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 an apparatus and method for sharpening a cutting tool having a blade portion with a cutting edge, such as but not limited to a kitchen knife.
In some embodiments, a sharpener has a flexible abrasive member that is moved by an electric motor and supported by at least a first support member along a neutral plane having opposing proximal and distal ends. The flexible abrasive member has a front side with an abrasive surface and a back side opposite the front side. A second support member is disposed to contactingly engage the back side of the flexible abrasive member between the proximal and distal ends so that the neutral plane comprises a first segment that extends from the proximal end toward the second support member and a second segment that extends from the second support member toward the distal end. A guide assembly is positioned adjacent the flexible abrasive member to support the cutting tool during a sharpening operation in which a cutting edge of the cutting tool is presented against the flexible abrasive member. The guide assembly has a side support surface to contactingly support a side surface of the cutting tool and an edge guide surface to concurrently contactingly support a first portion of the cutting edge of the cutting tool while a second portion of the cutting edge of the cutting tool is presented against a contact region of the abrasive surface to deflect the flexible member out of the neutral plane. The contact region is offset from the second support member and disposed along a selected one of the first or second segments, the second support member imparting a non-uniform surface pressure of the abrasive surface against the second portion of the cutting edge.
In further embodiments, a sharpener has a flexible abrasive member that is moved by an electric motor and supported by at least a first support member along a neutral plane having opposing proximal and distal ends. The flexible abrasive member has a front side with an abrasive surface and a back side opposite the front side. A guide assembly is disposed adjacent the flexible abrasive member to support the cutting tool during a sharpening operation in which a cutting edge of the cutting tool is presented against the flexible abrasive member. The guide assembly has a side support surface to contactingly support a side surface of the cutting tool and an edge guide surface to concurrently contactingly support a first portion of the cutting edge of the cutting tool while a second portion of the cutting edge of the cutting tool is presented against a contact region of the abrasive surface. A platen member is disposed to contactingly support the back side of the flexible abrasive member between the proximal and distal ends of the neutral plane opposite the contact region. The platen member applies a biasing force to displace the flexible abrasive member toward the contact region beyond an initial tangential plane established by the first support member.
In yet further embodiments, a method for sharpening a cutting tool includes advancing a flexible abrasive member using an electric motor to move the flexible abrasive member along a neutral plane having opposing proximal and distal ends, the flexible abrasive member having a front side with an abrasive surface and an opposing back side contactingly supported by a first support member at the proximal end and contactingly supported by a second support member at a medial location of the neutral plane between the proximal and distal ends; placing the cutting tool into a guide assembly adjacent the flexible abrasive member to support the cutting tool during a sharpening operation in which a cutting edge of the cutting tool is presented against the flexible abrasive member, the guide assembly having a side support surface to contactingly support a side surface of the cutting tool and an edge guide surface to concurrently contactingly support a first portion of the cutting edge of the cutting tool while a second portion of the cutting edge of the cutting tool is presented against a contact region of the abrasive surface to deflect the flexible abrasive member out of the neutral plane; and drawing the second portion of the cutting tool across a width of the flexible abrasive member while the first portion of the cutting tool is contactingly supported by the edge guide surface, the second support member imparting a non-uniform surface pressure against the second portion of the cutting edge during the sharpening operation.
These and other features and advantages of various embodiments can be understood with a review of the following detailed description in conjunction with the accompanying drawings.
Generally, so-called slack belt sharpening techniques can be used to sharpen the cutting edge of a cutting tool, such as a knife, using a power-driven endless abrasive belt. One non-limiting example of a slack belt powered sharpener is provided in U.S. Pat. No. 8,696,407, assigned to the assignee of the present application.
As discussed more fully in the '407 patent, slack belt sharpening generally involves using an unsupported expanse of abrasive belt to contactingly engage a cutting edge of a knife or other cutting tool at an appropriate presentation (bevel) angle to deform a portion of the belt out of a neutral plane (e.g., a planar extent of the belt extending between a pair of belt supports, such as rollers). The deflection of the belt generally induces a small twisting effect in relation to curvilinear changes in the cutting edge along the length of the knife.
In this way, a user can draw the cutting edge across the moving belt and the belt will automatically adjust to follow the contour of the cutting edge as it removes material along the blade portion of the knife. By applying respective sharpening operations to opposing sides of the blade, a sharpened cutting edge can be efficiently produced.
