The present invention relates generally knife sharpeners and more particularly to an adjustable sharpening apparatus for cutting implements.
Available knife sharpening systems typically include a hand-held sharpening hone or block and a clamp used to hold a knife in a fixed position. In the art of knife sharpening, it is desirable to have the same angle between the hone or block and each side of the knife blade. The difficulty in doing so by hand resulted in the advance of clamps to hold a knife blade in a fixed position.
With the knife blade held in a clamp, the user slides the sharpening block at an angle across each side of the cutting edge of the knife. For a consistent angle on both sides of the knife blade, sharpening blocks may be attached to a rod that extends from the base of the clamp. Current knife sharpening clamps rely on a pivot screw that extends between an upper portion of the clamping members to define a pivot point between the clamping members. A spreading screw extending between the bottom of the clamping members is adjusted to spread apart the lower portions of the clamping members, causing the upper portions of the clamping members to pivot about the pivot screw and pinch together to clamp a knife blade.
In many configurations, one of the clamping members remains in a fixed position relative to the knife blade while the other clamping member pivots during adjustment of the pivot screw and/or the spreading screw.
U.S. Pat. No. 7,144,310 to Longbrake also discloses an adjustable knife sharpener apparatus. The apparatus includes a clamping mechanism having a first clamp member and a second clamp member. The first and second clamp members include first and second jaws, respectively, for securing a knife blade. The first and second clamp members are held together with a screw or other fastener. The screw extends through an aperture in the first clamp member and is threadably received in a tapped bore located in the second clamp member. A thumbscrew is threadably received in a tapped bore located in the first clamp member. An end of the thumbscrew bears against a surface of the second clamp member and is received in a dimple or complementary depression to move the first and second clamp members relative to each other. Adjusting the thumbscrew increases or decreases the separation of the first and second jaws as needed to hold the knife blade.
U.S. Pat. No. 4,512,112 to LeVine discloses a sharpener clamp comprising a pair of L-shaped clamp members. Ends of the first and second clamp members are brought together to clamp the spine of a knife with the blade extending from clamping members. A sharpening stone is attached to a guide rod that extends through an opening in the base of one or both clamp members. The user moves the guide rod in a reciprocating motion through the opening with the sharpening stone against the blade to sharpen the knife's cutting edge.
The prior art clamping mechanisms of knife sharpeners have several disadvantages. Prior-art sharpeners lack the portability required for field use while also providing the precision sharpening performance of a bench sharpener. Portable knife sharpeners of the prior art are generally flimsy, are not adjustable, and do not adequately sharpen a cutting edge with a consistent, repeatable angle between the hone and the blade. For example, some prior-art knife sharpeners have sharpening stone attached to a guide rod, but the sharpener is designed for use at home or in a workshop where the clamping members are secured to a base or are attached to a stable surface. In many cases, the base of the sharpener is large and heavy to provide stability to the sharpener during use. Additionally, the sharpener assembly may be sized and configured for use atop a bench or table. As such, hunters, outdoorsmen, and tactical teams lack a portable sharpener for use while away from the conveniences of home or a workshop and that delivers a precision cutting edge to cutting tools.
Another deficiency of the prior-art sharpeners is the difficulty in clamping knife blades with non-uniform thickness along the spine. The inside faces of the clamping members in prior-art sharpeners do not mate well with the spine of the blade. Accordingly, the poorly-clamped blade tilts to one side, resulting in the cutting edge being no longer perpendicular to the base and causing opposite sides of the blade have different sharpening angles. The user must measure the difference in angles and compensate for the angle change when sharpening opposite sides of the knife blade. If these angles are not accounted for by the user, the knife blade is sharpened with uneven angles on each side of the blade.
A further deficiency of prior-art clamping devices in sharpeners is that one side of the clamp has a permanent, fixed position. This fixed position assumes a pre-determined thickness of the knife blade for the cutting edge that is aligned along the centerline of the clamp. For blades having a thickness that is different than the predefined thickness of the clamp, the cutting edge is not aligned with the centerline of the clamp. This again results in unequal sharpening angles on each side of the knife blade.
Additional disadvantages result from using screws to define the pivot point and to separate the ends of the clamping members. Screw adjustments require the user to have additional tools to operate and adjust the clamp. Also, the screws often protrude beyond the outside faces of the clamping members, limiting the minimum angle at which the sharpening abrasives can contact the knife blade. Further, clamping mechanisms with screws require several steps to clamp and unclamp a knife blade, which takes extra time.
Additional deficiencies of prior art sharpeners result from the configuration of guide rods that hold the sharpening stone. Some designs lack the ability to securely fix a guide rod in an adjustable fixed position where the guide rod is coupled to a stable base with a clamping mechanism. The prior art designs also lack the ability to repeatedly and verifiably control the depth and alignment of the knife blade with respect to the clamping mechanism and the sharpening blocks.
Further, prior art knife sharpeners are also flimsy, limited in adjustment, and have no way to sharpen a cutting edge with a consistent, repeatable angle between the hone and the blade. Prior art sharpeners also lack the ability for the user to finely adjust or determine the sharpening angle with the desired level of accuracy. Currently-available sharpeners also lack the ability to precisely achieve a sharpening angle below ten degrees as required for Japanese knives and the like.
Still further, existing sharpeners generally lack the ability to sharpen complex cutting edges, such as found on sport knives and barber's shears. Due to the complex cutting edge profile, the user resorts to guessing, becoming so adept at sharpening by hand that the process becomes somewhat precise, using an expensive professional sharpening service, or purchasing a very expensive machine designed to sharpen implements with complex cutting edge profiles.
Accordingly, a need exists for improvements in knife sharpeners, including a clamping mechanism that provides better clamping of knife blades of various thicknesses and shapes. A need also exists for a sharpener useful with a variety of different cutting implements and that provides controlled, adjustable, and repeatable sharpening angles from one sharpening session to the next. A need further exists for a precision sharpener designed for field use.
One aspect of the present invention is directed to a knife sharpener that can be disassembled to a compact form and transported for use in the field.
In one aspect of the present invention, a sharpening apparatus has components securable to a base using mating or interlocking structures on the base and the components. In one embodiment, a sharpening apparatus includes a base having a top surface that defines a longitudinal channel or a mounting rail. A clamping assembly is releasably securable to the base using the channel or rail. When secured to the base, the clamping assembly includes a pair of jaws extending substantially perpendicularly upward from the top surface in opposed alignment and with distal ends adjustably spaced to grip a cutting implement therebetween. The apparatus includes one or more angle adjustment assembly securable to the base with a position adjustable along the channel or mounting rail. Each angle adjustment assembly has a bracket and a rod receptacle pivotably attached to the bracket. A guide rod extends longitudinally between a first rod end portion and a second rod end, where the first rod end portion is constructed to be releasably secured to the rod receptacle. The sharpening apparatus is constructed to be reversibly assembled with the clamping assembly secured to the base, the angle adjustment assembly secured to the base and adjustably spaced from the clamping assembly, and the first rod end portion secured to the rod receptacle.
