Cutting tools such as knives are used in a variety of applications to cut or otherwise remove material from a workpiece. 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 that intersect along a line that lies along the cutting edge.
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 systems are known in the art, including but not limited to grinding wheels, whet stones, abrasive cloths, abrasive belts and sharpening steels.
Various embodiments of the present disclosure are generally directed to an apparatus and associated method for sharpening a cutting tool, such as but not limited to a kitchen knife.
In accordance with some embodiments, a method includes placing a selected side surface of the tool in contacting engagement against an upper reverse sharpening guide surface to orient the tool at an acute angle with respect to an abrasive surface. The abrasive surface extends in a lateral direction from a first end to a second end along a first plane, and the upper reverse sharpening guide surface is located proximate the first end and aligned along a second plane that intersects the first plane at the acute angle. The cutting edge contactingly engages a non-abrasive support surface disposed between the upper reverse sharpening guide surface and the first end of the abrasive surface to establish a plunge depth of the tool prior to contact with the abrasive surface. The tool is thereafter moved away from the upper reverse sharpening guide in said lateral direction toward the second end while nominally maintaining the tool at the acute angle. In this way, the cutting edge of the tool disengages the non-abrasive support surface and moves along the abrasive surface from the first end toward the second end for sharpening thereagainst in a trailing cutting edge orientation.
These and other features and advantages of various embodiments can be understood with a review of the following detailed description and the accompanying drawings.
The present disclosure is generally directed to an apparatus and method for sharpening a cutting tool. As explained below, a reverse sharpening guide arrangement is used to orient a tool prior to advancement of the tool along an abrasive surface to sharpen a cutting edge of the tool. The reverse sharpening guide is configured such that the tool is “pulled” across the abrasive surface, rather than “pushed” across the abrasive surface as is commonly employed in existing designs. During sharpening in accordance with the present disclosure, the tool is oriented so that a top surface of the tool opposite the cutting edge precedes the cutting edge with respect to the abrasive surface.
The reverse sharpening guide may be disposed below an elevation of the abrasive surface so that the tool is moved upwardly in sliding engagement along a guide surface of the reverse sharpening guide prior to engagement with the abrasive surface. Alternatively, the reverse sharpening guide may be disposed above an elevation of the abrasive surface so that the tool is placed against the guide surface and then laterally advanced away from the guide surface and across the abrasive surface.
In both cases, the abrasive surface is generally subjected to a tension force proximate the cutting edge, rather than a compressive force, and the tool is oriented in a trailing cutting edge orientation so that the cutting edge is pointing away from the direction of movement. This reduces a likelihood that the cutting edge will cut or otherwise damage the abrasive surface. While the abrasive surface may be locally deformable, enhanced sharpening efficiencies may be achieved even with the use of rigid abrasive members since material removed from the tool in the vicinity of the cutting edge is drawn away from, rather than pushed into, the tool.
These and other features of various embodiments can be understood beginning with a review of
The guide member 14 is configured to enable a user to orient a cutting tool 18 prior to a sharpening operation. The cutting tool may take the form of a knife or similar tool, and includes an elongated blade portion 20 that terminates in a cutting edge 22. To orient the cutting tool 18, the user places a side surface 24 of the blade portion 20 in contacting engagement with an angled guide surface 26 of the guide member 14. The guide surface 26 presents the tool 18 at an obtuse angle β with respect to the abrasive surface 16, as shown in
Once the tool 18 has been placed against the guide surface 26, the user advances the tool 18 away from the guide surface 26 and along the abrasive surface 16 while nominally maintaining the tool 18 at the desired sharpening angle established by the guide surface 26. The user may apply moderate pressure to the tool 18 during the sharpening process to enable grit in the abrasive surface to remove and/or align material of the blade portion 20 to sharpen the cutting edge 22.
While operable to improve the alignment of the cutting edge 22 and hence, to sharpen the tool 18, the guide surface 26 places the tool in a leading cutting edge orientation so that the cutting edge 22 is pointing in the direction of movement and is the closest part of the tool to a distal end 28 of the abrasive surface 16.
This leading cutting edge orientation generally tends to place the abrasive surface 16 into compression as the cutting edge 22 is pushed into the abrasive surface. Relatively flexible abrasive media such as leather, cloth, sandpaper and other paper-backed media, etc. may be damaged and/or cut by the cutting edge 22, as represented in
The sharpening member 102 includes an abrasive surface 108 arranged along a top of the block of material. Without limitation, in some embodiments the sharpening member 102 may comprise a rigid metal, plastic or glass substrate, a compressible or semi-compressible foam block, a paper substrate, an elastomeric layer of material, etc. The abrasive surface 108 may be a coating of abrasive of selected grit affixed to or supported by the underlying block, a layer of sandpaper or other abrasive media supported by the underlying block, etc.
