The invention generally relates to handles for razors, more particularly to handles with movable portions.
Since the invention of the safety razor in the 1850's, four main design architectures of razors—the safety razor, the disposable edge safety razor, the modern cartridge system razor, and the disposable razor—have dominated the market. During this time, both the razor handle and the razor cartridge/blade provide benefits to the shaver.
In the last fifty years, the premium wet shave market has been dominated razors using replaceable cartridges, which are the only component that touches the skin during shaving. The consumer benefits of these cartridge razors have been limited to mainly safety, convenience, ergonomics, and/or control of blade geometry and have been driven mainly by improvement to the cartridges.
Handles for razors that use replaceable cartridges have improved by better ergonomics of handle grips, better cartridge attachment and detachment mechanisms, and the utilization of multiple axes of rotation of the cartridge relative to the handle. Typically, these improvements require additional components, including some of them that have prescribed motion. These additional components often require tight tolerances with little room for error. As a result, current approaches introduce complexities, costs, and durability issues for manufacturing, assembling, and using such razors.
Additionally, recent advances in shaving razor handles that use replaceable cartridges have enabled the delivery of other consumer experiential benefits from the handle close to or onto the shaved surface. Such razor handles include liquid dispensing razors and heated razors. Most of these razor handles have been adapted to fit cartridges like those currently manufactured for existing premium system handles. These handle and cartridge systems have many disadvantages, including being expensive to manufacture—e.g. need heating elements in the cartridge and having poor handle ergonomics and shave performance due to the interfaces between handle and cartridge and the large contact area of shaving surfaces.
What is needed, then, is a better design or architecture of a cartridge and a razor handle system that enables good core shaving performance, good product integrity and safety, multiple axes of cartridge motion relative to the handle, easy attachment and detachment of cartridge from the razor handle, and simple, reliable, and cost-effective manufacturing when compared to existing razors. Such a design architecture would apply to both powered and unpowered razors suitable for wet or dry shaving and to both durable and disposable razor handles. Such a design may also apply to razors that delivery of benefits from the handle close to or onto the skin.
The present invention is directed to a method of manufacturing a razor handle comprising the steps of providing an upper portion with one or more upper elements, providing a lower portion with one or more lower elements, securing the upper portion to the lower portion wherein a rigid member extends between the upper portion and the lower portion.
Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, suitable methods and materials are described below. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety. In case of conflict, the present specification, including definitions, will control. In addition, the materials, methods, and examples are illustrative only and not intended to be limiting.
Other features and advantages of the invention will be apparent from the following detailed description, and from the claims.
While the specification concludes with claims particularly pointing out and distinctly claiming the subject matter which is regarded as forming the present invention, it is believed that the invention will be better understood from the following description which is taken in conjunction with the accompanying drawings in which like designations are used to designate substantially identical elements, and in which:
Except as otherwise noted, the articles “a,” “an,” and “the” mean “one or more.”
The present invention described herein involves a novel razor structure and method of manufacturing such structure. The razor structure relates to the layering of functional components, and the layering of one or movable members and assemblies, above and below, a member of the handle that is made from a more rigid material than other portions of the handle. Preferably, this rigid member forms a relatively thin and wide section of the handle at least one or more of the functional assemblies above the rigid member are connected directly to the member below through holes, openings or o a thin and relatively wide section of the razor handle. This thin and relatively wide section of the razor handle is typically more rigid than other large components in the handle through choice of material and design. Functional assemblies of components such as cartridge eject mechanisms and pivot mechanism can be attached above and below this rigid member.
Existing razor designs place functional components within an internal cavity of a rigid component of the razor handle. The advantage of the present invention's layering of functional components and assemblies above and below a relatively wide and relatively thin rigid member over existing razors includes the ability to incorporate large and more complex functional components within those functional components and to manufacture razors with a larger variety of improved consumer benefits in a simple, reliable, and cost-effective manner.