In some embodiments, the channel is a T-slot. In another embodiment, the channel is a T-slot and each bracket substantially has an L shape with an upright portion, a horizontal portion joined to the upright portion, and a protrusion on a bottom of the horizontal portion, where the protrusion shaped to mate with and slide along the T-slot.
In some embodiments, the mounting rail is a Picatinny rail or the like. In other embodiments, the rail has a T-shape and each bracket defines a T-shaped channel in a bottom surface to mate with and slide along the rail. In some embodiments, the bracket has a fastener configured to releasably tighten the bracket to the rail.
In another embodiment, the base further defines at least one rod storage slot constructed to receive and retain the guide rod. In some embodiments, the rod storage slot includes a deformable member adjacent an inside surface of the rod storage slot, where the deformable member is constructed to frictionally engage the guide rod and maintain the position of the guide rod in the rod storage slot. For example, the deformable member is a rubber cord disposed along an inside surface of the rod storage slot.
In some embodiments, the apparatus includes an abrasive element holder with a body defining central aperture extending longitudinally therethrough for slidable movement along the guide rod. In some embodiments, the base further defines a storage slot sized and shaped to receive the abrasive element holder therein. For example, the storage slot has a cross-sectional shape corresponding to a cross-sectional shape of the abrasive element holder.
Another aspect of the present invention is a sharpener clamp for use with a variety of cutting implements. In one aspect of the invention is an apparatus for sharpening a cutting implement held in a vertical plane between first and second clamping members extending above a base. The first and second clamping members have opposite top portions and proximal end portions. Vertical inside surfaces of the clamping members face each other and are substantially parallel to the vertical plane. A guide rod is pivotably attached to the base at is proximal end and has a distal end that extends above the base at an angle to the vertical plane. An abrasive element holder is configured to slidably move along the guide rod.
In one embodiment, the abrasive element holder has a body with a holder aperture therethrough. The holder aperture extends along a guide rod axis and is sized and configured to receive the guide rod. An adjustable face plate is pivotably connected to the body and defines a second angle with the guide rod axis, where pivoting the adjustable face plate changes the second angle.
In another embodiment, the distance between the proximal end of the guide rod and the vertical plane is adjustable. In one embodiment, the apparatus includes an angle adjustment assembly with at least one arm connected to the proximal end of a guide rod. A control gear is disposed in rotational engagement with the arm(s), where rotating the control gear changes the distance between the proximal end and the vertical plane.
In another embodiment, a universal joint is connected between the control arm and the proximal end of the at least one guide rod. In one embodiment, the universal joint is a ball-and-socket joint. In another embodiment, the universal joint has a shaft portion that threadably engages a bracket, where rotating the shaft member changes the distance between the proximal end of the guide rod and the vertical plane.
In another embodiment, a fulcrum is disposed between the first and second vertical inside surfaces. A wedge member is configured to move between the first clamping member and the second clamping member to change the gap between the top portions by pivoting the first clamping member about the fulcrum with respect to the second clamping member.
In another embodiment, the apparatus includes a straight-line clamp connected to the wedge member, where actuating the straight-line clamp moves the wedge member.
In another embodiment, the wedge member has gears for engaging a geared rotatable shaft or lever.
In another embodiment, one or both of the first vertical inside surface and the second vertical inside surface has a slot with a slot depth. The slot is sized and configured to movably engage the wedge member. In one embodiment, slot depth increases towards the first proximal end portion.
In another embodiment, the contact angle between the abrasive element holder and the vertical plane is adjustable to less than ten degrees. In another embodiment, the angle is adjustable to less than six degrees.
In another embodiment, the knife sharpener includes an inclinometer configured to display the angle with the vertical plane.
In another aspect of the invention, an apparatus for sharpening a cutting implement held in a vertical plane includes a base assembly, a first clamping member pivotably supported by the base assembly and a second clamping member pivotably supported by the base assembly. The first and second clamping member each have an inside surface, a proximal portion, and a distal portion, where the inside surfaces face each other and are spaced apart from each other. The first clamping member and the second clamping member are each adapted to pivot first and second distal portions towards each other to thereby clamp a cutting implement therebetween. A clamping assembly is attached to the base assembly and includes a cam member movably supported by the base assembly, a follower assembly having a first follower end and a second follower end. The first follower end is disposed in operational engagement with the cam member and the second follower end is disposed in operational engagement with the first clamping member and the second clamping member. A handle is operatively connected to the cam member, where operating the handle moves the cam member, thereby moving the follower assembly and causing the first and second clamping members to pivot.
In one embodiment, the cam member is rotatable and has a cam shaft connected thereto. The cam member has an arcuate cam surface eccentric about the cam shaft axis, where the follower assembly is disposed in operational engagement with the arcuate cam surface.
In another embodiment, the cam member is slidably movable along a linear direction transverse to the follower assembly and has an inclined cam surface that is operationally engaged by the follower assembly.
In another embodiment, the apparatus includes a rod positioning assembly attached to the base assembly that includes a first arm mounted to the base assembly. The first arm is movable along a longitudinal direction of the first arm. The rod positioning assembly also has a second arm mounted to the base assembly. The second arm is adjacent the first arm and movable in a longitudinal direction parallel to the longitudinal direction of the first arm. A rod positioning lever is pivotably connected to the base assembly and operatively connected to the first arm and to the second arm. Pivoting the rod positioning lever causes the first arm to move in the longitudinal direction of the first arm and causes the second arm to move in the longitudinal direction that is parallel to the longitudinal direction of the first arm but in a direction that is opposite of the direction of the first arm.
In another embodiment, the rod positioning assembly also includes a central pivot pin attached to the base assembly, where the rod positioning lever is pivotable about the central pivot pin. A first guide pin is connected to and extends from the first arm and engages the rod positioning lever to one side of the central pivot pin. A second guide pin is connected to and extends from the second arm and engages the rod positioning lever to an opposite side of the central pivot pin. Pivoting the rod positioning lever about the central pivot pin moves the first arm in the longitudinal direction and moves the second arm in a second longitudinal direction.
In another embodiment, the follower assembly includes a follower disposed in contact with the cam member, a wedge member disposed in contact with the first proximal end portion of the first clamping member and the second proximal end portion of the second clamping members, and a compressible member disposed between the follower and the wedge member. The compressible member may be, for example, a spring, a compressible polymer, gas piston, or other resiliently compressible object.
In another embodiment, the base assembly has a base and a second base plate disposed in a spaced apart and substantially parallel relation to the base. The first arm, the second arm, and the rod positioning lever are each at least partially disposed between the base and the second base plate.
In another embodiment, the base assembly also has at least one support member having a proximal support member portion and a distal support member portion. The proximal support member portion is connected at a proximal end to the second base plate. The distal support member portion extends transversely from the second base plate and is pivotably connected to the first and second clamping members. In one embodiment, the base assembly also includes a riser block disposed between and attached to the second base plate and the support member(s). The riser block defines a cam member well sized to at least partially receive the cam member.