The abrasive surface 108 in
It will be noted that the guide surface 112 is generally disposed below the elevational location of the abrasive surface 108; that is, guide surface 112 is located below the first plane 110. For clarity, such arrangements are referred to herein as “lower reverse sharpening guides.”
The lower reverse sharpening guide 104 is arranged to allow a user to orient the cutting tool 116 in a desired angular orientation prior to a sharpening operation thereon. To align the tool 116, a selected side surface, in this case side surface 120, is brought into contacting abutment against the guide surface 112 as shown.
Once the tool 116 has been aligned, the tool is slidingly advanced upwardly along the guide surface 112 while maintaining the tool in the established angular orientation set by the guide surface 112. Once the tool 116 is advanced up onto the abrasive surface 108, as depicted in
The user moves the tool in this manner while applying moderate force to the tool to maintain contact between the cutting edge 124 and the abrasive surface 108 and to nominally maintain the tool 116 at the acute angle established by the guide surface 112. This places the cutting edge 124 in a trailing cutting edge orientation so that the cutting edge 124 is pointing away from the direction of movement as the tool 116 is pulled across the abrasive surface 108. Stated another way, the lateral distance from the top surface 126 of the blade portion 118 to the second end 108B of the abrasive surface is consistently smaller than the lateral distance from the cutting edge 124 to the second end 108B (e.g., the top surface 126 is maintained closer than the cutting edge 124 to the distal end 108B as the tool 116 is advanced toward the distal end).
The trailing cutting edge orientation tends to place the abrasive surface 106 under linear tension, as generally represented in
The sharpener 130 as oriented in
While not all of the above stages are fully visible in
For reference, aspects of the first stage 132 visible in
While not necessarily limiting, it is contemplated that the fourth stage 138 uses a leather strop as the abrasive member 150. This allows the fourth stage to provide a final stropping of the tool in a trailing cutting edge orientation following one or more sharpening operations from the prior stages using a leading cutting edge orientation for the tool. It will be appreciated, however, that any or all of the other stages could alternatively be configured to also provide the respective sharpening operations with a reverse sharpening guide and a trailing cutting edge orientation for the tool as discussed above.
As before, the abrasive surface 174 has opposing proximal and distal ends 174A, 174B along a lengthwise (lateral) direction, and the abrasive surface 174 is aligned in this lateral direction along a first plane denoted by dotted line 180. The reverse sharpening guide 178 includes a guide surface 182 that is aligned along a second plane (dotted line 183) that intersects the first plane at an acute angle θ1. In this case, the guide surface 182 is substantially located above the elevational location of the abrasive surface 174, so that sharpening guides having a configuration such as at 178 are referred to herein as “upper reverse sharpening guides.”
A cutting tool 184 includes opposing side surfaces 186, 188, a front surface 189 and a cutting edge 190. The cutting edge 190 can be sharpened against the abrasive surface 174 by placing the side surface 188 in contacting engagement with the guide surface 182 to set a desired acute angle of the tool 184 relative to the abrasive surface 174. The user thereafter laterally advances the cutting tool 184 away from the guide surface 182 while maintaining the tool nominally at the acute angle established by the guide surface 182. This presents the tool 184 in a trailing cutting edge configuration as discussed above.
At this point it will be noted from
It follows that the acute angle θ1 between the first and second planes 180, 183 in
Continuing with
The tool 184 depicted in
As before, the abrasive member can be rigid, semi-rigid, compressible, etc. In some cases, high density “shoe leather” can be used with micron sized loose diamond grit to provide frequent touch-up honing for hard use blades such as plane irons, etc.
The sharpening member 202 can be a laminate formed from a first block 208 affixed to a second block 210. The first block 208 has a first abrasive surface 212, used as depicted in
A planar abrasive medium 228, such as sandpaper, is affixed to the base support structure 222, such as by inserting a proximal end 230 of the medium 228 into a corresponding securement slot 232. In this way, different grits of abrasive can be used to provide multi-stage sharpening, and worn media can be readily replaced. As desired, different foam densities can be used for the support block 226 when sharpening with different grits to alter the radius of deflection of the medium 228. A shape, sharpen, hone and strop progression can be provided by using successively less aggressive abrasive and more compressive support block combinations.
The sharpening system 240 includes a lower reverse sharpening guide surface 244 and a planar abrasive surface 246. The knife 242 includes a handle 248, blade 250, curvilinearly extending cutting edge 252 and a top surface 254 opposite the cutting edge 252.
