coarse grinding operation to the second side of the blade. As before, sensors may be used to detect each stroke and the counter is used to accumulate the total number of strokes applied, after which the system signals the completion of the coarse part of the sharpening process.
The system next operates at step 412 to reduce the speed of the medium to a second, lower speed. As noted above, a first roller rpm rate may be on the order of around 1000 rpm during the coarse sharpening, and this rate may be reduced to around 500 rpm during the fine sharpening operation. Other values may be used.
To carry out the fine sharpening, the foregoing steps are largely repeated at the lower speed. The counter is re-initialized and, as desired, the user is directed to once again place the knife in the first guide slot at step 414. As before, the user draws the tool through the first guide slot the predetermined number of times, as indicated by the counter, step 416. These steps are repeated for the second guide slot at steps 418 and 420, after which the sharpener provides an indication to the user that the sharpening operation is completed at step 422, such as by powering down or some other operation, and the process ends at step 424.
A number of variations may be enacted to the routine of
Finally, it is contemplated that the medium (belt 310) in the routine of
As before, the process begins at step 502 with the initialization of movement of the abrasive medium (e.g., belt 310) at a first, higher speed. A first sensor is initiated at step 504 and, as desired, the user is signaled to use the first guide slot, step 504. The user proceeds to draw the knife through the first slot at step 506 while the sensor monitors the sharpening process. In this way, a variable number of strokes through the first slot may be provided based on changes made to the cutting edge. The settings used by the sensor may be obtained empirically through evaluation of a number of different cutting tool sharpening characteristics.
A second sensor is initiated at step 508 and the user proceeds to draw the knife through the second slot at step 510. The second sensor monitors the sharpening process to detect changes in the cutting edge. This provides an adaptive sharpening process based on the rates of material removal for the blade, and may provide better overall sharpening results for a large variety of cutting tools with various levels of damage, dullness, etc.
Once the higher speed coarse sharpening operation is completed, the sharpener decreases the speed of the medium to the lower speed at step 512. The foregoing steps are repeated for the lower speed, fine sharpening operation at steps 514, 516, 518 and 520. As before, once the fine sharpening operation has been performed, a user indication is provided to signal that the sharpening operation is completed, step 522, and the process ends at step 524.
It follows that various embodiments can be characterized as directed to a single stage powered sharpener with a moveable abrasive surface adapted to carry out multi-stage sharpening on a cutting tool. The system can include a relatively coarse abrasive surface (such as a grit from 80-200), a pair of opposing guides, and a drive system for the abrasive surface with respective first and second speeds to effect the different first and second rates of material removal. In some embodiments, the second speed of the material (as measured with respect to the associated guide) can be any suitable speed, such as less than or equal to about 500 surface feet per minute. The first speed is greater than the second speed, such as greater than or equal to about two (2) times the second speed. Other suitable speed ratios can be used.
A two speed sharpening process can include placing the blade of the cutting tool to be sharpened into a first guide against a first guide surface and a first edge stop. The first guide surface can extend at a selected bevel angle, and the first edge stop can be arranged at a selected distance from the abrasive surface. The abrasive surface can be controlled to advance at a first speed. The blade is drawn across the abrasive surface, multiple times in succession as needed, to remove material from the blade and to impart a selected bevel surface on the first side of the blade. It is contemplated that this first operation will also generate a burr on an opposing second side of the blade.
The blade can be placed into a second guide against a second guide surface and a second edge stop. The second guide surface can extend at the selected bevel angle and the second edge stop can be the selected distance from the abrasive surface. The abrasive surface is controlled to advance at a second, lower speed. The user draws the blade across the abrasive surface, multiple times in succession as needed, to remove material from the blade such that the burr is removed and the final geometry is achieved.
Optional parameters for the foregoing can include the first and second guides being the same guide, or different guides. If the first and second guides are the same guide, the blade is inserted at different orientations so that the first side is presented to the abrasive surface in the first orientation and the second side is presented in the second orientation at the same bevel angle. This may be accomplished, for example, by flipping the handle of the tool end to end to reverse the direction of the blade through the guide.
In cases where the first and second guides are different guides, the guides may be placed on opposing sides of the abrasive and the blade is inserted in the first guide at a first bevel angle to the abrasive surface and the blade is subsequently inserted into the second guide at a second bevel angle. The first and second bevel angles may be the same and may extend, for example, over a range of from about 10 degrees to about 25 degrees.
As noted above, the abrasive surface may extend on a flexible belt routed along a path having two or more rollers, one of which is driven by a drive system with an electric motor. Alternative, the abrasive surface may extend on one or more flexible discs driven by an electric motor.
The abrasive surface may be spring biased to allow it to impart a selected force to the blade as it is displaced by the blade inserted against the first or second guides. In various cases, the force between the blade and surface in the first guide is equal to the force in the second guide, or greater than the force in the second guide. In some cases, the abrasive surface is a flexible belt and the spring bias on the belt is between about 2 and 12 pounds. Deflection of the abrasive surface away from a neutral plane may occur in the range of from about 0.04 inches, in. and about 0.25 in.
It will be recognized by the skilled artisan in view of the present disclosure that the flexibility of the associated medium (e.g., flexible disc, flexible belt) provides different surface pressures to the associated cutting tool based on changes in speed of the abrasive. It is believed that a faster speed of the abrasive may tend to generally impart greater inertia and/or structural rigidity to the medium (such as through centrifugal forces) so that greater rates of material removal are obtained at the faster speeds of the media. The slower speed of the media is generally selected such as to be fast enough to remove any burring but slow enough so as to not otherwise significantly change the geometry of the blade. The actual speeds will depend on a variety of factors including different blade geometries, abrasiveness levels, abrasive member stiffness and mass, etc., and may be empirically determined. A sharpener may be provisioned with multiple available speeds and the user selects the appropriate speeds based on various factors. A final honing stage, such as an abrasive rod or other stationary abrasive member, can be further provided to provide final honing of the final cutting edge.
It is to be understood that even though numerous characteristics and advantages of various embodiments of the present disclosure have been set forth in the foregoing description, together with details of the structure and function of various embodiments, this detailed description is illustrative only, and changes may be made in detail, especially in matters of structure and arrangements of parts within the principles of the present disclosure to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
The present application makes a claim of domestic priority under 35 U.S.C. 119(e) to U.S. Provisional Patent Application No. 62/294,354 filed Feb. 12, 2016, the contents of which are hereby incorporated by reference.
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