This razor structure is also advantageous in providing consumers with a safe product with good product integrity in case of accidental drops. Most existing handles weight less than 56 grams and the majority weight less than 40 grams. As handles become more complex and more premium in market tier, they tend to weigh more. The razor structure of the present invention is well suited for handles that are two to three times heavier than most razors commonly found on the market, specifically handles from about 57 grams to about 150 grams and preferably about 80 grams. Such a handle is considered a “heavy” handle in the present invention.
The razor structure and methods of manufacturing the razor structure of the present invention are also advantageous for non-limiting embodiments of razors described herein that can provide benefits to a consumer's skin using a razor handle, where the razor handle has a skin interconnect member through which benefits can be provided and such that the skin interconnect member is in a pivotal relationship to the main body of the handle. This skin interconnect member can be joined or fixed to the razor cartridge.
Other embodiments of razor structures and methods of manufacturing are contemplated in the present invention such as those without skin interconnect members or pivoting mechanisms.
The movable member or portion of the present invention is desirably disposed on a razor structure or a component of a razor, preferably a handle.
The “main body” of the handle as used herein signifies the razor handle of the present invention without the skin interconnect member 22. As shown in
A “movable member” or “movable member assembly” as used herein signifies a member comprised of one or more portions on the razor which are capable of moving or providing a motion functionality for the razor. For instance, the movable member of the present invention may preferably comprise portions which provide a pivot mechanism or a release or ejection mechanism.
The term “spring”, “spring mechanism”, or “spring member” as used herein, signifies any type of mechanical spring, such as a compression spring, a leaf spring, or any feasible spring or combination thereof. A spring member of the present invention generally has a loop shape. The term “loop” as used herein signifies a generally curved, circular shape, which may form a loop. Non-limiting loops of the present invention comprise oval, circular, elliptical, ring shape, substantially a V-shape, tear drop shape, or any modification or combination thereof. The loop may be split and the loop itself, the end portions or distal ends of the loop can be unconnected or free, unsupported, connected or mounted, or overlap each other. The distal ends can be facing towards each other or can be facing away from each other. A loop spring member of the present invention, when straightened, desirably has an overall length of about 30 mm to about 90 mm.
The spring mechanism of the present invention is based on an interaction between the portions of the movable member assembly (whether disposed on the cartridge or the handle of the razor) and the spring member. During the pivot or eject functions, the spring member offers a resistance that is a function of its preload compression, its geometry and material, and the geometry of the carrier structure, and depending on the intensiveness of that resistance, the effect will be larger or smaller.
The term “rigid member” as used herein signifies a member comprised of a hard metal that can include a rigid member platform. The terms frame and rigid member of the present invention can be used interchangeably herein. However, a secondary frame is generally not a part of the rigid member of the present invention. The rigid member can be a longitudinal portion in a handle main section. The rigid member platform can accommodate a movable member assembly with one or more movable members disposed thereon or therethrough. The frame 18 is desirably comprised of a hard metal. The hard metal may be comprised of a diecast material. A nonlimiting example of a diecast material of the present invention is zinc. Die-cast zinc materials include ZAMACK3, ZAMACK5, and ZA8. Other suitable materials include glass fiber reinforced plastics such as IXEF, stainless steel, aluminum, aluminum diecast, and magnesium diecast. The rigid member or frame may be comprised of one material, preferably a strong metal, but may be formed as two bodies that are then connected. In this case, it is preferable that the rigid member platform is made of hard metal that is necessarily harder than that of the rest of the frame.
The rigid member platform of the present invention can be a section of the rigid member having a wide and thin profile relative to the overall rigid member. The movable member assembly can be mounted above and below the rigid member platform. In the present invention, a maximum width to median thickness ratio of the platform itself is about 7 to 60, and preferably about 20. The median thickness of the platform ranges from about 0.5 mm to about 2.5 mm, and preferably about 1 mm. The area of the rigid member platform including the area from features such as openings and pockets ranges from about 50 mm2 to about 700 mm2, and is preferably about 300 mm2. The rigid member platform has a hydraulic diameter, (e.g., in standard engineering this diameter can be defined as about four times the area divided by the perimeter) from about 8 mm to about 50 mm, and preferably about 20 mm. The width of the rigid member platform ranges from about 10 mm to about 50 mm. The length to thickness ratio of the rigid member platform itself is 7 to 60, and preferably about 20.
