The present invention relates generally to the field of hair clippers or a hair cutting apparatus. The present invention relates specifically to an adjustable tensioning assembly configured to adjust a blade gap between a reciprocating blade and a stationary blade of a blade assembly. The present invention also relates to a magnetic tensioning assembly configured to provide tension between a reciprocating blade and a stationary blade of the blade assembly.
One embodiment of the invention relates to a magnetic blade assembly. The magnetic blade assembly includes a first blade, a second blade, and a blade guide assembly. The first blade has a first blade edge having a plurality of teeth. The second blade has a second blade edge having a plurality of teeth. The second blade edge is parallel to the first blade edge and the blades oscillate relative to one another. The blade guide assembly is captured between the first and second blades and maintains a relative position of the first blade edge relative to the second blade edge. The blade guide includes a guide member and a magnetic assembly. The guide member has a base and a cross-portion, the cross-portion is captured between the first and second blades and has a first side adjacent to the first blade and a second side adjacent to the second blade. The magnetic assembly includes a plurality of magnets extending along the cross-portion of the guide member between the first and second blades to generate an attractive force between the blade guide assembly and the first blade.
Another embodiment of the invention relates to a magnetic blade assembly. The magnetic blade assembly includes an outer blade, an inner blade, and a blade guide assembly. The outer blade has an outer blade edge with a plurality of teeth. The inner blade has an inner blade edge with a plurality of teeth. The inner blade edge is parallel to the outer blade edge and the inner blade oscillates over the outer blade. The blade guide assembly is captured between the inner blade and outer blade and maintains a relative position of the inner blade edge relative to the outer blade edge as the inner blade oscillates over the outer blade. The blade guide assembly includes a T-shaped guide member and a magnetic assembly. The T-shaped guide member has a base and a cross-portion. The cross-portion is captured between the inner blade and the outer blade and has an inner section adjacent to the inner blade and an outer portion adjacent to the outer blade. The magnetic assembly has a plurality of magnets disposed on the inner section of the cross-portion between the guide member and the inner blade that generates a magnetic attractive force between the blade guide assembly and the inner blade.
Another embodiment of the invention relates to a blade assembly that includes an inner blade, an outer blade, and a blade guide assembly. The inner blade has an inner blade edge with a plurality of teeth. The outer blade has an outer blade edge with a plurality of teeth that is parallel to the inner blade edge. The inner blade oscillates over the outer blade. The blade guide assembly is captured between the inner and outer blades. The blade guide assembly has a guide member, an adjustable gap assembly, and a diagonal slot mechanism. The guide member has a base and a cross-portion captured between the inner and outer blades. The adjustable gap assembly is in the guide member and extends along the cross-portion of the guide member between the inner and outer blades. The adjustable gap assembly generates a force between the blade guide assembly and the inner blade that maintains a relative position of the inner blade edge relative to the outer blade edge. The diagonal slot mechanism is coupled to the base of the guide member and the adjustable gap assembly. Movement of the diagonal slot mechanism in a direction parallel to the inner and outer blade edges moves the cross-portion of the guide member perpendicular to the inner and outer blade edges such that a gap between the inner blade edge and the outer blade edge increases or decreases based upon movement of the diagonal slot mechanism in a direction parallel to the inner and outer blade edges.
Alternative exemplary embodiments relate to other features and combinations of features as may be generally recited in the claims.
This application will become more fully understood from the following detailed description, taken in conjunction with the accompanying figures, wherein like reference numerals refer to like elements in which:
Referring generally to the figures, various embodiments of hair cutters or clippers are shown. The cutters include a blade assembly with an upper or inner blade that oscillates over a lower or outer blade to cut or trim hair. The alignment or gap of an edge of the inner blade relative to an edge of the outer blade affects the cut hair length. For example, if the outer blade has a surface that decreases along the length of the blade, moving the inner blade relative to the outer blade will change the length of hair that is cut. In order to adjust the gap created between the cutting end of the teeth on the inner blade and the cutting end of the teeth on the outer blade an adjustment slider or selector mechanism couples to the inner blade and moves the cutting end of the inner blade relative to the outer blade. This movement extracts or retracts the blades, which enlarges or diminishes a gap between the cutting ends of the inner and outer blades. Controlling the size of the gap enables an operator to adjust the desired cut length that the clippers will cut hair.
