BACKGROUND INFORMATION
1. Field
Embodiments of the disclosure relate generally to the field of shaving razors and more particularly to a system incorporating a razor with an extendible blade received within an automated sharpening system having a blade extension armature, a reciprocating sharpening mandrel rotatable between two positions for sharpening both sides of the blade, a stropping system, a positioning sensor system, an ultraviolet disinfecting element and a magnetic blade polarization system.
2. Background
Shaving of facial and body hair is undertaken by both men and women to various degrees. Initially shaving was accomplished using a straight razor. However, the relative skill required to avoid cutting the skin during shaving made the straight razor an unattractive tool. Various devices including the safety razor and modern removable/replaceable/disposable head razor cartridges with multiple blades or entirely disposable razors have been invented to reduce the hazards of shaving while providing a reasonably safe and comfortable shave.
However, the advantages of the straight razor including the a rigid high quality steel construction for maintaining a sharp edge for an extremely clean and close shave, and the ability to resharpen the edge continuing long term use have not been duplicated in modern razor systems. Further, disposable razors are wasteful of both economic and natural resources and are by definition engineered to be operationally obsolescent within weeks if not days.
It is therefore desirable to provide a razor and sharpening system which maintains the efficiency and safety of modern disposable razor systems but also provides a higher quality shave with a long life reusable system.
SUMMARY
Embodiments disclosed herein provide a shaving system which includes a razor having a handle and a safety housing with a blade extendably received within the safety housing. An integrated sharpening system incorporates an armature receiving the razor, the armature being movable from a first position for attachment and extraction of the razor and a second position for sharpening of the blade. A sharpening mandrel is provided with a first sharpening surface for sharpening a first side of the blade and a second surface for sharpening of a second side of the blade. The sharpening mandrel is rotatable from a first position for engagement of the first sharpening surface to a second position for engagement of the second sharpening surface. The sharpening mandrel is laterally oscillated for sharpening of the blade. A controller is provided for positioning of the armature and sharpening mandrel.
The shaving system allows a method for sharpening a razor which is accomplished by engaging a razor having a blade extendibly mounted in a safety housing in an integrated sharpening system. The blade is then extended and a sharpening mandrel is rotated to a first position for engagement of a first side of the blade. The sharpening mandrel is then oscillated to hone the first side of the blade. The sharpening mandrel is then rotated to a second position for engagement of the opposite second side of the blade and oscillated to hone the second side of the blade. The blade is then retracted and the razor is disengaged from the integrated sharpening system.
The features, functions, and advantages that have been discussed can be achieved independently in various embodiments of the present disclosure or may be combined in yet other embodiments further details of which can be seen with reference to the following description and drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective partial section side view of a first embodiment of the razor and integrated sharpening system;
FIG. 2 is a perspective partial section side view of the embodiment of FIG. 1 with the sharpening mandrel and mandrel holder removed for display of remaining components;
FIGS. 3A and 3B are side section views of the embodiment of FIG. 1 with the razor in preparation for insertion and inserted into the integrated sharpening system;
FIGS. 4A-4E are simplified schematic representations of the operating components of the embodiment of FIG. 1 showing the sequence of operation for blade sharpening;
FIG. 5A is a perspective view of a second embodiment of the razor;
FIG. 5B is a perspective partial section view of the razor embodiment of FIG. 5A with the blade retracted;
FIG. 5C is a perspective partial section view of the razor embodiment of FIG. 5A with the blade extended;
FIG. 6 is a perspective partial section side view of a second embodiment of the integrated sharpening system for use with the razor of FIGS. 5A and 5B;
FIGS. 7A-7D are side section views of the operating components of the embodiment of FIG. 6 showing the sequence of operation for blade sharpening;
FIG. 8A is a top partial section perspective view of a third embodiment of the razor with the blade in a retracted position;
