Indian Patents. 218312:"A SAFETY RAZOR BLADE UNIT"

Title of Invention	"A SAFETY RAZOR BLADE UNIT"
Abstract	A safety razer including at least one movable blade.  The blade is moveable  with respect to other parts of the razer. Movement of the blade increases the blade tangent angle irt response to forces encountered during shaving.

Full Text	This invention relates to a safety razor blade unit and in particular it is concerned with a blade unit for a safety razor. The blade units of the invention may be either cartridges which are mounted replaceably on the handle for use, or the shaving heads of disposable razors having blade carrying parts permanently attached to a handle. A safety razor cartridge as currently marketed comprises a generally rectangular moulded plastics frame with guard and cap surfaces on the lengthwise extending frame parts. Within the opening of the frame are a pair of blades arranged in tandem with their cutting edges parallel to each other and directed towards the guard surface. The blades are carried on respective supports to which they are fixedly attached, and the ends of the blade supports are slidably guided in grooves in the end walls of the frame to enable the blades to retract, under forces exerted on the blades during shaving. Springs act on the blades to urge them to a normal rest position. It is well known that the so-called shaving geometry of a blade unit is important in determining the shaving performance of the blade unit. The shaving geometry defines the position and Crientation of the blades in relation to other skin contacting parts, in particular the guard and cap, of the blace unit. One parameter of the shaving geometry is the blade exposure, which is the perpendicular distance by which the edge of a blade protrudes above a shaving plane tangential to the surfaces of the skin contacting parts immediately in front of ard behind the blade edge. The known blade unit described above has the blades mounted so that the exposure is reduced when loads of sufficient magnitude to overcome the force of the springs are exerted on the blades. Another important factor in the shaving geometry is the blade tangent angle, which is the angle at which the central plane of the blade intersects the tangent plane, tie tangent plane being the plane which is tangent to the edge of the blade and to the surface of l:he skin contacting part ,next in front of the blade, For example, in a twin blade cartridge, the blade tangent angle of the first or primary blade is the angle of the blade to the tangent plane tangential to the guard surface and the edge of the primary blade, During shaving the blades of a blade unit are subjected to a combination of drag-fcrces and load,forces. Drag forces are those forces cirected essentially parallel to the snaving plane, and load forces are those forces directed aga nst the blade by the skin in the direction substantially perpendicular to the shaving plane. It has been proposed for example in and US 4774765, to mount the blades so that the blades can move to increase both exposure and blade tangent angle in response to increasing drag forces. Strain gauge measurements have shown that drag forces do not vary substantially during shaving. Hairs do not usually grow perpendicular to the skin surface and for the majority of men beard hair is inclined downwardly with respect to the face. It is believed that, when shaving, men apply the razor against the face with less pressure during upstrokes, when the blades are moving essentially against the grain, than during downstrokes, and the net result is that drag forces are not substantially different during upstrokes and downstrokes. On the basis that by applying the razor against the skin surface under greater load pressure a person is seeking greater closeness of shave, a more aggressive blade geometry would be desirable under such conditions.. The prior art razors with movatrte blades are not capable of responding to load forces in this way. Accordingly, the present invention seeks to fill this gap left by the prior art and in accordance with the invention there is provided a safety razor blade unit having at least one blade mounted for independent movement relative to other skin contacting parts of the blade unit under forces exerted at the blade edge during shaving, wherein the or each blade is mounted to move to increase the blade tangent angle in response to load forces exerted on the blade during shavina. Accordingly, there is provided a safety razor blade unit having at least one blade having a blade edge for shaving, said blade being independently movable relative to the other skin contacting parts of the blade unit under forces exerted at the blade edge during shaving, said blade unit defining a tangent plane and a tangent angle, characterized in that said blade is moveable about a pivot axis displaced from the blade edge and located in or closely adjacent to the tangent plane to increase the blade tangent angle in response to load forces exerted on the blade during shaving, and in that said pivot axis is located between the blade edge and the skin contacting surface next in front of the blade. In the preferred embodiments of this invention the blade unit includes a frame, and the or each blade is fixedly carried on a blade support, and the blade support is connected to the frame by means defining a fulcrum, the movement of the blade under load fulcrum teing located closer to the blade edge than is the point where the tangent plane meets the skin contacting surface next in front of the blade. Also, the fulcrum lies in or