Rigid members and rigid member platforms of the present invention are shown and described with respect to
The term “location feature” as used herein signifies a feature such as an aperture or opening, a slot, one or more protrusions, or any combination thereof. These features provide a structure that enables travel of movable assemblies, to attach movable assemblies or secondary frames to the rigid member or the rigid member platform, and they provide attachment points for other rigid features to the rigid frame enhancing integrity.
In one embodiment of the present invention, the location feature is an aperture. The feature may be disposed in a part of the frame (or rigid member), such as in the rigid member platform, or in one or more, or all of the portions of the movable member assembly of the razor structure present invention. In another embodiment of the present invention, the location features are protrusions and apertures. The frame may be part of a handle or may be part of a razor cartridge. The location feature is utilized for aligning and coupling portions of the razor structure together by utilizing the location feature in the frame and portions.
The term “benefit” or “benefit delivery assembly” or “benefit delivery system” as used herein signifies something delivered to a user that is perceived to be advantageous. In the case of a razor or hair removal device, the term benefit refers to a skin benefit. Such a skin benefit cane be a heating or cooling of the skin. Another benefit to the user is fluids (e.g., liquids) or waxes to the skin. Further, benefits may be provided in combination, such as a benefit of heat and fluids. These may be advantageous to a user by enhancing their shaving experience.
Referring to
In
Referring to
Two types of non-limiting embodiments of razors providing for a skin benefit are disclosed herein. The first razor embodiment provides a benefit to the user by heating or cooling the skin. The second razor embodiment provides a benefit to the user by fluids (e.g., liquids) or waxes to the skin. It should be noted that many of the components described in relation to the razor providing a benefit by heating and cooling the skin can also be incorporated into a razor providing benefits by delivering fluids and waxes to the skin. Both embodiments share common problems and have similar solutions including the structural elements of the handle 12, the handle main section 21, the handle transition section 23, and the skin interconnect member 22, the mechanisms that enable skin interconnect member 22 to rotate about different combinations of axes A1-A5, and the manufacturing of these components.
As shown in
In the illustrated embodiments, skin interconnect member 22 is configured to pivot about axes A1 and A4. Other embodiments may be configured to move skin interconnect member 22 about axes A1, A2, A3, A4, A5 or any combination thereof. The bearings, which enable these rotary motions, may lie directly along an axis such as pin bearing or a shaft, or they may offset from the axis of rotation, creating by a virtual pivot. Virtual pivot bearings include shell bearings and linkages.
In a like manner,
As shown in the illustrated embodiment of
The embodiments in
Referring now to
In
The main frame 18 can be made of metal and can provide a significant portion of the structural integrity of the handle. Preferably, the component main frame is made from a light, stiff (high elastic modulus) and impact resistance material to minimize its volume and maximize volume for other components while still providing product integrity and safety. In an embodiment the frame 18 is made of zinc. In an embodiment the main frame 18 is made of die-cast zinc. Die-cast zinc materials include ZAMACK3, ZAMACK5, and ZA8. Other suitable materials include glass fiber reinforced plastics such as IXEF, stainless steel, aluminum, aluminum diecast, and magnesium diecast. The secondary frame 20 can be made of a plastic material and can overlie most of the main frame 18 and provide for a significant portion of the size and comfort of the handle 12.
As shown in
Continuing to refer to
A benefit delivery system may be disposed above, below or through the frame. As shown for instance in
The skin interconnect member 22 can have a shape beneficially conducive to both attaching to the blade cartridge unit 15 and facilitating the delivery of a skin comfort benefit from the handle 12 to and through the blade cartridge unit 15 attached to the handle 12.
