JP2011502616A - Safety razor with multiple swingable blade units - Google Patents

Abstract

A safety razor blade unit 11 mounted for pivotal movement relative to a razor handle 12 about a pivot axis B substantially perpendicular to a blade 20 mounted in the blade unit. The blade unit is biased to a rest position by a magnetic return force generated by a set of magnetic elements 32, 34, 36. The set of magnetic elements are so disposed that the return force increases as the pivotal displacement of the blade unit from the rest position increases.

Description

  The present invention relates to a safety razor, and in particular, a safety razor blade unit including at least one blade having a sharp cutting edge can swing with respect to the handle under the force acting on the blade unit while shaving. It relates to a safety razor that is attached to a razor handle. The blade unit may have a plurality of blades, for example two, three or more than four blades, and the straight parallel cutting edge is also between the guard surface and the cap surface provided on the blade unit. Placed in contact with the skin. The guard includes a strip of elastomeric material with upstanding protrusions, such as surface shapes, e.g. fin shapes, to create the desired interaction with the skin as the blade unit moves across the skin during a shave stroke. May be. The cap surface may include a strip of material that includes a shaving enhancement product, such as a lubricant, and the enhancement product gradually leaches out of the strip material for application to the skin while shaving. be able to. The safety razor blade unit may be removably attached to the razor handle so that it can be replaced with a new blade unit when the blade sharpness drops to an unsatisfactory level. Alternatively, it may be permanently connected to the handle with the intention of discarding the entire razor when one or more blades become dull. The removable and replaceable blade unit is commonly referred to as a shaving cartridge.

  The present invention relates to a safety razor having a blade unit arranged so as to be swingable about an axis substantially perpendicular to the cutting edge of one or more blades. The exact angle at which the handle is held with respect to the skin is less important in order to achieve good shaving performance and efficiency, as the blade unit can follow the contours of the skin more easily by rocking motion. Razors with oscillating blade units have been successfully marketed for many years. A conventional rocking shaft can be defined by a rocking structure that extends parallel to the cutting edge of the normal blade and is connected to the blade unit by a handle. Alternatively, the blade unit may include an attachment member to which a frame or housing incorporating one or more blades and other skin contact portions is pivotably coupled. This form of blade unit is described in International Patent Publication No. WO 97/37819, the contents of which are incorporated herein by reference, including a hub for engaging the upper end of the handle, and both ends of the frame. A swinging journal has a mounting member in the general form of a yoke with a pair of oppositely facing arms provided at both ends so as to engage in a provided socket. In order to maintain the swing journal in the socket, a retaining clip is applied around the corresponding end of the frame.

  A razor has been proposed having a blade unit mounted for oscillating movement about a single axis substantially parallel to the blade edge. The blade unit is biased to a rest position by a magnetic return force generated by a magnet. Oscillating motion about a single axis substantially parallel to the cutting edge provides a degree of conformity with the skin so that the blade unit can more easily follow the skin contour while shaving To do. However, the blade unit often moves away from the skin while shaving because of the limited ability of the blade unit to swing about a single axis.

International Patent Publication No. WO97 / 37819

  The present invention uses this magnetic return force around a pivot axis substantially perpendicular to the blade edge to improve the compatibility of the blade unit with the user's skin while shaving. To deal with.

  The present invention provides a safety razor comprising a handle and a blade unit having a guard, a cap and at least one blade. The blade unit is attached to the handle so as to move relative to the handle about a pivot axis substantially perpendicular to the at least one blade so as to follow the contour of the skin while shaving. The blade unit has a rest position. When the blade unit swings around the swing shaft away from the rest position, the blade unit is biased by a return force toward the rest position. The return force includes the magnetic force generated by the set of magnetic elements that cause the blade unit to oscillate about an oscillating axis substantially perpendicular to the at least one blade. Moved relative to each other accordingly. The return force increases as the blade unit swings away from the rest position.

  Further provided is a safety razor comprising a handle and a blade unit having a guard, a cap and at least one blade. The blade unit is attached to the handle so as to move relative to the handle about the first swing axis and the second swing axis so as to follow the contour of the skin while shaving. . The blade unit has a first rest position and a second rest position, and is biased toward the rest position by the first return force and the second return force. The first return force is generated when the blade unit swings around the first swing shaft away from the first rest position. The first return force includes a magnetic force generated by the first set of magnetic elements, the first set of magnetic elements about a first swing axis that is substantially parallel to the at least one blade. Are moved relative to each other as the blade units oscillate. The first return force increases as the blade unit swings away from the first rest position. The second return force is generated when the blade unit swings around the second swing axis away from the second rest position. The second return force includes a magnetic force generated by a second set of magnetic elements, the second set of magnetic elements being about a second swing axis that is different from the first swing axis. Are moved relative to each other as the blade units oscillate. The second return force increases as the blade unit swings away from the second rest position.