While operable, one limitation that has been found with these and other forms of slack-belt sharpeners is a non-uniform amount of material removal along the length of the blade (e.g., so called material take off, or MTO rate). Certain types of cutting tools, such as kitchen (“chef”) knives, tend to have a curvilinearly extending cutting edge with relatively small amounts of curvature near a handle of the knife and increasingly greater amounts of curvilinearity near the tip of the blade. In such knives, it has been found that the unsupported segment of the belt can tend to remove too little material at the base of the blade near the handle, and too much material near the tip. One factor that induces this variation is the amount of deflection (twist) induced in the belt; generally, the greater the deflection, the higher the localized surface pressure and higher the corresponding MTO rate.
It follows that some belt sharpening operations can result in a rounding of the tip of the blade rather than retaining the tip as a sharp, well defined point, as well as incomplete sharpening of the cutting edge immediately adjacent the handle. While the user may be able to mitigate these and other effects through controlled presentation and withdrawal of the blade across the belt, various embodiments of the present disclosure present a number of operative features that can promote easier, more consistent abrasive belt sharpening that reduces such variations in surface pressure and corresponding MTO rates during a sharpening operation.
As explained below, such features include the use of what is collectively and/or variously referred to herein as “tilted angle abrasive belt sharpening.” Generally, tilted angle abrasive belt sharpening, also referred to as “modified slack belt sharpening,” refers to a novel sharpener configuration and methodology that purposefully induces a selected non-orthogonal alignment between the cutting edge of the knife or other cutting tool with respect to the abrasive belt in order to better control surface pressures and corresponding MTO rates across the width of the belt. A variety of different approaches can be used to achieve this tilted sharpening effect.
In some embodiments, a presentation angle of the knife or other cutting tool is fixed at a selected non-orthogonal angle with respect to the axis of one or more rollers along which the endless abrasive belt is driven. This may be carried out by tilting the belt path in a “backward” direction so that the top of the belt path is moved in a direction away from the user and using a substantially horizontal set of edge guides to support the presentation of the tool. Another way in which the non-orthogonal angle can be established is by skewing the presentation angle of the knife inwardly with respect to the belt. Yet another way the non-orthogonal angle can be established is through the use of a backing support member the supports the belt in the vicinity of the contact zone. These respective approaches can be combined or used individually.
In each of these cases, surface pressures and corresponding MTO rates are controlled to enhance the sharpening process. Depending on the configuration, greater surface pressures and higher MTO rates can be supplied to the front edge of the belt (e.g., closer to the user or adjacent a proximal end of the tool) and lower surface pressures and lower MTO rates can be supplied to the rear edge of the belt (e.g., farther from the user or adjacent a distal end of the tool).
These and other features and advantages of various embodiments of the present disclosure can be understood beginning with a review of
The exemplary sharpener 100 is configured as a powered sharpener designed to rest on an underlying horizontal 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 direct current (DC) battery pack, etc. Other forms of tilted angle abrasive belt sharpeners can be implemented, including hand-held sharpeners, non-powered sharpeners, etc. that employ the various features disclosed herein.
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 and power control module 104 includes one or more user operable switches (e.g., power, speed control, etc.) and power conversion circuitry to transfer electrical power to an electrical motor 106.
The motor 106 induces rotation of a shaft or other coupling member linked to a power transfer assembly (PTA) 108, which may include various mechanical elements such as gears, linkages, etc. which, in turn, impart rotation to one or more drive rollers 110. It is contemplated albeit not necessarily required that the drive roller 110 will rotate at a steady state rotational velocity during powered operation of the sharpener.
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 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 the 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 layers are shown more fully in
The exemplary arrangement of
Each segment 126, 128 is 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 the modified slack-belt sharpening operation. A specially configured support member that provides controlled support to less than the full width of the belt will be discussed below.
An abrasive belt axis is represented by broken line 138 and indicates 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 (identified in the drawing as Roller Axes 1 and 2).
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 edge guide surfaces that serve as plunge depth limiting surfaces to limit the distance the knife 130 can be lowered, or advanced, toward the belt 112. The surfaces define a retraction path 144 for the blade 134 as the user draws the cutting edge across the belt 112 via the handle 132 while drawing the cutting edge 136 in contacting engagement across the rollers.
The retraction path 144 is non-orthogonal to the abrasive belt axis 138. The intervening angle between lines 138 and 144 is referred to herein as a tilt angle, and is denoted in
A second angle, referred to herein as a bevel angle, is represented as angle B in
The magnitude of the tilt angle A can vary. In some embodiments, the tilt angle A as defined in
The magnitude of the bevel angle B can also vary. In some embodiments, the bevel angle B is selected to be in the range of from about 5 to about 15 degrees. The bevel angle generally determines the side geometry of the blade adjacent the cutting edge. For clarity, it will be appreciated that the conformal nature of the belt 112 will tend to impart a convex curvilinear shape to the side of the cutting edge rather than a flat “bevel” shape. Nevertheless, the term “bevel” is useful in generally denoting the relative orientation between the belt extent 126 and the blade 134.