closely adjacent to the tangent plane. This arrangement minimises the changes in biade exposure as the blade tangent angle increases, and to the ertent that the exposure of the blade does change it reduces as the b ade tangent angle increases. Also, the angular displacement of the blade is largely insensitive to the drag forces on the blade, and the blade span, i.e, the distance between the blade edge and the skin contacting surface in front of the blade edge measured in the tangent plane, does not change significantly as the blade tangent angle increases. It is expedient for the fulcrum to be spaced from the blade edge at a distance in the range of 0.2 mm to 0.6 mm. With a blade unit embodying the inversion the blade or blades are initially set with a minimum blade tangent angle, and this angle increases under increasing load forces. As a consequence there is greater comfort as compared with other arrangements which provide the blade tangent angle to be initially set at a rnaximum. The blade supports can conveniently be coupled to the frame so that the fulcrum is fixed with respect to the frame, out this is not essential and it is also possible to allow a degree of controlled movement of the fulcrum A better understanding of the invention will be gaired from the detailed description which follows reference being made tot the accompanying drawings in which:- Figure 1 is a cross-section through a razor cartridge in accordance with the invention, the blades being shown in a normal rest position; Figure .2 shows the cartridge of Figure 1 with the blades in the position of maximum angular displacement; Figure 3 is an exploded perspective view of the cartridge shown in Figure 1; Figure 4 is an enlarged detail showing part of a blade unit and its support; Figure 5 is a perspective view showing a modified blade mounting arrangement; Figures 6A and 6B are perspective and end views showing an alternative blade mounting arrangement with a hinge; Figures 7A and 7B are perspective and end views showing another alternative blade mounting arrangement with a shell bearing; Figures 8A and 8B are perspective and end views showing a further alternative blade mounting arrangement with a moving fulcrum; Figures 9A and 9B show in perspective and and view a blade mounting arrangement including a four bar linkage, and Figure 9c shows this embodiment in a maximum blade displacement condition. The safety razor blade unit shown in Figures 1 -4 is a shaving cartridge. The nandle to which the cartridge is attached is not shown and may be of conventional form. The cartridge comprises a moulded plastics frame 1 of generally rectangular shape. The front rail of the; frame includes a guard bar 2 and carries a guard strip 3 of elastomeric material having upstanding fins extending along the strip. The rear rail of the frame defines a cao surface 5 and carries a strip 6 of lubricating material Three bla des 7 with parallel edges are mounted in the frsrre between the guard bar 2 and cap surface 5 so that the blades pass in turn over the s kin during shaving. Each blade is fixedly attached to a blade support 8, and as best seen in Figure 4, integral with each end of the blade support Is a forwardly and upwardly inclined suspension arm 9 having a journal 10 at its free end. The journal axis is parallel to the edge of the blade and spaced forwardly therefrom at a distance of 0.2 to 0.6 mm. The journals are received in bearinas defined by spring blocks 12 and the end walls of the cartridge frame. The spring blocks have connection elements 13 which engage with a snap fit in sockets formed in the frame walls, and integral with the spring blocks are spring fngers 14 which act on the undersides of the respective blades for urging the blades to their rest positions shewn in Figure 1. Upwardly directed key elements 15 on the spring blocks are arranged to extend into slots formed in the end walls of the frame to retain the journals 10 in their bearings defined at the upper enc's of these slots, as may be seen in Figures " and 2. By this arrangement each blade 7 is mounted in the cartridge frame 1 for pivotal movement about the axis defined by the journals 10, this axi's being located between the blade edge, and the skin contacting member next in front of the blade, this axis be^ng in or cbsely adjacent the tangent plane of the blade. The spring fingers 14 bias the blades to the rest position of Figure 1 in which the blades, or their support, abut against shoulders 18 jormed on the frame; end wails. When a blade 7 is subjected to a load force, applied at the biade edge and directed substantially perpendicular to the shaving plane, and the load force is of sufficient magnitude to overcome the prestress in the spring fingers 14, the blade is caused to pivot so that the blade tangent angle gradually increases as the load force increases further. As may be seen from Figure 2, the blade exposure reduces, but only slightly if desired, the reduction in exposure could be compensated by arranging for the guard bar 2 to be itself spring mounted or to be elasticity deformabls so that if will be gradually depressed under the corresponding load force applied on the guard bar as the blades pivot under the load fcrces imparted on the blades. It will be understood that the cartridge construction is such that the blade tangent angles will increase with increasing force used by the razor user to press the razor against the skin being shaved. Instead of being formed integrally with the biade support, as shown in Figure 5, the suspension arms 9 and journals 10 can be formed as a separate