  By using a magnetically generated return force, it is possible to ensure a very smooth and consistently oscillating swinging motion. The magnetic force can be conveniently generated by a magnetic element, which is moved relative to each other in response to the swinging movement of the blade unit relative to the handle and interacts repulsively to cause the blade unit to correspond to a corresponding rest. Drive to position.

  Preferably, the first set of magnetic elements is arranged to generate a repulsive magnetic return force for driving the blade unit to the first rest position. Similarly, the second set of magnetic elements is arranged to generate a repulsive magnetic return force for driving the blade unit to the second rest position.

  The first set of magnetic elements may include a first magnetic element and a second magnetic element, the first magnetic element being attached to a blade unit adjacent to the cap. However, the first set of magnetic elements may include more than two magnetic elements, such as, for example, two opposing pairs.

  Conveniently, the blade unit is pivotally supported by a pair of opposed arms extending from the hub, and the second magnetic element is disposed on the hub.

  The first swing axis is preferably arranged in front of the at least one blade. The first swing shaft may be disposed below a tangent plane with respect to the guard and the cap.

  Advantageously, the magnetic elements that generate the first return force and the second return force are moved from the first rest position and the second rest position around the first swing axis and the second swing axis. As the swing angle increases, the spring constant characteristics of the magnetic return force are arranged to increase smoothly. A further advantage of the present invention is that the strength of the return force can be easily changed by using magnetic elements of different magnetic forces.

  The first swing shaft is preferably arranged so as to be substantially orthogonal to the second swing shaft.

  The magnetic element may conveniently be a permanent magnet, but at least one of the magnetic elements may include an electromagnetic element, in which case the control device is used to adjust the electromagnetic current supplied to the electromagnetic element. Can be provided. A sensor may be provided, for example, to detect a rocking displacement from the rest position of the blade unit, and the controller can react to the output from the sensor.

  The second set of magnetic elements preferably includes a third magnetic element, a fourth magnetic element, and a fifth magnetic element. The second set of magnetic elements may include a sixth magnetic element.

  The third magnetic element may be attached to the handle, and the fourth magnet and the fifth magnet may be attached to the blade unit. Alternatively, the third magnetic element may be attached to the blade unit, and the fourth magnet and the fifth magnet may be attached to the handle.

While the specification concludes with claims that particularly point out and distinctly claim the subject matter regarded as forming the invention, the invention is described below in connection with the accompanying drawings. Is considered to be further understood.
FIG. 3 is a side view of a safety razor according to the present invention. The rear perspective view of the safety razor shown in FIG. The top view of the handle | steering-wheel of the safety razor shown in FIG. The bottom view which cut off some blade units of the safety razor shown in FIG. FIG. 6 is a plan view of another safety razor handle of the present invention. FIG. 6 is a bottom view of a part of the blade unit corresponding to the safety razor in FIG. 5. FIG. 6 is a plan view of another safety razor handle of the present invention. The bottom view which cut off some blade units corresponding to the safety razor of FIG.

  The safety razor 10 shown in FIGS. 1 to 4 has a blade unit 11 mounted on a handle 12. As is well known in the art, the blade unit 11 has a frame 13 having a guard 14 and a cap 15 and a plurality of blades 20 having a blade edge parallel to each other and disposed between the guard 14 and the cap 15. Including.

  The blades 20 are movable independently of each other and are driven upward relative to the tangential plane against the surface of the guard 14 and cap 15 by a spring 19 that determines the force of the blade against the skin while shaving. The The guard 14 preferably includes a strip of elastomeric material having protrusions such as fins, and the cap 15 may include a strip for applying a well-known skin shaving enhancement product.