The shape of the skin interconnect member 22 can alternatively be described as a “funnel,” or as “tapered,” or a “trapezoidal prism-shaped.” As understood from the description herein, the description “trapezoidal prism” is general with respect to an overall visual impression the skin interconnect member. For example, a schematic representation of a trapezoidal prism-shaped element is shown and described in more detail below with respect to
The description “trapezoidal prism” is used herein as the best description for the overall visual appearance of the skin interconnect member 22, but the description does not imply any particular geometric or dimensional requirements beyond what is described herein. That is, the skin interconnect member 22 need not have complete edges or surfaces. Further, edges need not be unbroken and straight, and sides need not be unbroken and flat.
The skin interconnect member 22 can have a shape beneficially conducive to both attaching to the blade cartridge unit 15 and facilitating the delivery of a skin comfort benefit from the handle 12 to and through the blade cartridge unit 15 attached to the handle 12.
As shown in
Various elements such as the grip members 39 and other features are removed from the frame and/or handle, showing the frame 18 as a skeleton-like structure upon which the movable member assembly 44 is disposed.
The frame desirably provides a base upon which other elements of a razor may be disposed. The frame may be located substantially in the center of the handle 12. As shown in the figures herein, ergonomic elements such as grip portions 39, protrusions or buttons, and benefit-dispensing structures such as electronics, fluids, thermal elements, and the like, may all be disposed on any side of the frame or within the frame 18 or within the handle transition section 23.
The movable member assembly 44 is configured to have a rotational movement about an axis of rotation A4 that is substantially perpendicular to the axis of rotation A1 and substantially perpendicular to a longitudinal axes A2 or A3 of the razor 10. The movable member assembly 44 or a portion thereof may be configured to have a linear motion substantially parallel to the longitudinal or linear axes of movement A2 or A3 that are substantially parallel to the frame 18. Linear axis of movement A3 is substantially parallel to the handle transition section 23 and linear axis of movement A2 is substantially parallel to the handle main section 21.
When the blade cartridge unit 15 is attached to the handle 12, the blade cartridge unit 15 is configured to rotate about multiple axes of rotation, for example, a first axis of rotation A1 and a second axis of rotation A4.
The movable member assembly 44 is configured to move in a first movement type and/or a second movement type. A first movement type of the present invention comprises a rotational movement and a second movement type comprises a non-rotational or linear movement. Preferably, the rotational movement is about an axis of rotation A4 or axis of rotation A1 or both (as shown in
The frame 18 may be of any suitable size, shape, or configuration. Though shown as being a part of the razor handle, the frame of the present invention may or may not be part of the razor handle. If the frame 18 is part of the razor handle as shown for instance in
In
The frame 18 also comprises a frame location feature 43. The rigid member or frame location feature 43 of the present invention preferably comprises an aperture, though a slot or other feasible structure or configuration or combination thereof is contemplated.
Aperture 43 shown in
In
The upper portion 44a of the movable member assembly 44 may move in both a first movement type and a second movement type. In a second movement type (e.g., non-rotational, linear), the upper portion may be comprised of a button such as an eject button which serves to remove the blade cartridge unit 15 from the handle 12 when pushed.
In one embodiment, an upper portion 44a comprises a first upper element 47a, second upper element 47b, a third upper element 47c and a fourth upper element 47d, all of which are operably coupled to each other. The upper portion 44a may be comprised of more or fewer elements and may be of any suitable size, shape or configuration in accordance with the present invention.
Additionally, or alternatively the upper portion 44a includes upper portion location features 46 in one or more of each upper element, and preferably in each upper element where these features are all apertures, and more preferably these apertures are substantially similar to the rigid member location feature 43, and most preferably substantially circular shaped, though any feasible configuration of location features and shapes are contemplated.
The first upper element 47a functions as a base structure for the upper portion 44a. It preferably includes rails, tracks and/or projections. Desirably it is coupled to one or more of the upper elements such as the second and third upper elements but also one or more of the lower elements as will be described below. In one embodiment, the first upper element 47a is comprised of a material that is less expensive and more flexible to design with enabling more intricate features (e.g., snap fits, bearing surfaces, etc.) in smaller volumes than would be possible if a rigid member were used by itself without such an interface. Plastics or other flexible materials are contemplated in the present invention for any elements that are most proximal or contacting a metal rigid member. For instance, first upper element 47a can be made of plastic while the rigid member is made of die-cast zinc material.
