The disclosure relates to razors and more particularly to razor blades wherein the cutting area of the razor blade is profiled.
The shape of a razor blade plays an important role in the quality of a shave. The blade typically has a continuously tapering shape converging toward an ultimate tip. The portion of the blade which is closest to the ultimate tip is called the tip edge.
If the tip edge is robust, it will enable less wear and a longer service life, but it would result in larger cutting forces, which adversely affect shaving comfort. A thin tip edge profile leads to less cutting forces but also to an increase in risk of breakage or damage, and a shorter service life. Therefore, an optimal trade-off between the cutting forces, the shaving comfort and the service life of the cutting edge of a razor blade is desired.
To achieve this optimal trade-off, the cutting edge of the razor blade is shaped using a grinding process.
Historically, there has been numerous technologies related to the geometry of some specific parts of the blade. A typical example includes a known technology that focuses on the geometry of the ultimate tip of the blade. The technology precisely defines the geometry of the tip up to 8000 Angstroms, that is 0.8 micrometers from the tip. This geometry mostly relates to the entry of the blade inside the hair to be cut (the diameter of which is generally of the order of 100 micrometers).
Other technologies focus on an overall view of the whole blade geometry. One example of uses numerical data and a specific angle to define the blade tip.
Other examples of technologies focus on blade geometries that are related to thinning the the blade within micrometers of the tip, in relation to a specific angle furthest away from the tip.
Still other examples of blade technologies focus on improving the tip shape by using a hyperbolic equation or constant facet convergence towards the tip of the blade to define the shape of the tip, with respect to a distance within micrometers from the tip.
It is an object of the disclosure to provide a razor blade, suitable for a shaving head of a shaver, wherein the wear of the razor blade may be reduced and the service life may be further extended, while the cutting forces may at least be equally small and the shaving comfort may at least be equally high.
According to an aspect, a razor blade substrate may include a symmetrical tapering cutting edge ending in a sharpened tip. The substrate may have a continuously tapering geometry toward the tip with a thickness of between 1.55 and 1.97 micrometers measured at a distance of five micrometers from the tip, a thickness of between 4.60 and 6.34 micrometers measured at a distance of twenty micrometers from the tip, a thickness of between 19.80 and 27.12 measured at a distance of hundred micrometers from the tip. Unless explicitly stated otherwise, all blade edge measurement data provided herein are obtained through confocal microscopy measurements.
It has been found that the definition of the geometry of the profile, according to the above-specified key points, may be essential to define a properly supported thin edge tip, which would in turn provide an optimal trade-off between shaving performance, in terms of comfort, since such a profile results in low cutting forces and adequate service life, due to the resulted geometry and the thickness beyond the 20 μm area from the ultimate tip.
According to an aspect, the substrate may have a thickness of between 6.50 and 8.94 micrometers measured at a distance of thirty micrometers from the tip.
According to an aspect, the substrate may have a thickness of between 8.40 and 11.54 micrometers measured at a distance of forty micrometers from the tip.
According to an aspect, the substrate may have a thickness of between 10.30 and 14.13 micrometers measured at a distance of fifty micrometers from the tip.
According to an aspect, the substrate may have a thickness of between 29.30 and 40.11 micrometers measured at a distance of hundred fifty micrometers from the tip.
According to an aspect, the substrate may have a thickness of between 38.80 and 49.74 micrometers measured at a distance of two hundred micrometers from the tip.
According to an aspect, the substrate may have a thickness of between 48.30 and 59.37 micrometers measured at a distance of two hundred fifty micrometers from the tip.
According to an aspect, the substrate may have a thickness of between 57.80 and 69.00 micrometers measured at a distance of three hundred micrometers from the tip.
According to an aspect, the substrate may have a thickness of between 67.30 and 78.62 micrometers measured at a distance of three hundred fifty micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 1.80 and 1.95 micrometers measured at a distance of five micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 5.40 and 6.30 micrometers measured at a distance of twenty micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 7.00 and 8.00 micrometers measured at a distance of thirty micrometers from the tip.
According to an aspect, the substrate may have a thickness of between 9.20 and 10.70 micrometers measured at a distance of forty micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 11.20 and 13.10 micrometers measured at a distance of fifty micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 23.00 and 25.10 micrometers measured at a distance of hundred micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 32.30 and 37.10 micrometers measured at a distance of hundred fifty micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 41.00 and 47.30 micrometers measured at a distance of two hundred micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 51.40 and 56.50 micrometers measured at a distance of two hundred fifty micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 61.00 and 65.40 micrometers measured at a distance of three hundred micrometers from the tip.
