This invention relates to razors and in particular to razors of the kind in which blades with sharp cutting edges are positioned between guard and cap surfaces that contact the skin as the cutting edges are moved over the skin for severing hairs that project from the skin.
Safety razors generally comprise a handle by means of which one or more blades with sharp cutting edges are moved across the surface of the skin in performing a shaving stroke with the razor. Usually there is a guard for contact with the skin in front of the cutting edges of the blades and a cap for contacting the skin behind the cutting edges, the guard and cap elements being important for establishing the so-called shaving geometry that is critical in determining the shaving performance. Factors by which shaving performance can be judged include closeness, comfort and safety. The parameters of the shaving geometry that influence the shaving performance include the blade span, which is the distance from the cutting edge of a blade to the surface of the skin contacting element next in front of that cutting edge, blade exposure, which is in the height of the cutting edge of a blade above a plane tangential to the skin contacting elements immediately in front of and behind that cutting edge, and the blade angle, which is the angle at which a plane bisecting the tip of the blade intersects a plane extending between skin contacting surfaces of the cap and guard. There have been many prior proposals for appropriate shaving geometries for razors designed for unidirectional use, that is to be moved in one predetermined direction across the skin during shaving. In W095/09071 (Gilder et al) and W096/29183 (Gilder et al) there is disclosed an effective shaving geometry for a razor with three blades between the guard and the cap of the razor.
Although unidirectional safety razors are most common, there are also known razors with blades that are arranged with their cutting edges facing in opposite directions so that the razor is bi-directional and can be used with a back and forth movement in the course of shaving so that respective blades are effective in cutting hairs during forward strokes and rearward strokes of the razor. In U.S. Pat. No. 6,161,288 (Andrews) for example there are described several razor constructions in which two pairs of blades are arranged on opposite sides of a central cap member with the cutting edges of the blade pairs facing away from each other and towards respective guard members. Described in WO 2004/037037 (Coffin et al) is a razor having two pairs of blades included in respective blade assemblies on opposite sides of a central guard, the cutting edges of the blades facing inwardly towards the guard. The cutting edges have rest positions slightly above a plane extending between cap surfaces located behind the respective blade pairs, and the blade assemblies are movable for the cutting edges to retract into the housing under influence of forces encountered during shaving. The guard is shown to project significantly above the shaving plane so that the cutting edges are below planes extending between the guard and cap surfaces.
The present invention has for its aim to provide improved shaving geometry for a blade unit of a razor adapted for bi-directional shaving.
Provided in accordance with the invention is a blade unit in or for a razor comprising a guard element, first and second cap elements on opposite sides of the guard element, a plurality of blades with cutting edges disposed between the guard element and the first cap element and facing towards the guard element, and at least one blade with a cutting edge disposed between the guard element and the second cap element and facing towards the guard element, wherein the first cap element, the guard element and the second cap element are circumscribed by an arc of a circle, a first plane extends between positions at which the circumscribing arc meets a first surface on the guard element and a surface on the first cap element, a second plane extends between positions at which the circumscribing arc meets a second surface on the guard element and a surface the second cap element, characterised in that the cutting edge of at least one of the blades in said plurality of blades has a position that is above the first plane and at or below the circumscribing arc.
A blade unit construction in accordance with the invention is especially suited for use in a razor which is equipped with a motor for driving the blade unit so that bi-directional shaving is achieved even when the razor as a whole is moved unidirectionally across the skin surface. Such a razor is described in our pending UK patent application No. 0432099.1 (Royle & Saker) filed on 18 Oct. 2004, the contents of which are incorporated herein by reference. In a preferred embodiment the blade unit is mounted for pivotal movement relative to a handle of the razor about an axis located substantially at the centre of curvature of the circumscribing arc. A drive mechanism actuable by the motor may be operable to oscillate the blade unit about the pivot axis through an angle that results in a stroke of blade movement in the range of about 0.3 mm to about 3.0 mm, e.g. an angle of 5° to 30° with the blade edges at a radius of about 10 mm from the pivot axis.