The second upper element 47b is preferably a spring member disposed in between a first and third upper element 47c. The spring member is desirably disposed within one or both first and third upper elements. As shown, the spring member can be a loop or generally circular shape. This spring assists in providing a first or second movement type. Preferably, element 47b provides a second movement type (e.g., linear).
The spring member of the present invention can be attached to the frame or rigid member to provide for motion of the upper portion, lower portion, or a combination thereof.
A spring member can have points of attachment between any elements within the movable assembly 44—i.e. any elements of the upper portion, any element of the lower portion, and any combination thereof. At least one connection of the spring member is desirably connected to either the frame 18, the first upper element 47a, or the first lower element 49a. Connection to the rigid frame can provide a simpler design in smaller volumes while connection to the either the first upper element or the first lower can provide flexibility in design by allowing construction of complex mechanisms in less room and at less cost than mounting them directly onto the frame 18.
A connection of the spring member directly to the frame 18 can provide smoother motions and a less complex design when the upper portion 44a and the lower portion 44b are connected and move together relative to the frame 18. A preload of the spring member can be used to provide a better consumer experience by preventing the upper portion 44a and the lower portion 44b from rattling within the handle 12 and by either pushing either the upper portion, lower portion, or combination thereof against a bearing surface on the rigid member or by maintaining a clearance between the rigid member and the upper portion and lower portion.
The third upper element 47c is preferably an eject button which desirably, coupled with one or both of the second upper element 47b (e.g., spring member) and the first upper element 47a (e.g., base structure), desirably provides a second movement or a linear movement in a forward path along axes A2 or A3 (as shown in
The lower portion 44b comprises a first lower element 49a, a second lower element 49b, and a third lower element 49c. The lower portion 44b may be comprised of more or fewer elements and may be of any suitable size, shape or configuration.
Additionally, or alternatively, the lower portion 44b includes lower portion location features 48 in one or more of each lower element, and preferably in each lower element where these features are all apertures, and more preferably these apertures are substantially similar to the rigid member location feature 43 and/or the upper portion location features 46 and most preferably substantially circularly shaped, though any feasible configuration of location features and shapes are contemplated.
First lower element 49a of the lower portion 44b is preferably comprised of a spring member which is disposed in between a lower side of said frame or a lower side of said first upper portion 47a and second lower element 49b. The spring member is desirably disposed on the underside 92b of the upper frame 18a and/or within any of the elements disposed on a lower side of said frame, such as the second lower element 49b but also may be disposed on the lower side of said first upper element 47a (not shown). As depicted, the spring member is comprised of a loop, V-shape, or a generally circular shape.
Second lower element 49b of the lower portion 44b is preferably comprised of a bottom base structure having tracks, rails, and/or projections and a pair of arms 52. The pair of arms are preferably connected to an interconnect member for connection to a blade cartridge unit or directly to a blade cartridge unit. When coupled with spring member of first lower element 49a, the arrangement assists in providing a first or second movement type, preferably, a first movement type (e.g., rotational). This first movement type allows the blade cartridge unit 15, when connected to the handle 12, to move or pivot in a rotational or side-to-side manner along axis of rotation A4.
Third lower element 49c comprises an outermost lower element, and may be a dome shaped feature similar to fourth upper element 47d. The third lower element 49c generally provides a bottom finger pad area for comfortable placement of a user's finger along with an aesthetic outer décor enhancement.
It should be noted that the bottom part 92 of first upper element 47a and the top part 94 of the second lower element 49b are generally encompassed or covered by a frame 18 towards proximal end 96 of the frame 18 as shown in
Desirably, the upper and lower portions 44a and 44b, respectively, are coupled to each other. The engagement of the upper and lower portions may be achieved by mechanical engagement such as a snap-fit engagement, chemical engagement such as adhesive or glue, frictional engagement such as welding comprising ultrasonic welding such as energy director or pinch-off welding, or torsional, spin, laser or hot-plate (e.g., mirror-imaged) type welding, or by any other feasible manner or any combination of the foregoing, thereof.
