This invention relates to honing and sharpening guides used for holding chisels, plane blades and other edge tools and tool blades while grinding, sharpening and honing the tools and blades.
Honing guides have long been available for holding chisels and plane blades at a predetermined angle relative to a planar abrasive surface, such as the surface of a sharpening stone or a sheet abrasive material affixed to a flat surface such as plate glass. Such commercially available guides generally have wheels or a wide roller that rolls over the abrasive surface or another parallel reference surface and a means for fixing the chisel or plane blade to the guide during use. Some of the prior art guides engage the sides of the chisel or plane blade in a clamping arrangement, and other of the prior guides use a clamping screw to apply force to one face of the chisel or plane blade to force it against guide structure in contact with the other face of the chisel or plane blade.
It is well known in the prior art that a sharp edge can be created more quickly by forming a first bevel on a plane blade or a chisel with a relatively coarse, fast cutting abrasive and then using a finer abrasive, which is therefore slower cutting, to form a micro bevel immediately adjacent to the cutting edge or arris of the blade or chisel at a slightly steeper angle than the principal bevel. This can be accomplished, for instance, by putting a shim under the wheels or roller associated with the honing guide (where the guide separates the roller a substantial distance from the blade bevel) or by adjusting the position of the axis of rotation of the wheels or rollers to slightly lift the guide as taught by U.S. Pat. No. 4,733,501.
While prior honing guides are very useful tools, several aspects of the functionality of these jigs can be improved.
For instance, recent reintroduction of manufacture of number 8 jointer bench planes creates a need for honing jigs able to accommodate the 2⅝ inch wide plane blades of such planes, and many currently available honing guides cannot accept blades of that width.
It is also desirable to provide enhanced ability to select bevel angles within the range of such angles typically used, approximately 20 degrees to 40 degrees. It is also desirable to properly locate the entire cutting edge or arris relative to the guide, because some prior guides make it easy for the arris to be located out of square with the guide.
It is desirable to make the honing guide and its blade bevel setting functionality useable with skew chisels.
Many prior art honing guides secure the chisel or plane blade in the guide by reference to the longitudinal tool face surface adjacent to the bevel. This happens, for instance, in a guide where a bench chisel is positioned bevel down and a thumbscrew above the chisel presses against the back face or underside of the chisel, forcing the opposite, top side of the chisel against a guide reference surface. The cutting arris on such a chisel is defined, however, by the intersection of the bevel with the back face of the chisel, against which the thumbscrew presses. The way these prior art honing guides secure the tool being honed is not a problem if the back face and the opposite, front face or top surface are parallel, but they often are not. Additionally, longitudinal bevels on the sides of relatively narrow bench chisels cause this top surface to be quite narrow, which introduces additional difficulty associated with use of it as a reference surface because the chisel may “rock” to one side or the other when it is being secured in the honing guide.
It is desirable to provide a honing guide with enhanced clamping to prevent the tool from skewing while the honing guide is in use. Most existing clamping devices use a single, large screw with a swiveling pad to hold the tool in position. No matter how much pressure is applied to clamp the tool, relatively little force is need to rotate the tool about the axis of the screw.
Another consideration associated with honing guides is the range of bevel angles that can be formed using the guide. Many guides provide a range of angles of approximately 20° to 40°, and it is sometimes desirable to be able to hone either smaller or larger angles.
Honing guides with wide rollers provide a stable holder for blades being sharpened so that blade cutting edge or arris remains perfectly straight and square to the blade. While this is desirable for most blades, such perfectly straight cutting edges in larger smoothing planes can produce “plane tracks,” which are small steps in the surface of the wood between plane strokes or paths.
To avoid production of such “plane tracks,” it is beneficial to add a slight camber or curve to the cutting edge of the plane blade, rather than keep the edge straight. Such a slightly curved-edge plane blade takes a slightly scalloped cut and the resulting surface will be slightly wavy, a feature that is recognized as a hallmark of quality hand woodworking.
The improved honing guide of this invention is an extremely versatile guide useable with a wide range of chisel and blade widths, thicknesses, lengths, and end configurations (square or skewed) to hone a wide range of bevel angles. Associated bevel-setting jigs that couple to the guide makes it easy and quick to position a tool or blade in the guide at a desired bevel angle with the cutting arris properly positioned parallel to the axis of rotation of a guide roller that contacts the planar abrasive surface during use of the guide. A clamping bar contacting the face of the tool or blade adjacent to the bevel securely presses against a reference surface in the guide a surface of the tool or blade that intersects the bevel to form the cutting edge or arris. This reference surface is parallel to the roller axis of rotation.