FIG. 8B is a top partial section perspective view of a third embodiment of the razor with the blade in an extended position;
FIG. 9A is a perspective partial section side view of a third embodiment of the integrated sharpening system for use with the razor of FIGS. 8A and 8B;
FIG. 9B is a perspective partial section view of the embodiment of FIG. 9A with the razor moved into the sharpening position and the blade extended;
FIG. 9C is a top view of the embodiment of FIG. 9A;
FIG. 10 is an isometric view of an embodiment providing an alternative honing structure with stropping wheels for finer edge finish;
FIG. 11 is a side view of the embodiment of FIG. 10 partially sectioned to demonstrate the components in the honing and stropping assemblies;
FIG. 12A is a side view of the embodiment of FIG. 11 with elements removed showing the honing assembly engaging the blade for honing on a first side;
FIG. 12B is a side view with elements removed showing the honing assembly engaging the blade for honing on a second side;
FIG. 13A is a side view showing the stropping assembly engaging the blade for stropping on a first side;
FIG. 13B is a side view showing the stropping assembly engaging the blade for stropping on a second side;
FIG. 14 is an isometric view of yet another embodiment providing combined honing and stropping in adjacent wheels;
FIG. 15A is a side view of the embodiment of FIG. 14 with elements removed showing the honing assembly engaging the blade for honing on a first side;
FIG. 15B is a side view with elements removed showing the honing assembly engaging the blade for honing on a second side; and,
FIG. 16 is a block diagram of an exemplary control system for implementation of blade sharpening.
DETAILED DESCRIPTION
Embodiments disclosed herein provide a self sharpening razor system incorporating a razor carrying a high quality steel blade, for example stainless or carbon steel with minimum Rockweel hardness of approximately 58, which is extendible from a safety housing for sharpening and an integrated sharpening system in an enclosure receiving the razor. The integrated sharpening system provides a blade extension armature for positioning the razor and/or blade, a reciprocating sharpening mandrel rotatable between two positions for sharpening both sides of the blade, a proximity sensor positioning system an ultraviolet disinfecting element and a magnetic blade polarization system with an internal controller for automated sharpening and preparation of the razor for use.
Referring to the drawings, FIG. 1 shows a first exemplary embodiment for a razor 10 and integrated sharpening system 12. The razor 10 employs a handle 14 which carries a safety housing 16 enclosing a blade 18 which is extendible from the housing. The integrated sharpening system 12 is housed in a case 20 A blade extension armature 22, which removably receives the razor housing and blade on an engagement post 24, is movable from a first position (shown) for insertion of the razor to a second adjustable position for sharpening of the blade indicated by arrow 26 (as will be described in greater detail with respect to FIGS. 4A-4C). A translation motor 28 supports the blade extension armature 22 and provides the desired reciprocating motion.
Contained within the case 20 is a sharpening mandrel 30 which is removably carried by a mandrel holder 32. The holder is supported on saddles 34 (shown in greater detail in FIG. 2) for rotation, represented by arrow 36, about a longitudinal axis by a mandrel rotation motor 38. The sharpening mandrel 30 incorporates two sharpening surfaces which for the embodiment shown are two sharpening pads 40a and 40b on angularly displaced faces which are positioned for sharpening of opposing sides of the blade 18 of the razor through the rotation of the sharpening mandrel. For an example embodiment, the sharpening pads are an injection molded plastic with a thin coating of Cubic Boron Nitride (CBN) dust or diamond dust bonded to its surface to act as a sharpening media. The estimated size of the sharpening dust particles will be between 0.25-2 microns in size. For the embodiment shown, the open angular segment of the mandrel subtends approximately 75° of arc. An oscillating motor 42 attached to the mandrel holder 32 provides lateral oscillation of the sharpening mandrel 30 and associated sharpening pads 40a and 40b as indicated by arrow 44. In the example embodiment, a voice coil motor is employed but alternative motor types may be used in other embodiments.
While described with respect to the drawings as sharpening pads with abrasive surfaces, the pads may also employ materials for stropping the blade to provide blade alignment and sharpness without actual removal of material as in sharpening. In alternative embodiments, the sharpening pads, 40a and 40b may be replaceable with interchangeable abrasive and stropping elements.
