The present invention relates to shaving razors and particularly to shaving razor designs that provide users with improved control and closeness during shaving. Particularly, the shaving razor includes a biasing member producing a progressively increasing cartridge return torque that forces the cartridge into flat contact with the skin and a handle geometry that provides enhanced control during shaving.
This invention relates to a wet shaving razor comprising a cartridge that includes a shaving blade with a cutting edge which is moved across the surface of the skin being shaved by means of an adjoining handle. Conventional safety razors have a blade unit connected to a handle for a pivotal movement about pivotal axis which is substantially parallel to the blade or the blade edge. For example, U.S. Pat. Nos. 7,197,825 and 5,787,586 disclose such a razor having a blade unit capable of a pivotal movement about a pivot axis substantially parallel to the blade(s). The pivotal movement about the single axis provides some degree of conformance with the skin allowing the blade unit to follow the skin contours of a user during shaving. Such safety razors have been successfully marketed for many years. However, the blade unit can fail to remain flat and often disengages from the skin during shaving due to the blade unit's limited ability to pivot about the single axis combined with the dexterity required to control and maneuver the razor handle. The combination of these deficiencies can affect the glide and overall comfort during shaving.
There have been various proposals for mounting a cartridge on a handle to enable movement of the cartridge during shaving with the aim of maintaining conformity of the skin contacting parts with the skin surface during shaving. For example, many razors currently marketed have cartridges which are pivotable about longitudinal axes extending parallel to the cutting edges of the elongate blades incorporated in the cartridges. There is an increasing need to provide a shaving consumer with a closer, more effective shave. Applicant has attempted to provide this in its commercially available Fusion® razor which incorporates a spring in its following system to bring about a reduced cartridge to skin angle, which has been found to lead to a better shave. Similarly, others have attempted to manipulate the biasing mechanisms of their commercial razors. For instance, US Patent Publication 2005/0241162 A1 discloses a biasing assembly for a wet shave razor wherein the assembly includes 1) an abutment surface defined by a cartridge and located on the underside of the cartridge and 2) a biasing member extending outwardly from the handle and having an end which when the cartridge is coupled to the handle is in sliding engagement between the neutral and fully-rotated positions. The biasing member exerts a variable torque against the abutment surface. The reference, however, focuses primarily on a low spring force to prevent the cartridge from lifting off of the skin and does not focus on the effect that the biasing member has on maintaining the cartridge flat relative to the skin during shaving strokes and corresponding shaving closeness.
In addition, current shaving razors found on the market typically include handle configurations that are variations of an ‘L’ shape where the longitudinal axis 30 of the handle 14 is offset from the razor cartridge 12 such that it intersects the cutting plane 122 behind the cartridge 12 as shown in
In pursuit of an improved shaving product, there is a need for a shaving razor that can maintain the blade unit of a razor cartridge flat against the skin throughout a shaving stroke. Particularly there is a need for a shaving razor having a biasing member producing a progressively increasing return torque on a cartridge forcing the cartridge into contact with the skin throughout the shaving stroke. In addition, there is a need for a handle geometry that provides the user with improved control while shaving.
In one aspect, the invention features, in general, a shaving razor including a biasing member producing a progressively increasing cartridge return torque that forces the cartridge into flat contact with the skin as the cartridge pivots and handle geometry that provides enhanced control during shaving. The shaving razor comprises a cartridge. The cartridge comprises a cartridge housing having a front edge portion, a rear edge portion and two opposing side edge portions extending from the front edge portion to the rear edge portion. One or more shaving blades are disposed between the front edge portion and the rear edge portion. A cutting plane is tangent to the rear edge portion and the front edge portion of the cartridge housing with a forward cutting direction toward the front edge portion. The cartridge includes a connecting member and a cartridge pivot axis providing an axis of rotation for the cartridge.