The non-orthogonal tilt angle A is selected to reduce the deflection of the rear edge of the belt (e.g., that portion of the belt farthest from the handle) and to increase the deflection of the front edge of the belt (e.g., that portion of the belt closest to the handle). Tilting the belt with respect to the blade such as exemplified in
Referring again to
From
The particular configuration of the sharpener 100 (see
The relative tilt angle A between the guide 168 and the belt 112 is contemplated as extending from about 65 degrees to about 89 degrees, as indicated in
As noted above, an alternative way to define the non-orthogonal tilt angle A is to state that the retraction path line 144 is non-parallel with the associated roller axes that support the segment of belt against which the knife is drawn (see e.g., roller axes 110A, 114A in
The aforementioned edge surface 170 extends along the top of portion 168B. An inwardly facing guide surface 174 extends along portion 168A, and an outwardly facing guide surface 176 extends along portion 168C. Surfaces 170, 174 and 176 form a generally u-shaped channel, or guide slot, to accommodate the knife 160. The edge guide surface contactingly supports the cutting edge 166, and the opposing side guide surfaces can contactingly support the opposing sides of the blade 164. The relative elevation and orientation of the surfaces 170, 174 and 176 are selected with respect to the central axis 138 of the belt 112 (see
However, as further shown by the top plan view of
Further amounts of non-orthogonality can be supplied by combining the arrangement of
While the tilt belt arrangement of
A suitable low wear material may be used for stationary support members such as 190. Any number of contact shapes can be used (e.g., circular, oval, rectangular, etc). It is contemplated that the support member 190 and base 192 may be incorporated as a portion of the guide assembly used to support the cutting tool (see e.g., guide 168 in
As further illustrated in
As the belt serpentines over the pin and adjacent the tool, a greater surface pressure and a higher MTO rate are applied closer to the handle (front edge of the belt or to the right of centerline 196 in
In this way, the support member 190 contactingly engages the back side of the flexible abrasive belt 112 between proximal and distal ends of the neutral plane. This induces a non-uniform surface pressure along the cutting edge of a cutting tool during a sharpening operation against the contact region to provide a greater material take off (MTO) rate at one end of the cutting edge.
The relative presentation angle of the tool (see e.g., line 144 in
As shown in
As shown by
For example, in an alternative embodiment, each support member 200 has a tapered (e.g., frusto-conical) shape so that the support varies in a direction toward the rear edge of the belt. Other shapes can be used such as crowned rollers, etc. While the support rollers 200 extend across the full width of the belt 112, this is merely exemplary and is not limiting. In other embodiments, the support rollers 200 may extend less than a full width across the belt.
The roller axes 200A of the support rollers 200 are skewed inwardly from the front edge to the rear edge of the belt so as to be non-parallel with the roller axes 110A, 114A and 120A of the belt rollers 110, 114 and 120. The amount of skew of the support roller axes 200A can vary, but may be on the order of from about 5-15 degrees with respect to the belt roller axes 110A, 114A and 120A. This induces a localized increase in the surface pressure of the belt 112 upon each roller 200 toward the front edge, as depicted by force vectors 204 in
The force vectors 204 in
More specifically, this serpentine path 206 is caused by passage of the belt 112 over the skewed support roller 200, which induces a small amount of twist in the belt, with less belt deflection adjacent the front edge of the belt and greater belt deflection adjacent the rear edge of the belt. The belt continues to pass upwardly until the belt encounters the inward side of the knife blade 202. The belt contactingly engages this inward side to perform a sharpening operation upon a cutting edge of the blade. The blade then continues to pass upwardly to upper roller 114A (see
As the belt 112 engages the side of the knife blade 202, the belt induces a variable surface pressure as generally represented by force vectors 208 in
While the serpentine path 206 in
Accordingly, the rotatable support members 200 contactingly engage the back side of the flexible abrasive belt 112 between proximal and distal ends of the neutral planes. As with the stationary support member, this induces a non-uniform surface pressure along the cutting edge of a cutting tool during a sharpening operation against the contact region to provide a greater material take off (MTO) rate at one end of the cutting edge.