Proper tensioning between the blades reduces friction on the system, wear and tear on the blades, and enhances the operational life of the motor. The inner and outer blade should be tensioned/pulled together so that the oscillation of the inner and outer teeth do not interfere with the cutting ends of the blades. A guide member such as a T-guide that is formed by including an arm on the inner blade enables the inner and outer blades to oscillate while retaining the desired tensile force (e.g., with a spring or other biasing mechanism).
Applicant has found that using a magnetic force to generate a tensioning force between the inner and outer blades reduces friction between the blades, which reduces load on the motor and improves overall efficiency of the system. For example, a guide member situated between the upper and the lower blade (e.g., inner and outer blade) is magnetized, includes magnets, or includes an electromagnetic system that creates an attractive force between the blades and reduces the friction of oscillation of the inner blade. In some embodiments, the system detects the load or speed of the motor or blades and increases or decreases the electromagnetic attractive force to minimize the load.
Combining the T-guide with a guide rail or cross-portion and arm or body having a diagonal slot mechanism enables the operator to select a gap between the cutting edges of the inner and outer blades to cut hair at a desired length. This configuration enables the operator to selectively adjust the blade set before, during, or after operation. The operator is able to select the relative closeness of the cut without having to detach the blade set and realign the blades manually. Pre-set detents within the diagonal slot or along the adjustment slider form predetermined gaps associated with desirable cut lengths. The adjustment slider moves between the detents to a selected and fixed hair cutting length (e.g., a predetermined length of cut).
For ease of discussion and understanding, the following detailed description will refer to and illustrate the blade assembly that incorporates magnetic tensioning and/or blade set adjustment in association with a hair cutting apparatus or “cutter.” It should be appreciated that a “cutter” is provided for purposes of illustration, and the blade assembly disclosed herein can be used in association with any hair cutting, hair trimming, or hair grooming device. Accordingly, the term “cutter” is inclusive, and refers to any hair grooming device including, but not limited to, a hair trimmer, a hair clipper, or any other hair cutting or hair grooming device. The cutter device can be suitable for a human, animal, or any other living or inanimate object having hair.
Drive assembly 106 is positioned within cavity 118 and couples blade assembly 104 to motor 120. As illustrated, motor 120 is a rotary DC electric motor 120. In other embodiments, motor 120 is a pivot motor or a magnetic motor 120 that generates oscillating or reciprocating movement for blade assembly 104. In other embodiments, motor 120 is an AC electric motor or any other suitable motor for generating oscillating or reciprocating movement for a blade assembly 104, e.g., inner blade 112 and/or outer blade 114. As illustrated, motor 120 is configured to operate on battery power (e.g., cordless), but may be configured to operate with electricity from any suitable electric source, e.g., a corded cutter 100 plugged into an outlet.
Motor 120 couples to a rotating motor output shaft 122 that rotates about a rotational axis. An eccentric drive 124 is coupled to motor output shaft 122 and rotates eccentrically about the rotational axis. Eccentric drive 124 includes an eccentric shaft 126 that is offset from motor output shaft 122. In other words, eccentric shaft 126 is offset from the axis of rotation of motor 120, such that eccentric shaft 126 rotates non-concentrically around the axis of rotation to create an oscillatory rotational motion. Eccentric shaft 126 is configured to engage a yoke 128 (
Blade assembly 104 includes an adjustment gap assembly, mechanism, or slider 130 that translates inner blade 112 over outer blade 114 in a direction that is transverse to the oscillatory motion of inner blade 112. Translation of inner blade 112 in this transverse direction changes the cut-length during operation of cutter 100. Spring retainer 132 couples to inner blade 112 via a spring 134. Spring retainer 132 is fixedly attached to outer blade 114 (e.g., by fasteners 136). Spring 134 interconnects spring retainer 132 to yoke 128 and permits yoke 128 to oscillate from the rotational output of eccentric shaft 126.