In one embodiment of the present invention, the coupling is preferably achieved by engaging one or more features of the lower surface of first upper element 47a with one or more features of the upper surface of the second lower element 49b. For instance, projections 104 on upper surface 101 of the second lower element 49b desirably engage with recesses or notches in the lower surface 112 of first upper element 47a as shown in a top view of a coupled arrangement 120 of second lower element 49b engaged with first upper element 47a in
The area of engagement (e.g., a welding area or a mechanical engagement area) can be located on external surfaces of upper and lower elements, can be located internal to the elements (as shown in
Once upper and lower portions are engaged and secured to each other, the movable member assembly 44 can substantially function as an integral unit.
In the present invention, a single component, such as the upper portion 44a or the lower portion 44b serves multiple functions. For instance, the lower portion 44b facilitates an axis of rotation in a razor handle, namely an axis of rotation substantially perpendicular to one or more blades when a razor is assembled and substantially perpendicular to a frame of a handle. When rotated from an at rest position, the lower portion 44b and for instance, the second lower element 49b can generate a return torque to return to the rest position by way of the spring member 49a, such shown as a loop shaped spring but may comprise a cantilever spring or a leaf spring. The return torque is generated by the spring member of the second lower element 49b. Additionally, the upper portion 44a also serves as a carrier for an ejector button assembly and may also serve as a carrier for other components of a razor such as a docking structure (not shown), and/or a blade cartridge unit (e.g., via the docking structure). In this embodiment, the first lower element 49a (the spring member), can be attached to the frame 18 providing optimal motion and clearances for the assembly.
In an alternate embodiment, the movable member assembly 44 is unitary and, optionally, formed from a single material.
In
As noted, the frame 18 of the present invention can be comprised of die-cast zinc such as ZAMACK3, ZAMACK5, and ZA8. Other suitable materials include glass fiber reinforced plastics such as IXEF 1032, stainless steel, aluminum, aluminum diecast, and magnesium diecast.
Arms 24 of the present invention are shown in
In embodiment 130b, a frame 18 comprises a rigid member platform 132b corresponding to the views shown in
In
As shown in
As shown in
A maximum length L1 across the rigid member platform across cross-sectional view E-E is shown parallel to the longitudinal axis of the razor handle. A maximum width W1 across the rigid member platform is shown transverse to the longitudinal axis of the razor handle. The rigid member platform 132 can be partially surrounded by walls 146 having a height T2. These walls provide additional product integrity to the rigid member and allow for flexibility in design aesthetics. Embodiments of
Upper and lower portions of a movable member assembly are coupled together by passing through the aperture 43 of the rigid member platforms and are held in position and clearance by a spring member mounted to the rigid member. This spring member of the present invention, while flexible in the desired direction of motion, is stiff enough in other directions of motion to maintain sufficient clearance between portions of the movable member assembly and the rigid member and rigid member platform. The spring member may be preloaded as described herein.
In the present invention, a median thickness T1 of the platform 132a or 132b ranges from about 0.5 mm to about 2.5 mm, preferably about 1 mm A maximum width W1 to median thickness T1 ratio of the platform itself is about 7 to 60, and preferably about 20. The area of the rigid member platform including the area from features such as openings and pockets ranges from about 50 mm2 to about 700 mm2, and is preferably about 300 mm2. A perimeter of the rigid member platform can be about 40 mm to about 90 mm, and preferably 63 mm. The rigid member platform has a hydraulic diameter, (e.g., in standard engineering this diameter can be defined as about four times the area divided by the perimeter) from about 8 mm to about 50 mm, and preferably about 20 mm. The maximum width W1 of the rigid member platform ranges from about 10 mm to about 50 mm. The maximum length L1 to median thickness T1 ratio of the rigid member platform itself is 7 to 60, and preferably about 20. The height T2 of the walls ranges from about 1.5 mm to about 18 mm, and preferably about 4 mm.