The sharpener 300 is a powered combination sharpener configured to rest on a horizontal base surface 301 during operation. As explained below, the sharpener 300 includes an endless abrasive belt that is driven along three rollers in a manner as discussed above in
An internal motor rotates the belt along the belt path. The motor may be mounted at the same tilt angle so that an output drive shaft of the motor is parallel to the roller axes and non-parallel to the horizontal direction. Alternatively, an internal linkage system can be used to link a horizontally disposed motor drive shaft to the non-horizontal roller axes. The sharpener further utilizes stationary guide slots with edge guide surfaces that are arranged in a horizontal fashion, as generally depicted in
Referring now specifically to
An endless abrasive belt 306 is partially enclosed by the housing 302. Linear extents 308, 310 of the belt are exposed adjacent corresponding guide slots 312, 314 (best viewed in
To sharpen a cutting tool such as a kitchen knife, the user activates the sharpener 300 using the switch 304. While facing the front side of the sharpener (e.g.,
The foregoing process may be repeated a suitable number of times, such as 3-5 times. This applies a primary sharpening operation to one side of the knife. The user then places the knife in the other slot (e.g., slot 314) and repeats. This completes the primary sharpening operation to the other side of the knife, producing a sharpened cutting edge. The tilt angle configuration of the sharpener will provide enhanced surface pressure and MTO control, and tip rounding will be avoided.
Continuing with
In some cases, the user may elect to perform a secondary sharpening operation upon the knife using the abrasive rod. This is carried out by placing the side of the blade against a selected one of the guide surfaces (such as the surface 324) to establish a desired orientation angle of the blade with respect to the rod 322. Once oriented, the user advances the blade along the rod while retracting the cutting edge thereacross, maintaining the angular orientation established by the guide surface. This can be repeated a number of times, such as 3-5 times, after which the process may be repeated using the other guide surface (e.g., surface 326). This applies a secondary honing operation to further sharpen the knife. In this way, the sharpening applied against the rod 322 is similar to sharpening applied using a steel-type sharpener.
In some cases, the primary sharpening angle applied to the blade by the belt 306 may be a first value, such as nominally 20 degrees, and the secondary sharpening angle applied to the blade by the rod 322 may be a second value, such as nominally 25 degrees. This allows the blade to be configured with a micro-beveled geometry to enhance sharpness and durability. Touch up sharpening may be applied using just the ceramic rod 322 as desired. Sharpening may be applied by the belt without the use of the ceramic rod.
As with the sharpener 300, the sharpener 400 is a powered sharpener configured to rest on a horizontal base surface 401 during operation. Generally, an endless abrasive belt is driven along a triangular belt path over three internally disposed rollers that are parallel with each other and are each tilted forward at a selected non-orthogonal angle with respect to the horizontal direction. An internal motor rotates the belt along the belt path, and includes an output drive shaft that is parallel to the roller axes and non-parallel to the horizontal direction. Guide slots are arranged with stationary, horizontal edge guide surfaces to provide non-orthogonal angles with respect to the belt roller axes.
With reference now to
An endless abrasive belt 406 is routed along a plurality of rollers, including rollers 408, 410. Opposing guide slots 412, 414 operate as before to enable a user to carry out modified slack-belt sharpening on opposing distal extents of the belt. An interior motor drive assembly 416 transfers rotational power to the drive roller 410 from the interior motor via a drive belt 418.
Powered sharpeners such as those discussed above will tend to generate and expel debris during the sharpening process. The debris may be in the form of fine chips or filings that are removed from the workpiece (cutting tool), as well as loose or spent abrasive particles from the abrasive surface. This combination of debris is commonly referred to as swarf.
The swarf is made up of small particles that can be both very hard and very sharp. A buildup of swarf can reduce the operational life and performance of the sharpener through such effects as abrasion of bearing surfaces, electrically shorting of components, etc. Loose swarf also tends to damage the workpiece through unintended secondary abrasion by particles collecting on guiding or clamping surfaces held in contact with the workpiece. These particles can be expelled from the machine resulting in a mess and damage of surrounding surfaces or equipment.
Accordingly, the sharpener 400 incorporates a swarf management system to direct the generated swarf away from the sharpening area and the user. Similar swarf management systems can be adapted into other powered sharpeners including the exemplary sharpeners 100, 200 and 300 discussed above.
As explained below, the swarf management system can be configured to include a number of internal cavities within the sharpener, an impeller fan that is driven by the motor to establish an internal airflow through these internal cavities, a number of magnets to collect magnetic swarf, and a filter material to filter out fine particulates and retain the accumulated swarf within the unit.