An ultraviolet (UV) lighting system having a lower head 46a and an upper head 46b is provided in the case as a sanitizing element. The heads are positioned such that the extended blade 18 and end portion of the safety housing 16 passes between the lower and upper head exposing all contact points on the razor to the UV light for optimal elimination of microbial contaminants. An electromagnet 48 positioned in the case adjacent the extended blade enhances corrosion resistance by alignment of the metal ions in a plane of the shaving edge of the blade with an electromagnetic field after the sharpening cycle as described subsequently.
Control of the integrated sharpening system is accomplished with a controller 50 which may incorporate a microprocessor or other control logic and associated control circuitry on a printed circuit board 52 mounted within the case. Power for the motors and controller is provided by a battery 54, or in alternative embodiments a standard 110v AC connection stepped down with an appropriate transformer circuit to 6 volts for either direct use or battery charging. Associated with the controller 50 is a Radio Frequency Identification (RFID) reader 56 which is positioned in the case 20 to read an RFID tag associated with each razor housing 16. Identification of the razor being sharpened allows the controller to specifically tailor the sharpening operation to that razor blade taking into account age and wear and may also provide the ability to notify the user when the useful life of a blade has been exceeded based on stored data as well as track product warranty related usage. proximity sensor positioning system 58, which may employ a photo cell “detection eye”, other optical sensor, a capacitive or inductive position sensor, is connected to the controller 50 and positioned adjacent the sharpening mandrel 30 for precise location of the edge of the blade 18 for accurate positioning and sharpening. Measurements by the proximity sensor positioning system of the blade position/length prior to sharpening and after sharpening may be stored by the controller for use in blade wear data cataloging. A second proximity sensor positioning system may also be used to accurately reposition the razor blade relative to the to safety housing 16 account for blade wear caused by sharpening.
A removable debris catch tray 60 is positioned in the case 20 under the sharpening mandrel to catch and retain debris such as hair and grinding dust accumulated from sharpening of the blades. Slots in the sharpening mandrel 30 allow metal debris to fall into the tray 60. The case 20 includes a frame providing the mounting features required to securely fasten all internal components with accuracy. This sub-frame may be made from injection molded ABS plastic or die cast zinc material.
As shown in FIGS. 3A and 3B, the safety housing 16 of the razor 10 is inserted through aperture 62 to be received on engagement post 24. For the embodiment shown the engagement post employs a spring loaded detent ball to engage a receiving cavity on the blade 18 in the safety housing 16 of the razor 10. In the inserted position as shown in FIG. 3B, the razor is then ready for the sharpening operation. As shown in simplified schematic form for the first embodiment in FIGS. 4A-4D, the razor is aligned with the engagement post 24 (FIG. 4A) and pressed onto the post (FIG. 4B). For this embodiment of the razor safety housing and blade the blade 18 is frictionally engaged between resilient back elements 64 and a front plate 66 of the housing 16 (as best seen in FIG. 4D). Engagement arms 68 are received through slots in the front plate and, when the razor safety housing 16 is urged onto the engagement post 24, urge the resilient back element away from the rear surface of the blade 18 releasing the frictional engagement of the blade in the housing. An array of spaced ridges or dimples 70 may be employed to enhance the frictional engagement to additionally secure the blade and to provide fixed increments for length positioning of the blade upon reinsertion into the housing.