Thus, the present invention comprises a relatively thin rigid member platform which is beneficial because it provides a robust support for complex functional members above or below it, and an ease of manufacturing or assembly including flexibility for use of other manufacturing techniques such as additive manufacturing, while also providing space for benefit delivery system components.
In a preferable embodiment of the present invention, these upper and lower elements are coupled together by securing one to the other with the rigid member location feature 43. This may desirably be achieved by utilizing the rigid member location feature aperture 43 of the frame 18 for alignment with the upper aperture 46 and lower aperture 48, as will be described in more detail below.
Referring to
In a preferred embodiment, at Step 1 of
At Step 2 shown in
Turning to
At Step 4, the first upper element 47a is secured to the second lower element 49b. This securing step is preferably comprised of welding between the two elements, more preferably ultrasonic welding, and most preferably pinch off type ultrasonic welding. The welded material 184 is shown in a close-up cross-sectional view (B) of Step 4. As can be seen, the welded material 184 is disposed in area in between the first upper element 47a and the second lower element 49b. Other methods for securing these elements are also contemplated (e.g., gluing).
These elements are coupled together through the main frame which as noted herein is preferably a rigid member, and more preferably comprised of a diecast material such as zinc. Since the first upper element is a part of the upper portion and the second lower element is a part of the lower portion, in this way, the upper portion 44a can be secured to the lower portion 44b through the main frame. In the embodiment, the main frame extends between the upper and lower portions. In the embodiment, the upper and lower portions are engaged within, pass through, or around the rigid member or main frame's location feature 43. The upper and lower elements of the upper and lower portions have location features 46, 48, respectively which are apertures of a similar size and shape as that of the rigid member, a generally circular aperture.
The upper and lower elements can also feasibly be coupled via mechanical engagement such as a snap-fit. Features on the upper surface of the second lower element 49b and features on the lower surface 47a can be engaged within, pass through or around, a rigid member location feature such as aperture 43 disposed within the rigid member. The one or more surface features can be recesses, projections, notches, or other attachment structures which can mate or engage, or any combination thereof.
Turning to
Pivot spring member can be any spring member facilitating biasing and pivoting of the pivoting. Pivot spring member can be, for example, any of torsion coil springs, coil spring, leaf spring, helical compression spring, and disc spring. In one embodiment, spring member comprises one or more coil springs. In an embodiment, two coil springs can be coupled together in a spaced relationship by a main bar portion. Pivot spring members are described in co-owned co-pending, which are hereby incorporated herein by reference.
In
Portions of the main frame 18 corresponding to openings 194 of arms 192 can be permanently deformed by pressing into the openings 194. The operation, known as cold stamping or cold staking, permits secure coupling of arms 192, and therefore, skin interconnect member 22, to main frame 18 (and therefore, handle 12). Cold stamped pockets 202 can be formed after the cold stamping is completed as shown in
In
It should be noted that at least one or more elements of the upper or lower portions do not move relative to the rigid member. For instance, the lower portion may include an element that does not move relative to the rigid member.
The frame, movable member assembly with upper and lower portions comprising an ejector button assembly, and a rotational movement unit (second lower element 49b) are configured for simplification of assembly, for example, in high-speed manufacturing. Each component is configured to automatically align and to securely seat. In an embodiment, each component engages to another component in only a single orientation such that the components cannot be inaccurately or imprecisely assembled. Further, each component does not need an additional step of dimensional tuning or any secondary adjustment in manufacturing to ensure proper engagement with other components. The design of the handle also provides control and precision. For example, when the razor is assembled, the movable member and/or the blade cartridge unit is substantially centered, the preload of the springs may be controlled precisely over time even after repeated use, and the performance of each spring, is controlled, consistent, and robust.