In the current embodiment, three cavities are designed to impart the desired flow rate, velocity and/or pressures to a volume of air being moved by the fan. These cavities are referred to as a grind cavity, a filter cavity and an exhaust cavity. The magnets are located in the filter cavity and serve to remove coarse magnetic swarf from the air flow and retain the magnetic swarf for storage. The filter forms the interface between the filter cavity and the exhaust cavity, and operates to remove both magnetic and non-magnetic particles that were not captured by the magnets.
The grind cavity is provided adjacent the sharpening operation. Airborne swarf is directed internally from the grind cavity into the filter cavity using an intake opening adjacent the fan. The intake opening is sized appropriately to provide high air velocity to keep the swarf suspended in the air flow.
The filter cavity ideally has a cross section substantially larger than the intake opening to allow for the air velocity to drop substantially. This permits the majority of swarf to fall out of the air flow and be retained by and/or adjacent the magnet(s). The magnet(s) are suspended and spaced apart to allow for a large accumulation of swarf.
The filter is of a sufficiently large surface area to provide for the desired flow rate as airflow passes from the filter cavity to the exhaust cavity. The filter is ideally place horizontally or on an incline above the magnets and filter cavity. This facilitates “self-cleaning” by dislodging particles with normal vibrations/movement of the sharpener where gravity will pull the dislodged particles down to be retained by the magnets. Other configurations can be used, however. The exhaust cavity terminates in a series of exhaust openings that enable clean airflow to exit the sharpener, such as at a rear side of the unit away from the user.
A hinged front cover 420 has been rotated to an open position to reveal various components of interest. The belt 406 is shown routed around the previously described rollers 408 and 410, as well as a third roller 422. Any number of rollers and belt path configurations can be used, including the use of a greater number or lesser number of rollers as desired. As noted previously, drive belt 418 extends from the drive assembly 416 to the drive roller 410, and the drive roller 410 in turn drives the belt 408 about the rollers 408 and 422.
The drive assembly 416 is shown in greater detail in
A segmented central opening 430 is provided between the impeller blades 428, the central hub 423 and the plate 426. This opening provides an entry point or inlet passageway for airflow that is directed into the housing 402 during rotation of the blades.
During a sharpening operation, rotation of the fan assembly 416 will draw an initial airflow into the grind cavity 432, as indicated by arrows 434. A portion of this airflow will be directed through the opening 430 in the fan assembly, as indicated by arrows 436. The location of the opening 430 proximate the sharpening guides 412, 414 will tend to ensure that a majority of the swarf generated by the sharpening process will be drawn through the opening.
Disposed within the housing 402 of the sharpener is a relatively large, elongated filter cavity 438. The airflow 436 exiting the fan assembly 416 passes into a first end of the filter cavity 438, as indicated by arrows 440. The increase in cross-sectional area from the opening 430 to the cavity 438 induces a reduction in airflow velocity and/or pressure, enabling heavier swarf particles to drop to a lower portion of the filter cavity.
Magnets 442 are located along the lower portion of the filter cavity to further attract and retain magnetic particles within the airborne swarf. While three (3) magnets 442 are shown, other numbers of magnets can be used, including arrangements that do not use any magnets. Other attraction and retention mechanisms for the swarf can be used as desired.
A filter membrane 444 extends along an interior of the housing 402 to form an upper boundary of the filter cavity 438 and a lower boundary of an exhaust cavity 446. As depicted in
It is beneficial if the rotational speed of the fan assembly 416 is greater than the speed of the abrasive 408. This permits the air velocity to be substantial larger than the velocity of loose swarf released during grinding. The fan may be driven by a separate motor than the grind motor. Alternatively, the system may utilize a speed change mechanism to increase the fan speed or reduce the abrasive speed.
The fan/motor may be located in any of the cavities in this process or externally at the exhaust location. The cavities may be have negative or positive pressure depending on the location of the fan. The design of the fan/impeller will be chosen to fit the application to account for suction, blowing, or mixed flow as shown. These and other considerations will readily occur to the skilled artisan in view of the present disclosure, and any number of different configurations can be designed based thereon.
The sharpener 500 is a steel-type sharpener with a user handle 502 with an outer grip surface 504 adapted to be grasped by the hand of the user. An abrasive rod 506 extends from a selected end of the handle 502. As best viewed in
The guide surfaces 508, 510 are configured to provide a line contact alignment of a side of the cutting tool, such a side of a blade of a kitchen knife. This allows a user to orient the tool at the guide angle, and then advance the cutting edge along an abrasive surface 512 of the abrasive rod 506 while nominally maintaining the blade at the established guide angle. The rod 506 may be rotatable with respect to the handle 502 to allow different abrasive surfaces arrayed about the outer surface of the rod to be aligned with the respective guide surfaces 508, 510.