The safety housing for various embodiments may be made from injection molded Acrylonitrile-Butadiene-Styrene (ABS) plastic or Die Cast aluminum with an anodized finish. If made from aluminum the resilient back elements may be spring steel component to act as the locking feature for the guard. If made from plastic the resilient elements can be molded directly into the part as a “living hinge” type design. For the example embodiment, the razor blade is a steel alloy in the 200 series with post hardening treatment to achieve a Rockwell hardness of approx. 58-62. The edge of the blade is sharpened to an included angle of 15 degrees. The blade will include the ridges 70 as a stamped feature. The thickness of the blade is between 0.035″-0.045″
Extension armature 22 is then translated downward by translation motor 28 extending the blade 18 which is secured by the engagement post 24. Depending securing elements 72 on the arms 68 (which are shown as smooth for mere frictional engagement but may be hooked or otherwise mating indexed to the front plate 66 of the housing) prevent downward translation of the housing. Translation motor 28 is controlled by the controller 50 to move the extension armature 22 for positioning of the blade 18 as determined by the proximity sensor positioning system 58. The blade edge is placed at a predetermined position for correct angular contact by the sharpening pad 40a on the sharpening mandrel 30 which has been angularly positioned by the mandrel rotation motor 38 (shown in FIGS. 1 and 2) for contact with the blade. The sharpening mandrel 30 is then reciprocated laterally along the blade edge by the by the oscillating motor 42 (as seen in FIGS. 1 and 2) honing a first side of the blade edge. The sharpening mandrel 30 is then rotated by the mandrel rotation motor 38 to angularly position the second sharpening pad 40b on an opposite contact plane with the blade. The sharpening mandrel 30 is then reciprocated laterally along the blade edge by the by the oscillating motor 42 honing a second side of the blade edge. Adjustment of the extended length of the blade between the honing of the two sides of the edge may be accomplished, if required, by the translation motor moving the extension armature as directed by the controller based on the blade location detected by the proximity sensor positioning system.
Upon completion of the sharpening process, the translation motor 28 moves the extension armature 22 upward to retract the blade 18 into the safety housing 16 with calculated alignment with the spaced array of dimples 70 for optimal shave angle of the blade relative to the housing. The translation motor 28 may be a stepper motor, piezo electric motor or similar precision motor allowing precise control by the controller for the retracted length to accommodate the overall length reduction in the blade due to the sharpening procedure. Removal of the razor from the engagement post 24 returns the resilient arms 64 into contact with the blade 18 to frictionally secure the blade within the safety housing 16. Additionally with use of a stepper motor or motor having similar accuracy as the mandrel rotation motor 38, the controller may adjust the rotation angles of the mandrel 30 in combination with the blade position using the translation motor 28 such that the blade is moved for spaced contact slightly outward on pads 40a and 40b from where the blade touched in the last sharpening session. Once the entire pad has been used, the logic resets the blade onto the inside portion of the sharpening pads 40a and 40b closest to the vertex of the mandrel and the sequence starts over again.
A second exemplary embodiment of the razor 10 is shown in FIGS. 5A through 5C. As with the first embodiment, the blade 18 is extendably retained with a safety housing 16. However, the blade 18 incorporates a tracking dolly 74 which is engaged by a jack screw 76. The screw 76 incorporates a hex bore 78 for drive engagement. Rotation of the screw 76 drives the tracking dolly 74 which extends or retracts the blade into the housing. In alternative embodiments, a gear rack machined into the upper surface of the blade 18 may engage the jack screw for extension and retraction of the blade.
A second exemplary embodiment of integrated sharpening system 20 to accommodate the razor second embodiment is shown in FIG. 6 with components in common with FIGS. 1-3C carrying the same element numbers. The razor 10 is inserted into the aperture 62 in case 20 and rotating engagement post 80 is received within the hex bore 78 which may incorporate a spring loaded detent ball to be received within a detent in the hex bore to secure the razor into the case. A drive motor 82 with appropriate drive train rotates the rotating engagement post 80 and the engagement post 80 with drive motor 82 and drive train are mounted to a translation armature 84. A translation motor 86 moves the translation armature 84 to position the safety housing 16 within the case as required by the controller 50. While not shown in FIG. 6, the UV lighting system, RFID reader and electromagnetic polarization system as described with respect to FIGS. 1 and 2 may be employed in the second embodiment.