Consequently, when a plane blade or chisel is secured in the guide, a bevel will be formed that intersects the adjacent tool or blade surface to produce an arris parallel to the axis of rotation of the roller.
In order to minimize the amount of material that needs to be removed during a sharpening operation using the guide of this invention, it is desirable that that the existing arris be positioned parallel to the roller axis of rotation and a distance from that axis of rotation that results in a desired bevel angle. These objectives are achieved by providing a jig or gauge that is temporarily coupled to the honing guide and that has a stop locatable at desired distances from the guide to produce desired bevel angles. One such jig for square end tools provides a reference surface or fence to position a side of the blade or chisel square to the roller so that the bevels formed using the guide will be properly oriented square to the tool. A different positioning jig allows the user to exercise similar control over the positioning of the skew chisels in the jig. It attaches to the honing guide in the same manner, is fitted with an adjustable stop as well, and may include one or two reference fences to contact with the side of a skew chisel or blade.
The tool or blade holding structure of the guide projects beyond the guide roller toward the bevel and grasps the tool relatively near the bevel for better control and so that short tools and blades can be secured in the guide and sharpened.
The roller is positionable in at least two locations relative to the tool holder to facilitate formation on a tool of a primary bevel with the roller in one location and a micro bevel with the roller in a second position that slightly lifts the guide. This may be accomplished as taught in U.S. Pat. No. 4,733,501, which is incorporated herein by this reference. The roller may be moved between the two positions by moving the position of axle on which the roller rotates. The axle may be eccentrically positioned on a shaft that is spring loaded to hold a knob on the end of the shaft against a protrusion on one of the guide body or the knob and one of at least two detents in the other of the guide body or the knob. The knob is pulled axially to disengage the from the detent and rotated to engage another detent.
The honing guide of this invention may also be used as a grinding jig. Structure behind the roller, such as a protruding ledge, enables the guide to rest on a tool rest on a typical motorized bench grinder, belt grinder or other motorized abrasive device. This will allow the user to position a tool to be sharpened once in the guide for both rough grinding and fine honing. Although the guide may not necessarily enable closely controlled, or repeatable grinding angles, by resting the guide on a bench grinder tool rest, such control is not generally required because the angle at which a tool is ground will typically be 2° to 5° less then the honing angle. Such a slightly different grinding angle can typically be judged by eye with very little practice. As is described in detail at page 62 of Leonard Lee's book, The Complete Guide to Sharpening, which book is incorporated herein in its entirety by reference, grinding material from the heel of the bevel at a lower angle will allow much faster honing with less wear on the honing media. Performing both grinding and honing with the tool in the same position in the guide will ensure that the relief grind and the desired cutting arris are parallel—additionally reducing honing time.
The honing guide of this invention may also include concave surface clamp bars to improve the blade-holding ability of the assembly. The concave clamping surface of the clamp bar of this honing guide forces the separation of the regions of contact with the tool being honed and concentrates the clamping force along parallel lines.
The geometry of typical honing guides enables honing of bevel angles of approximately 20° to 40°. Although this meets the requirements for the vast majority of tools, some specialized woodworking techniques require an angle that is either very high (for example, 40° to 60°) or very low (for example, 5° to 20°).
The honing guide of this invention can accommodate such larger or smaller bevel angles using two alternative structures. The first of these is a pair of generally wedge-shaped spacers that that may be employed to shift the range of achievable bevel angles. These spacers allows two identical parts to be used together and with the honing guide to modify the opposed clamping surfaces through by 16° (or another appropriate similar angle) at each end of its range, thus adding a total of approximately 32° of range. Each spacer, when viewed in cross section, has a 16° included angle. Each spacer is equipped with a slot at one end and a half slot on the other end. This allows the user to place the slotted end against one clamp screw or stud and then pivot the spacer into position. The half-slotted end is fitted with a small leaf or other spring to ensure it will snap into place and remain in proper position without being held by the user. The pair of spacers is reversible in order to permit extension of each end of the range of angles that the honing guide is otherwise capable of achieving.