The various elements of the movable member assembly are desirably formed of plastics, including thermoplastic elastomers. The spring members can be made of plastic, impact-resistant plastic, metal, and composite materials. In an embodiment, the spring member can be made from materials that are resistant to stress relaxation such as metal, polyetheretherketone, and some grades of silicone rubber. Such an embodiment of spring member, comprised of stress relaxation resistant materials, can prevent the pivot head from undesirably taking a “set,” a permanent deformation of the spring member that prevents the pivot head from returning to its rest position when unloaded. In an embodiment, spring member can be made of 200 Series or 300 Series stainless steel at spring temper per ASTM A313. In an embodiment, spring member can be comprised of stainless steel wire (e.g., 302 stainless steel wire) having an ultimate tensile strength metal greater than 1800 MPa or an engineering yield stress between about 800 MPa and about 2000 MPa.
Arms 24 or frame 18 can be made of plastic, impact-resistant plastic, metal, and composite materials. In an embodiment, arms 24 and frame 18 can be comprised of metal. Arms 24 and frame 18 can be made of a 200 or 300 Series stainless steel having an engineering yield stress measured by ASTM standard E8 greater than about 200 MPa, and preferably greater than 500 MPa and a tensile strength again measured by ASTM standard E8 greater than 1000 MPa.
Arms 24 and frame 18 can be made of a zinc die-cast with an engineering yield stress of about 200 MPa measured by ASTM standard E8 and a tensile strength again measured by ASTM standard E8 about 300 MPa.
Preferably, the assembly is formed from thermoplastic polymers. For example, nonlimiting examples of materials for the movable member with desirable properties, such as flexibility, durability (breakdown from drop impact), fatigue resistance (breakdown from bending over repeated use), and creep resistance (relaxing of the material), can include POLYLAC® 757 (available from Chi Mei Corporation, Tainan, Taiwan), HYTREL® 5526 and 8283 (available from E. I. DuPont de Nemours & Co., Wilmington, Delaware), ZYTEL® 122L (available from E. I. DuPont de Nemours & Co., Wilmington, Delaware), CELON® M90 (available from Ticona LLC, Florence, Kentucky), PEBAX® 7233 (available from Arkema Inc., Philadelphia, Pennsylvania), CRASTIN® 5500, S600F20, S600F40, and S600LF (available from E. I. DuPont de Nemours & Co., Wilmington, Delaware), CELENEX® 1400A (M90 (available from Ticona LLC, Florence, Kentucky.), DELRIN® 100ST and 500T (available from E. I. DuPont de Nemours & Co., Wilmington, Delaware.), HOSTAFORM® XT 20 (available from Ticona LLC, Florence, Kentucky.), and SURLYN® 8150 (available from E. I. DuPont de Nemours & Co., Wilmington, Delaware). Furthermore, the selection of a material may affect the stiffness and yield stress of the movable member or a spring. For example, each material may have different stiffnesses depending on the temperature and rate of rotation of the upper or lower portions of the movable member relative to the frame. Dimensions of the spring elements can be varied to achieve a desired torque and/or a desired stiffness.
Other components of the handle, blade unit, and other rigid plastic parts of the shaving system can be made of any suitable material including, for example, polyethylene terephthalate (PET or PETE), high density (HD) PETE, acrylonitrile butadiene styrene (ABS), thermoplastic polymer, Polypropylene, oriented polypropylene, polyurethane, polyvinyl chloride (PVC), polytetrafluoroethylene (PTFE), polyester, high-gloss polyester, or combinations thereof.
It should be understood that every maximum numerical limitation given throughout this specification includes every lower numerical limitation, as if such lower numerical limitations were expressly written herein. Every minimum numerical limitation given throughout this specification includes every higher numerical limitation, as if such higher numerical limitations were expressly written herein. Every numerical range given throughout this specification includes every narrower numerical range that falls within such broader numerical range, as if such narrower numerical ranges were all expressly written herein.
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” is intended to mean “about 40 mm.”
Every document cited herein, including any cross referenced or related patent or application, is hereby incorporated herein by reference in its entirety unless expressly excluded or otherwise limited. The citation of any document is not an admission that it is prior art with respect to any invention disclosed or claimed herein or that it alone, or in any combination with any other reference or references, teaches, suggests or discloses any such invention. Further, 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 assigned to that term in this document shall govern.
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. It is therefore intended to cover in the appended claims all such changes and modifications that are within the scope of this invention.
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