The first and second surfaces on the guard element may be respective areas of the same surface or the same part of a surface on the guard element. In many embodiments the surfaces on the guard and cap element met by the circumscribing arc are surfaces on these elements which contact the skin during shaving.
There may be one or more additional blades on either side of the guard element and the cutting edge of any such additional blade may face either towards or away from the guard element. In a preferred construction there is a second plurality of blades with cutting edges disposed between the guard element and the second cap element, and the cutting edge of at least one of the blades in the second plurality of blades has a position that is not below, preferably above, the second plane and at or below the circumscribing arc. There may be two, three, four or more blades in the or each plurality of blades, a preferable arrangement being for equal numbers of blades, e.g. two blades on each side of the guard element and the blades being disposed in symmetrical arrangements on opposite sides of the guard element.
The cutting edge of each blade in the or each plurality of blades is ideally positioned between the circumscribing arc and the adjacent one of the first and second planes.
In a preferred construction, in at least one plurality of blades the cutting edge of a blade further from the guard element is positioned at a greater distance from the adjacent one of the first and second planes than the cutting edge of a blade closer to the guard element. Furthermore, the cutting edge of a blade further from the guard element has a position inside the circumscribing arc and at a greater distance from the circumscribing arc than the cutting edge of a blade closer to the guard element.
Suitably the circumscribing arc has a radius of from 8.0 mm to 12.0 mm, such as 9.0 mm to 11.0 mm and preferably from 9.5 mm to 10.5 mm In at least one plurality of blades the cutting edge of the blade closest to the guard element is at a distance of from 0.2 to 1.2 mm, preferably 0.2 to 0.7 mm and more precisely 0.25 to 0.45 mm, from a point at which extension of the first and second planes intersect, this distance being measured along the adjacent plane. Also, in at least one plurality of blades the tips of the cutting edges of two adjacent blades are separated by a distance of 0.2 to 1.5 mm, preferably 0.6 to 1.2 mm, and more specifically 0.9 to 1.1 mm, this distance being measured along the adjacent plane.
In the preferred structural arrangement the or each plurality of blades includes a front blade nearest the guard element and a following blade, the tip of the cutting edge of the front blade has a position at a distance of from 0.02 to 0.03 mm above the adjacent one of the first and second planes, and/or the tip of the cutting edge of the following blade has a position at a distance of from 0.03 to 0.07 mm, preferably 0.04 to 0.06 mm above the plane.
The blade edge positions defined by the dimensions detailed above are those preferred and at which the blades may be fixed relative to the guard and/or cap elements, but it may be desirable for the blades to be movable into or away from these positions during shaving, for example as a result of the shaving forces that are imparted on components of the blade unit.
The foregoing and other features of the invention will be better understood from the detailed description that follows and in which reference is made to the accompanying drawings, wherein
The safety razor blade unit 110 illustrated in
The safety razor has a handle 1, only an upper part of which is shown. The handle has a bifurcated upper end defining a pair of yoke arms 2 having pivot elements 3 at their free ends. Pivotally connected to the pivot elements 3 for pivotal motion relative to the handle about a pivot axis A transverse to the length of the handle 1 is a razor head structure 5. The head structure includes a body 6 with a pair of end members 7 respectively connected to the pivot elements 3 and integrally attached to opposite end walls of a motor housing 9. The housing has a bottom cover 15 formed with an externally projecting tubular spigot 14 defining a cable entry opening 16. An electric motor 18 is sealed within the chamber enclosed by the housing 9 and has an output drive shaft 19 with an eccentric cam element 20. A flexible tube 42 interconnects a spigot on the handle with the spigot 14 on the motor housing for electrical cable conductors to pass between the handle 1 and the head structure 5 for conducting electric current from a battery accommodated in the handle to the electric motor 18.