While slight relocation of the axis of rotation of the wheel in the manner described above facilitates formation of micro bevels, relocation of the axis of rotation of the wheel by greater amounts can enable honing of a wider range of bevel angles. Accordingly, a second way of achieving such additional versatility with expanded bevel angle range may be accomplished in the honing guide of this invention by providing structure that permits the location of the wheel support structure to be move relative to the blade securing or carrier structure. This can be achieved by making the blade carrier and the wheel frame separate parts that may be secured together in more than one relationship. “Wedges” and “valleys” incorporated in the contacting surfaces of the blade carrier and wheel frame make it easy to repeatably join these two parts in multiple alternative relative positions and rigidly secure the components to each other in each of the alternative positions.
An alternative embodiment of this invention facilitates the process of adding a slight camber to the edge of a blade being sharpened by replacing a wide cylindrical honing guide roller with a barrel-shaped roller that allows the guide to rock slightly as pressure is alternatively applied in different places across the blade.
It is thus an object of this invention to provide improved honing guides. The improved honing guides of this invention can accommodate a wider range of chisel and plane blade sizes than prior guides, including skew chisels and blades.
It is another object of this invention to provide a honing guide that facilitates accurate production of micro-bevels.
It is another object of this invention to provide a guide that can be more easily and accurately positioned for use on a chisel or plane blade or other tool and is more securely attachable to a chisel or plane blade than prior guides.
It is a further object of this invention to provide a honing guide that positions a tool or blade for sharpening by reference to the tool or blade's longitudinal cutting arris-forming surface.
It is another object of this invention to provide a guide for holding a tool while grinding the tool on a motorized grinding wheel, belt or other abrasive by engaging the grinder's tool rest with guide structure.
It is an object of this invention to provide a tool or blade positioning jig for use with the guide that facilitates accurate positioning of the tool or blade in the guide to form a bevel at a desired angle and with minimal removal of blade material.
It is an object of this invention to provide a honing guide and tool or blade setting jig that facilitate accurate repositioning of the tool or blade in the guide in a desired bevel-forming position.
It is another object of this invention to provide a honing guide and bevel setting jig that can be economically manufactured utilizing components made from aluminum extrusions, zinc die-castings, or plastic.
It is a further object of this invention to provide a concave surface clamp bar that improves the blade-holding ability of the honing guide assembly.
It is a further object of this invention to provide a honing guide capable of honing a wide range of bevel angles, including such angles smaller than 20° and larger than 40°.
It is a further object of this invention to provide a honing guide capable of accommodating chisels or other blades that are very short.
It is a further object of this invention to provide a honing guide that facilitates the formation of a curve or camber to the cutting edge or arris of a blade being sharpened using the honing guide.
These and other benefits of this invention may be understood by reference to the following drawings, the description set forth below, and the claims.
The chisel and plane blade honing apparatus of this invention illustrated in
Bar 34 is desirably relatively rigid so that it can be used with narrow, as well as wide, chisels 22 or other blades or tools without bending significantly. At the same time, positioning of bar 34 near the end of the chisel 22 requires that the forward-most portion of bar 34 be relatively thin so that it will not contact abrasive surface 44, as will be particularly well appreciated by reference to
As will also be appreciated by reference to
In the alternative, a jig 30 or 40 could be configured to remain attached to a guide during honing provided that it pivots out of the way or otherwise avoids preventing or unduly impairing honing functionality. One embodiment of this feature is illustrated in
In the illustrated embodiment, the jig 30 attaches to a sliding dovetail 48 formed on the front guide beam 28 so that the jig 30 is generally co-planer with the honing guide 20. Dovetail 48 is received in a dovetail way 50 on jig body 52. Jig arms 54 and 56 may be tightened against dovetail 48 by rotating thumb screw 58 to draw the jig arms 54 and 56 toward each other. Although the dovetail 48 structure is well adapted for temporary connection of the jigs 30 and 40 to the guide 20, any other attachment structures that temporarily and properly position the jig being used with respect to the guide could be used instead. For instance, such attachment could be accomplished with one or more screws or bolts, pins in one of the guide 20 or jig 30 or 40 could be received in holes in the other of the guide or jigs, or a tongue on one of the guide or jigs could be received in a groove in the other of the jigs or guide.