Yoke 128 is coupled to inner blade 112 and to eccentric shaft 126, which is coupled to motor 120. Yoke 128 oscillates inner blade 112 over outer blade 114 based on the rotational output of motor 120 through eccentric shaft 126. In other words, spring retainer 132 fixedly couples to outer blade 114 and connects to yoke 128 via spring 134 to allow translation of yoke 128 relative to spring retainer 132. Yoke 128 is fixedly coupled to inner blade 112 and receives motor 120 output through eccentric shaft 126. The eccentric rotation of eccentric shaft 126 oscillates inner blade 112 over outer blade 114. With reference to
In some embodiments, outer blade 114 includes a track, slot, or recess 142 for T-guide 138. Recess 142 captures T-guide between inner blade 112 and outer blade 114 and directs T-guide 138 along recess 142 to translate inner blade 112 relative to outer blade 114 in a direction transverse to the sliding motion of slider 130 along the rear edge of outer blade 114.
One or more fasteners 136 fixedly couple outer blade 114 to spring retainer 132 and/or body 102 (
Flanges 154 extend from either side of slider 130 and include a projection (detent) that fits within detents of ridges 144 (
As slider 130 translates in a first or oscillatory direction 162 (e.g., left and right), inner blade 112 translates in a second or transverse direction 164 (e.g., forward and back). As shown, the translation along transverse direction 164 can be orthogonal to the oscillatory direction 162, but it may also include translations in other non-orthogonal directions. Elongated body or arm 158 ensures that translation of slider 130 in the oscillatory direction 162 translates inner blade 112 and inner blade edge 166 in the transverse direction 164 to increase or decrease a distance (or gap) to outer blade edge 168.
In some embodiments, a diagonal slot mechanism (e.g., arm 138 in slider 130) is coupled to the base or elongated arm 158 of T-guide 138, such that movement of slider 130 in a direction parallel to the inner and/or outer blade edges 166 and/or 168 moves the guide rail 170 in a direction perpendicular to inner and/or outer blade edges 166 and/or 168. In other words, slider 130 and channel 172 create a diagonal joint between arm 158 and guide rail 170.
Elongated arm 158 interconnects a cross-member or guide rail 170 (captured between inner and outer blades 112 and 114) of T-guide 138 to slider 130. Guide rail 170 is illustrated in
In some embodiments, guide rail 170 includes a magnetic tension assembly 174. For example, guide rail 170 is a ferromagnetic material that is magnetized. In other embodiments, guide rail 170 includes one or more magnets 176 and/or another electromagnetic device (e.g., windings). The magnetic tension assembly 174 and/or magnets 176 generate an attractive (e.g., tensile) force between the blade guide assembly or T-guide 138 and inner 112 and/or outer 114 blades. In some embodiments, the force is repulsive. In some embodiments, the magnetic tensile force between guide rail 170, inner and/or outer blades 112 and/or 114 is adjustable.
In some embodiments, inner blade 112, outer blade 114, yoke 128, and/or T-guide 138 are magnetized to create an attractive or repulsive force between inner blade 112 and outer blade 114. In some embodiments, the magnetic assembly is located on at least one of a yoke 128, the inner blade 112, the outer blade 114, or the T-guide 138. In other words, inner blade 112, outer blade 114, yoke 128, T-guide 138, and/or any combination thereof, creates a magnetic field to adjust or control a tensile force (attractive or repulsive) between inner and outer blades 112 and 114. For example, a magnetized yoke 128 is a non-conductive magnet carrier (e.g., a plastic yoke 128 carrying a ferrous magnet 176) or conductive magnetic material. In some embodiments, a compounding force is generated from a plurality of magnets 176 with relatively weaker magnetic forces to create a compounded magnetic force from the plurality of magnets 176. A variety of magnets may be used and may reduce the total cost of the magnetic assembly. In addition, using a magnetic force to control the force between blades 112 and 114 creates a reliable and efficient method to control the tensile force generated to maintain the friction between blades 112 and 114 while cutting hair.
Movement of slider 130 translates inner blade 112 relative to outer blade 114, which changes the placement of eccentric shaft 126 within yoke 128. Yoke 128 is configured to receive eccentric shaft 126 on drive assembly 106 to oscillate inner blade 112 at any blade gap 178. As illustrated in
Slider 130 may include words or inscriptions (e.g., “deep” and “fine”) and tactile and/or visual indicators to indicate which configuration of slider 130 results in a longer “deep” or shorter “fine” cut. For example, a single bump on one side (e.g., “fine”) and two or more bumps (e.g., “deep”) on an opposite side of slider 130 provides both visual and tactile indication of blade gap 178 in either configuration. Similarly, short lines on one side and long lines on an opposite side of slider 130 provide visual and/or tactile indication of a cut length in the slider 130 position.