  The blade unit 11 includes an attachment member 16 including a hub 17. The attachment member 16 of the blade unit 11 is swingably attached to the handle 12 by a pin 21. The hub 17 is removably clipped onto the mounting member 16. The hub 17 includes a pair of opposing yoke arms 18 having swing journals at both ends, and the swing journals are inserted into sockets provided at both ends of the frame 13. The journal is held in the socket by metal clips applied around the ends of the frame 13. The journal and socket define a first swing axis A around which the blade unit 11 can swing relative to the handle 12. The first swing axis A is preferably in front of the blade and below the tangent plane to the surfaces of the guard 14 and cap 15, although other swing positions are possible. The first swing axis A is substantially parallel to the plurality of blades 20. The socket includes a stop surface. As shown in the figure, when the frame 13 is in the end swinging position corresponding to the first rest position of the blade unit, the arm 18 is abutted against the stop surface. Touch. This oscillating movement of the blade unit 11 away from the first rest position is the return force generated by the opposing first set of magnetic elements in the form of a first small permanent magnet 22 and a second small permanent magnet 24. Resisted by. The first magnet 22 is fixed to the lower side of the frame 13 adjacent to the cap 15, and the second magnet 24 is fixed to the hub 17. The first magnet 22 and the second magnet 24 are positioned so as to face each other with the same type of pole, and as a result, the blade unit 11 swings away from the first rest position as indicated by an arrow 26. As the magnets move toward each other, an increasing strength reaction force is generated between the magnets that acts to return the blade unit 11 to the first rest position. The increasing reaction force is a non-linear response that acts to return the blade unit 11 to the rest position. When the blade unit swings around the first swing axis A from the rest position to the complete swing range, the torque range is about 0 to about 15 Nmm. Other larger torque ranges and smaller torque ranges may be used as desired. The torque can be varied by changing the spacing between the magnets, the spacing of the magnets from the swing axis, the strength and number of magnets used.

  Preferably, the blade unit 11 has a swing range up to about 45 ° around the first swing axis A. Other larger swing ranges and smaller swing ranges may be used as desired.

  The pin 21 defines a second swing axis B around which the blade unit 11 can swing relative to the handle 12. The second swing axis B is preferably behind the frame 13 and inside the mounting member 16.

  The second swing axis B is substantially orthogonal to the plurality of blades 20 and the first swing axis A. The blade unit 11 is shown in the second rest position in FIG. The oscillating motion around the second oscillating axis B of the blade unit 11 away from the second rest position is resisted by the return force generated by the opposing second set of magnetic elements.

  The opposing second set of magnetic elements is in the form of a third small permanent magnet 32, a fourth small permanent magnet 34, and a fifth small permanent magnet 36. The third magnet 32 is fixed to the upper side of the handle 12. The fourth magnet 34 and the fifth magnet 36 are fixed to the lower side of the attachment member 16. The third magnet 32 and the fourth magnet 34 are positioned so as to face each other with the same type of pole, so that the blade unit 11 is separated from the second rest position as shown by the arrow 40 (FIG. 1). As the magnets move toward each other as a result of swinging, an increasing strength reaction force is generated between the magnets that acts to return the blade unit 11 to the second rest position. In the second rest position, the third magnet 32 and the fourth magnet 34 are not placed on top of each other but are offset from each other.

  The third magnet 32 and the fifth magnet 36 are positioned so as to face each other with the same type of pole, and as a result, the blade unit 11 is separated from the second rest position as indicated by the arrow 42 (FIG. 1). As the magnets move toward each other as a result of swinging, an increasing strength reaction force is generated between the magnets that acts to return the blade unit 11 to the second rest position. In the second rest position, the third magnet 32 and the fifth magnet 36 are not placed on top of each other, but are offset from each other. The increasing reaction force is a non-linear response that acts to return the blade unit 11 to the rest position. When the blade unit swings about the second swing axis B in any direction from its rest position to the complete swing range, the torque range is about 0 to about 15 Nmm. Other larger torque ranges and smaller torque ranges may be used as desired. The torque can be varied by changing the spacing between the magnets, the spacing of the magnets from the swing axis, the strength and number of magnets used.

  Preferably, the blade unit 11 has a swing range up to about 30 ° around the second swing axis B. The 30 ° range includes a 15 ° swing range in the direction indicated by arrow 40 and a 15 ° swing range in the direction indicated by arrow 42. Other larger swing ranges and smaller swing ranges may be used as desired.

  Referring now to FIGS. 5-6, another embodiment of the safety razor of the present invention is shown. The opposing second set of magnetic elements is in the form of a third small permanent magnet 32, a fourth small permanent magnet 34, and a fifth small permanent magnet 36. The third magnet 32 is fixed to the lower side of the attachment member 16. The fourth magnet 34 and the fifth magnet 36 are fixed to the upper side of the handle 12. The third magnet 32 and the fourth magnet 34 are positioned so as to face each other with the same type of pole, so that the blade unit 11 is separated from the second rest position as shown by the arrow 40 (FIG. 1). As the magnets move toward each other as a result of swinging, an increasing strength reaction force is generated between the magnets that acts to return the blade unit 11 to the second rest position. In the second rest position, the third magnet 32 and the fourth magnet 34 are not placed on top of each other but are offset from each other.

