The present invention relates generally to sharpening devices for knives, shears and other blades. In particular, the present invention is directed to a sharpening system for both convex and beveled edges, with varying angles of the edge along the length of the blade.
There are currently a wide variety of different blade types used on a wide variety of different cutting implements. Depending upon the implement used and the duty cycle that it must endure, periodic sharpening is required. A sharpening system and process is often adapted to the particular type of blade used.
One major drawback in the art of sharpening blades is that there is a certain amount of deterioration of the blade caused by the sharpening process. Over time, this can either destroy or alter the blade's fundamental characteristics. Accordingly, the precision of the sharpening device and sharpening process, (as well as the duty cycle of the blade) become critical to the life of the blade.
One type of blade that is subject to intense duty cycles, and subsequently frequent sharpening programs, is found in shears/scissors, especially those used for cutting hair. There are three types of blade typically found in barber shears/scissors, as depicted in
Practice indicates that convex blades are preferred for scissors or shears, especially those used for cutting human hair. Because of the duty cycle for such shears/scissors, frequent sharpening is necessary. Unfortunately, the sharpening of convex blades, such as those preferred in barbering applications, is the most difficult to accomplish. This type of blade is especially vulnerable to degradation or changes in shape during the sharpening process.
Currently, a number of approaches to the sharpening of convex edges, such as those that are used in barber shears exist. The first of these is to maintain the convex edge along the length of the blade by rolling the edge on the outside of a grinding wheel. This technique requires that several passes be made, in which the angle to the sharpening wheel is changed for each pass. The result is usually a series of hollow ground cuts that look similar to a convex edge, but in reality, differs slightly (as indicated in the comparison of edges depicted in
There are conventional sharpening devices that use a flat disk and a clamp to carry out a process of rolling the blade against the flat disk to create a convex edge. However, this approach has a number of problems. Firstly, if the blade is not lifted at exactly the right time (within a millisecond of the precise time required) during the pass, a “micro-bevel” is placed on the outside of the cutting edge. This is a deviation from the true convex edge (as depicted in
Another problem with conventional sharpening process for shears/scissors is that many scissor manufacturers have started to coat the outside of the blade with electro-plated metals to provide certain blade characteristics. Unfortunately, when conducting the conventional process of rolling the blade during sharpening, the plating can be moved or damaged, resulting in an unsightly finish on the scissors, as well resulting in a failure to obtain a true convex edge.
To complicate matters, such problems are often exaggerated by some scissor designs that include a changing angle from the back of the blade to the tip. This initial design is accomplished in the factory by uniformly sharpening the scissors blades in the manufacturing plant and then bending them to the final curve (which includes the varying edge angle along the length of the blade). The result of this particular design is that the sharpening process is rendered extremely difficult, especially in view of the need to not alter or damage the blade.
Currently, approximately 90% of the barber/beauty shear manufacturing industry production is directed to convex edges. Further, approximately of all barber/beauty shears or scissors are coated with a colored finish. In order to address such products, conventional sharpening systems have become quite complex, and very time consuming. For example, a conventional sharpening process for a convex edge can take as many as four or five abrasive wheel changes (and many passes) for each blade. Even with extreme care and expenditure of time, damage or unfavorable deformation of the blade can still take place with conventional systems.
Accordingly, a need exists for a sharpening system, especially a sharpening system for shears or scissors, that can quickly sharpen a convex blade along its entire length without damaging or deforming the blade from its desired shape, or cover. An improved sharpening system would also be relatively error free while conducting rapid sharpening of both convex and bevel edged shears.
Accordingly, it is a primary object of the present invention to provide a sharpening system and method that overcome the limitations of conventional blade sharpening systems.
It is an ongoing object of the present invention to provide a sharpening system that can sharpen both convex blades and bevel edged blades without causing damage or unfavorable deformation to any part of the blade surface.
It is another object of the present invention to provide a sharpening system that operates very quickly without causing unfavorable changes to the blade.
It is a further object of the present invention to provide a sharpening system that easily accommodates accurate sharpening along the entire length of the blade.
It is an additional object of the present invention to provide a sharpening system that automatically accommodates changes in the shape of the blade along its length.