As shown, slider 130 is not centered on outer blade 114, but is located nearer to a first fastener hole 160 (on the left) than to a second fastener hole 160 (on the right). In other words, slider 130 is located on a first side (e.g., left of center) along the edge of outer blade 114 and extends T-guide 138 a maximum distance. This outer blade edge 168 configuration places outer blade edge 168 near inner blade edge 166 to create a small or non-existent blade gap 178. The result is that inner blade edge 166 fully extends and/or aligns with outer blade edge 168 and produces a short or “fine” cutting length.
As shown in
In some embodiments, inner blade 212, outer blade 214, yoke 228, and/or blade guide assembly 286 are magnetized to create an attractive or repulsive force between inner blade 212 and outer blade 214. For example, a magnetic assembly is located on at least one of the yoke 228, inner blade 212, or outer blade 214. In other words, inner blade 212, outer blade 214, the yoke 228 and/or any combination thereof, creates a magnetic field to adjust or control a tensile force (attractive or repulsive) between inner and outer blades 212 and 214. For example, a magnetized yoke 228 is a non-conductive magnet carrier (e.g., a plastic yoke 228 carrying a ferrous magnet 276) or conductive magnetic material. In some embodiments, a compounding force is generated from a plurality of magnets 276 with relatively weaker magnetic forces to create a compounded magnetic force from the plurality of magnets 276. A variety of magnets may be used and may reduce the total cost of the magnetic assembly. In addition, using a magnetic force to control the force between blades 212 and 214 creates a reliable and efficient method to control the tensile force generated to maintain the friction between blades 212 and 214 while cutting hair.
Referring to
Referring to
In some embodiments, blade assembly 204 includes a magnetic tension assembly 274. Magnetic tension assembly 274 uses electromagnetic forces to apply an attractive or tension force between inner blade 212 and outer blade 214, for example, blade assembly 204 and inner and/or outer blades 212 and/or 214. In some embodiments, magnetic tension assembly 274 replaces traditional spring based systems that apply a tension force between blades 212 and 214. The attractive tensile force maintains inner blade 212 position (up and down) relative to outer blade 214 during oscillatory reciprocation (e.g., cutting hair).
As will be described in detail below, in some embodiments, the magnetic tensile force between inner and/or outer blades 212 and/or 214 is adjustable. In some embodiments, the magnetic polarities are reversed, such that the magnetic force repels the inner and outer blades 212 and 214 (e.g., generates a repulsive force on blades 212 and 214).
Magnetic tension assembly 274 includes a magnetized ferromagnetic material and/or at least one magnet 276 positioned between inner and outer blades 212 and 214. The illustrated bar magnet 276 is sandwiched between inner and outer blades 212 and 214. In other embodiments, magnet 276, includes any suitable electromagnetic force (e.g., a permanent magnet, a polymagnet, electric coil, etc.) or shape (e.g., circular, oblong, or a magnetized cross-member or guide rail 270). In some embodiments, magnet 276 includes a plurality of magnets positioned between inner and outer blades 212 and 214. Magnet 276 is fastened (or otherwise coupled) to outer blade 214. For example, magnet 276 is fastened by an adhesive, a fastener (e.g., a screw, etc.), or any other suitable fastening device. Magnet 276 then applies an attractive magnetic or tensile force on inner blade 212 during oscillation. Stated another way, inner blade 212 is drawn towards outer blade 214 by magnet 276. The attractive tensile force applied by magnet 276 is such that inner blade 212 is able to reciprocate relative to outer blade 214 while maintaining the position of inner blade edge 266 relative to outer blade edge 268. Magnet 276 is captured between the blades 212 and 214 to apply a magnetic attractive (e.g., tensile) force on inner blade 212, which provides improved tension control of inner blade 212 during reciprocation.