As shown in FIGS. 7A-7C, the safety housing 16 of the razor 10 is inserted through aperture 62 and hex bore 76 is aligned with the engagement post 80 (FIG. 7A) and pressed onto the post (FIG. 7B). Translation armature 84 is then translated downward by translation motor 86 (FIG. 7C). Drive motor 82 is then operated to rotate rotating engagement post 80 and 76 screw to drive gear rack 74 extending the blade 18 (FIG. 7D). Translation motor 86 and drive motor 82 are controlled by the controller 50 for positioning of the blade 18 as determined by the proximity sensor positioning system 58. The blade edge is placed at a predetermined position for correct angular contact by the sharpening pad 40a on the sharpening mandrel 30 which has been angularly positioned by the mandrel rotation motor 38 (shown in FIGS. 1 and 2) for contact with the blade. The sharpening mandrel 30 is then reciprocated laterally along the blade edge by the by the oscillating motor 42 (as seen in FIGS. 1 and 2) honing a first side of the blade edge. The sharpening mandrel 30 is then rotated by the mandrel rotation motor 38 to angularly position the second sharpening pad 40b on an opposite contact plane with the blade. The sharpening mandrel 30 is then reciprocated laterally along the blade edge by the oscillating motor 42 honing a second side of the blade edge. Adjustment of the extended length of the blade between the honing of the two sides of the edge may be accomplished, if required, by the drive motor 82 turning rotating engagement post 80 and attached screw 74 as directed by the controller based on the blade location detected by theproximity sensor positioning system.
Upon completion of the sharpening process, the drive motor 82 turns the rotating engagement post 80 and screw 74 to retract the blade. The drive motor 28 may be a stepper motor or similar precision motor allowing precise control by the controller for the retracted length to accommodate the overall length reduction in the blade due to the sharpening procedure. The controller then moves the translation armature 84 with translation motor 86 upward to return the razor to the initial position for extraction from the case.
A third exemplary embodiment of the razor 10 is shown in FIGS. 8A and 8B. As with the first and second embodiments, the blade 18 is extendably retained with a safety housing 16. Similar to the second embodiment, the blade 18 incorporates angled tracks 88 which are engaged by pins extending from a tracking dolly 90 carried on a jack screw 92. The jack screw 92 incorporates a hex bore 94. Rotation of the screw drives the tracking dolly along the screw laterally within the safety housing from a retracted position as shown in FIG. 8A, extending the blade from the housing as the tracking dolly drives the angled tracks as shown in FIG. 8B. An engagement recess 96 is provided in the handle 14 of the razor.
A third exemplary embodiment of integrated sharpening system 20 to accommodate the razor third embodiment is shown in FIGS. 9A, 9B and 9C with components in common with FIGS. 1-3C again carrying the same element numbers. The razor 10 is inserted into the aperture 62 in case 20 and engagement recess 96 is removably attached to a translation armature 98. A translating motor 100 moves the translation armature to position the razor in the case 20 as shown in FIG. 9B. As shown in FIG. 9C, a rotating engagement post 102 (shown in hidden line) is received within the hex bore 94 which may incorporate a spring loaded detent ball to be received within a detent in the hex bore to secure the razor into the case. A drive motor 104 with appropriate drive train turns the rotating engagement post 102. While not shown in FIGS. 9A-9C, the RFID reader and electromagnetic polarization system as described with respect to FIGS. 1 and 2 may be employed in the third embodiment.
Operation of the third embodiment is substantially similar to the operation of the second embodiment with positioning of the safety housing within the case by the translating motor 100 and extension and retraction of the blade with the drive motor 104.