According to an aspect, the substrate of the razor blade may have a thickness of between 70.40 and 76.10 micrometers measured at a distance of three hundred fifty micrometers from the tip.
According to an aspect, the thickness of the cutting edge of the substrate may be described with the following mathematical formulas:
t=a·(xb) (A)
t=(c·x)+d (B)
wherein, in formulas A and B, a and c are constants from an interval (0, 1), b is a constant from an interval (0.5, 1), d is a constant from an interval (0.5, 20), x refers to a distance from the tip in micrometers and t refers to the thickness of the blade in micrometers, and wherein equation A is applied from the tip to a transition point, and either equation A or equation B elsewhere. According to an aspect, the substrate may contain a stainless steel including in weight:
According to an aspect, the substrate may be covered by a strengthening coating.
According to an aspect, the strengthening coating comprises Titanium and Boron.
According to an aspect, the substrate may be covered by an interlayer, and the interlayer may be covered by said strengthening layer.
According to an aspect, the strengthening layer may be covered by a top layer.
According to an aspect, the top layer may be covered by a polytetrafluoroethylene layer.
According to some aspects, the thickness range between 50 and 350 μm distance from the tip may be important in order to achieve the desired geometry for shaving comfort and blade durability.
Other characteristics and advantages of the disclosure will readily appear from the following description of some of embodiments, provided as non-limitative examples, and of the accompanying drawings.
In the drawings:
On the different Figures, the same reference signs designate like or similar elements.
According to aspects of the disclosure, the desired blade profile may be achieved by a grinding process that involves two, three or four grinding stations.
As the metal strip 3 moves along the grinding stations 2a, 2b, continuous strip 3 may be sequentially subjected to a rough grinding, a semi-finishing and a finishing grinding operation. Depending on the number of stations involved, the rough grinding and semi-finishing operation may be performed separately or in the same station. Thereafter, a finishing grinding operation may be required. The grinding steps may be performed continuously, in that the continuous strip 3 may be moved continuously through the stations without stopping.
When the rough grinding is performed separately, one or two grinding stations may be required. Each grinding station may utilize one or two abrading wheels that may be positioned parallel with respect to the moving continuous strip 3. The abrading wheels may have a uniform grit size along their length. The abrading wheels may also be full body or helically grooved along their length. The material of the abrading wheels may use resin-bonded or vitrified diamond, resin-bonded or vitrified CBN (Cubic Boron Nitride), or resin-bonded or vitrified silicon carbide, aluminum oxide grains or a mixture of the above grains.
When rough grinding and semi-finishing operations are performed simultaneously, a single grinding station may be required for these operations. In this case, the station may include two abrading wheels formed into spiral helixes or a sequence of straight discs with a special profile. The rotational axes of these wheels may be parallel or positioned at an angle α1 with respect to the moving continuous strip 3. The tilt angle ranges between 0.5 degrees and 2 degrees. The grit size of the wheels may also be uniform or progressively decreasing along their length towards the exit of the strip. The material of the abrading wheels might use resin-bonded or vitrified diamond, resin-bonded or vitrified CBN (Cubic Boron Nitride) or resin-bonded or vitrified silicon carbide, aluminum oxide grains or a mixture of the above grains.
The finishing operation may require a single grinding station with two abrading wheels positioned at an angle with respect to the moving continuous strip 3. The tilt angle α2 may be reversed compared to the tilt angle used in the rough grinding operation. The tilted angle may range between 1 degree and 5 degrees. The wheels may form spiral helixes and may be specially profiled. The abrasive material may be single grain or multi-grain material from the aforementioned CBN, silicon carbide, aluminum oxide or Diamond.
The process may be tuned so as to obtain a symmetrical razor blade substrate 10 with a continuously tapering geometry toward the tip, as shown in
For the measurement of the blade geometry, surface roughness and grinded angle, a confocal microscope may be used. For example, is shown on
The piezo-drive 24 may be adapted to move the lens 23 along the light propagation axis, to change the position of the focal point in depth. The focal plane may be changed while keeping the dimensions of the measurement field.
To extend the measurement field (in particular, in order to measure the blade edge further away from the tip), another measurement may be performed at another location, and the data resulting from all measurements may be stitched.
The other side of the blade may then be measured, simply by flipping the blade to the other side.
According to one aspect, a confocal microscope based on the Confocal Multi Pinhole (CMP) technology may be used.