In operation, motor 220 drives reciprocation of inner blade 212 relative to outer blade 214 through a drive assembly 206 and/or a transmission (not shown). During reciprocation of inner blade 212, blade guide assembly 286 guides reciprocal movement of inner blade 212 relative to outer blade 214 to maintain a consistent blade gap 186. In addition, magnetic tension assembly 274 applies a magnetic tensile force on inner blade 212 to maintain the position of inner blade edge 266 relative to outer blade edge 268 to reduce friction and facilitate an even cut.
In some embodiments, inner blade 312, outer blade 314, and/or blade guide assembly 386 are magnetized to create an attractive or repulsive force between inner blade 312 and outer blade 314. For example, a magnetic assembly is located on at least one of, inner blade 312, or outer blade 314. In other words, inner blade 312, outer blade 314, blade guide assembly 386, and/or any combination thereof, creates a magnetic field to adjust or control a tensile force (attractive or repulsive) between inner and outer blades 312 and 314. In some embodiments, a compounding force is generated from a plurality of magnets 376 with relatively weaker magnetic forces to create a compounded magnetic force from the plurality of magnets 376. A variety of magnets may be used and may reduce the total cost of the magnetic assembly. In addition, using a magnetic force to control the force between blades 312 and 314 creates a reliable and efficient method to control the tensile force generated to maintain the friction between blades 312 and 314 while cutting hair.
Referring to
In some embodiments, upper magnet 376 and bottom magnet 376b are magnets having the same polarity, such that the inner and outer blades 312 and 314 experience a repulsive force. In some embodiments, upper magnet 376 and bottom magnet 376b have opposite polarity, such that the inner and outer blades 312 and 314 experience an attractive force. Thus, the orientations of magnets 376a and 376b are such that they magnetically repel each other. Magnets 376a and 376b push apart or repel, with bottom magnet 376b pushing inner blade 312 towards outer blade 314. This generates a magnetic force that separates the blades 312 and 314 to maintain the position of inner blade edge 366 relative to outer blade edge 368 during operation to reduce frictional load and facilitate cutting. As will be described in detail below, in some embodiments, the magnetic force between inner and/or outer blades 312 and/or 314 is adjustable.
In some embodiments, inner blade 412, outer blade 414, and/or Blade guide assembly 486 are magnetized to create an attractive or repulsive force between inner blade 412 and outer blade 414. For example, a magnetic assembly is located on at least one of, inner blade 412, outer blade 414, or blade guide assembly 486. In other words, inner blade 412, outer blade 414, blade guide assembly 486, and/or any combination thereof, creates a magnetic field to adjust or control a tensile force (attractive or repulsive) between inner and outer blades 412 and 414. In some embodiments, a compounding force is generated from a plurality of magnets 476 with relatively weaker magnetic forces to create a compounded magnetic force from the plurality of magnets 476. A variety of magnets may be used and may reduce the total cost of the magnetic assembly. In addition, using a magnetic force to control the force between blades 412 and 414 creates a reliable and efficient method to control the tensile force generated to maintain the friction between blades 412 and 414 while cutting hair.
In some embodiments, the magnetic tensile force between inner and/or outer blades 412 and/or 414 is adjustable. In some embodiments, the magnetic polarities are reversed, such that the magnetic force repels the inner and/or outer blades 412 and/or 414.
In some embodiments, inner blade 512, outer blade 514, and/or Blade guide assembly 586 are magnetized to create an attractive or repulsive force between inner blade 512 and outer blade 514. For example, a magnetic assembly is located on at least one of inner blade 512, outer blade 514, or blade guide assembly 586. In other words, inner blade 512, outer blade 514, blade guide assembly 586, and/or any combination thereof, creates a magnetic field to adjust or control a tensile force (attractive or repulsive) between inner and outer blades 512 and 514. In some embodiments, a compounding force is generated from a plurality of magnets 576 with relatively weaker magnetic forces to create a compounded magnetic force from the plurality of magnets 576. A variety of magnets may be used and may reduce the total cost of the magnetic assembly. In addition, using a magnetic force to control the force between blades 512 and 514 creates a reliable and efficient method to control the tensile force generated to maintain the friction between blades 512 and 514 while cutting hair.