An additional embodiment of the integrated sharping system for use with a razor embodiment as shown and described with respect to FIGS. 5A-C is shown in FIG. 10. An alternative to the sharpening mandrel 30 of FIGS. 7A-D is provided by a carriage 110 movable on a rail base 112 in the case 20 (only a bottom plate 114 of the case is shown for viewing of the other system components). For sharpening of the blade 18 in razor 10, carriage 110 supports two honing elements, honing plates 116a and 116b which are reciprocated in guides 118 on the carriage 110 by a honing motor and cam system 120 to be described in greater detail subsequently. To provide a fine finish on the blade 18, the carriage 110 additionally supports two stropping rollers 122a and 122b rotationally driven by a stropping motor and gear assembly 124 to be described in greater detail subsequently. As with the embodiments described previously, razor 10 is held in the case 114 and the blade 18 extended through a blade extension motor assembly 126 to be described in greater detail subsequently. Positioning of the carriage 110 on the rail base 112 for engagement of the blade 18 by a selected one of the honing plates or stropping rollers is accomplished with a carriage motor 128. As with prior embodiments, the controller 50 as previously described (shown schematically in FIG. 10 in an electronics bay in case bottom plate 114) is employed for operation of the motors and motor assemblies.
As shown in detail in FIG. 11 (with blade extension motor assembly 126 and the side plate of the carriage 110 removed for clarity), honing plates 116a and 116b are driven for vertically reciprocating motion in guides 118 by honing motor and cam system 120. System 120 incorporates a gear head motor 130 driving a shaft 132 through bevel gears 133a and 133b to rotate a cam 134 which engages the honing plates 116a and 116b causing them to reciprocate in the guides. Carriage 110 is translated laterally as indicated by arrow 136 to engage the desired honing plate 116a or 116b with opposing sides of the extended blade 18.
Stropping wheels 122a and 122b are supported in the carriage 110 and, as with the honing plates, are placed into engagement with the blade 18 by lateral translation of the carriage 110. For translation between the honing processes and stropping processes, the blade 18 may be retracted to clear the top extremities of the honing and stropping elements. The stropping motor gear assembly 124, seen in detail in FIG. 10, incorporates a drive motor 138 rotating bevel gears 140a and 140b to rotate stropping gear 142a, connected to stropping roller 122a, which in turn rotates stropping gear 142b, connected to the stropping roller 122b, thereby rotating the stropping rollers in opposite directions.
As shown in FIG. 12A (with motor 138 and the side of the carriage removed for clarity), with the razor 10 installed on the rotating engagement post 80, the carriage motor 128 positions the carriage 110 for placement of the first honing plate 116a proximate the blade 18. The blade 18 is extended from the safety housing 16 of razor 10 using the blade extension motor assembly 126 which incorporates a stepper motor 144 engaging a gear train 146 to rotate the rotating engagement post 80 for extension of the blade as previously described. Motor 130 drives the cam 134 (as best seen in FIG. 11) to reciprocate the honing plate 116a to hone the blade 18 on a first side. A position sensor 148, as an implementation of the proximity sensing system 58 previously described, is employed to sense position of the blade tip for positioning by blade extension motor assembly 126 and carriage positioning motor 128 to control engagement of the blade and honing plate.
Carriage 110 is then shifted by motor 128 to a position as shown in FIG. 12B (with motor 138 and the side of the carriage removed for clarity) for sharpening a second side of the blade by engaging blade 18 with honing plate 116b. Motor 130 drives the cam 134 (as best seen in FIG. 11) to reciprocate the honing plate 116a to hone the blade 18 on the second side.
For the embodiment shown, the blade 18 is then retracted and motor 128 repositions the carriage as shown in FIG. 13A (with stropping motor and gear assembly 124 removed in its entirety and the side of the carriage removed for clarity) and the blade is again extended by blade extension motor assembly 126 to engage stropping roller 122b on the first side. Sensor 148 is again employed for relative positioning of the blade and carriage for proper engagement. The stropping motor and gear assembly 124 rotates stropping roller 122b as previously described with respect to FIG. 11 to strop the blade 18 on the first side.
Carriage 110 is then shifted by motor 128 to a position as shown in FIG. 13B (with stropping motor and gear assembly 124 removed in its entirety and the side of the carriage removed for clarity) for stropping the second side of the blade by engaging blade 18 with stropping roller 122a. Sensor 148 is again employed for relative positioning of the blade and carriage for proper engagement. The stropping motor and gear assembly 124 rotates stropping roller 122a as previously described with respect to FIG. 11 to strop the blade 18 on the second side.