The pinhole plate 22 may have a large number of holes arranged in a special pattern. The movement of the pinhole plate 22 may enable seamless scanning of the entire surface of the sample within the image field and only the light from the focal plane may reach the CCD camera, with the intensity following the confocal curve. Thus, the confocal microscope may be capable of high resolution in the nanometer range.
Also, other methods may be used to measure the thickness of the razor blade. For example, measuring the cross-section of the blade by a Scanning Electron Microscope (SEM). SEM may be performed on a blade cross-section. Currently, SEM may be limited with regards to providing relevant measurement data because it is compulsory to prepare a cross-section of the razor blade. The preparation of samples to be imaged may be rather difficult, in that very few samples may be imaged, and the results may likely be non-statistically relevant.
According to other aspects, it may also possible to measure the thickness of the blade by an interferometer. For this measurement, white light probes from one of a variety of sources (halogen, LED, xenon, etc.) may be coupled into an optical fiber in the controller unit and transmitted to an optical probe. The emitted light may undergo reflection from the blade and may be collected back into the optical probe, and pass back up the fiber where it is collected into an analysis unit. The modulated signal is may be subjected to a fast Fourier transform to deliver a thickness measurement. However, since this measurement is based on light interference from the surface of the blade, the thickness measured by this method may be adversely affected.
Measurements of the same blade using the same method may be performed at different times by different operators in order to that the method is capable of being repeated. Test have shown that confocal microscopy may offer a much better repeatability and reproducibility than the interferometry method.
Additionally, numerous measurements were carried out with the above-mentioned measurement methods on several blades in order to determine the correct thickness of the cutting edge. The average results of these measurements are depicted in the following Table 1.
From the above Table 1, it may be apparent that the results of the interferometry measurement method are different from the results of the confocal microscopy method. Therefore, in view of the better reproducibility of the measurement using confocal microscopy as discussed above, the dimensions are obtained by measurement using the above confocal microscopy method.
According to an aspect, the razor blade, may include a blade substrate 10 which may be sharpened. The blade substrate 10 may have a planar portion 8, wherein the two opposite sides of the blade may be parallel to each other. Further, the blade substrate 10 may also include a cutting edge portion 11, shown in cross-section on
Razor blades with various geometries may have been manufactured, measured, and tested for shaving performance. Manufacture may include, not only substrate sharpening by grinding, but also coatings as will be described below. For the shaving tests, only the grinding step may be modified in order to generate various substrate geometries, the other process steps may be kept equal.
The tests determined that the thinness of the tip edge may be defined by checking the thickness of control points located 5 and 20 micrometers from the tip. Further, the strength of the edge tip may be defined by checking the thickness of control points located 20 and 100 micrometers from the tip.
Further, the dimensions given here may be average dimensions along the length of the blade. Due to the manufacturing process, a single blade may not have exactly the same profile along its whole length. Hence, each thickness value may be an average value of various data obtained along the length, for example, between 4 and 10 data.
After intense testing, it was determined that suitable shaving effects may be obtained for blades having the following features:
The cutting edge portion 11 of the blade may have a thickness of T5 between 1.55 and 1.97 micrometers measured at a distance D5 of five micrometers from the tip.
The cutting edge portion 11 of the blade may have a thickness of T20 between 4.60 and 6.34 micrometers measured at a distance D20 of twenty micrometers from the tip.
The cutting edge portion 11 of the blade may have a thickness of T100 between 19.80 and 27.12 micrometers measured at a distance D100 of hundred micrometers from the tip.
The above dimensions may be obtained through a dispersion of products manufactured using the same manufacturing process.
The blade may have a smooth profile in between and beyond (both from and away from the tip) these control points. The above-mentioned results may the profiles as detailed in Table 2 (although measured thickness geometry in other check points may not be considered as relevant in terms of qualifying the quality of the product).
According to some aspects, the thickness of the cutting edge portion 11 may have the following configuration of thicknesses. The thickness T5 may be between 1.80 and 1.95 micrometers measured at a distance D5 of five micrometers from the tip. The thickness T20 may be between 5.40 and 6.30 micrometers measured at a distance D20 twenty micrometers from the tip. The thickness of T100 may be between 23.00 and 25.10 micrometers measured at a distance D100 hundred micrometers from the tip.
In such cases, the thickness configuration may be detailed in following Table 3.
According to further aspects, Table 4 may detail examples of thickness configurations.
The blade thickness increase rate (slope) from the tip up to the transition point may be continuously decreasing, making the blade edge easier to penetrate the hair leading to better comfort. The blade profile after the transition point 100 (for example from 40 μm to 350 μm) may be lying in a specific range of values in order to support a geometrically smooth transition from the first 40 μm to the unground part of the blade. In this region, the thickness increase rate may be less than, or equal to, the increase rate at 40 μm.