Magnetic tension assembly 574 is substantially the same as the magnetic tension assembly 474, with like numbers identifying like components. Magnetic tension assembly 574 includes a metallic member 598 coupled to outer blade 514 (e.g., an adhesive and/or fastener). Metallic member 598 is positioned on outer blade 514 and sandwiched between inner and outer blades 512 and 514. Stated another way, metallic member 598 is positioned on an internal side of outer blade 514 that faces inner blade 512, and between inner and outer blades 512 and blade 514. Metallic member 598 provides an additional surface or material that attract magnets 576. Thus, metallic member 598 engages with the attractive magnetic force emitted from magnets 576 that attracts inner blade 512 towards outer blade 514, drawing inner blade 512 towards outer blade 514. The generated magnetic tension maintains the position of inner blade edge 178 relative to outer blade edge 568 during operation. In this embodiment blades 512 and/or 514 need not be a metallic component, for example, blade 512 or 514 is a plastic or composite part.
Metallic member 598 can be any suitable ferromagnetic material or other suitable material that attracts to magnets 576 by magnetic force. In some embodiments, metallic member 598 is magnetized with the same polarity as magnets 576, such that inner and outer blades 512 and 514 are repelled. As will be described in detail below, in some embodiments, the magnetic force between inner and/or outer blades 512 and/or 514 is adjustable or scalable.
In some embodiments, inner blade 612, outer blade 614, yoke 628, and/or T-guide 638 are magnetized to create an attractive or repulsive force between inner blade 612 and outer blade 614. For example, a magnetic assembly is located on at least one of a yoke 628, inner blade 612, outer blade 614, or T-guide 638. In other words, inner blade 612, outer blade 614, yoke 628, T-guide 638, and/or any combination thereof, creates a magnetic field to adjust or control a tensile force (attractive or repulsive) between inner and outer blades 612 and 614. For example, a magnetized yoke 628 is a non-conductive magnet carrier (e.g., a plastic yoke 628 carrying a ferrous magnet 676) or conductive magnetic material. In some embodiments, a compounding force is generated from a plurality of magnets 676 with relatively weaker magnetic forces to create a compounded magnetic force from the plurality of magnets 676. A variety of magnets may be used and may reduce the total cost of the magnetic assembly. In addition, using a magnetic force to control the force between blades 612 and 614 creates a reliable and efficient method to control the tensile force generated to maintain the friction between blades 612 and 614 while cutting hair.
Guide rail 638 is positioned between inner and outer blades 612 and 614 (
The embodiment of cutter 700 is substantially the same or similar to the embodiments of
In some embodiments, inner blade 712, outer blade 714, and/or blade guide assembly 786 are magnetized to create an attractive or repulsive force between inner blade 712 and outer blade 714. For example, a magnetic assembly is located on at least one of inner blade 712, outer blade 714, or blade guide assembly 786. In other words, inner blade 712, outer blade 714, blade guide assembly 786, and/or any combination thereof, creates a magnetic field to adjust or control a tensile force (attractive or repulsive) between inner and outer blades 712 and 714. In some embodiments, a compounding force is generated from a plurality of magnets 776 with relatively weaker magnetic forces to create a compounded magnetic force from the plurality of magnets 776. A variety of magnets may be used and may reduce the total cost of the magnetic assembly. In addition, using a magnetic force to control the force between blades 712 and 714 creates a reliable and efficient method to control the tensile force generated to maintain the friction between blades 712 and 714 while cutting hair.
With reference to
The current or voltage (or electric charge) supplied to electromagnet 776 from magnetic tension assembly 774 can be associated with operation of cutters 700. Specifically, a load sensor 788 is incorporated with cutters 700 to detect increases and/or decreases in a load on or speed of the motor. Changes in the load or speed of the motor are proportional to a frictional load or speed between blades 712 and 714. Sensor 788 sends signals indicative of load and/or speed changes on the motor to electromagnet 776 to increase or decrease the magnetic force between inner and outer blades 712 and 714. Changes in load on the motor are representative and/or proportional to the frictional load (and/or speed) between blades 712 and 714 incurred during the cutting of hair. As the detected load increases or the speed decreases, the voltage and/or current supplied to electromagnet 776 is increased to improve tension between inner blade 712 and outer blade 714. For example, when sensor 788 detects a changed load on the motor or change of speed between the motor, inner blade 712 and/or outer blade 714, sensor 788 sends a signal to electromagnet 776 to increase current in magnetic tension assembly 774 that increases the magnetic attractive or tensile force between guide member 780 and inner and outer blades 712 and 714 and reduces the frictional load and reduces the load on the motor.