A series of parallel indicia lines 60 on jig body 52 may be marked with various bevel angles, and a jig stop 62 may be positioned on jig body 52 in predetermined locations using a securing device 64. Securing device may be a knurled head thumb screw threaded into stop 62 or a spring loaded pin, either of which may be received in one of several pin grooves 66 in jig body 52. Other securing devices 64 could be used, such as cam-acting clamps or any other structure that repositionably secures stop 62 in a selected desired location. Pin grooves 66 are preferably located at intervals that will position stop 62 to in turn position a chisel or blade for forming bevels 74 that form, with the reference surface 24 of the tool, angles between 20° and 40° in five degree intervals. A spring loaded ball or pin received in grooves 66 may also be used, as may a variety of other structures for securing stop 62 at any predetermined or other desired location on jig body 52. For instance, predetermined positioning of stop 62 could be achieved by penetrating jig body 52 with holes into which an end of securing device 64 is inserted to position stop 62 at the positions determined by hole locations. The location of stop 62 may be read by reference to the stop's location along the scale formed by indicia 60. While indicia 60 are illustrated on the side of jig 30, they could also be located on the top or bottom of jig 30.
As may be best appreciated by reference to
Adjacent to, and substantially parallel to, fence 25 is groove 25A, which is adapted to receive a pin (not shown) projecting from stop 62. This pin slidably engages groove 25A and provides a contact surface for the edge of the blade being sharpened. This prevents the blade from wedging itself between the underside of jig 30 and the opposing surface of stop 62.
After a principal bevel has been formed by abrading the bevel surface 74 against an abrasive surface such as stone 46 surface 44, the axis of rotation of roller 42 may be positioned further from back surface 24 of the chisel, thereby slightly lifting the tool or blade 22 and slightly increasing the angle of the tool or blade 22 by reference to the abrasive surface 44. This facilitates the easy formation of a micro bevel on the tool 22. Such axis of rotation movement may be accomplished, for instance, by rotating knob 76 that is part of an eccentric mechanism described in U.S. Pat. No. 4,733,501, the entirety of which patent is incorporated herein by reference.
For instance, in the embodiment of the invention shown in the figures, the roller 42 may be moved between the two positions by moving the position of the axle 49 on which the roller 42 rotates. The axle 49 may be eccentrically positioned on a shaft 43 that is spring loaded to hold a knob 76 on the end of the shaft 43 against a protrusion 45 (see
Honing guide 20 may also be used as a grinding jig. Structure behind the roller 42, such as a protruding ledge 21 easily seen in
The reference faces 81 and 83 of reference block 85 form the same angle “a” with base side 86 of block 85 as longer side 78 of skew chisel 70 forms with arris 172. A “right hand” skew is positioned on one side of the block 85 and a “left hand” skew is positioned for sharpening on the other side of block 85. For skew chisels having an arris at a different angle, a different block 85 with different angles “a” will be needed. Block 85 can be removably attached using appropriate fasteners such as screws (not shown), permitting use of interchangeable blocks for skews with different angles. Preferably, however, block 85 will be formed as a part of skew-setting jig 40, which is feasible because most skew chisels have the same angle (60°). As in setting jig 30 described above, arms 154 and 156 of jig 40 tighten against opposite sides of dovetail 48 in order temporarily to position jig 40 on guide 20 during positioning of skew chisel 70 in guide 20, but, as described above, any suitable alternative method of attachment could instead be used.
As may be understood by reference to
Indicia 90 (see
As will be appreciated by those familiar with tool manufacture, the guide body 32 and bar 34 can be made by die casting. Components so formed can then be anodized to form an attractive and wear-resistant surface. Components of this invention can also be manufactured of other materials and utilizing other manufacturing techniques. For instance, components could be machined from steel, brass (particularly in the case of the screws), or aluminum bar stock or could be molded of suitable plastic or plastic composite materials or produced by zinc die-casting.
As will be appreciated by those skilled in the art, this invention can be practiced in numerous alternative embodiments in addition to those shown in the drawings and described above without departing from the spirit of this invention or the scope of the following claims.
For instance, one or more wheels could be used rather than the illustrated roller, and other structures could be used for shifting the axis of rotation of the roller in order to form micro bevels, or such structure could be omitted entirely if its micro bevel forming function were not desired. A jig in accordance with this invention could also be structured for contact between the roller 42 and reference structure other than the abrasive surface 44. For instance, roller 42 could be arranged to contact bench-top or other planar surface on which the abrasive 46 rests, as is done in some prior art honing guides.
Another possible variation of the blade honing guide of this invention involves utilization of structures that change the range of bevel angles possible. This can be accomplished by changing the positions of the wheel axis of rotation relative to the blade securing structure (as is done in the micro-bevel structure described and incorporated by reference above, but by greater amounts). This can also be done by changing the angular position of the blade being held by the guide, as for instance changing the planes of the surfaces that clamp the blade.