moulded members 20 which can be formed with slots to receive the ends of the blade support 8, Figures 6A and 6B illustrate an arrangement in which a fulcrum about which a bladeis pivotable is formed by a living hinge 22 incorporated in a nernber 23 including the suspension arm 9. The member may be integral with the cartridge frame 1 or can be moulded separately and attached to it. In the alternative construction of Figures 7A and 7B the blade support is arcuate and end extensions 24 on the support are arranged to fit into correspondingly curved slots in the frame end walls to form a shell bearing defining the centre of pivotal movement of the blade 7. It is not essential for each of the blades tn be contrained to move about a fixed fulcrum or pivot axis. In the modified construction of Figures 8A and 8B, the suspension arrrs 9 showing integral with the blade support although they could be moulded separately and attached to the blade support as in Figure 5, have hooks 26 at their free forward ends. The nooks rest on cantilever support bars 27 fixed to the frame end walls and having substantially flat surfaces with opposite edges defining respective pivot axes. During initial pivotal displacement of the blade, the suspension arms 9 and blade 7 pivot about the axis defined by the forward edges of the stpport bars 27, and during subsequent angular movement the pivoting takes place about the pivot axis defined by the rear edges of support bars, In the modified embodiment cf Figures 9A, 9B and 9C the blades 7 are supported by integrally moulded four bar linkage assemblies. A first link 30 forms the suspension arm 9 a second L-shaped link 31, is fixed to the cartridge frame, a third link 32 is connected to the suspension arm 9 by one living hinge 33 defining a fulcrum for movement of the blade 7, and to one end of the second link 31 by another living hinge 34, and a fourth link, 35 of short length is connected by respective living hinges 36, 37 to the other end of the second link and to the first l;:nk. Under load forces sppliea at the blade edge the link 30 moves about the fulcrum defined by the hinge 33. There is some downward movement of the fulcrum due to the hinge 34, but this displacement which will result in reduction of the blade exposure, is only small due to the short length of the fourth link 35. In all the described embodiments the fulcrums will be located substantially as described in relation to the embodiment of Figures 1-4 and as a consequence the desired effect of the blade tangent angels increasing as the load forces increase is obtained, while the blade spans do not change substantially, and the changes to the blade exposures are kept small. WE CLAIM:- 1. A safety razor blade unit having at least one blade (7) having a blade edge for shaving, said blade (7) being independently movable relative to the other skin contacting parts (2, 5) of the blade unit under forces exerted at the blade edge during shaving, said blade unit defining a tangent plane (T) and a tangent angle (A), characterized in that said blade (7) is moveable about a pivot axis displaced from the blade edge and located in or closely adjacent to the tangent plane (T) to increase the blade tangent angle (A) in response to load forces exerted on the blade during shaving, and in that said pivot axis is located between the blade edge and the skin contacting surface (2) next in front of the blade (7). 2. A safety razor blade unit as claimed in claim 1, wherein said blade unit having a frame (1) with each blade (7) being fixedly carried on a blade support (8), and the blade support (8) being connected to the frame (1) by means defining a fulcrum, the movement of the blade (7) comprising angular displacement about said fulcrum, wherein said fulcrum is located closer to the blade edge than is the point where the tangent plane (T) meets the skin contacting surface (2) next in front of the blade (7). 3. A safety razor blade unit as claimed in claim 2, wherein said fulcrum is fixed with respect to the frame (1) and said pivot axis comprises said fulcrum. 4. A safety razor blade unit as claimed in claim 3, wherein said fulcrum comprises journals (10) provided at the opposite ends of the blade support (8) and engaged in bearings in the frame (1). 5. A safety razor blade unit as claimed in claim 2, wherein said blade support (8) is connected to the frame (1) so that the fulcrum moves relative to the frame (1) during angular displacement of the blade (7). 6. A safety razor blade unit as claimed in claim 5, wherein said blade support (8) has a suspension arm (9) engaged with a support bar (27) fixed to the frame (1) and having opposite edges about which the suspension arm (9) pivots sequentially as the angular displacement of the blade (7) increases. 7. A safety razor blade unit as claimed in either claim 2 or 5, wherein said fulcrum comprises a living hinge (22). 8. A safety razor blade unit as claimed in claim 2, wherein said fulcrum comprises a shell bearing. 9. A safety razor blade unit as claimed in any one of claims 2 to 8, wherein said fulcrum is spaced from the blade edge at a distance in the range of 0.2mm to 0.6mm. 10. A safety razor blade unit as claimed in claim 1, wherein said unit has a plurality of blades (7) having parallel cutting edges, each blade (7) being mounted for pivotal movement about a pivot axis displaced from its cutting edge and located in or closely adjacent to the tangent plane (T) of the blade. 11. A safety razor blade unit substantially as hereinbefore described with reference to and as illustrated in the accompanying drawings.