It is again a further an object of the present invention to provide a sharpening system that is equally efficacious for both convex and bevel-edged blades.
It is yet a further object of the present invention to provide a sharpening system that allows for exact sharpening angles to be set and transferred to the blades that are being sharpened.
It is still an additional object of the present invention to provide a sharpening system in which a true convex blade can be sharpened in a single pass, while accommodating a changing edge angle along the length of the blade.
It is yet a further object of the present invention to provide a sharpening system which can adjust the angle to a greater or lesser degree from one part of a blade to another.
It is again another object of the present invention to provide a sharpening system which facilitates easy operation on virtually any type of blade.
These and other goals and objects of the present invention are accomplished by a sharpening system which places an edge to be sharpened on the interior diameter of a grinding wheel.
a) is a perspective view of a grinding wheel used with the present invention.
b) is a front view of the grinding wheel of
c) is a side view of the grinding wheel of
a) is a perspective view of a cam used as part of the present invention.
b) is a top view of the cam of
c) is a bottom view of the cam of
d) is a side view of the cam of
a) is a top view of a cam shim of the present invention.
b) is a side view of the cam shim of
a) is a top view of the grinding wheel and blade holding mechanism of the present invention, in a first position.
b) is a perspective view of the blade holding clamp used to hold the blade in the arrangement of
The present invention is a sharpening device which sharpens both convex and beveled edges and has the ability to create a graduated angle along the length of the blade edge. The basic system, as depicted in
In particular, the abrasive surface of grinding wheel 5 is found on the inner circumference 51, rather than on the outer circumference as is done conventionally. The outer circumference of grinding wheel 5 contains a circumferential indent or groove 10. The circumferential groove 10 is used to accommodate driving and stabilization devices as will be described supra. The use of the novel blade holding and guide mechanism with the novel grinding wheel 5 is also described supra. The particular configuration of grinding wheel 5 facilitates a number of desirable features.
For example, the grinding, honing and polishing wheels 5 are arranged for quick changes to facilitate the sharpening of a wide variety of different blades. The drive motor (not shown) has a reversing switch as well as a speed control, thereby allowing for very precisely controlled metal removal during the sharpening process. The mounted motor has a drive tire 3 on the shaft 2 and a triangular configuration of idler wheels 4(a), 4(b) (all located in groove 10) to maintain speed control and stability. The top idler wheel 4(b) is spring loaded to allow the grinding, honing and polishing wheels 5 to be quickly changed.
A tri-part arm assembly (
The details of the present invention are depicted in
A guide arm 6 is attached to the vertical leg 1(b) of the base in such a manner that the face of the arm 6 is in the same vertical plane as the face of the vertical leg 1(b) of the base 1. Guide arm 6 has a pivot connection 7 that allows for a torsion spring 8 to place a force downward in the direction of the horizontal leg of the base 1. An idler tire 4(b) is attached to the guide arm 6 in such a position so that when the guide arm 6 is lifted, and the abrasive or grinding wheel 5 is inserted, it will form an equilateral triangle (with idler tires 4(a), 4(b) and drive tire 3) over the outside of the abrasive wheel 5.
The abrasive wheel 5 is arranged with the annular, circumferential indentation or groove 10 formed between sidewalls 52 of the abrasive wheel 5. The indentation 10 is specifically sized to accommodate the drive tire 3 and idler tires 4(a), 4(b). The torsion spring 8 on the guide arm 6 holds the drive tire 3 annular indentation 10. This configuration allows the abrasive or grinding wheel 5 to be held in place and to spin freely and be rotated easily by the drive tire 3. This arrangement allows for quick change of the abrasive wheel 5 by simply lifting guide arm 6 and inserting a different abrasive wheel 5 into the configuration.