The embodiment of cutter 800 is substantially the same or similar to the embodiments of
In some embodiments, inner blade 812, outer blade 814 and/or blade guide assembly 886 are magnetized to create an attractive or repulsive force between inner blade 812 and outer blade 814. For example, a magnetic assembly is located on at least one of inner blade 812, outer blade 814, or blade guide assembly 886. In other words, inner blade 812, outer blade 814, blade guide assembly 886, and/or any combination thereof, creates a magnetic field to adjust or control a tensile force (attractive or repulsive) between inner and outer blades 812 and 814. In some embodiments, a compounding force is generated from a plurality of magnets 876 with relatively weaker magnetic forces to create a compounded magnetic force from the plurality of magnets 876. A variety of magnets may be used and may reduce the total cost of the magnetic assembly. In addition, using a magnetic force to control the force between blades 812 and 814 creates a reliable and efficient method to control the tensile force generated to maintain the friction between blades 812 and 814 while cutting hair.
The first and second ends 855 and 877 of magnetic tension assembly 874 extend through outer blade 814 and contact inner blade 812. In operation, electricity (or an electrical charge or current) is applied to windings 833 to magnetize member 811. The magnetic field extends through the first end 855 and the second end 877 to engage inner blade 812. The ends 855 and 877 concentrate the magnetic flux to provide an attractive magnetic force (e.g., tension force) that engages and draws inner blade 812 towards outer blade 814. The magnetic force is sufficient to generate magnetic tension to maintain the position of inner blade edge 866 relative to outer blade edge 868 during operation to facilitate cutting. Thus, the ends 855 and 877 act as a magnetic conduit (or electromagnet) that draws inner blade 812 towards outer blade 814.
The current or voltage (or electricity or electric charge) supplied to electromagnet 876 from magnetic tension assembly 874 can be associated with operation of cutters 800. Specifically, a load or speed sensor 888 is incorporated with cutters 800 to detect increases and/or decreases in a load on or speed of motor 820. Changes in the load or speed of motor 820 are proportional to a frictional load between blades 812 and/or 814. Sensor 888 sends signals indicative of the load and or speed changes on motor 820 to electromagnet 876 to increase or decrease the magnetic force between inner and outer blades 812 and 814. Changes in load on motor 820 are representative and/or proportional to the frictional load between blades 812 and 814 incurred during the cutting of hair. Similarly, changes in speed of motor 820, inner and/or outer blades 812 and/or 814 are representative and/or proportional to the frictional load between blades 812 and 814. As the detected load increases or speed decreases, the voltage and/or current supplied to electromagnet 876 is increased to improve tension between inner blade 812 and outer blade 814. For example, when sensor 888 detects a changed load or speed on motor 820, sensor 888 sends a signal to electromagnet 876 to increase current in magnetic tension assembly 874 that increases the magnetic attractive or tensile force between guide member 880 and inner and/or outer blades 812 and/or 814 and reduces the frictional and motor 820 loads.
In some embodiments, electromagnet 876 is used in association with other magnets 876 (e.g., 176, 276, 376, 476, 576, 676, and 776), such as those disclosed in association with the other embodiments of magnetic tension assembly (e.g., 174, 274, 374, 474, 574, 674, and 774). Further, electromagnet 876 (and/or magnets 176, 276, 376, 476, 576, 676, and 776) can be associated with at least one sensor 888 to facilitate selective engagement (or magnetization) of electromagnet 876. For example, electromagnet 876 is associated with a proximity sensor 888 configured to detect hair, a motion sensor 888 configured to detect movement of cutters 800, and/or a sound sensor 888 configured to detect the sound of clipper operation (or motor 820 operation). In response to an associated detection by sensor 888, electromagnet 876 selectively engages electromagnet 876 (e.g., sends signals to increase or decrease a current to electromagnet 876). Thus, a magnetic force between inner blade 812 and outer blade 814 is selectively variable. Selective application of the magnetic force reduces the friction load between blades 812 and 814, the motor 820 load, and heat emitted by cutters 800, allowing the user an improved experience during use. In other words, sensor 888 communicates with electromagnet 876 to enhance overall performance and lifecycle of cutter 800.
