This invention relates generally to the field of woodworking tools.
In the hands of a skilled woodcarver, chisels and gouges are an excellent (and sometimes the only) hand tools that can cut virtually any contour on a workpiece. They are best used to cut specific shapes and details while working to layout lines, and for incising away sizeable chunks of waste material quickly. Often a mallet is used to drive the cutting edge into the wood. These tools are not as well suited to working areas of freeform surfaces to continuously blended finished contours, a task best performed by a tool that merely shaves or planes the surface, rather than cutting deeply into the wood under the skillful guidance, control, and physical effort of the woodcarver.
There are a great many designs and styles of woodworking hand planes and spokeshaves that have been developed over time, all to perform the same basic operation on a workpiece of wood or other workable material. That operation is to remove thin shavings of controlled thickness from a rough and/or uneven surface to render it smooth and even. When a perfectly flat surface is the objective, there are many designs to accomplish this task. From ancient wood-block planes to the most modem metal hand planes in current production, all have the same two features in common: a planar sole surface and a sharp-edged blade (traditionally called an “iron”) protruding slightly from the sole surface to shave material only from those areas of the workpiece that can come into physical contact with the sole.
In some cases, a convex surface or a concave surface must be made accurate in form and smooth in appearance. If the surface is cylindrical, a plane having a sole of complementary (matching) cylindrical curvature and a straight-edged iron can be used in the same manner as flat-soled planes are used on a planar surface. There are even some designs for planes with flexible soles that can be adjusted to match a desired curvature, and multi-piece soles whose elements can be positioned in relation to each other so they all will be in contact only with a certain cylindrical surface.
In general, a plane is adapted for work on a given flat, concave, or convex surface by machining its sole (the surface that contacts the workpiece) to have a complementary contour; i.e., flat, convex, or concave respectively. For compound-curved surfaces, the cutting edge of the blade can also be curved. Obviously, planes having flat or concave soles have limited utility on free-form three-dimensional surfaces because they can engage and cut only convex surfaces whose radius of curvature is less than that of the sole or the cutting edge. Work on any given three-dimensional free-form surface requires a plane having both a convex sole and a convex edge, each having a radius of curvature less than or equal to the smallest concave radius of curvature anywhere on the surface.
The cutting conditions on a three-dimensional compound-curved surface are quite different than on either planar or cylindrical surfaces. The sole of the plane is not in full contact with the work surface. Rather, contact occurs only in the vicinity of the mouth, through which the cutting edge of the iron protrudes. In order to maintain smooth cutting conditions, the plane must be guided over the work surface in such a way that the mouth is kept tangent to the work surface at all times. Sight and feel must be relied upon to selectively remove material only from those areas that are proud of the desired finished contour. The curvature of the sole has no influence upon the curvature of the surface of the workpiece unless the sole can come into substantially full contact with that surface.
A plane taking a full-width chip in hardwood, or even most softwood, requires a lot of force to push (or pull). For this reason, bench planes, with irons from 1.75 inches up to 2.63 inches in width, are designed to be held and used with two hands. Block planes are designed to be held and used with just one hand, and their irons are generally 1.38 inches wide, and not more than 1.63 inches wide, in order to limit the maximum force required to push the tool. They are often used to chamfer edges and corners, which limits the width of the chip and thereby minimizes the force required. However, when used to plane a flat surface, a block plane becomes much harder to push and control with just one hand, so the other hand is often needed to assist the gripping hand.
Aside from undesirably high force requirements, planes also have another characteristic that can cause great difficulty. Cutting “with the grain” is a term all woodworkers come to know and understand. This is especially important to the proper functioning of a plane, because cutting “against the grain” causes the iron to dig into the wood, lifting the fibers and splitting them apart ahead of the cutting edge rather than cutting them cleanly. Such a split will always extend below the line of cut, and the finished surface will have a defect (crater) in it that is called a “tear out”. In straight-grained woods, cuts can easily be made with the grain by good judgment gained from experience, and so-called “paring cuts” made across the grain at about a 45° angle to either side. However, there are woods having a curly grain pattern, such as Bird's Eye Maple and Tiger Maple, that cannot be planed in any direction without going against the grain in some portion of any cutting stroke. Here it is essential that the plane be able to cut freely and continuously without any tendency to “catch”, “dig-in”, or “stall in the cut” (common descriptive terms for typical interruptions of the cutting process). Whenever such an interruption occurs, it is likely to produce a tear-out in the surface. It should be noted that the lower the cutting force, the easier it is to control and maintain ideal cutting conditions at the cutting zone.
According to one aspect of the invention, a hand tool (shave) includes a housing, a handle portion, and a working portion with a blade rigidly mounted from the working portion of the housing. The blade has a sharp cutting edge at the protruding end, and a regulating post both rigidly and adjustably mounted in and protruding from the working portion of the housing. The embodiments include a regulating post which has a workpiece-engaging surface at its outer end that is closely proximate to but spaced apart from and generally aligned with said cutting edge of said blade.