In another embodiment, the apparatus includes a first guide rod having a proximal end and a distal end, where the proximal end is pivotably attached to the first arm. A second guide rod has a proximal end and a distal end, where the proximal end is pivotably attached to the second arm. The apparatus also has one or more abrasive element holder that is constructed to slidably move along the first guide rod and/or the second guide rod.
In another embodiment, the first inside surface of the first clamping member defines a first sloped proximal portion and the second inside surface of the second clamping member defines a second sloped proximal portion. The first sloped proximal portion and the second sloped proximal portion each extend and diverge away from each other. The follower assembly is disposed in operational engagement with and to cause pivotal movement of the first sloped proximal portion and the second sloped proximal portion.
In another aspect of the invention, an apparatus for sharpening a cutting implement held in a plane includes a base assembly and first and second clamping members each pivotably supported by the base assembly. A wedge member is in movable contact with the distal portions of the first and second clamping members and adapted to cause pivotal movement of the first clamping member and the second clamping member. A handle operatively coupled to the wedge member is operable to move the wedge member. A rod positioning assembly is attached to the base assembly and includes a first arm mounted to the base assembly and movable parallel to a first arm longitudinal axis and a second arm mounted to the base assembly adjacent the first arm and movable parallel to the first arm longitudinal axis. A rod positioning lever is pivotably connected to the base assembly and operatively connected to the first arm and to the second arm, where pivoting the rod positioning lever moves the first arm along the first arm longitudinal axis and moves the second arm in a second direction parallel to the first arm longitudinal axis and opposite of the first direction. A first guide rod pivotably connected to the first arm and a second guide rod is pivotably connected to the second arm.
In another embodiment, a cam member is movably supported by the base assembly, a follower is disposed in operational engagement with the cam member, and a compressible member, such as a spring or compressible polymer, is disposed between the follower and the wedge member. The handle is connected to the cam member, where operating the handle moves the cam member, thereby displacing the wedge member and pivoting the first and second clamping members.
In one embodiment, the cam member is rotatably movable and has an arcuate cam surface eccentric about a cam shaft axis. The follower is disposed in operational engagement with the arcuate cam surface. In another embodiment, the cam member is slidably movable and has an inclined cam surface, where the follower is disposed in operational engagement with the inclined cam surface.
In another aspect of the invention, a method of sharpening a cutting implement includes the steps of providing a sharpening apparatus comprising a base assembly, first and second clamping members, a clamping assembly attached to the base assembly and operable to pivot the first and second clamping members; positioning the blade of a cutting implement in a plane between a first inside surface of the first clamping member and the second inside surface of the second clamping member; and operating the handle, thereby causing the first and second clamping members to clamp the blade.
In one embodiment, the method includes selecting the sharpener to include a rod positioning assembly attached to the base assembly, where the rod positioning assembly has a first arm mounted to the base assembly and movable parallel to a first axis, a second arm mounted to the base assembly adjacent the first arm and movable parallel to the first axis, and a rod positioning lever pivotably connected to the base assembly and operatively connected to the first arm and to the second arm. Pivoting the rod positioning lever moves the first arm in a first direction parallel to the first axis and moves the second arm in a second direction parallel to the first axis and opposite of the first direction. A first guide rod has a proximal end and a distal end, where the proximal end is pivotably attached to the first arm. A second guide rod has a proximal end and a distal end, where the proximal end is pivotably attached to the second arm. The apparatus has one or more sharpening blocks that are constructed to slidably move along the first guide rod and/or the second guide rod. The method also includes the step of operating the rod positioning lever, thereby setting a sharpening angle between the plane and the first and second guide rods, and the step of sliding the one or more sharpening block up and down along the first and second guide rods and in frictional engagement with the cutting implement.
In another embodiment, the sharpening angle is set between five and thirty-five degrees.
In another embodiment of the method, operating the handle rotates the cam member. In another embodiment, operating the handle slides the cam member.
A further aspect of the present invention is a method of sharpening a cutting implement where the cutting implement is held in a vertical plane and where an abrasive element holder is slidably moved along a guide rod in frictional engagement with the cutting implement.
In one embodiment the method includes securing the cutting implement between a first distal end portion of the first clamping member and a second distal end portion of the second clamping member, where the first clamping member and the second clamping member extend from (e.g., above) a base member. A first angle is set between a guide rod and the cutting implement held in a plane between the first and second clamping members, where the guide rod has a proximal end attached to the base member at an adjustable distance from the vertical plane. A second angle is set between the sharpening bock and the guide rod. An abrasive element holder slidably mounted to the guide rod is moved up and down along the guide rod and in frictional engagement with the cutting implement.
In another embodiment of the method, the securing step includes advancing a wedge member between the first clamping member and the second clamping member, thereby increasing a gap between a proximal end portion of the first clamping member and a proximal end portion of the second clamping member and causing the distal end portion of the first clamping member and the distal end portion of the second clamping member to engage and hold the cutting implement.
In another embodiment of the method, the first angle is set between five and fifteen degrees, between fifteen and twenty-five degrees, or between twenty-five and thirty-five degrees. In another embodiment of the method, the second angle is set between zero and forty-five degrees. In another embodiment, the second angle is set between forty-five and eighty degrees.
In yet another embodiment, an apparatus for sharpening a cutting implement includes a base, a first clamping member mounted to and extending above the base with a first inside surface configured to engage a cutting implement, a first top portion, and a first bottom portion. A second clamping member is adjustably connected to the first clamping member and extends above the base. The second clamping member has a second inside surface aligned with and opposing the first inside surface, a second top portion opposite the first top portion, and a second bottom portion opposite the first bottom portion. The first clamping member and the second clamping member are adjustable to releasably secure a cutting implement between the first inside surface and the second inside surface. The apparatus includes at least one guide rod having a proximal end and a distal end, where the proximal end is pivotably attached to the base at a distance between the proximal end and the vertical plane, where the distal end extends above the base, and where the at least one guide rod defines a first angle with the vertical plane. An abrasive element holder has a body defining a holder aperture therethrough, where the abrasive element holder is configured to receive the guide rod in the holder aperture and slidably move along the guide rod. In some embodiments, an abrasive member is attached to the body of the abrasive element holder.
The preferred embodiments of the present invention are illustrated in
A first fastener 208 extends through aligned apertures 50a in base rod 50, base 20, and riser block 70. First fastener 208 extends into and engages a proximal end portion 132 of first clamping member 130. A second fastener 209 extends through base rod 50 and base 20. Second fastener 209 extends into and engages riser block 70. First and second fasteners 208, 209 secure together base rod 50, base 20, riser block 70, and first clamping member 130.