Full Text

This invention relates to a safety razor blade unit and in particular it is concerned with a blade unit for a safety razor. The blade units of the invention may be either cartridges which are mounted replaceably on the handle for use, or the shaving heads of disposable razors having blade carrying parts permanently attached to a handle. A safety razor cartridge as currently marketed comprises a generally rectangular moulded plastics frame with guard and cap surfaces on the lengthwise extending frame parts. Within the opening of the frame are a pair of blades arranged in tandem with their cutting edges parallel to each other and directed towards the guard surface. The blades are carried on respective supports to which they are fixedly attached, and the ends of the blade supports are slidably guided in grooves in the end walls of the frame to enable the blades to retract, under forces exerted on the blades during shaving. Springs act on the blades to urge them to a normal rest position.
It is well known that the so-called shaving geometry of a blade unit is important in determining the shaving performance of the blade unit. The shaving geometry defines the position and
Crientation of the blades in relation to other skin contacting parts, in particular the guard and cap, of the blace unit. One parameter of the shaving geometry is the blade exposure, which is the perpendicular distance by which the edge of a blade protrudes above a shaving plane tangential to the surfaces of the skin contacting parts immediately in front of ard behind the blade edge. The known blade unit described above has the blades mounted so that the exposure is reduced when loads of sufficient magnitude to overcome the force of the springs are exerted on the blades. Another important factor in the shaving geometry is the blade tangent angle, which is the angle at which the central plane of the blade intersects the tangent plane, tie tangent plane being the plane which is tangent to the edge of the blade and to the surface of l:he skin contacting part ,next in front of the blade, For example, in a twin blade cartridge, the blade tangent angle of the first or primary blade is the angle of the blade to the tangent plane tangential to the guard surface and the edge of the primary blade,
During shaving the blades of a blade unit are subjected to a combination of drag-fcrces and load,forces. Drag forces are those forces cirected essentially parallel to the snaving plane, and load forces are those forces directed aga nst the blade by the skin in the direction substantially perpendicular to the shaving plane.
It has been proposed for example in