The distance between the cutting edge and a proximate portion of the regulating post is approximately in the range of 0.0002 meters (0.010 inches) to 0.0007 meters (0.030 inches). Alternately, the distance between the cutting edge and a proximate portion of the regulating post is in the range of approximately 0.003 meters (0.125 inches) to 0.0008 meters (0.035 inches). The blade has a primary flat bevel and a secondary cylindrical bevel that defines a crowned cutting edge. According to certain embodiments of the invention, the primary flat bevel of said cutting edge is in the range of approximately 20 to 30 degrees. The cutting blade is made from a standard sized, industrial, pre-hardened and pre-ground blank tool bit. In an alternate embodiment, the blade is an ordinary wood chisel.
Another aspect of the invention includes the working portion being made from either metal and wood. In an embodiment, the working portion is made from an aluminum alloy.
The regulating post is adjusted to increase or decrease the thickness of the shavings removed from the workpiece surface. The blade and regulating post are positioned at an angular relationship with respect to each other, and the angle between the blade and the post is approximately 45° or be in the range of approximately 30°-60°.
In another aspect of the invention, the blade has a heel clearance with respect to a workpiece surface to optimize either a contouring or cutting function. The heel clearance is approximately 15 to 30°. The distance between the cutting edge and a plane defined by the surface of the working portion from which both the blade and regulating post protrude is greater than 0.006 meters (¼″). Alternately, this distance ranges between ⅜″ to ⅞″ or ½″ to ⅝″.
The body member adjustably locates and holds fixedly a lateral guide member. This guide member can be held in the form of a 90° V in close proximity to the workpiece-engaging surface of the regulating post, and the blade has a primary flat bevel and a secondary flat bevel that defines a straight cutting edge. Alternately, the body member adjustably locates and holds fixedly a lateral guide member in the form of a 90° V in close proximity to the workpiece-engaging surface of the regulating post, and the blade has a primary flat bevel and a secondary flat bevel that defines a straight cutting edge that is centrally notched at the same secondary bevel angle with a quarter-circle arc of arbitrary radius.
The foregoing and other features and advantages of the invention will be apparent from the following more particular description of embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention.
The embodiments of the invention include the use of two working elements, a cutting blade and an adjustable post in front of and closely proximate to the cutting edge to regulate and limit the depth of the cut. The end surface of the post is substantially flat, although it need not be, and is so positioned that when sighting across the flat, the cutting edge is just barely visible. If this flat end is brought into substantially full contact with a workpiece surface, the cutting edge is also just touching the workpiece. As the tool is tilted backwards with respect to the forward (cutting) direction, more of the cutting edge is exposed beyond the edge of the end surface of the post. This causes the thickness of the chip to increase in proportion to the angle of tilt. However, the tool can be tilted back only to the attitude where the sharpening bevel (defining the cutting edge of the blade) becomes parallel to and just begins to come into full contact with the freshly cut surface of the workpiece just behind the cutting edge. Any further backward tilt causes the cutting edge bevel surface to direct the cutting path up and out of the workpiece, thereby terminating the cut.
The embodiments of the invention recognize that in order to improve upon the cutting ability, ease of use, and the material removal performance of existing hand planes and spokeshaves to smooth and shape rough three-dimensional surfaces, it is necessary to (1) greatly lower the required cutting force, (2) maximize the rigidity of the blade with respect to the sole, (3) optimize the ergonomics of the tool to facilitate the following of complex surfaces while maintaining proper cutting conditions, (4) ensure that the cutting edge of the iron is truly sharp, can retain sharpness in extended heavy use, and can be easily renewed with minimum interruption of work whenever the edge begins to dull, and (5) improve visibility of the cutting process to enable the tool user to more easily judge material removal progress and accurately determine where further material removal is needed.
The embodiments of the invention also maximize the capability to cut and remove material without sacrificing full control of the cut. Productivity is directly dependent upon the number of cutting strokes that can be performed per unit of time. Good visual and tactile feedback from the tool can greatly reduce the wasted time between strokes, while improving the accuracy and quality of the completed workpiece.
There is always the aspect of safety in the use of any tool having a sharp cutting edge. The embodiments to not lend themselves readily to improper use and minimize the potential injury to the user in the event of a slip, attempted misuse, or merely just simple carelessness. This requires the cutting edge to be inherently well guarded, so that the user should need no special cautionary warnings regarding safe use of the tool.