In one embodiment, base 20 is a substantially-rectangular block with a first base end 22 and a second base end 24 positioned on opposite sides of a horizontal central axis 53 centered between lateral faces 138a & 138b, 148a & 148b of clamping members 130, 140, respectively (lateral faces 138b and 148b are not visible). Base 20 provides a common element to which the other components of knife sharpener 10 are joined. In one embodiment, a middle region 26 of base 20 defines an arch between first end 22 and second end 24. Middle region 26 has an optional upper slot 28 sized and configured to accept riser block 70. Optionally, riser block 70 is omitted and upper slot 28 accepts clamping members 130, 140. Upper slot 28 provides additional stability to sharpener 10 by preventing movement of riser block 70 and clamping members 130, 140 towards either of first base end 22 or second base end 24. Middle region also optionally has a lower slot or channel 30 sized and configured to accept base rod 50. Base 20 preferably has sufficient size and mass to provide a stable foundation for using knife sharpener 10. It is contemplated that base 20 may be a flat sheet of stone, a work bench, a metal block, or other suitable object with a flat surface and that provides a stable mounting platform to which components of knife sharpener 10 are attached. When base 20 is a slab of stone, for example, it has a slot to accept base rod 50 or has feet or other feature that allow sufficient space for base rod 50 to pass below base 20. In yet other embodiments, base rod 50 is attached to a top surface of base 20 and extends through a slot (not shown) in riser block 70.
Base rod 50 preferably has a square or rectangular cross-sectional profile and extends longitudinally along central axis 53 from a first end 51a to a second end 51b. Other cross-sectional geometries are also acceptable, depending on the method used to attach and adjust other components of angle adjustment assembly 170. In one embodiment, base rod 50 has a plurality of markings 52 along its length. Markings 52 are preferably in a side face 54 of base rod 50. Markings 52, such as a detent, scribe mark, or other indicium, allow the user to fix a bracket 172 or other connector at any one of several pre-determined locations. In one embodiment, base rod 50 has distance markings 56 to indicate the distance 165 between a reference point 58, such as the center point of base rod 50, and a proximal end of guide rod 160, which is discussed below. In one embodiment, each marking 52 corresponds to a change of one degree in a contact angle 166 between sharpening block 210 and cutting implement 8.
Base rod 50 is preferably secured to base 20 along central axis 53 and oriented perpendicularly to a vertical plane 167 extending through cutting implement 8 (shown in
Riser block 70 is an optional accessory for sharpener 10 that raises clamping members higher above base 20 to achieve a smaller contact angle 166 between sharpening block 210 and cutting implement 8. Riser block 70 in one embodiment has an upper riser slot 72 that is sized and configured to accept clamping members 130, 140. Riser block also has a lower riser shoulder 74 sized and configured to fit into upper slot 28 of base 20. Upper riser slot 72 and lower riser shoulder 74 provide stability to sharpener 10 by preventing movement between adjacent components.
In one embodiment, first clamping member 130 and second clamping member 140 are each wedge-shaped blocks with respective bottom surfaces 135, 145, sloping outer surfaces 136, 146, vertical inner surfaces 137, 147, proximal end portions 132, 142, top portions 139, 149, and two lateral surfaces 138a, 138b, 148a, 148b. Preferably, first and second clamping members 130, 140 have the cross-sectional shape of a right triangle with an angle in a range of about five to fifteen degrees between sloping outer surfaces 136, 146 and vertical inner surfaces 137, 147, respectively. Having a wedge shape provides top portions 139, 149 with smaller profiles than the profiles of proximal end portions 132, 142. The smaller profiles at top portions 139, 149 allows sharpener 10 to be used to sharpen very small cutting implements since having thicker top portions 139, 149 would impede sharpening blocks 210 from approaching and being applied to a cutting edge located relatively close to top portions 139, 149 of clamping members 130, 140. Other configurations of first and second clamping members 130, 140 are also acceptable, such as an L-shaped bracket. In one embodiment, first and second clamping members are sized and shaped to permit a contact angle 166 below ten degrees and as small as five degrees.
In one embodiment, one or more apertures 134 extend through or partially through clamping members 130, 140. Clamping fasteners 150 extend horizontally through apertures 134 in first clamping member 130 and into apertures 144 (not visible) of second clamping member 140. Clamping fasteners 150 extend into and engage second clamping member 140 to fasten second clamping member 140 to first clamping member 130. Clamping fasteners 150 and first and second fasteners 208, 209 preferably are threaded machine screws, bolts, or the like. By tightening clamping fasteners 150, second clamping member 140 is drawn towards first clamping member 130 to engage cutting implement 8 and securely hold it in place with its blade in a vertical plane 167 (shown in
Still referring to
First clamping member 130 and second clamping member 140 are supported by riser block 70 with bottom surfaces 135, 145 positioned in upper riser slot 72 of base 20. If riser block 70 is not used, lower surfaces 135, 145 of clamping members 130, 140, respectively, are supported by base 20 and preferably positioned in an upper slot 28 of base 20.
Clamping members 130, 140 optionally include depth control apertures 154. Cutting implement 8 may be supported between clamping members 130, 140 on horizontal posts (not shown) that extend through depth control apertures 154. In this manner, cutting implement 8 is secured at a consistent vertical position between clamping members 130, 140 for each sharpening session. Clamping members 130, 140 are then drawn together by tightening clamping fasteners 150.
Alternate embodiments may use different systems for controlling the depth of cutting implement 8 between clamping members 130, 140. One example (not depicted) is a slidable shoulder located between clamping members 130, 140 that slides up and down. In one embodiment, slidable shoulder is a fulcrum block 304 that slides up and down clamping member 140 along a channel 330 in inside vertical face 140a (shown in
One or more guide rods 160 are pivotably connected to base rod 50 or to base 20. Guide rods 160 are preferably rigid cylindrical rods made of metal with a proximal end 162 positioned towards base rod 50 and a distal end 164 extending above base 20. In one embodiment, proximal end 162 of one guide rod 160 is positioned towards a first end 51a of base rod 50 and a proximal end 162 of a second guide rod 160 (not shown) is mounted towards a second end 51b of base rod 50. The position of first guide rod(s) 160 relative to vertical plane 167 is preferably adjustable along base rod 50 or on base 20. Other shapes and materials of guide rod(s) 160 are acceptable provided that guide rod(s) 160 have the rigidity, strength, and other physical characteristics to deliver the desired level of precision positioning and adjustment.
Angle adjustment assembly 170 allows guide rod 160, and thus sharpening block 210, to move both parallel and perpendicular to a vertical plane 167 through cutting implement 8 (shown in
An abrasive element holder 200 is configured to slide along guide rod 160 via holder aperture 212 that extends through abrasive element holder 200 from end to end. Sharpening block 210 is removably attached to abrasive element holder 200, which is slidably mounted on guide rod 160. In one embodiment, abrasive element holder 200 has a substantially rectangular cross-sectional shape, therefore including four holder sides 200a, 200b, 200c (not visible). A sharpening block 210 with a grinding or honing material is affixed to one or more of holder sides 200a, 200b, 200c, 200d. When using multiple sharpening blocks 210, for example one on each side 200a-200d, abrasive element holder 200 may be rotated about guide rod 160 to select a honing material with the desired grit. Grinding or honing material may take any of a number of forms. Such honing material typically ranges from a coarse grit to a fine grit (for example, 80 to 1000 grit) and multiple honing materials are used in successive iterations during the sharpening process to achieve the desired sharpening effect.