and US 4774765, to mount the blades so that the blades can move
to increase both exposure and blade tangent angle in response to
increasing drag forces. Strain gauge measurements have shown that drag forces do not vary substantially during shaving. Hairs do not usually grow perpendicular to the skin surface and for the majority of men beard hair is inclined downwardly with respect to the face. It is believed that, when shaving, men apply the razor against the face with less pressure during upstrokes, when the blades are moving essentially against the grain, than during downstrokes, and the net result is that drag forces are not substantially different during upstrokes and downstrokes. On the basis that by applying the razor against the skin surface under greater load pressure a person is seeking greater closeness of shave, a more aggressive blade geometry would be desirable under such conditions.. The prior art razors with movatrte blades are not capable of responding to load forces in this way.
Accordingly, the present invention seeks to fill this gap left by the prior art and in accordance with the invention there is provided a safety razor blade unit having at least one blade mounted for independent movement relative to other skin contacting parts of the blade unit under forces exerted at the blade edge during shaving, wherein the or each blade is mounted to move to increase the blade tangent angle in response to load forces exerted on the blade during shavina.
Accordingly, there is provided a safety razor blade unit having at least one blade having a blade edge for shaving, said blade being independently movable relative to the other skin contacting parts of the blade unit under forces exerted at the blade edge during shaving, said blade unit defining a tangent plane and a tangent angle, characterized in that said blade is moveable about a pivot axis displaced from the blade edge and located in or closely adjacent to the tangent plane to increase the blade tangent angle in response to load forces exerted on the blade during shaving, and in that said pivot axis is located between the blade edge and the skin contacting surface next in front of the blade.
In the preferred embodiments of this invention the blade unit
includes a frame, and the or each blade is fixedly carried on a blade
support, and the blade support is connected to the frame by means
defining a fulcrum, the movement of the blade under load
fulcrum teing located closer to the blade edge than is the point where the tangent plane meets the skin contacting surface next in front of the blade. Also, the fulcrum lies in or closely adjacent to the tangent plane. This arrangement minimises the changes in biade exposure as the blade tangent angle increases, and to the ertent that the exposure of the blade does change it reduces as the b ade tangent angle increases. Also, the angular displacement of the blade is largely insensitive to the drag forces on the blade, and the blade span, i.e, the distance between the blade edge and the skin contacting surface in front of the blade edge measured in the tangent plane, does not change significantly as the blade tangent angle increases. It is expedient for the fulcrum to be spaced from the blade edge at a distance in the range of 0.2 mm to 0.6 mm.
With a blade unit embodying the inversion the blade or blades are initially set with a minimum blade tangent angle, and this angle increases under increasing load forces. As a consequence there is greater comfort as compared with other arrangements which provide the blade tangent angle to be initially
set at a rnaximum.
The blade supports can conveniently be coupled to the frame so that the fulcrum is fixed with respect to the frame, out this is not essential and it is also possible to allow a degree of controlled movement of the fulcrum
A better understanding of the invention will be gaired from the detailed description which follows reference being made tot the accompanying drawings in which:-