The shaving razor includes a handle. The handle comprises a forward portion comprising a connecting structure that releasably mounts to the cartridge connecting member; a rear portion opposite the forward portion comprising a free end; and an elongate central portion disposed between the forward portion and the rear portion. The elongate central portion includes an upper surface and a lower surface and a longitudinal axis disposed therebetween. A projection of the longitudinal axis of the elongate central portion of the handle intersects the cutting plane at a point of intersection that leads a point of equilibrium on the razor cartridge in the cutting direction. In one embodiment the point of intersection leads the point of equilibrium in the cutting direction by a distance ranging from about 0 mm to about 10 mm.
In an alternate embodiment, the shaving razor includes a handle roll axis extending between the point of equilibrium and the free end of the rear portion of the handle and a handle load point on the upper surface of the elongate central portion proximate the forward portion. The handle load point is the location where forces are applied to the handle to steer the cartridge during use. The handle roll axis either intersects or is less than 5 mm below the handle load point. In one embodiment, the handle roll axis is above the handle load point.
The handle connecting structure includes a biasing member that contacts and exerts a progressively increasing return torque on the cartridge as the cartridge rotates about the pivot axis during use. The progressively increasing return torque increases from a minimum torque of 0 Nmm when the cartridge is in a neutral position to a peak torque of about 14 Nmm when the cartridge is at a fully rotated position, wherein the gradient of the progressively increasing return torque is less than 0.3 Nmm/degree.
In an alternate embodiment, the axis of rotation of the cartridge provides a cartridge pivot angle ranging from about 0 degrees to about 40 degrees. The progressively increasing return torque increases at a gradient of less than 0.25 Nmm/degree from a minimum torque of 0 Nmm at 0° cartridge rotation to a peak torque of about 14 Nmm at 40° cartridge rotation. Alternatively, the progressively increasing return torque can increase at a gradient of less than 0.25 Nmm/degree to a peak torque of about 10 Nmm at 40° cartridge rotation. Alternatively, for each aforementioned peak torque, the progressively increasing return torque can increase at a gradient of less than 1.0 Nmm/degree from 0° to 6° of cartridge rotation and at a gradient of less than 0.25 Nmm/degree from 6° to 40° of cartridge rotation.
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 taken in conjunction with the accompanying drawings.
a illustrates the effects of the loads applied to the handle configuration in
a illustrates the effects of loads applied to the handle of
a illustrates the effects of loads applied to the handle of
The shaving razor according to the present invention will be described with reference to the following figures which illustrate certain embodiments. It will be apparent to those skilled in the art that these embodiments do not represent the full scope of the invention which is broadly applicable in the form of variations and equivalents as may be embraced by the claims appended hereto. Furthermore, features described or illustrated as part of one embodiment may be used with another embodiment to yield still a further embodiment. It is intended that the scope of the claims extend to all such variations and equivalents.
The present invention provides a wet shaving razor that improves stability and corresponding user control of a shaving razor and provides an improved closer shave to skin covered with hair. The wet shaving razor according to the present invention includes a biasing member that produces a progressively increasing return torque (interchangeably referred to “as progressively increasing return torque” and “progressively increasing torque”) that forces the cartridge into flat contact with the skin during shaving thereby reducing the angle between the cartridge and the skin which improves glide and shaving closeness. In addition, the wet shaving razor includes a razor handle configuration which reduces the propensity for the shaving razor to roll or spin in a user's hand during shaving and improves the maneuverability of the shaving razor during shaving. These and other features of the shaving razor are further described below.
Referring to
In a forward pivoting razor system like the one shown in
The wet shaving razor of the present invention is able to provide an improved closer shave to skin covered with hair by forcing the blade unit 16 of a razor cartridge 12 into a more even contact with the skin with a progressively increasing return torque in order to minimize the cartridge to skin angle throughout a shaving stroke. As shown in
As shown in
Referring to
Referring now to
As the blade unit 16 is rotated from its rest position, the torque about the pivot axis due to the force applied by plunger 134 increases due, at least in part, to the increasing horizontal distance between the contact point y and the pivot axis 70 and the rotation of the plunger 134 to a more perpendicular orientation to the cam surface 216. In some embodiments, the minimum torque applied by the spring-biased plunger, e.g., in the rest position, is at least about 1.5 N-mm, such as about 2 N-mm. However, as discussed below preferably, the minimum torque applied by the spring biased plunger 134 in the rest position is 0 Nmm.