An alternative embodiment of this invention having provision for an increased range of bevel angles by making the blade carrier and wheel frame separate components is illustrated in
As is shown in
Other structures than those illustrated in the Figures and described above can be used to join carrier 131 and frame 133. The mating surfaces of these components can have matching protrusions and recesses having many different structures or can utilize entirely different structures such as a sliding dovetail or other adjustable, interfitting structure and appropriate locking mechanism, including arrangements allowing pivoting attachment of the carrier 131 to the frame 133. Any structure may be used provided that it provides for securely and, preferably, repeatably attaching the carrier 131 to the frame 133 in a range of locations or in multiple locations, including more or less than three locations.
Furthermore, a wheel need not be the only structure used for contact with the abrasive stone or other reference surface. A low friction pad, a rail system, or another appropriate guiding system could all be used all be suitable.
The angular position of the blade or chisel being honed in the blade carrier portion of the honing guide of this invention can be modified by placing the blade or chisel between an opposed pair of matching wedges within the blade clamping structure.
Wedges 200 are shown installed in guide 20 in
Alternative end structures could be used on wedges 200 for positioning and retaining them on the honing guide. For instance, the ends of the wedges 200 could be penetrated by round holes for receiving the studs 38. Assembly of such wedges 200 and the honing guide would require removal of the bar 34 from the guide to position the wedges on the studs.
A recess 214 in the faces of the wedge 200 ensures that the blade or honing guide structure as may be the case contacts the wedge near its edges. Similar recesses 216 may be used in the face of the bar 34.
As is clear from the foregoing description and the accompanying
Formation of a gently curved cutting arris 300 like that of the typical bench plane blade 302 illustrated in
The width of the cylindrical middle 144 can vary from virtually none to a significant portion of the entire width of the roller 142, provided that the cylindrical portion is not so wide as to thwart the purpose of the non-cylindrical geometry of roller 142 as further described below and not so narrow as to make registration difficult. Alternatively, the roller could have a particular diameter in the middle 144 and continuously diminishing diameters moving away from the middle 144 toward each end 146 so that the roller (such as roller 148 in
While the camber roller 142 or 148 can be a variety of widths and nominal diameters and can have a variety of differences in diameter between the greatest diameter in the middle 144 and the smallest diameter at ends 146, such cylindrical middle portions 144 will usually be between 0.25 inch and 1.25 inches in length, preferably between 0.5 inch and 1 inch in length and most preferably between 0.375 inch and 0.625 inch in length. Roller 142 or 148 diameters will be dictated by the space available and are not critical to function of the device. The nominal roller diameter can be, for instance, approximately three-fourths of an inch. Differences in diameter between the roller middle 144 and the ends 146 may be about 60 thousands of an inch. For instance, the maximum diameter of the roller (at middle 144) can be approximately 0.712 inches, and the minimum diameter at ends 146 can be approximately 0.652 inches. As noted above, this taper can be straight or can have an arc profile from tangent at the maximum diameter to the minimum diameter. Such an arc can have a radius, for instance, of approximately 9.39 inches.
The honing guide having a camber roller 142 is utilized in the normal manner to hone a relatively wide blade such as a bench plane blade to produce a cutting edge or arris with a slight curve. This is accomplished by applying consistent finger pressure against the blade during honing in various locations across the blade and taking the same number of strokes with the finger pressure at each location. This can be done, for instance in three locations (left, right and middle of the blade) or in five or more locations across the blade. Because honing during application of pressure in turn in multiple discrete locations across the blade will result in a slightly faceted bevel, a few strokes can be taken while varying the pressure across the blade during the stroke in an effort to smooth out the arris curve.
Once a smooth primary bevel has been achieved, a micro-bevel can be produced by rotating knob 76 to utilize the eccentric system described above, thereby slightly elevating the angle of the blade relative to the abrasive surface, after which the above described process of applying varying pressure across the blade is repeated.
This application claims the benefit of U.S. Provisional Patent Application No. 60/809,230 filed May 30, 2006. This application is also a continuation in part of U.S. patent application Ser. No. 10/553,592 filed Oct. 17, 2005, which is a 371 U.S. national phase of International Patent Application No. PCT/IB2004/001152 filed Apr. 16, 2004, which claims the benefit of U.S. Provisional Patent Application No. 60/463,484 filed Apr. 17, 2003, the contents of all of which are incorporated herewith.
Number | Date | Country | |
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60809230 | May 2006 | US | |
60463484 | Apr 2003 | US |
Number | Date | Country | |
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Parent | 10553592 | Oct 2005 | US |
Child | 11754760 | May 2007 | US |