In one embodiment, sharpening block 210 comprises a strap of leather or a synthetic material that is embedded with a diamond paste or other abrasive or polishing compounds. Similarly, diamond or polishing paste may be applied to the strap. Abrasive element holder 200 optionally has hand or finger depressions along opposite sides (e.g., 200a, 200c) that provide an ergonomic benefit as well as a functional benefit of protecting the user's fingers from the cutting edge 9 (shown in
In one embodiment, knife sharpener 10 includes an inclinometer 220. In one embodiment, inclinometer 220 has a digital display 221 and is affixed to or built into abrasive element holder 200. For example, in place of sharpening block 210 on holder side 200d, inclinometer 220 is removably attached using magnets, fasteners, hook-and-loop fasteners, clips, adhesive, or the like. As another example, components of inclinometer 200 (e.g., battery, digital display 221, electronics) are included in abrasive element holder 200 with digital display 221 along holder side 200a. Inclinometer 200 may alternately be affixed to abrasive element holder 200 using a frame 222 that supports inclinometer 220 around its perimeter. For example, frame 222 is configured to be inserted into guide slots (not shown) along abrasive element holder 200 or attach to abrasive element holder 200 using methods described above. An example of one acceptable inclinometer is the iGaging digital AngleCube, which measures an angle with respect to a reference surface (e.g., vertical surface 137) with an accuracy of +/−0.2 degree, precision of 0.1 degree, and resolution of 0.05 degree. Inclinometer 220 is useful to measure contact angle 166 between sharpening block 210 and cutting implement 8.
Referring now to
In other embodiments of knife sharpener 10 discussed below, bracket 172 slides along a channel or track defined in or attached to base 20. For example, horizontal portion 173 of bracket 172 includes a flange that mates with a channel defined in base 20.
Upright portion 178 extends upwardly from horizontal portion 173, along an upright axis 178a preferably oriented at an angle 180 of between seventy-five and eighty-five degrees to central axis 53. Angle 180 is not limited to these values. Upright portion 178 has a transverse second opening 182 extending therethrough, preferably perpendicular to upright axis 178a and aligned in the same general direction of base rod 50. Second opening 182 is preferably threaded and accepts a stem portion 194 of pivot joint 190.
In one embodiment, pivot joint 190 is a ball-and-socket joint, universal joint, coupling, or the like that permits proximal end 162 of guide rod 160 to pivot freely in any direction. When pivot joint 190 is a ball-and-socket joint, a first part 192 of pivot joint 190 has a stem portion 194 that is received in second opening 182 of bracket 172 and terminates in a sphere or ball 196 at its opposite end. A second part 198 has a socket portion 200 at one end with an opening that receives ball 196. Second part 198 has a rod connector or rod receptacle 202 opposite of socket portion 200 to attach proximal end 162 of guide rod 160. Rod receptacle 202 may be a hollow cylindrical sleeve, a threaded rod, a coupler, or other connector shaped and configured to accept and retain proximal end 162 of guide rod 160.
By advancing threaded stem portion 194 into or out of second opening 182, proximal end 162 of guide rod 160 moves closer or farther away from vertical plane 167. Thus, the user may finely and precisely adjust contact angle 166 between sharpening block 210 and vertical plane 167. Preferably, stem portion 194 is threaded and has a hexagonal recess in one end to receive hex-wrenches for adjusting the position of stem portion 194 relative to vertical plane 167. In one embodiment, a 180° turn of threaded stem portion 194 advances pivot joint 190 towards or away from vertical plane 167 to cause a change in contact angle 166 of about 0.5° between sharpening block and cutting implement 8. By rotating stem portion 194 in smaller increments (e.g., 5°, 10°, or 15°) the user may achieve highly precise adjustment of contact angle 166. The position of stem portion 194 may be fixed by tightening fastener 176 extending transversely through upright portion 178 and contacting stem portion 194. In other embodiments, second opening 182 is not threaded and receives a smooth stem portion 194.
Turning now to
Base 20 is preferably lightweight, but is sufficiently rigid to be secured to a stable support structure or work surface and enable the user to sharpen a cutting implement 8 held in the clamping assembly 300. In some embodiments, base 20 is made from extruded or machined aluminum. Other materials and methods of manufacture are acceptable.
In one embodiment, one mating or interlocking feature is a channel 30 defined in or attached to a top surface 20a of base 20 and the other mating or interlocking feature is a fastener/nut combination, protrusion, rail, or other feature on the component (e.g., bracket 172). For example, base 20 is machined or manufactured by extrusion to define channel 30 configured as a T-slot. In other embodiments, channel 30 is defined by a track attached to base 20, such as a T-track mechanically fastened to base 20.
As used herein, the term “T-slot” means a channel having a cross-sectional shape of a T or a similar shape, where the cross-sectional shape includes a vertical slot portion 33 that is narrower than and connected to a horizontal slot portion 34 extending transversely to the vertical slot portion 33. As such, the horizontal slot portion 34 is configured to slidingly receive a nut 179, washer, slider, flange, or the like while connected to a fastener 179 that extends through the vertical slot portion 33. Horizontal slot portion 34 of the T-slot may be rectangular, trapezoidal, circular, or any other shape provided that horizontal slot portion 34 is greater in cross-sectional size than vertical slot portion 33.
In some embodiments, bracket(s) 172 and clamping assembly 300 have an interlocking feature that mates with channel 30 on base 20. As shown in
In another embodiment, components mounted to base 20 (e.g., clamping assembly 300 and bracket(s) 172) define channel 30 to mate with a rail 40 on base 20. As shown in
In other embodiments as shown, for example, in
Turning now to
Optionally, base 20 also defines one or more rod storage slots 36 sized and configured to receive and retain guide rod 160. For example, each rod storage slot 36 is a generally-cylindrical recess or bore in base 20 that extends along the front surface 20b and/or rear surface 20c of base 20. In one embodiment, each rod storage slot 36 intersects front surface 20b or rear surface 20c to define an opening 37 that allows the user to adjust the position of the guide rod 160 while retained in the rod storage slot 36 as well as to visually inspect the rod storage slot 36 to determine the presence of guide rod 160. In one embodiment, opening 37 is intentionally undersized to require insertion of guide rod 160 axially into an end 36a of rod storage slot 36 rather than through opening 37. In other embodiments, rod storage slot 36 permits installation and removal of guide rod 160 through opening 37. In such embodiments, an insert, clip, or other device in rod storage slot 36 may be employed to retain guide rod 160 in rod storage slot 36 via a snap fit, friction fit, or the like.