In this way, once a tool has been sharpened using a powered sharpener (e.g., the sharpener 400), a final honing operation can be supplied to the cutting edge using the manual sharpener 500. The angle(s) of the guide surfaces 508, 510 may be greater than the angle of the guides 412, 414 in the powered sharpener 400 to impart a micro-bevel sharpening geometry to the cutting tool. In one example, the guides 412, 414 may apply an angle of about 20 degrees to the side of the blade adjacent the cutting edge, and the guide surfaces 508, 510 may provide a micro-bevel region adjacent the cutting edge of about 25 degrees.
As shown in greater detail in
The cold forging member 520 is characterized as a knurl roller and is mounted for rotation within the handle 502 about a roller axis 522 at a suitable angle relative to the central longitudinal axis 514, as discussed below. The knurl roller 520 comprises a hard cylindrical member made of metal or other suitable material with a projection pattern about an exterior circumference thereof configured to be transferred to a corresponding workpiece upon the application of force thereto.
As further shown in
The knurl roller 520 forms a series of recessed channels, or notches, into a cutting edge of a tool using a cold forging process (also referred to as a roll forming process). As shown in
The blade 530 is advanced along the insertion plane established by the slot so that the cutting edge 532 contactingly engages the roller 520 via contact force F, as depicted in
The surface pressure imparted by the teeth 526 forges (deforms or displaces) the material of the blade 530 to form spaced apart projecting channels 538 along the length of the cutting edge 532. Depending on the angle θ, the magnitude of the force F and the respective material configuration of the blade and the roller, the displaced material may project beyond one or both sides of the blade. This deflected material can be maintained on the blade, or a secondary honing operation using a suitable abrasive (such as the abrasive rod 506 or belt 406) can be applied to remove the displaced material and substantially align the channel wall with the exterior tapered surfaces of the blade.
In this way, a plurality of spaced apart channels can be formed in the sharpened cutting edge by contactingly engaging the sharpened cutting edge with the cold forging member with sufficient force to displace portions of the sharpened cutting edge. This provides the channels as locally deformed, work hardened notches.
An advantage of the use of a cold forging process to form the channels is the quick and easy manner in which the features can be generated. A single pass of the blade against the knurl roller 520 (or other forging member) while applying moderate force upon the blade may be sufficient in most cases to form the respective channels. Although the applied force is light, the resulting surface pressure is relatively high because only a single projection, or a few projections, are in contact with the blade at any given time, and the projections are so small that the applied pressure is high. Secondary honing can be applied with a single or a few strokes of the blade against the abrasive rod 506 to remove the displaced material. Substantially any knife or other cutting tool can be subjected to this processing. Another advantage of cold forging is that, depending upon the material, the metal of the blade in the vicinity of the channels will tend to be work hardened, thereby providing localized zones of material with enhanced hardness and durability as the material is locally deformed.
To the extent that subsequent passes are required to re-form the channels during a subsequent resharpening operation, the knurl roller 520 will tend to align with the existing channels 538 so that the channels are formed in the same locations during subsequent cold forging passes. Such alignment has been found to occur because the distal ends of the knurl teeth 526 tend to engage the existing channels as the cutting edge 522 is drawn across the roller 520. Once engaged, the roller 520 will turn in a keyed fashion to the previously embossed pattern of channels. Any number of rollers can be concurrently applied to the blade to form different channel patterns.
In another embodiment, the blade 530 can be held stationary and the roller 520 can be rollingly advanced therealong to form the channels 538. Motive power can be applied to the blade 530 and/or the roller 520 during the channel forming process as desired. While
Stated another way, the channels 556 in
This honing operation may be carried out as follows. With reference again to
The blade 540 retains an effective sharpness for a significantly longer time as compared to the pristine fine edge configuration of
As will be recognized, it is often desirable to provide a specific shape to the bevel surfaces of a blade or other cutting tool during a sharpening operation. Convex angles can be achieved by sharpening against an unsupported or partially supported segment of an abrasive belt as discussed above. Using an unsupported extent of the belt generally allows the belt to deflect at a curvature and imparts that curvature to the side of the blade adjacent the cutting edge. As discussed above, the unsupported belt can be combined with a tensioner system, angle guide, and edge stop to accurately position the blade while providing a desired maximum sharpening force.