  The third magnet 32 and the fifth magnet 36 are positioned so as to face each other with the same type of pole, and as a result, the blade unit 11 is separated from the second rest position as indicated by the arrow 42 (FIG. 1). As the magnets move toward each other as a result of swinging, an increasing strength reaction force is generated between the magnets that acts to return the blade unit 11 to the second rest position. In the second rest position, the third magnet 32 and the fifth magnet 36 are not placed on top of each other but are offset from each other. The increasing reaction force is a non-linear response that acts to return the blade unit 11 to the rest position. When the blade unit swings about the second swing axis B in any direction from its rest position to the complete swing range, the torque range is about 0 to about 15 Nmm. Other larger torque ranges and smaller torque ranges may be used as desired. The torque can be varied by changing the spacing between the magnets, the spacing of the magnets from the swing axis, the strength and number of magnets used.

  Preferably, the blade unit 11 has a swing range up to about 30 ° around the second swing axis B. The 30 ° range includes a 15 ° swing range in the direction indicated by arrow 40 and a 15 ° swing range in the direction indicated by arrow 42. Other larger swing ranges and smaller swing ranges may be used as desired.

  Referring now to FIGS. 7-8, another embodiment of the safety razor of the present invention is shown. The opposing second set of magnetic elements is in the form of a third small permanent magnet 32, a fourth small permanent magnet 34, a fifth small permanent magnet 36, and a sixth small permanent magnet 38. The third magnet 32 and the sixth magnet 38 are fixed to the lower side of the attachment member 16. The fourth magnet 34 and the fifth magnet 36 are fixed to the upper side of the handle 12. The third magnet 32 and the fourth magnet 34 are positioned so as to face each other with the same type of pole, so that the blade unit 11 is separated from the second rest position as indicated by the arrow 40 (FIG. 1). As the magnets move toward each other as a result of swinging, an increasing strength reaction force is generated between the magnets that acts to return the blade unit 11 to the second rest position. In the second rest position, the third magnet 32 and the fourth magnet 34 are not placed on top of each other but are offset from each other.

  The fifth magnet 36 and the sixth magnet 38 are positioned so as to face each other with the same type of pole, so that the blade unit 11 is separated from the second rest position as shown by the arrow 42 (FIG. 1). As the magnets move toward each other as a result of swinging, an increasing strength reaction force is generated between the magnets that acts to return the blade unit 11 to the second rest position. In the second rest position, the fifth magnet 36 and the sixth magnet 38 are not placed on top of each other but are offset from each other. The increasing reaction force is a non-linear response that acts to return the blade unit 11 to the rest position. When the blade unit swings about the second swing axis B in any direction from its rest position to the complete swing range, the torque range is about 0 to about 15 Nmm. Other larger torque ranges and smaller torque ranges may be used as desired. The torque can be varied by changing the spacing between the magnets, the spacing of the magnets from the swing axis, the strength and number of magnets used.

  Preferably, the blade unit 11 has a swing range up to about 30 ° around the second swing axis B. The 30 ° range includes a 15 ° swing range in the direction indicated by arrow 40 and a 15 ° swing range in the direction indicated by arrow 42. Other larger swing ranges and smaller swing ranges may be used as desired.

  A further advantage of the present invention is that the strength of the return force can be easily changed by using magnetic elements of different magnetic forces.

  The razor return force characteristics embodying the invention increase smoothly as the effective spring constant of the return force characteristics gradually increases as the swing angle increases from the corresponding rest position. Further, during the swinging motion returning toward the first resting position and the second resting position, the return force characteristic curve closely follows the curve related to the swinging motion in the opposite direction, so that the blade unit is shaved. The return force is always consistent with respect to a specific oscillating displacement, as if the oscillating direction is reversed during the execution of the stroke, and a smooth oscillating motion is realized.

  Modifications to the described embodiments are naturally possible without departing from the principles of the invention. Accordingly, it is understood that the specifically described embodiments are presented as non-limiting examples only and that the present invention is intended to be limited only by the following claims. Should. Although permanent magnets were used in the above-described embodiments, electromagnetic elements can also be used to generate a magnetic return force. This option may be convenient if the razor includes a power source such as a battery for supplying current to an electrical device such as a motor that drives a vibration generating mechanism. Further, the control device adjusts the current transmitted to the electromagnetic element according to the output signal from the sensor that detects the swinging motion from the rest position of the blade unit, for example, to increase the swing displacement of the blade unit. A desired increase in the corresponding magnetic return force can be obtained.