The plunger 134 is biased by a compression spring. Referring to
With the embodiment shown in
For the compression spring 205 to be relaxed, the dimensions of the aforementioned components must be tightly controlled to ensure the spring is not compressed or tensioned when the cartridge is at rest. For the present invention, the cavity 139 inside the plunger 134 and the overall dimensions of the plunger 134 are important to achieving a relaxed spring if the tank 167, release button 196 and cam surface 216 are unchanged. The compression spring can exhibit a spring stiffness of from about 0.85 N/mm to about 1.13 N/mm with a particular embodiment having a spring stiffness of about 1.02 N/mm. In certain embodiments, the entire length of the spring will be accommodated within the cavity 139 when the spring 205 is under no stress (i.e., no tension or compression). The diameter and length of cavity 139 is relative to the diameter and free length of the spring 205 to create a near zero load. In a certain embodiment, the cavity may be about 6.8 mm in length.
In an alternate embodiment, the biasing member can include a leaf spring 50 as described in U.S. Pat. No. 6,223,442 B1. For this embodiment the plunger 134 shown in
Other mechanisms providing a biasing member 44 for a razor cartridge 12 can be provided. Such mechanisms include four bar linkages as described in U.S. Pat. Nos. 7,137,205 and 6,115,924. Other biasing members 44 can include torsion springs, diaphragm springs, and live hinges.
Referring now to
The position of the pivot axis 70 along the width W of the blade unit 16 determines how the cartridge will pivot about the pivot axis 70, and how pressure applied by the user during shaving will be transmitted to the user's skin and distributed over the surface area of the razor cartridge. For example, if the pivot axis 70 is positioned behind the blades and relatively near to the rear edge 38 of the housing, so that the pivot axis is spaced significantly from the center of the width of the housing 20, the blade unit may tend to exhibit “rock back” when the user applies pressure to the skin through the handle. “Rock back” refers to the tendency of the wider, blade-carrying portion of the blade unit 16 to rock away from the skin as more pressure is applied by the user. Positioning the pivot point 70 in this manner generally results in a safe shave, but may tend to make it more difficult for the user to adjust shaving closeness by varying the applied pressure.
In blade unit 16, the distance between the pivot axis 70 and the front edge 40 of the blade unit 16 is sufficiently long to balance the cartridge about the pivot axis. By balancing the cartridge in this manner, rock back is minimized while still providing the safety benefits of a front pivoting arrangement. Safety is maintained because the additional pressure applied by the user will be relatively uniformly distributed between the blades and the elastomeric member rather than being transmitted primarily to the blades, as would be the case in a center pivoting arrangement (a blade unit having a pivot axis located between the blades). Preferably, the distance from the front of the blade unit to the pivot axis (Wf) is sufficiently close to the distance from the rear of the blade unit to the pivot axis (Wr) so that pressure applied to the skin through the blade unit 16 is relatively evenly distributed during use. Pressure distribution during shaving can be predicted by computer modeling.
Referring to
A measure of cartridge balance is the ratio of the projected distance Wr between the rear edge 38 of the blade unit 16 and the pivot axis 70 to the projected distance W between the front edge 40 and rear edge 38 of the blade unit 16, each projected distance being measured along a line parallel to a housing axis that is perpendicular to the pivot axis 70. The ratio may also be expressed as a percentage termed “percent front weight”.
Referring now to
By balancing the blade unit 16, the weight carried by the front portion 135 over Wf and rear portion 137 over Wr is more evenly distributed during use, which corresponds to a more even distribution of pressure applied to the shaving surface during shaving. Also, more weight is shifted to the rear portion 137 of the cartridge 12 where the blades 28 are located during use, inhibiting rock back of the rear portion 137, which can provide a closer shave.