Figure 1 is a cross-section through a razor cartridge
in accordance with the invention, the blades being
shown in a normal rest position;
Figure .2 shows the cartridge of Figure 1 with the
blades in the position of maximum angular
displacement;
Figure 3 is an exploded perspective view of the
cartridge shown in Figure 1;
Figure 4 is an enlarged detail showing part of a
blade unit and its support;
Figure 5 is a perspective view showing a modified
blade mounting arrangement;
Figures 6A and 6B are perspective and end views
showing an alternative blade mounting arrangement
with a hinge;
Figures 7A and 7B are perspective and end views
showing another alternative blade mounting
arrangement with a shell bearing;
Figures 8A and 8B are perspective and end views
showing a further alternative blade mounting
arrangement with a moving fulcrum;
Figures 9A and 9B show in perspective and and
view a blade mounting arrangement including a four
bar linkage, and
Figure 9c shows this embodiment in a maximum
blade displacement condition.
The safety razor blade unit shown in Figures 1 -4 is a shaving cartridge. The nandle to which the cartridge is attached is not shown and may be of conventional form. The cartridge comprises a moulded plastics frame 1 of generally rectangular shape. The front rail of the; frame includes a guard bar 2 and carries a guard strip 3 of elastomeric material having upstanding fins extending along the strip. The rear rail of the frame defines a cao surface 5 and carries a strip 6 of lubricating material Three bla des 7 with parallel edges are mounted in the frsrre between the guard bar 2 and cap surface 5 so that the blades pass in turn over the s kin during shaving. Each blade is fixedly attached to a blade support 8, and as best seen in Figure 4, integral with each end of the blade support Is a forwardly and upwardly inclined suspension arm 9 having a journal 10 at its free end. The journal axis is parallel to the edge of the blade and spaced forwardly therefrom at a distance of 0.2 to 0.6 mm. The journals are received in bearinas defined by spring blocks 12 and the end walls of the cartridge frame. The spring blocks have connection elements 13 which engage with a snap fit in sockets formed in the frame walls, and integral with the spring blocks are spring fngers 14 which act on the undersides of the respective blades for urging the blades to their rest positions shewn in Figure 1. Upwardly directed key elements 15 on the spring blocks are arranged to extend into slots formed in the end walls of the frame to retain the journals 10 in their bearings defined at the upper enc's of these slots, as may be seen in Figures " and 2. By this arrangement each blade 7 is mounted in the cartridge frame 1
for pivotal movement about the axis defined by the journals 10, this axi's being located between the blade edge, and the skin contacting member next in front of the blade, this axis be^ng in or cbsely adjacent the tangent plane of the blade. The spring fingers 14 bias the blades to the rest position of Figure 1 in which the blades, or their support, abut against shoulders 18 jormed on the frame; end wails. When a blade 7 is subjected to a load force, applied at the biade edge and directed substantially perpendicular to the shaving plane, and the load force is of sufficient magnitude to overcome the prestress in the spring fingers 14, the blade is caused to pivot so that the blade tangent angle gradually increases as the load force increases further. As may be seen from Figure 2, the blade exposure reduces, but only slightly if desired, the reduction in exposure could be compensated by arranging for the guard bar 2 to be itself spring mounted or to be elasticity deformabls so that if will be gradually depressed under the corresponding load force applied on the guard bar as the blades pivot under the load fcrces imparted on the blades. It will be understood that the cartridge construction is such that the blade tangent angles will increase with increasing force used by the razor user to press the razor against the skin being shaved.
Instead of being formed integrally with the biade support, as shown in Figure 5, the suspension arms 9 and journals 10 can be formed as a separate moulded members 20 which can be formed with slots to receive the ends of the blade support 8,
Figures 6A and 6B illustrate an arrangement in which
a fulcrum about which a bladeis pivotable is formed by a living hinge 22 incorporated in a nernber 23 including the suspension arm 9. The member may be integral with the cartridge frame 1 or can be moulded separately and attached to it.
In the alternative construction of Figures 7A and 7B the blade support is arcuate and end extensions 24 on the support are arranged to fit into correspondingly curved slots in the frame end walls to form a shell bearing defining the centre of pivotal movement of the blade 7.
It is not essential for each of the blades tn be contrained to move about a fixed fulcrum or pivot axis. In the modified construction of Figures 8A and 8B, the suspension arrrs 9 showing integral with the blade support although they could be moulded separately and attached to the blade support as in Figure 5, have hooks 26 at their free forward ends. The nooks rest on cantilever support bars 27 fixed to the frame end walls and having substantially flat surfaces with opposite edges defining respective pivot axes. During initial pivotal displacement of the blade, the suspension arms 9 and blade 7 pivot about the axis defined by the forward edges of the stpport bars 27, and during subsequent angular movement the pivoting takes place about the pivot axis defined by the rear edges of support bars,
In the modified embodiment cf Figures 9A, 9B and 9C the blades 7 are supported by integrally moulded four bar linkage assemblies. A first link 30 forms the suspension arm 9 a second L-shaped link 31, is fixed to the cartridge frame, a third link
32 is connected to the suspension arm 9 by one living hinge 33 defining a fulcrum for movement of the blade 7, and to one end of the second link 31 by another living hinge 34, and a fourth link, 35 of short length is connected by respective living hinges 36, 37 to the other end of the second link and to the first l;:nk. Under load forces sppliea at the blade edge the link 30 moves about the fulcrum defined by the hinge 33. There is some downward movement of the fulcrum due to the hinge 34, but this displacement which will result in reduction of the blade exposure, is only small due to the short length of the fourth link 35. In all the described embodiments the fulcrums will be located substantially as described in relation to the embodiment of Figures 1-4 and as a consequence the desired effect of the blade tangent angels increasing as the load forces increase is obtained, while the blade spans do not change substantially, and the changes to the blade exposures are kept small.