  The dimensions and values disclosed herein are not to be understood as being strictly limited to the exact numerical values recited. Instead, unless otherwise specified, each such dimension is intended to mean both the recited value and a functionally equivalent range surrounding that value. For example, a dimension disclosed as “40 mm” shall mean “about 40 mm”.

  All documents cited in “Mode for Carrying Out the Invention” are incorporated herein by reference in the relevant part, and any citation of any document admits that it is prior art with respect to the present invention. It should not be interpreted as a thing. To the extent that any meaning or definition of a term in this document conflicts with any meaning or definition of the same term in a document incorporated by reference, the meaning or definition given to that term in this document applies. Shall be.

  While particular embodiments of the present invention have been illustrated and described, it would be obvious to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the invention. Accordingly, it is intended to cover in the appended claims all such changes and modifications that are within the scope of this invention.

Claims (15)

A safety razor comprising a handle and a blade unit having a guard, a cap and at least one blade,
The blade unit moves on the handle so as to move relative to the handle about a pivot axis substantially perpendicular to the at least one blade so as to follow the contour of the skin while shaving. Attached,
The blade unit has a rest position, and when it swings around the swing shaft away from the rest position, the blade unit is biased by a return force toward the rest position,
The return force includes a magnetic force generated by a set of magnetic elements, the blade unit swinging about the swing axis substantially perpendicular to the at least one blade. Moved relative to each other as you move,
The return razor increases as the blade unit swings away from the rest position, a safety razor.   The safety razor according to claim 1, wherein the set of magnetic elements is arranged to generate a repulsive magnetic return force for driving the blade unit to the rest position.   The safety razor blade unit according to claim 1, wherein a spring constant characteristic of the magnetic return force increases smoothly as an angle of swinging around the swing shaft from the rest position increases.   The safety razor according to claim 1, wherein the set of magnetic elements comprises three magnetic elements.   The safety razor according to claim 1, wherein the set of magnetic elements comprises four magnetic elements.   The safety razor of claim 1, wherein the blade unit is attached to the handle for movement relative to the handle about a second pivot axis substantially parallel to the at least one blade. A safety razor comprising a handle and a blade unit having a guard, a cap and at least one blade,
The blade unit has a first pivot axis substantially parallel to the at least one blade and substantially to the at least one blade so as to follow the contour of the skin while shaving. Attached to the handle for movement relative to the handle about a second pivot axis orthogonal to the handle;
The blade unit has a first rest position with respect to the first swing shaft and a second rest position with respect to the second swing shaft, and the first blade unit is separated from the first rest position. , When oscillating around the oscillation axis of
The first return force includes a magnetic force generated by a first set of magnetic elements, and the first set of magnetic elements is the first swing substantially parallel to the at least one blade. Moved relative to each other as the blade units swing around the axis,
The return force increases as the blade unit swings away from the first rest position,
The blade unit is biased by a second return force toward the rest position when swinging around the second swing shaft away from the second rest position,
The second return force includes a magnetic force generated by a second set of magnetic elements, and the second set of magnetic elements is different from the first swing axis in the second swing axis. Are moved relative to each other as the blade units swing around
The return force is a safety razor that increases as the blade unit swings away from the second rest position.   The safety razor according to claim 7, wherein the second set of magnetic elements are arranged to generate a repulsive magnetic return force for driving the blade unit to the second rest position.   The first set of magnetic elements includes a first magnetic element and a second magnetic element, the first magnetic element being attached to the blade unit adjacent to the cap. Safety razor.   The safety razor according to claim 9, wherein the blade unit is swingably supported by a pair of opposed arms extending from a hub, and the second magnetic element is disposed on the hub.   The safety razor blade unit according to claim 9, wherein the first pivot shaft is disposed in front of the at least one blade.   The safety razor blade unit according to claim 7, wherein the first swing shaft is disposed below a tangent plane to the guard and the cap.   The safety razor according to claim 7, wherein a spring constant characteristic of the magnetic return force increases smoothly as an angle of swinging around the first swing axis from the first rest position increases. Blade unit.   The safety razor according to claim 7, wherein a spring constant characteristic of the magnetic return force smoothly increases as an angle of swinging around the second swing axis from the second rest position increases. Blade unit.   The safety razor blade unit according to claim 7, wherein the first swing shaft is substantially perpendicular to the second swing shaft.

Images