While being suitable for most blades and applications it is often desirable to impart other shapes such as flat or concave (hollow) grinds to the bevel. In these cases a shaped support surface, or platen assembly such as the assemblies 602 in
Some embodiments involving the platen assembly include a moving abrasive belt powered by an electric motor. The belt is support by a spring loaded member that provides an opposing sharpening force. The force is limited by providing a limit stop within the desired spring travel of the platen. In order for the platen to provide a specific shape to the belt it is further intended to operate in a position between two supports (rollers) and bias the belt outside of a “tangent” plane tangent to both pulleys. When the blade is inserted, the platen is allowed to move toward, and possibly up to, the tangent plane. The travel is limited by a depth limit stop to insure the belt doesn't deflect beyond the tangent plane thereby; limiting the maximum force applied and ensuring the belt is still in conformance to the platen so than the desired bevel shape is imparted to the blade.
Referring again to
The shaft 612 passes through an aperture in the associated base 606 (
The head 610 in
The flat platen surface 614 generally operates to apply a flat grind geometry to the sides of the blade in the vicinity of the cutting edge during a sharpening operation.
Because of the additional support supplied to the underside of the belt 406 by the respective platen assemblies 602, it is contemplated that enhanced heating due to friction may be generated during the sharpening assembly. As desired, air cooling fins 616 may be applied such as shown in
The housing houses an interior, transverse mounted electric motor (not separately shown). A user activated trigger or activation button 708 can be applied to control the rotation of the motor.
A sharpening assembly 710 is attached to the housing and includes an abrasive belt 712 that is routed along a belt path that passes about a drive roller 714 and a pair of idler rollers 716, 718. While three (3) rollers are shown, any suitable number of rollers can be used including less than, or more than, three rollers. As before, the belt path provides a pair of opposing tangent (planar) extents against which a cutting tool can be sharpened using opposing guides 720, 722. The sharpening guides 720, 722 are mirrored and both impart a common grinding angle to the cutting tool, such as nominally 20 degrees. A third sharpening guide 723 can also be provided to sharpen at a different angle, such as nominally 60 degrees. The guides 720, 722 may be suitable for knives and the like, and the guide 723 may be suitable for sharpening scissors and the like. The upper idler roller 716 is configured as a tensioner roller with a biasing member 724 to maintain a desired tension in the belt 712 as the belt is deformed out of the associated extent during sharpening.
The sharpener 700 includes a platen assembly 730 adjacent the sharpening guides 720, 723. An opposing, second platen assembly can be supplied adjacent the sharpening guide 722, although such is not depicted in
The respective rollers 806, 808 and 810 are supported by an interior frame 814. The frame 814 maintains the rollers in the relative fixed positions shown in the figures, as well as supporting a moveable angle guide 816. The edge guide is adjustable to enable an edge guide surface 818 to be fixed relative to a tangent (planar) extent of the belt 804 between rollers 806 and 808 to effect a sharpening operation on a cutting tool.
A platen assembly 820 is mounted to the frame 814. The platen assembly 820 comprises an elongated flexible plate 822 configured to extend along and support the back side of the belt 804 along the planar extent adjacent the angle guide 816. The plate 822 includes opposing ends 824, 826 that are affixed to the frame 814. The attachment of the opposing ends 824, 826 may be about respective shafts 828, 830, as generally represented in
An adjustment mechanism 832 is secured between a medial portion of the plate 822 and the frame 814. The adjustment mechanism 832 includes a threaded shaft 834 and a user rotatable nut 836. A distal end of the shaft 834 is attached to a medial portion of the plate 822 via a coupling 838. User rotation of the nut 836 advances or retracts the distal end of the shaft 834, which in turn adjusts the profile of the plate 822 along the belt 804 by increasing or decreasing the length of the shaft. A substantially flat configuration for the plate is shown in
A platen assembly 900 can be utilized on one or both sides of the belt path. The platen assembly 900 provides biased support to the back side of the belt 112 during a sharpening operation and includes a curvilinearly extending platen or plate 902 bounded by rollers 904, 906. A biasing mechanism 908 such as in the form of a coiled spring exerts a biasing force between the plate 902 and a stationary support 910. In this way, the plate 902 is urged forward in the manner shown. Other configurations may provide a stationary plate or a fixed position plate as discussed above such as in
As discussed previously, broken line 911A represents a tangential plane for the abrasive belt 112 that would be provided in the absence of the platen assembly 900, as represented on the right-hand side of the drawing between support members 114 and 120. The platen assembly 900 thus advances the flexible abrasive belt 112 beyond this tangential plane to provide a neutral plane with segments 911B, 911C and 911D.