An additional alternative embodiment is shown in FIG. 14 wherein the honing elements are honing wheels 150a and 150b. As in the prior embodiment of FIG. 10, the honing elements are supported on carriage 110 which now employs a reduced travel on rail base 112 driven by carriage motor 128. A honing motor 152 rotates a first tooth gear 154a which drives a second tooth gear 154b attached and rotating honing wheel 150a. A third tooth gear 154c engages the second tooth gear 154 and is attached to and rotates honing wheel 150b.
As shown in FIG. 15A, (with the carriage side plate and tooth gears 154b and 154c removed for clarity), with the razor 10 installed on the rotating engagement post 80, the carriage motor 128 positions the carriage 110 for placement of the first honing wheel 116a proximate the blade 18. The blade 18 is extended from the safety housing 16 of razor 10 using the blade extension motor assembly 126 which incorporates a stepper motor engaging a gear train to rotate the rotating engagement post 80 for extension of the blade as previously described. Honing motor 152 drives the first and second tooth gears (as best seen in FIG. 14) to rotate the honing roller 150a to hone the blade 18 on a first side. The position sensor 148 is employed to sense position of the blade tip for positioning by blade extension motor assembly 126 and carriage positioning motor 128 by controller 129 to control engagement of the blade and honing roller.
Carriage 110 is then shifted by motor 128 to a position as shown in FIG. 15B (with the carriage side plate and tooth gears 154b and 154c removed for clarity) for sharpening a second side of the blade by engaging blade 18 with honing roller 150b. Honing motor 152 drives tooth gear 154c (through first and second tooth gears 154a and 154b as best seen in FIG. 14) to rotate the honing roller 150b to hone the blade 18 on the second side.
For the described embodiment with stainless steel blades, the honing wheels incorporate cubic boron nitride (CBN) crystals of a desired grit level (between 4k and 15k) embedded in rubber cylinders formulated in such a manner that the CBN wears down at a predictable rate and, in the process reveals, a fresh layer of CBN as wear occurs during sharpening. CBN is used in this embodiment for sharpening a stainless steel blade. In this manner the blade will be both honed by the CBN and stropped by the rubber cylinder for edge straightening. For carbon steel blades the same rubber cylinders may be employed, but industrial diamonds will be embedded in place of the CBN.
Control of the sharpening system is accomplished using the controller 50 as shown in FIG. 16. Positioning of the blade 18 for sharpening employs the extension motor assembly 126, which may be implemented with motor 144 as a stepper motor, for extending the blade as specific number of counts counted by extension logic 166 associated with controller 50 and position is verified using sensor 148. Motor 128 then positions the carriage 110 for engaging the blade with honing rollers 150a and 150b as described above using carriage control logic 167. Using impedance feedback 160 from the honing motor 152 as the blade 18 is engaged and wheel wear data lookup tables 162 in a sharpening algorithm 164 in the controller, the desired blade angle is maintained (17 degrees for an example blade) as multiple sharpenings occur and the diameter of the wheel declines over time. For retraction of blade 18, turns of extension motor assembly 126 are again counted by logic 166 and a trigger switch 168 allows for exact positioning of the retracted blade at the end of the process such that the position of the blade relative to the cartridge is the same every time regardless of the fact that the blade length is reduced over time. The user may adjust the exposure of the blade 18 relative to the cartridge 16 to set how aggressive or exposed the blade is for shaving. This is done by a variable dial 170 which provides input to the controller 50 in the base 114, which in turn, adjusts logic 166 for the blade exposure.
Having now described various embodiments of the disclosure in detail as required by the patent statutes, those skilled in the art will recognize modifications and substitutions to the specific embodiments disclosed herein. Such modifications are within the scope and intent of the present disclosure as defined in the following claims.
Patent Application
20140087639