WE CLAIM:-
1. A safety razor blade unit having at least one blade (7) having a
blade edge for shaving, said blade (7) being independently movable
relative to the other skin contacting parts (2, 5) of the blade unit
under forces exerted at the blade edge during shaving, said blade
unit defining a tangent plane (T) and a tangent angle (A),
characterized in that said blade (7) is moveable about a pivot axis
displaced from the blade edge and located in or closely adjacent to
the tangent plane (T) to increase the blade tangent angle (A) in
response to load forces exerted on the blade during shaving, and in
that said pivot axis is located between the blade edge and the skin
contacting surface (2) next in front of the blade (7).
2. A safety razor blade unit as claimed in claim 1, wherein said blade
unit having a frame (1) with each blade (7) being fixedly carried on
a blade support (8), and the blade support (8) being connected to
the frame (1) by means defining a fulcrum, the movement of the
blade (7) comprising angular displacement about said fulcrum,
wherein said fulcrum is located closer to the blade edge than is the
point where the tangent plane (T) meets the skin contacting
surface (2) next in front of the blade (7).
3. A safety razor blade unit as claimed in claim 2, wherein said
fulcrum is fixed with respect to the frame (1) and said pivot axis
comprises said fulcrum.
4. A safety razor blade unit as claimed in claim 3, wherein said
fulcrum comprises journals (10) provided at the opposite ends of
the blade support (8) and engaged in bearings in the frame (1).
5. A safety razor blade unit as claimed in claim 2, wherein said blade
support (8) is connected to the frame (1) so that the fulcrum moves
relative to the frame (1) during angular displacement of the blade
(7).
6. A safety razor blade unit as claimed in claim 5, wherein said blade
support (8) has a suspension arm (9) engaged with a support bar
(27) fixed to the frame (1) and having opposite edges about which
the suspension arm (9) pivots sequentially as the angular
displacement of the blade (7) increases.
7. A safety razor blade unit as claimed in either claim 2 or 5, wherein
said fulcrum comprises a living hinge (22).
8. A safety razor blade unit as claimed in claim 2, wherein said
fulcrum comprises a shell bearing.
9. A safety razor blade unit as claimed in any one of claims 2 to 8,
wherein said fulcrum is spaced from the blade edge at a distance
in the range of 0.2mm to 0.6mm.
10. A safety razor blade unit as claimed in claim 1, wherein said unit
has a plurality of blades (7) having parallel cutting edges, each
blade (7) being mounted for pivotal movement about a pivot axis
displaced from its cutting edge and located in or closely adjacent to
the tangent plane (T) of the blade.
11. A safety razor blade unit substantially as hereinbefore described
with reference to and as illustrated in the accompanying drawings.

Documents:

2121-del-1997-abstract.pdf

2121-del-1997-claims.pdf

2121-del-1997-correspondence-others.pdf

2121-del-1997-correspondence-po.pdf

2121-del-1997-description (complete).pdf

2121-del-1997-drawings.pdf

2121-del-1997-form-1.pdf

2121-del-1997-form-13.pdf

2121-del-1997-form-19.pdf

2121-del-1997-form-2.pdf

2121-del-1997-form-4.pdf

2121-del-1997-form-6.pdf

2121-del-1997-petition-137.pdf

2121-del-1997-petition-138.pdf

« Previous Patent

Next Patent »

Patent Number

218312

Indian Patent Application Number

2121/DEL/1997

PG Journal Number

21/2008

Publication Date

23-May-2008

Grant Date

31-Mar-2008

Date of Filing

30-Jul-1997

Name of Patentee

THE GILLETE COMPANY

Applicant Address

PRUDENTIOAL TOWER BUILDING, BOSTON, STATE OF MASSACHUSETTS 02199, UNITED STATES OF AMERICA.

Inventors:

#	Inventor's Name	Inventor's Address
1	PAUL WARRICK	45 CHARLVILLE DRIVE, BEANSHEAF FARM, CALCOT, READING, BERKSHIRE RG31 7AU, ENGLAND.
2	DANIEL BRIAN LAZARCHIK	261 MARLBOROUGH ST. APT. 2, BOSTON, MA 02116, USA.

PCT International Classification Number

B62B 21/22

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	9616402.5	1996-08-05	U.K.