As best shown in
The tray 922 includes a groove, or sharpening channel 924 to contactingly engage and orient a given cutting tool, and a cold forging member such as the knurl roller 520 discussed above in
A sharpening zone or contact region is denoted at 936, which generally represents an area against which a cutting tool may be applied to carry out a sharpening operation thereon as the disc is rotated in direction 938. Other locations on the disc surface for the sharpening zone, and other directions of rotation, can be used.
In some embodiments, the abrasive layer(s) may take the general form of sandpaper, diamond overcoat, a matrix file pattern, etc. with a random or regular abrasive media pattern. The backing layer 942 may be cloth, paper, thin metal, or some other construction. In some embodiments, no separate backing layer is used. It will be appreciated that the abrasive layer 940 forms the front side of the disc 930 and the backing layer 942 forms the opposing back side of the disc in
The shaft 956 has a diameter sized to closely fit within the central aperture of the disc, and the disc is secured to the shaft via a support member (hub) 958. Other disc attachment arrangements can be used, including multiple spaced apart discs and multiple hubs, clamping systems that clamp the disc with a smaller (or no) central aperture extending through the disc, etc.
The attachment mechanism, in this case the hub 958, maintains the innermost periphery of the disc 930 in a fixed position along the shaft 956 (e.g., a selected distance from the motor 952) both while at rest and during rotation.
The flexible nature of the disc 930 may allow the disc to deform under the weight thereof into a non-linear orientation while the disc is at rest, as depicted in
Presentation of a cutting tool for sharpening against the disc 930 during rotation induces localized curvilinear displacement of the disc out of the neutral position. The type and extent of curvilinear displacement can vary depending on a variety of factors including presentation angle, surface pressure, angular and radial location of the contact region 936, and stiffness of the disc.
In the configuration of
It will be noted that the stationary support member 964 can alternatively be configured to be collinear as in
It some embodiments, a pair of abrasive discs 930A, 930B can be arranged to enable double sided sharpening operations, as generally illustrated in
A powered sharpener 980 is shown in
In
It will now be appreciated that the various embodiments presented herein can provide a number of benefits over the prior art. In embodiments that provide a non-orthogonal alignment angle, a differential deflection can be induced across the width of the belt with respect to the blade being sharpened. This provides a more uniform surface pressure and MTO rate against the side of the blade along the length thereof and tends to reduce increases of surface pressure at points along the cutting edge that experience relatively large amounts of variation of curvature, such as points adjacent the tip of the blade. As noted above, this non-orthogonal “tilt angle” belt sharpening can be carried out by enacting one or more of a tilt angle B (see e.g.,
In some embodiments, different belts and discs having different abrasiveness levels and linear stiffness levels can be successively applied to the tool to provide a more complex sharpening process. For example and not by limitation, in one embodiment a first relatively stiffer, higher abrasive belt can be installed to provide a relatively coarse level of sharpening to the knife in which relatively more material is removed therefrom, followed by installation of a second, relatively less stiff belt with a more fine level of abrasive can be installed to provide a honing operation. The differences in stiffness can provide different levels of contour to the final blade geometry.
In further embodiments, sharpeners can be configured to employ a swarf airflow management system to remove swarf and enhance cooling of the sharpening operation; a secondary manual sharpening operation can be provided for honing, and this can include the generation of recessed notches to enhance cutting edge performance; and a biased platen assembly can be provided to further adjust various sharpening geometries.
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 is a continuation of copending U.S. patent application Ser. No. 15/919,850 filed Mar. 13, 2018, which issues as U.S. Pat. No. 10,814,451 on Oct. 27, 2020, which is a continuation-in-part of copending U.S. patent application Ser. No. 15/676,722 filed Aug. 14, 2017, which in turn is a continuation in part of copending U.S. patent application Ser. No. 15/430,222 filed Feb. 10, 2017, issued as U.S. Pat. No. 9,731,395 on Aug. 15, 2017 and which claimed domestic priority to U.S. Provisional Patent Application No. 62/294,351 filed Feb. 12, 2016, the contents of which are hereby incorporated by reference.
Number | Date | Country | |
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62294351 | Feb 2016 | US |
Number | Date | Country | |
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Parent | 15919850 | Mar 2018 | US |
Child | 16949375 | US |
Number | Date | Country | |
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Parent | 15676722 | Aug 2017 | US |
Child | 15919850 | US | |
Parent | 15430222 | Feb 2017 | US |
Child | 15676722 | US |