The pressure distribution on the blade unit 16 produces a distributed force that can be described as a resultant of forces. The resultant of forces coincides with a point of equilibrium 48 on the razor cartridge 12 which typically separates the front portion Wf and rear portion Wr. The point of equilibrium 48 intersects the cutting plane and is preferably aligned with the cartridge pivot axis 70 providing balanced axis of rotation for the shaving razor cartridge 12 about the pivot axis 70.
In addition to a biasing member providing a progressively increasing return torque in order to minimize the cartridge to skin angle throughout a shaving stroke, the shaving razor of the present invention can include a handle configuration that improves stability and corresponding user control of the razor cartridge during shaving. Stability involves the balance of the razor which can be described in terms of static loading applied to the razor configuration. Control involves the ability to steer or guide the razor cartridge which can be described in terms of dynamic loading.
Stability can be classed in three conditions, unconditionally unstable, conditionally stable, and unconditionally stable. In a shaving context, during shaving strokes a razor may be described as unconditionally unstable where the razor handle configuration has a natural imbalance creating a top heavy scenario causing the handle to have a propensity to spin or roll about the handle roll axis when simply supported between the free end of the handle and the point of equilibrium on the cartridge. As a result, an unconditionally unstable razor handle configuration requires more effort to maintain control to overcome the imbalance during use. A conditionally stable razor may include a balanced razor handle configuration such that the razor does not have a propensity to spin or roll when simply supported between the free end of the handle and point of equilibrium on the razor cartridge. An unconditionally stable razor may include a razor handle configuration having a natural imbalance creating a bottom heavy scenario similar to a pendulum. For this configuration, not only does the razor not have a propensity to spin or roll when simply supported between the free end of the handle and point of equilibrium on the razor cartridge, when the simply supported razor is displaced from its equilibrium position the bottom heavy imbalance influenced by a restoring force applied by the user's forefinger easily returns the razor to its equilibrium position.
During shaving different users have different ways of gripping the handle. For instance many apply a simply supported grip during use such that the shaving razor includes three simply supported points of contact where loads are applied. As shown in
As shown in
For the configuration in
For the embodiment in
Other configurations providing the forward portion 160 of the handle that is offset from the longitudinal axis 130 of the handle are contemplated. For instance, in an alternate embodiment shown in
In another embodiment, the forward portion of the handle can be offset from the longitudinal axis forming an arcuate shape having a convex upper surface and a concave lower surface. For this embodiment, the arcuate shaped forward portion can be offset for the elongate central portion of the handle such that the projection of the longitudinal axis intersects the cutting plane forward of the point of equilibrium on the cartridge.
The handle load point 380 is located on the elongate central portion 364 of the handle 314 proximate the forward portion 360. The shaving razor 310 includes a handle roll axis 336 extending between the free end of the rear portion 362 of the handle 314 and the point of equilibrium 348 on the cartridge 312. As shown in
In addition to the simply supported grip previously described, users are also known to grip a razor handle 14 at the handle load point 80 in a tripod grip that applies a moment force similar to the way a writer grips a pencil. For instance in a tripod grip a user can grip the elongate central portion 64 around the handle load point 80 with the forefinger positioned on the load point 80 and the thumb pad and side of the middle finger positioned along the sides of the elongate central portion 64 adjacent the load point 80 so that equal pressure is applied by the forefinger, thumb pad and side of the middle finger. For the tripod grip, the handle 14 shown in
In addition to improving the stability of the razor by minimizing or eliminating moments that induce roll about the handle axis of roll when securing the razor handle with the simply supported grip, the offset in the handle configuration according to the present invention can improve a user's control of the razor by enhancing the ability to guide or steer the razor cartridge particularly when using the tripod grip. The improvements to control can be explained in terms of dynamic loading.