It should be understood that the figures illustrate the exemplary embodiments in detail, and it should be understood that the present application is not limited to the details or methodology set forth in the description or illustrated in the figures. It should also be understood that the terminology is for the purpose of description only and should not be regarded as limiting.
Further modifications and alternative embodiments of various aspects of the invention will be apparent to those skilled in the art in view of this description. Accordingly, this description is to be construed as illustrative only. The construction and arrangements, shown in the various exemplary embodiments, are illustrative only. Although only a few embodiments have been described in detail in this disclosure, many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described herein. Some elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. The order or sequence of any process, logical algorithm, or method steps may be varied or re-sequenced according to alternative embodiments. Other substitutions, modifications, changes and omissions may also be made in the design, operating conditions and arrangement of the various exemplary embodiments without departing from the scope of the present invention.
For purposes of this disclosure, the term “coupled” means the joining of two components directly or indirectly to one another. Such joining may be stationary in nature or movable in nature. Such joining may be achieved with the two members and any additional intermediate members being integrally formed as a single unitary body with one another or with the two members or the two members and any additional member being attached to one another. Such joining may be permanent in nature or alternatively may be removable or releasable in nature.
While the current application recites particular combinations of features in the claims appended hereto, various embodiments of the invention relate to any combination of any of the features described herein whether or not such combination is currently claimed, and any such combination of features may be claimed in this or future applications. Any of the features, elements, or components of any of the exemplary embodiments discussed above may be used alone or in combination with any of the features, elements, or components of any of the other embodiments discussed above.
In various exemplary embodiments, the relative dimensions, including angles, lengths and radii, as shown in the Figures are to scale. Actual measurements of the Figures will disclose relative dimensions, angles and proportions of the various exemplary embodiments. Various exemplary embodiments extend to various ranges around the absolute and relative dimensions, angles and proportions that may be determined from the Figures. Various exemplary embodiments include any combination of one or more relative dimensions or angles that may be determined from the Figures. Further, actual dimensions not expressly set out in this description can be determined by using the ratios of dimensions measured in the Figures in combination with the express dimensions set out in this description.
The present application claims the benefit of and priority to 62/830,829 filed on Apr. 8, 2019, and 62/719,281 filed on Aug. 17, 2018, which are incorporated herein by reference in their entireties.
Number | Name | Date | Kind |
---|---|---|---|
4059891 | Panagiotoulis | Nov 1977 | A |
4989324 | Andis | Feb 1991 | A |
7234242 | Yao | Jun 2007 | B2 |
8341846 | Holmes | Jan 2013 | B1 |
9943972 | Werner | Apr 2018 | B2 |
20070107234 | Yao | May 2007 | A1 |
20090019706 | Werner | Jan 2009 | A1 |
20090199413 | Tautscher | Aug 2009 | A1 |
20130312265 | Wilson | Nov 2013 | A1 |
20140117788 | Takahashi | May 2014 | A1 |
20160075039 | Werner | Mar 2016 | A1 |
20170019044 | Godlieb et al. | Jan 2017 | A1 |
20170348865 | Werner | Dec 2017 | A1 |
Number | Date | Country |
---|---|---|
101432104 | May 2009 | CN |
102909733 | Feb 2013 | CN |
203185375 | Sep 2013 | CN |
104128936 | Nov 2014 | CN |
204913971 | Dec 2015 | CN |
106103018 | Nov 2016 | CN |
108274496 | Jul 2018 | CN |
1974875 | Oct 2008 | EP |
WO 2017120610 | Jul 2017 | WO |
Entry |
---|
International Searching Authority, “International Search Report and Written Opinion,” issued in connection with International Patent Application No. PCT/US2019/046656, 13 pages. |
Partial Supplementary European Search Report for European Application No. 19850550.5, dated Mar. 18, 2022, 10 pages. |
Number | Date | Country | |
---|---|---|---|
20200055205 A1 | Feb 2020 | US |
Number | Date | Country | |
---|---|---|---|
62830829 | Apr 2019 | US | |
62719281 | Aug 2018 | US |