The embodiments of this invention derive their performance advantages not only from the ergonomic design features, but also from the redundant elements that have been eliminated by their design. While all prior art involves some sort of surrounding frame, either full or partial, to support and hold the cutting blade in relation to the toe and/or heel portions of the guiding sole surface(s), the present invention eliminates all such surrounding structure. The blade and its cutting edge are fully visible so the tool user can see the workpiece surface directly and observe the chip as it is being cut, just as when using a chisel or a gouge, but unlike all other shaves and planes of traditional construction. In fact, visibility of the cutting edge is comparable to that of the scorp, an old but obscure carving tool for one-handed use that is similar in function to the more widely known inshave, a two-hand tool used for scooping-out larger hollows such as wooden gutters, bowls, and chair seats. These ancient tools both have a curved cutting edge facing towards the user, so cutting is done by pulling, rather than by pushing, but their cutting action is otherwise the same as that of any ordinary chisel or gouge. It is, of course, possible to use these tools in a backhanded manner, but this is awkward and would be done only when made necessary by obstructions in the vicinity of the work area.
Referring now to
If the tool is moved forward (left to right as shown in this view), no cutting can occur because cutting edge 4 is constrained by post 2 to remain just barely touching the existing outer surface 6 of workpiece 7. If, however, the tool is tilted backwards (rotated counterclockwise as shown in this view), the cutting edge 4 can now start to cut into surface 6 of workpiece 7, cutting deeper and deeper until the edge 5a of the end surface 5 of post 2 again contacts surface 6 of workpiece 7, thereby limiting any further increase in cutting depth.
Referring now to
When ν is equal to μ, the path of cutting edge 4 of blade 1 is controlled by contact of cutting edge bevel β with freshly cut surface 8 of workpiece 7. The angular difference γ between the primary and secondary sharpening bevels of cutting blade 1 provides “heel” clearance when working on a surface 6 that is concave. If a discontinuous depression deeper than the cutting depth into surface 6 is encountered, the cutting path will not follow it, but rather will continue on the current cutting path 8 until it clears through the depressed area in surface 6 of workpiece 7. If the attitude of the tool is not changed, the cut cannot resume until the far side of the depression is reached and the local positive slope of its surface diminishes to a value equal to or less than the angle ν, so that the cutting edge 4 of blade 1 can again contact surface 6 of workpiece 7. This sequence of events will occur each time the tool encounters the depression, until the depth of the depression below the surface of the surrounding area 6 of workpiece 7 is reduced to an amount less than the cutting depth of the tool, whereupon the next pass of the tool will establish a smoothly faired continuous contour for the surface 8 of workpiece 7.
Referring now to
Cutting blade 12 protrudes from the bottom end of the groove 11, facing backwards at angle φ, which is approximately 45°. Blade 12 is clamped solidly in place by a single, overlapping, standard size #10-24 tee-nut 13 and a #10-24 by 0.75 inches length flat head machine screw 14 seated in a standard size “quarter-inch” flat washer 15, whose actual size is 0.75 inches OD by 0.31 inches ID by 0.06 inches thickness. Flat washer 15 is seated in a 0.75 inches diameter by 0.10 inches depth recess in the right (far) side of body 10. Tee-nut 13 operates within a similar recess in the left (near) side of body 10, but is seated against the near side of blade 12 rather than the bottom of the recess.
In manufacturing cutting blade 12, the end of a standard ground blank tool bit is first ground to a primary included angle α of approximately 15°, and the secondary bevel is then ground and honed to an included angle β of approximately 30° to produce the sharp cutting edge. The initial length of the secondary bevel, as measured from the cutting edge 12a back to the intersection with the primary bevel, is typically about 0.06 inches, but it will become longer each time the blade 12 is re-sharpened by grinding and/or honing the secondary bevel. As the length of the bevel increases, the tool becomes more able to smooth-out variations in surface contour, but is less able to cut smoothly in concave areas of small radius. The particular cutting conditions determine the optimum length for this bevel, but it is not at all critical for most typical work if the length of the secondary bevel is less than 0.25 inches.
A #10-32 by 2.00 inches length, fully threaded, standard thumbscrew 16 in a threaded hole inset 0.188 inches from the left (near) side of body 10 extends completely through body 10 from top to bottom, with its end 16a in close proximity to, and nominally centered on the width of the cutting edge 12a of blade 12. The end 16a of thumbscrew 16, which serves as the toe portion of the sole of the shave, is preferably ground flat and perpendicular to the axis of the screw, but alternatively may be left in the “as formed” condition, which is generally concave with a raised rim 16b defining a plane that is perpendicular to the axis of the screw. Since the size of end 16a is small in comparison to the radius of curvature of any typical contour that will be worked, concavity or slight convexity of 16a is virtually irrelevant, provided that the outside edge 16b of end 16a is uniform and the plane defined by this edge is perpendicular to the axis of the thumbscrew 16. The cutting edge 12a of blade 12 is typically positioned approximately 0.03 inches away from edge 16b of end 16a of thumbscrew 16, but this gap may be made smaller or larger to alter the cutting response of the tool to changes in angle ν (as previously defined in
In general, widening the gap between cutting edge 12a and edge 16b causes the tool to become more aggressive in stock removal and better suited to roughing work. Closing this gap makes the tool more controllable and easier to use for finishing work. Thumbscrew 16 is typically positioned initially to align the plane of its end surface 16a with cutting edge 12a, but its threads permit “fine tuning” to directly alter the effective exposure of cutting edge 12a and thereby to directly alter the cutting depth without changing the “feel” of the cutting action. Whatever the initial setting of the mouth opening (gap), thumbscrew 16 can be easily adjusted to compensate for varying cutting conditions, such as wood hardness or cutting edge sharpness, as the work progresses.