A compressible member 39 in rod storage slots 36 provides a frictional force to maintain the position of guide rod 160. As shown, compressible member 39 is a length of cylindrical rubber embedded into an additional recess along an inside surface 36b of rod storage slot 36 and that protrudes slightly into rod storage slot 36. When guide rod 160 is inserted into rod storage slot 36, compressible member 39 biases guide rod 160 to abut an opposing surface and thereby provides frictional forces that maintain the position of guide rod 160. In other embodiments, compressible member 39 may be a clip, detent, spring, foam insert, surface coating, spring, or other device that provides sufficient frictional force to maintain guide rod 160 in rod storage slot 36 against the force of gravity (when rod storage slot 36 is vertically oriented). In yet other embodiments, rod storage slot 36 includes a plug, door, or cap that may be installed in or over end 36a to prevent loss of the guide rod 160 due to inadvertent removal from rod storage slot 36.
As also shown in
Turning now to
Turning now to
In
For embodiments of sharpener 10 discussed above with reference to
Turning now to
A lever recess 232 extends through top surface 20a of base 20 and tunnels below block bridge 231, where lever recess 232 communicates with first arm recess 226 and second arm recess 228. First arm 242 and second arm 244 extend from first and second arm recesses 226, 228, respectively, into lever recess 232 below block bridge 231. First and second arms 242, 244 move longitudinally along first and second arm recesses 226, 228, respectively, due to engagement with a control gear 246 (not visible), which is discussed in more detail below.
Referring now to
As the user pivots rod positioning lever 248 about center 246a of control gear 246, control gear 246 rotates in engagement with first and second arms 242, 244, causing their longitudinal movement along central axis 53 towards or away from vertical plane 167 and clamping members 130, 140 (shown in
As shown in
In one embodiment, rod positioning assembly 240 is configured with detents, notches, or other structure on control gear 246 and/or rod positioning lever 248 that indicates to the user visually, audibly, and/or tactilely that movement has occurred between each pre-determined incremental distance between pivot joints 190 and clamping members 130, 140.
In other embodiments of rod positioning assembly 240, as illustrated in
Referring now to
In one embodiment, front cover plate 262 and rear cover plate 261 are fixed to housing 260 and are attached to clamping members 130, 140 by a fastener, pin, rod or the like (not shown) that extends through plate opening 262a and fulcrum blocks 304, 306 (shown in
In one embodiment, sharpener housing 260 has a substantially rectangular main housing body 262 with one or more side openings 263 (not visible) for access to moving parts of clamping assembly 300 and gear assembly 240. Main housing body 262 is preferably affixed to base 20 with fasteners (not shown). Side housing covers 264, 265 are preferably removably or hingedly attached to main housing body 262. Side housing covers 264, 265 are rectangular box-like covers, but may also have the form of a door or substantially planar panel. First arm 242 extends through a first arm aperture 266. Second arm 244 extends through a second arm aperture 268 (not visible). First and second clamping members 130, 140 are disposed over top opening 270 (not visible) through a top 262a of main housing body 262.
In one embodiment, first clamping member 130 is secured to housing and second clamping member 140 is attached to first clamping member via fulcrum blocks 304, 306 disposed connected to first and second clamping members, respectively, and discussed in more detail below. In another embodiment, riser block 70 is attached to top 262a of main housing body 262 and has an opening therethrough for wedge member 320. With riser block 70, first clamping member 130 is attached to riser block 70 with fasteners and second clamping member 140 is attached to first clamping member via fulcrum blocks 304, 306.
Referring now to
In one embodiment, fulcrum blocks 304, 306 have fulcrum openings 304a, 306a that extend parallel to a central cutting implement axis 305. Fulcrum blocks 304, 306 preferably overlap or alternate with one another where fulcrum openings 304a, 304b are aligned. Like a hinge, a pin, screw, bolt, or other connector extends through openings 304a, 304b of fulcrum blocks 304, 306 so that clamping members 130, 140 pivot about openings 304a, 304b, respectively, in response to operation of straight-line clamp 302, which is discussed below. Fulcrum blocks 304, 306 preferably are shaped as solid protrusions with a rounded or semi-circular profile, but other shapes and forms are also acceptable provided that they permit clamping members 130, 140 to pivot about fulcrum block(s) 304, 306, respectively. For example, one or both of fulcrum blocks 304, 306 may be a tab, plate, or other structure that permits hinged or pivoting movement.
Fulcrum block(s) 304 and/or 306 define a gap 307 between clamping members 130, 140. Gap 307 is measured between inside surfaces 130, 140a when inside surfaces 130a, 140a are parallel to each other. Gap 307 is preferably adjustable using a set screw to adjust the distance that fulcrum blocks 304, 306 extend from inside surfaces 130a, 140a, respectively.
Referring to
In one embodiment, at least one of clamping members 130, 140 has a slot or channel 330 along its inside surface 130a, 140a sized and configured to receive or guide second wedge member end 320b or an attachment thereto. As noted above, slot 300 may also be used for a sliding shoulder or fulcrum block 304. For example, engagement surfaces 332 are attached to wedge member 320 and are aligned to engage inside surfaces 330a of channels 330 in first and second clamping members 130, 140. Channels 330 extend into inside surfaces 130a, 140a by the distance of a channel depth 330a that preferably tapers from a first depth 330a near proximal end portions 132, 140 to a second, shallower depth 330b towards upper portion 139, 149.
Referring to
Although wedge member 320 is shown in the figures as having a cylindrical shape, wedge member 320 may also be a wedge, bar, block, or other shape that is configured to increasingly separate proximal end portions 132, 142 of first and second clamping members 130, 140, respectively, as wedge member 320 advances upwardly or otherwise between them. In one embodiment, second wedge member end 320b has engaging surface(s) 322, such as a roller, block, shoulder, protrusion, or other geometry that is shaped and configured to slidably engage or roll along inside surfaces 130a, 140a of clamping members 130, 140, respectively. As wedge member 320 moves upward between clamping members 130, 140, proximal end portions 132, 142 of clamping members 130, 140 are forced apart. Clamping members 130, 140 pivot about fulcrum block(s) 304 causing top portions 139, 149 of clamping members 130, 140 to move towards each other. Thus, when cutting implement 8 is positioned between clamping members 130, 140, handle 326 is moved to its first position to cause top portions 139, 149 to firmly engage cutting implement 8 and securely hold it in place for sharpening.
In other embodiments of clamping assembly 300, wedge member 320 has gears or threads. Wedge member 320 may alternately be advanced upward between first and second clamping members 130, 140 by engagement between a worm drive and gear or threads on wedge member 320. In other embodiments, the end of a lever or bar may be positioned between proximal end portions 132, 142 of clamping members 130, 140 and its opposite end moved sideways to increase or decrease gap 307 between proximal end portions 132, 142 of first and second clamping members, respectively. In such an embodiment, proximal end portions 132, 142 are preferably biased towards each other with a spring, piston, gravitational force, or other means.
Referring now to
A second stone angle 412 may be set and adjusted between adjustable face plate 408 and guide rod axis 406. Abrasive element holder 400 optionally has an angle guide 414 attached between adjustable face plate 408 and slidably attached to body 402 of abrasive element holder 400. In one embodiment, angle guide 414 is fixed at one end 416 to adjustable face plate 408 with a fastener 418. Angle guide 414 has a slot 420 and fastener 422 extending into body 402 for slidable adjustment of second stone angle 412. Fastener 422 may be tightened against angle guide 414 to “lock in” second stone angle 412. Notches (not shown) along angle guide may similarly be used to adjust and lock in second stone angle 412, where a notch is hooked over fastener 422 or other protrusion from body 402. In other embodiments, adjustable face plate 408 is adjusted by moving a threaded rod or fastener (not shown) forward or backward between body 402 and adjustable face plate 408.