It is crucial that this arrangement allows for the center of the abrasive wheel 5 and its inner circumference surface 51 to be free of obstruction so that a blade 300 can be presented to the inside surface 51 of the abrasive wheel 5 for sharpening. The blade holding the control arrangement in
A special tri-part arrangement of mutually hinged arms 14, 16, 23 (
A post 11 is attached to the horizontal leg 1(a) of the base 1. Post 11 has a hole in the center so that support pin 12 can be inserted into it. A locking mechanism 13 such as thumb screw will allow support pin 12 to be raised and lowered as well as turned and locked into place. On top of support pin 12 is the arrangement of three arms 14, 16, and 23, and two pivot joints, as depicted in
The details of the cam and arm interface are best illustrated in the exploded view of
A thumbscrew 20 is threaded through the bottom of arm 14 in such a position that it aligns with a circular arrangement of dents in the bottom of cam 15. This allows cam 15 to be locked into any position with the thumbscrew 20. Threaded screw 21 is threaded into a hole in arm 16 and passes through and rides on the surface of the cam 15, and along with the compressed spring 18 causes the arm 16 to raise and lower, as directed by cam 15, as the arm 16 is rotated.
The amount of vertical adjustment (and thus, the angle at which the blade is placed against the interior surface 51 of grinding wheel 5) over the length of the blade 300 is controlled through the use of magnetic shims 22 (as depicted in
Arm 16 can be set vertically by turning screw 21 when a shim 22 is added to cam 15 or a new cam is added. The position of arm 16, also effects the position of the upper most arm 23. This is done by means of the tri-arm structure (14, 16, 23) depicted in
At the opposite end of arm 23, is a bushing 28, with a bore the same size as pin 25 on the blade holding clamp 26, as depicted in
As the blade is drawn across the inner surface of the abrasive wheel 5, a true convex edge is maintained. The precise angle is maintained using calibration markings on pin 12 to identify specific angle settings. Cam 15 permits the angle to be changed by a specific amount per inch of blade so that the changing shape of the convex blade along the length can be accurately maintained during the sharpening operation.
When conducting the sharpening process, arms 14, 16 and 23 are set in position as depicted in
The tool rest assembly, as depicted in
The key advantage of using cam 15 is that a blade 300 can be drawn across the interior 51 of the abrasive wheel 5 in one fluid movement. The height of the blade 300 and thus the grinding angle is changed as required by the action of the cam 15 as arms 16, 23 rotate with respect to each other in each pass. Gradation marks on grind wheel 5, shaft 30, tool rest 29, and screw 37 all help to facilitate grinding accuracy.
The present invention also facilitates quick, exact sharpening for other types of blades. For example, if a uniform angle is desired, the arm (14, 16, 23) is adjusted along pin 12 for 45°, without the benefit of cam 15. The 45° grinding angle would be carried out along the full length of the blade. This would be considered ideal for beveled edges or hollow ground edges, which do not change angle along the length of the blade.
In another example, in a sharpening process used for convex blades, the cam 15 would be engaged at 1.5° per inch of blade (a very common setting) and the arm (14, 16, 23) position on pin 12 is set for a starting angle of 45°. As the blade 300 is drawn along the interior 51 of the abrasive wheel 5, the grinding wheel angle would drop uniformly at a rate equal to 1.5° per inch of blade until the end of the blade was reached. If the blade is four inches long, there would be a 6° less of grind angle, or a change from 45° to 39°. The testing of the present invention indicates that this would be an appropriate setting for the most commonly used beauty/barber shears.
In operation, as depicted in
Because of the precise adjustment to accommodate changes in blade shape, the present invention facilitates rapid sharpening of the blades. Very often, only a single pass is necessary to provide a complete sharpening operation using the system of the present invention. Because of its wide range of adjustments, the present invention can accommodate virtually every type of blade size and configuration. Likewise, a wide variety of blade types can be sharpened by the present invention.
While a number of embodiments have been provided as examples, the present invention is not limited thereto. Rather, the present invention should be understood to encompass any variations, modifications, adaptations, derivations, embodiments, or evolutions that would occur to one skilled in this part once in possession of the teachings of the present invention. Accordingly, the present invention should be construed as being limited only by the following claims.
The present application claims priority to U.S. Provisional Application No. 61/283,552 filed on Dec. 3, 2009, making reference to same herein in its entirety.
Number | Date | Country | |
---|---|---|---|
61283552 | Dec 2009 | US |