Referring now to
Again, for reference and to illustrate the fundamental relationship of the tool and workpiece during the cutting process, a partial workpiece 7 is shown in phantom in
Referring now to
Referring now to
In order to facilitate following a sharp or narrow edge and maintain constant dimensions of the finished chamfer, it is necessary to add only a simple guide. A bar 41, which is 0.250 inches square by 2.50 inches length, with a 90° V-notch 41a centered in its end serves this purpose. Bar 41 is aligned and located by a groove in the left (near) side of body 40 and clamped fixedly in place by a fastener assembly (identical to that used for blade 12′) comprising tee nut 13′, machine screw 14′, and flat washer 15′. To place the V-notch 41a closely proximate to the end surface 16a of thumbscrew 16, yet provide ample clearance for the wings of thumbscrew 16 at the top of body 40, the groove and bar 41 are tilted clockwise approximately 10°; i.e., angle φ is approximately 80°. For reference, a workpiece 7′ is shown with its 90° (nominal) sharp edge 6′ within the V-notch 41a and just touching the edge 16b of end surface 16a of thumbscrew 16, and with cutting edge 12a′ making a chip and thereby creating newly cut chamfer surface 8′ just behind it.
Referring now to
Referring now to
Although the embodiments of the invention already described are all designed to cut when pulled, this alternate embodiment is designed to cut when pushed. To illustrate the relationship of the tool and the workpiece, a partial workpiece 7′ is shown with its existing surface 6′ in contact with edge 53b of end surface 53a of thumbscrew 53, and cutting edge 52a of blade 52 cutting at maximum depth to expose freshly cut surface 8′ of workpiece 7′. It should be noted that the attitude of the tool, as measured by the angle ν between the surface 6′ of workpiece 7′ and the plane of end surface 53a of thumbscrew 53, is the same as in the other embodiments when any of them is performing a maximum depth cut.
Referring now to
It is of course possible to grind and hone the cutting edge with a negative crown; i.e., in the form of a quarter-circle notch having radius of curvature ρ and arc length πρ/2. If the notch radius is ρ=0.125 inches, this blade may be used in the above described fourth embodiment of the invention (instead of blade 12′ having a straight cutting edge 12′a) to shave a perfect 0.125 inch radius (instead of a straight 45° chamfer) on any straight or curved 90° edge. A blade, having a quarter-circle notch of radius ρ=0.06 inches, arc length πρ/2=3.1416*0.06/2=0.094 inches, and installed in the fourth embodiment of the invention, is the ideal tool for use by furniture builders and finish carpenters to quickly shave a clean, uniform radius on all sharp or ragged edges of trim boards, molding, shelves, casings, etc. in preparation for final sanding and finishing.
It should be emphasized here that there are many possible variations of design and construction of the elements of the embodiments of the invention in addition to those embodiments thus far described herein. For example, if the body is made of metal (which is much stronger than wood) the hand tool can be much smaller and can provide more operating clearance in very tight quarters. This can also offer more freedom to optimize the ergonomics of the tool by possibly providing a more comfortable hand position when gripping it. Another embodiment illustrating the combination of a machined aluminum body with an adjustable wooden handle is shown in
Referring now to
While threaded regulating posts have been shown and described with respect to all the embodiments, there are other constructions that can provide both adjustability and similar function. Generally, they are not as simple or inexpensive to make and/or to use as are standard thumbscrews or machine screws. Therefore, other alternative means are not now shown in the embodiments of the invention, even though they are intended to fall within its scope. It should be obvious to anyone skilled in the art that there are many specialized applications of the embodiments of the invention quite unrelated to wood carving that can benefit from other embodiments vastly different in appearance, size, and proportion from those described herein, and yet can employ the same underlying principles, knowledge, and understanding of the cutting process that is taught within this disclosure.
Other aspects, modifications, and embodiments are within the scope of the following claims.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 60/512,430 filed Oct. 20, 2003, the entire contents of which is incorporated herein by reference.
Number | Date | Country | |
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60512430 | Oct 2003 | US |