For instance, it is well known that it is easier to direct or steer a load that is pulled by a force than it is to direct or steer a load that is pushed by a force. The projection of the longitudinal axis 30 of the prior art shaving razor 10 shown in
The effects that handle geometry can have on guiding the razor cartridge through a shaving stroke can be further explained using a kinematics analogy and dynamic loads involved in steering a wheel. For steering a wheel, pivot points are angled such that a steering axis drawn through the pivot points intersects the road surface slightly ahead of the point where the wheel contacts the road. The purpose of this is to provide a degree of self centering for steering the wheel where the wheel casters around so as to trail behind the axis of steering. This makes the vehicle easier to drive and improves its directional stability by reducing its tendency to wander.
Caster angle is defined as the angle between the steering axis and the vertical plane as viewed from the side of the wheel. Positive caster is the distance between the wheels contact point and the point at which the steering axis intersects the road ahead of the contact point as viewed from the side. Caster determines the degree of self centering action in the steering as well as influences straight line stability and steering force in curves. Excessive caster will make steering heavier and less responsive through curves necessitating the need for additional force in order to turn.
Comparing a steering axis, contact point and caster of a wheel to the shaving razor 110 in
For the shaving razor of the present invention, a caster distance in excess of 10 mm has been found to make it difficult to maneuver the razor cartridge around corners. For this reason the point of intersection of the longitudinal axis leads the point of equilibrium by a distance which is less than 10 mm. Preferably the distance between the point of intersection and the point of equilibrium is between about 2 mm and about 10 mm. More preferably the caster distance is between about 2 mm and about 5 mm.
The impact that the handle configuration can have on the ability to steer the razor cartridge 12 using the tripod grip, particularly through turns, is further demonstrated in the diagram in
Mhand is a moment applied at the handle load point previously described needed to counteract the moment induced by the out of balance drag force, Fd, and the drag resistance to sideways rotation, Fsd that induce a moment about the longitudinal axis 30 of the handle 14. Mhand is also the moment required to steer the cartridge 12.
For a handle in equilibrium, summing the moments about the handle longitudinal axis point of intersection 72a forward of the razor cartridge in the shaving direction indicated by +Y results in the following expression:
M
hand
=F
d
X−F
sd
Y (1)
where
This shows that for positive +Y the out of balance force, Fd, and the drag resistance to sideways rotation, Fsd, work in opposition; therefore, reducing the counter moment, Mhand, needed to counteract the moments induced on the handle during a shaving stroke. As a result, the cartridge is easier to steer.
Alternatively, it can be seen that a handle configuration having a handle longitudinal axis that intersects the cutting plane at a point of intersection 72b that is behind the point of equilibrium 48 on the razor cartridge 12 relative to the cutting direction 74 increases the counter moment, Mhand, needed to counteract the moments induced by drag forces Fd and Fsd during a shaving stroke. As shown in
The histogram in
100% load imbalance occurs when the entire measured load is above one load cell arm indicated by the arrows shown in
Applying this to equation 1 above, X will have a maximum distance of about 10 mm. Thus, referring to
In addition, another disadvantage of further increasing Y is that it will reduce the speed at which a user can rotate the cartridge to steer for a given moment as shown below in equations (2) and (3). For this example, for simplicity, the drag force, Fd, is assumed to be balanced and therefore, Fd=0. As shown in equation (3), the angular velocity {dot over (θ)} decreases as Y increases.
where
Thus, minimizing the distance Y that the point of intersection 72c leads the point of equilibrium 48 reduces the impact that Fsd has on reducing the angular velocity and corresponding ability to steer the cartridge through turns.
In addition to affecting the ability to steer the cartridge, particularly through turns, handle configurations like the one shown in
Regarding all numerical ranges disclosed herein, 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. In addition, every minimum numerical limitation given throughout this specification will include every higher numerical limitation, as if such higher numerical limitations were expressly written herein. Further, every numerical range given throughout this specification will include every narrower numerical range that falls within such broader numerical range and will also encompass each individual number within the numerical range, as if such narrower numerical ranges and individual numbers 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.