A blade unit platform 101 is pivotally mounted between the end members 7 by journals 102, and a drive arm 103 with an elongated slot 104 extends downwardly from the platform 101. The arm 104 passes freely through a slot 105 formed in the top wall of the motor housing to which the arm 104 is sealed by a flexible sealing boot 108. The output drive shaft 19 of the motor carries an eccentric cam element 20 which engages in the slot 104 so that, when the motor is energised, the blade unit platform 101 is caused to rock back and forth about its pivot as indicated by the arrows 109 in
The blade unit 110 which is shown in detail in
The guard element 35 has a castellated top with upwardly directed projections 38 uniformly spaced apart along the guard element 35. Other forms of guard element for example a guard element with a continuous top surface, are also possible. The blades 32 are mounted on blade supports 34 in predetermined positions with respect to the top of the guard element 35, as defined by the free upper end faces of the projections 38, and the top surfaces of the cap elements 36, 37 as described in detail below. The blades are retained in the frame 31 by metal clips 39 wrapped around the ends of the frame in a manner known per se. Protrusions 40 on the outer faces of the cap elements 36, 37 have upper ends that are in alignment with the projections 38 and can provide a skin guiding or control function in use of the razor.
As can be best seen in
The described blade geometry, that is the positions of the cutting edges of the blades 32 between the guard and cap elements 35, 36, 37 can ensure an effective shaving performance in terms of the closeness of shave obtained and a good level of comfort both during and after shaving. The blade unit 110 can be oscillated back and forth through an angle in the range of from about 5° to about 30° which will achieve a blade movement of about 0.3 to 3.0 mm along the skin surface for cutting hairs. A suitable oscillation speed is around 95 Hz, which with the geometry described can produce and average blade speed of about 600 mm/sec. Speeds of this order can sufficient to ensure that the pairs of blades will act with maximum effect in succession to cut individual hairs in both oscillation directions and with the razor head as a whole being moved across the skin surface at a typical shaving speed of about 225 mm/sec. The pair of blades that is not performing a cutting action at any instant in time may be effective in raking up low lying hairs to improve the cutting efficiency of the other active pair of blades.
It should be understood that the foregoing description of the preferred embodiment is given by way of non-limiting example only and that modifications and variations are possible without departing from the scope of the invention as defined by the claims which follow. The invention has been particularly described with reference to a blade unit structure in which the guard and cap elements remain in fixed predetermined positions relative to one another during shaving. If any one or more of the guard and cap elements, or indeed the blades, is moveable within the blade unit the circumscribing arc and the first and second planes should be determined at any of the positions of the moveable element or moveable elements that can arise in the course of shaving as a result of the forces imposed on the skin contacting parts.
List of Reference Numerals
A. Pivot axis
1. Razor handle
2. Yoke
3. Pivot elements
5. Head Structure
6. Body
7. End Members
9. Motor housing
14. Spigot
15. Cover
16. Cable entry
18. Motor
19. Drive Shaft
20. Cam element
31. Frame
32, 32a, 32b. Blades
33
a & 33b. Cutting edges
34. Blade supports
35. Guard element
35
a & 35b. Guard element surfaces
36. First cap element
36
a. First cap element surface
37. Second cap element
37
b. Second cap element surface
38. Projections
39. Blade retention clips
40. Protrusions
42. Flexible tube
45. Circular arc
46. Circumscribing arc
47. First plane
48. Second plane
d1. Distance from intersections of the first and second planes to tip of front blade
d2. Distance between tips of front and following blades
h1& h2. Height of blade tips above the first and second planes
101. Platform
102. Journals
103. Drive arm
104. Slot
105. Slot
108. Sealing boot
109. Directional arrows
110. Blade unit
112. Casing
113. Opening
114. Guard strip
115. Lubricating strip
Number | Date | Country | Kind |
---|---|---|---|
0515990.0 | Aug 2005 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB2006/052679 | 8/3/2006 | WO | 00 | 7/29/2010 |