As can be seen from the sequence of
Next, the user draws the blade 250 upwardly along the guide surface 244 while maintaining the desired angular orientation of the blade 250, and then advances the blade 250 along the abrasive surface 246 toward a distal end thereof in a manner generally discussed above. Because of the curvilinear nature of the cutting edge 252, the user may rotate the knife 242 to bring different portions of the cutting edge 252 into contact with the abrasive surface 246 while maintaining the desired angular orientation of the blade 250. In this way, the user may move the knife 242 laterally (i.e., along the length of the abrasive surface), longitudinally (i.e., retracting along the length axis of the tool) and rotationally (i.e., about a center point near the junction of the handle 248 and the blade 250).
An abrasive member 304 extends from the main body portion 302. The abrasive member 304 takes a generally rectilinear shape and includes opposing top and bottom abrasive surfaces 306, 308. The abrasive member 304 has a first (proximal) end 310 adjacent the main body portion 302 and an opposing second (distal) end 312.
First and second reverse sharpening guide surfaces 314, 316 extend from the main body portion 302 adjacent the proximal end 310 of the abrasive member 304. As depicted in
More specifically, during a sharpening operation the user may grasp the main body portion 302 in a first hand, grasp a handle portion (not shown) of the tool 318 in a second hand, insert the tool 318 so as to be in contacting engagement against a selected one of the guide surfaces 314, 316 to set the angular orientation of the tool 318, and then advance the tool 318 along the respective abrasive surface 306, 308. Longitudinal and rotational manipulation of the tool may be carried out in a manner similar to that discussed above in
The rod has opposing proximal and distal ends 326, 328 with the proximal end 326 affixed to the main body portion 322. Reverse sharpening guide surfaces 330, 332 are disposed adjacent the proximal end 326. Sharpening of the tool 318 is carried out in similar fashion as discussed above. It will be noted that, although the abrasive rod 324 is cylindrical, the upper and lower portions thereof are aligned along respective planes and the respective guide surfaces 330, 332 form acute angles with these planes as before. It follows that while the abrasive member extends along a selected plane in a lengthwise direction, the abrasive surface itself need not necessarily be rectilinear or otherwise flat in a direction normal to this lengthwise direction (such as, e.g.,
At step 402, an abrasive surface with opposing first and second ends is aligned along a first plane. By way of illustration and not limitation, this is discussed above including in
At step 404, a reverse sharpening guide is arranged adjacent the first end of the abrasive surface, with the reverse sharpening guide having a guide surface aligned along a second plane that intersects the first plane at an acute angle. This is exemplified including by but not limited to lower reverse sharpening guide 104 in
At step 406, a side of a tool is placed in contacting engagement against the guide surface to orient the tool at the acute angle with respect to the abrasive surface. This is illustrated including in
A sharpening operation is thereafter carried out at step 408 by moving the tool away from the guide surface and along the abrasive surface toward the second end of the abrasive member while maintaining the tool at the acute angle. This is in a trailing cutting edge orientation so that a top surface of the tool opposite the cutting edge is maintained closer to the second end of the abrasive member than the cutting edge. This is illustrated including in
It will be appreciated that steps 406 and 408 can be repeated a suitable number of times in succession, such as 3-10 times. In some cases, longitudinal and/or rotational movement of the tool will be carried out by the user during step 408. In further cases, multiple sides of a tool will be sharpened, such as by reversing the orientation of the tool and using the same guide surface, or by using opposing pairs of guides.
The sharpening systems as embodied herein can be configured to provide certain advantages and benefits over sharpeners in accordance with the related art. While not necessarily required, flexible abrasives such as leather, sandpaper, rubberized media, etc. can be safely used without a likelihood of damage to the abrasive media since the cutting edge is pointed away from the direction of movement. Using locally deformable media can also support the sharpening of curvilinear concave surfaces on the sides of the tool adjacent the cutting edge (such as shown in, e.g.,
Using a trailing cutting edge orientation for the tool further reduces a likelihood of injury to the user during the sharpening operation. If the user slips and the tool inadvertently moves quickly away from the media as a result of the applied pressure to the tool, the cutting edge will tend to be pointing away from the direction of movement of the tool. Thus, there is a reduced likelihood that the cutting edge will injure the user or another nearby party.
As used herein, the term “acute angle” and the like will be defined consistent with the foregoing discussion as the angle between the tool and the abrasive surface with respect to the direction of movement of the tool, such as illustrated including in
Various additional alternatives and configurations will readily occur to the skilled artisan after reviewing the present disclosure, and all such alternatives and configurations are encompassed by the present application and the following claims.
The present application is a divisional of co-pending U.S. patent application Ser. No. 14/026,848 filed Sep. 13, 2013, which issued on Jul. 29, 2014 as U.S. Pat. No. 8,790,162.
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Number | Date | Country | |
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20150079880 A1 | Mar 2015 | US |
Number | Date | Country | |
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Parent | 14026848 | Sep 2013 | US |
Child | 14444652 | US |