Referring now to
Referring now to
In one embodiment, clamping assembly 300′ includes first support member 80a and second support member 80b, each of which extends upward from riser block 70 in substantially parallel and spaced-apart relation to each other. In some embodiments, support members 80a, 80b are fixedly attached to riser block 70, such as by using screws, welding, or other means. For example, fasteners extend through upper base plate 21, through riser block 70, and into a proximal end portion 81a, 81b of support members 80a, 80b, respectively. In other embodiments, riser block 70 is omitted and support members 80 extend upward from and are connected directly to upper base plate 21.
Each support member 80 has a plurality of support pins 82 or rods extending from an inside surface 84 and into first and second clamping members 130, 140. Each of first and second clamping members 130, 140 pivots about one or more support pin 82 that extends through or into the respective clamping member 130, 140.
Referring now to
Operation of handle 120 rotates cam member 90, which acts on follower assembly 100 to cause first and second clamping members 130, 140 to pivot and therefore to engage cutting implement 8 (shown in
Referring now to
One embodiment of cam member 90 has a cam shaft opening 91 sized to receive one end of cam shaft 92. Cam shaft 92 may be operatively connected to cam member 90 in other ways, such as being integrally connected by welding or being formed as a single item, or by using a coupler to connect cam shaft 92 to cam member 90. Cam shaft 92, or portion thereof, can have a cross-sectional shape that is circular, rectangular, triangular or other regular or irregular geometric shape. In one embodiment, for example, a tip of cam shaft 92 has a square cross-sectional shape that is received in a square cam shaft opening 91.
Cam surface 90a is eccentric of cam shaft axis 92a and may have a spiral, circular, oval, snail, or other profile shape that results in rise and fall of follower assembly 100 to operate first and second clamping members 130, 140 as cam member 90 is rotated. In one embodiment, cam member 90 has a generally circular shape with cam shaft axis 92a being off-center to the circular shape. A handle 120 is attached to the opposite end of cam shaft 92. Handle 120 can be a lever, wheel, knob, bar, protrusion, enlargement, or other structure that facilitates the user in rotating cam shaft 92 and therefore in rotating cam member 90.
Follower assembly 100 includes follower 102, a resilient compressible member 110, and wedge member 320. In one embodiment, follower 102 is a flanged follower pin that includes a pin portion 103 extending from a disk-shaped flange 104. Pin portion 103 usually has a cylindrical cross-sectional shape, but other cross-sectional shapes are acceptable. Follower 102 has a bottom surface 102a that contacts cam member surface 90a as cam member 90 rotates or moves. In one embodiment, bottom surface 102a is on flange 104. Pin portion 103 is sized to fit into resilient compressible member 110 that is a spring, where resilient compressible member 110 preferably abuts flange 104. In other embodiments, follower 102 has a cup shape that receives resilient compressible member 110 in a central cup opening (not shown).
In one embodiment, resilient compressible member 110 is a helical compression spring (i.e., coil spring), but may also be a wave spring, one or more stacked wave washers, a resilient compressible polymer, or other resilient member. For example, resilient compressible member 110 is polyurethane, such as polyurethane 95A, with an uncompressed thickness of about 35 mm between wedge member 320 and follower 102. Other materials and thicknesses are acceptable. In other embodiments, resilient compressible member 110 is a gas piston, a gas piston together with a spring, or other compressible structure that compresses under a load and returns to its uncompressed shape partially or completely after the load is reduced or removed. In one embodiment, resilient compressible member 110 is retained on follower 102 by having pin portion 103 of follower 102 inserted in a first compressible member end portion 111 (e.g., lower end), with first compressible member end portion 111 abutting flange 104. In other embodiments, first compressible member end portion 111 is attached to follower 102 with a clip, hook, fastener, welding, or other method.
In the embodiment shown in
Referring now to
Cam member 90 can be advanced or retracted with other methods. For example, cam shaft 92 threadably engages cam member 90. As cam shaft 92 rotates, cam member 90 moves along cam shaft 92 with sloped cam surface 90a in contact with follower assembly 100. In other embodiments, cam shaft 92 has a geared engagement with cam member 90.
Referring now to
As handle 120 is rotated to the second clamping position (e.g., closed or clamped) as shown in
As cam member 90 rotates to the second clamping position, it compresses resilient compressible member 110. The compression force of resilient compressible member 110 makes it possible for the clamping assembly 300′ to hold and lock onto knives 8 of varying thicknesses. When cam member 90 is in the second clamping position, such as with handle 120 rotated ninety degrees relative to the first clamping position as shown in
Optionally, wedge member 320 includes a set screw that moves a bias plate to adjust the depth of well 323 in wedge member 320. As such, compression of resilient compressible member 110 can be adjusted. Another option is to include adjustable bias plates on one or both of sloped surfaces 130b, 140b that independently adjust the contact point of wedge member 320 on clamping member 130, 140, respectively. Such an adjustment can be used to align cutting implement 8 with vertical plane 167 when clamping assembly 300′ is in the second clamping position.
Referring now to
Referring now to
Rod positioning lever 248 pivots about a central pivot pin 245. In one embodiment, central pivot pin 245 extends along or parallel to third (Z) axis 254 (e.g., upward) from base 20′ and into or through rod positioning lever 248. A center 245a of central pivot pin 245 is positioned between arms 242, 244. In such an embodiment, first arm 242 has a first arm cutout 242b and/or second arm 244 has a second arm cutout 244b to accommodate central pivot pin 245 as arms 242, 244 slide in proximity or in abutment with each other. In other embodiments, arms 242, 244 are positioned longitudinally in the direction of second axis 252 to permit arms 242, 244 to slide in opposite X-axis directions without the need for first arm cutout 242b and/or second arm cutout 244b. In yet other embodiments, central pivot pin 245 extends along or parallel to third (Z) axis 254 (e.g., downward) from a second or upper base plate 21 and into or through rod positioning lever 248. Accordingly, central pivot pin 245 may not extend between arms 242, 244, thereby obviating the need for first arm cutout 242b or second arm cutout 244b.
First arm 242 has a first guide pin 247a and second arm has a second guide pin 247b extending upward therefrom. Rod positioning lever has a first lever slot 248a or channel and a second lever slot 248b or channel positioned longitudinally along rod positioning lever 248 and each generally oriented to extend opposite of central pivot pin 245 from each other. As rod positioning lever 248 is pivoted about central pivot pin 245, first and second lever slots 248a, 248b engage guide pins 247a, 247b, respectively, causing arms 242, 244 to move in the second (X) axis 250 direction. As each arm 242, 244 moves in the second (X) axis 250 direction, a proximal end 162 of guide rod 160 (shown in
In one embodiment, upper base plate 21 is substantially parallel to and spaced apart from base 20′. For example, fasteners 208′ extend up through base 20′, through first and second slide guides 255a, 255b, through standoffs 207, and into upper base plate 21. Standoffs 207 also may function as a stop block for rod positioning lever 248. Riser block 70 (shown in
Optionally, upper base plate 21 has a plurality of angle measurement indicia 177, such as numbers, lines, dots, or other markings that relate the position of rod positioning lever 248 to contact angle 166 between vertical plane 167 and abrasive element holder(s) 200 (shown in
Optionally, rod positioning assembly 240′ includes one or more locking screws 256 that extend in the second (Y) axis 252 direction through or along first and/or second slide guides 255a, 255b to first and second arms 242, 244, respectively. For example, after setting contact angle 166 locking screws 256 can be advanced to engage first slide guide 255a and lock its position.
Referring now to
Referring now to
In step 805, a cutting implement 8 is placed between distal end portions 133, 143 of first and second clamping members 130, 140, respectively. In one embodiment, distal end portions 133, 143 are upward end portions of clamping members 130, 140 that extend upwardly.
In step 810, the distal end portions 133, 143 of the first and second clamping members 130, 140, respectively, are drawn together to engage cutting implement 8. In one embodiment, the distal end portions 133, 143 are drawn together by advancing a piston or wedge member 320 upwardly between the first and second clamping members 130, 140, thereby increasing gap 307 between proximal end portion 132 of first clamping member 130 and proximal end portion 142 of second clamping member 140 and causing distal end portions 133, 143 of the first and second clamping members 130, 140 to engage cutting implement 8. For example, sharpener 10 is selected to include cam member 90, follower assembly 100, and handle 120, where operation of handle 120 moves wedge member 320 between first and second clamping member 130, 140.
In step 815, if a contact angle or first angle 166 has not been set between an abrasive element holder 200 and a vertical plane 167 through cutting implement 8, the user optionally adjusts first angle 166. First angle 166 can be set by changing the horizontal distance between proximal end 162 of guide rod 160 and vertical plane 167 through cutting implement 8. In one embodiment, first angle 166 is adjusted by operating rod positioning lever 248 to move first arm 242 and second arm 244 towards or away from vertical plane 167. For example, sharpener 10 is selected to include rod positioning assembly 240 with rod positioning lever 248 connected to control gear 246 or rod positioning assembly 240′ with rod positioning lever 248 pivotable about a central pivot pin. When sharpening cutting implement 8 having a curved or complex cutting edge 9, the user optionally sets a second stone angle 412 between sharpening block 210 and guide rod axis 406. Setting a second stone angle 412 may be performed by using an abrasive element holder with adjustable face plate 408 and pivoting adjustable face plate 408 with respect to body 402 and guide rod axis 406.
First angle 166 is chosen in part by the cutting edge sought and in part on the type of cutting implement to be sharpened. For example, for Japanese culinary knives, first angle is typically from about nine to about thirteen degrees and may be as small as about five or six degrees. For some knives (e.g., German culinary knives), first angle 166 may be selected to be from about fifteen to about twenty-two degrees or from fifteen to about twenty-five degrees. For sport knives (e.g., bush knives), first angle may be set from twenty-five to about thirty-five degrees. For other cutting implements, such as salon shears, first angle may be selected to be from forty to sixty degrees or from forty to seventy degrees. These values are merely illustrative and acceptable values for first angle 166 are chosen as needed. These ranges for first angle 166 are not limited to any particular cutting implement and include all angles within the ranges.
Similarly, second stone angle 412 is chosen in part on the type of cutting edge sought and in part on the type of cutting implement to be sharpened. In general, a larger value for second stone angle 412 results in a greater curvature of cutting edge 9. In some cases, a larger value for second stone angle 412 reduces the need for a larger value of first angle 166. Also, a larger value for second stone angle 412 tends to provide less precision for cutting edge 9. When sharpening knives, second stone angle 412 is selected, for example, from zero to forty-five degrees. When sharpening salon shears, second stone angle 412 is selected, for example, from forty-five to eighty degrees. These values for second stone angle 412 are merely illustrative and other values for second stone angle 412 are acceptable. These ranges for second stone angle 412 are not limited to any particular type of cutting implement
In step 820, sharpening block 210 attached to the abrasive element holder 200 is drawn in frictional engagement across the cutting edge 9 of cutting implement 8 by reciprocally moving sharpening block 210 along a guide rod 160. When cutting edge 9 faces upward, this reciprocal movement is performed in an up-and-down motion. Sharpening block 210 is repeatedly drawn against and along all or a substantial portion of the length of cutting edge 9 of cutting implement 8 as necessary to obtain the desired sharpening effect. When sharpener 10 is equipped with two sharpening blocks 210, one on each side of cutting edge 9, each sharpening block 210 may be drawn across cutting edge 9 in an alternating fashion, one at a time for a repeated number of strokes before applying the opposite sharpening block 210. The use of alternating sharpening blocks 210 has been shown to be a very efficient method of sharpening cutting implement 8. By using sharpening blocks 210 that progress from coarse grit to fine grit, the desired angle of the cutting edge 9 of cutting implement 8 is created or set.
In step 825, cutting edge 9 of cutting implement 8 is optionally polished or finished. Once the user feels a burr being created on one side of the cutting edge 9, the burr indicates that the ridge of the cutting edge 9 is rolling over and that the angle is created or set, at which point it is appropriate to begin polishing cutting edge 9 with sharpening blocks 210 of finer grit. Polishing the cutting edge 9 may also be done by using a sharpening block 210 having a leather strap embedded with a diamond paste or other abrasive. As a final polishing or finishing step, it is preferable in some embodiments of sharpening method 800 that the first angle 166 is altered by about 0.5 to 1 degree to achieve a better sharpening effect.
Although the preferred embodiments of the present invention have been described herein, the above description is merely illustrative. Further modification of the invention herein disclosed will occur to those skilled in the respective arts and all such modifications are deemed to be within the scope of the invention as defined by the appended claims.
This application is a continuation of U.S. patent application Ser. No. 15/405,904 titled ADJUSTABLE SHARPENING APPARATUS AND METHOD FOR CUTTING IMPLEMENTS and filed on Jan. 13, 2017, which is a continuation-in-part of U.S. patent application Ser. No. 14/542,057 filed on Nov. 14, 2014 (now U.S. Pat. No. 10,131,028), which is a continuation-in-part of U.S. patent application Ser. No. 13/889,393 filed on May 8, 2013 (now U.S. Pat. No. 9,216,488), all of which applications are incorporated herein by reference in their entireties.
Number | Date | Country | |
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Parent | 15405904 | Jan 2017 | US |
Child | 16927239 | US |
Number | Date | Country | |
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Parent | 14542057 | Nov 2014 | US |
Child | 15405904 | US | |
Parent | 13889393 | May 2013 | US |
Child | 14542057 | US |