The blade edge profile generated by the rough grinding stage, typically covering an area between 50-350 μm from the tip, may determine the material removal rate of the finishing operation. Generally, the finishing grinding stage may be mainly called to smoothen out the excess surface roughness produced by rough grinding along with the final shaping of the blade edge profile. For optimal process efficiency, the material removal rate of finishing grinding wheel may be kept to a minimum but such that the induced surface roughness ranges between 0.005-0.040 μm.
For example, the thickness of the aforementioned blade profile may be described with the following mathematical formulas:
t=a·(xb) (A)
t=(c·x)+d (B)
In the above formulas, a and c may be constants from an interval [0, 1], b may also a constant from an interval [0.5, 1], d may be a constant from an interval [0.5, 20], x may refer to a distance from the tip in micrometers and t may refer to the thickness of the blade in micrometers.
One or more formulas (A) may be applied one after the other to the portion of the blade extending from the tip to a transition point 100, and one or more formulas (B) may be applied one after the other from the transition point 100 to the unground portion of the blade.
According to some aspects, formula (A) may describe the thickness of the cutting edge portion 11 from 0 to 40 micrometers from the tip, where a=0.5 and b=0.8 may be constants. Formula (B) may describe the thickness of the cutting edge portion 11 from 40 to 350 micrometers from the tip, with constants c=0.2 and d=1.5.
According to another aspect, the thickness of the cutting edge portion 11 of the blade may have the following thickness configuration as detailed in following Table 5.
Further, the thickness of the blade profile may be described by the above mentioned mathematical formulas (A) and (B).
Accordingly, formula (A) may describe the thickness of the cutting edge portion 11 from 0 to 20 micrometers, with constants a=0.47 and b=0.84. Formula (B) may describe the thickness of the cutting edge portion 11 from 20 to 150 micrometers, with constants c=0.251 and d=0.800. Formula (B) may also describe the thickness of the cutting edge portion 11 from 150 to 350 micrometers, with constants c=0.1775 and d=11.8750.
According to yet another aspect, the thickness of the cutting edge portion 11 of the blade may have the following thickness configuration as detailed in the following Table 6.
Further, the thickness of the blade profile may be described by the above mentioned mathematical formula (A).
Accordingly, formula (A) may describe the thickness of the cutting edge portion 11 from 0 to 20 micrometers, with constants a=0.45 and b=0.79. Formula (A) may also describe the thickness of the cutting edge portion 11 from 20 to 350 micrometers, with constants a=0.296 and b=0.93.
According to a further aspect, the thickness of the cutting edge portion 11 of the blade may have the following thickness configuration, as detailed in the following Table 7.
The thickness of the blade profile may be described by the above mentioned mathematical formulas (A) and (B).
Accordingly, formula (A) may describe the thickness of the cutting edge portion 11 from 0 to 20 micrometers, with constants a=0.54 and b=0.80. Formula (A) may also describe the thickness of the cutting edge portion 11 from 20 to 200 micrometers, with constants a=0.40 and b=0.90. Formula (B) may describe the thickness of the cutting edge portion 11 from 200 to 350 micrometers, with constants c=0.18 and d=11.10.
All the above aspects, which relate to the tip 14 and to the cutting edge portion 11 of the razor may be described by formula (A) and formula (B) or with the combination of both formulas. The formulas (A) and (B) may describe different sections measured from the tip 14 of the razor.
The razor blade substrate 10 including the cutting edge portion 11 may be made of stainless steel. A suitable stainless steel may include in weight
Other stainless steels may also be used. Other materials which are known as razor blade substrate materials, may also be considered.
The following manufacturing steps of a razor blade may be described below.
The blade substrate 10 including a cutting edge portion 11 having a profiled geometry and having a tapering geometry with two substrate sides 12, 13 converging toward a substrate tip 14, may be covered by a strengthening coating 16 deposited on the razor blade substrate at least at the cutting edge portion 11. Coating layers may be implemented on the blade edge substrate to improve the hardness of the blade edge and to thereby enhance the quality of the shaving.
The coating layers may reduce wear of the blade edge, may improve the overall cutting properties and may prolong the usability of the razor blade.
The strengthening coating 16 covering the substrate tip 14, may have a profiled geometry and may have a tapering geometry with two coating sides converging toward a coating tip. As shown in
The blade may be fixed or mechanically assembled to a razor head, and the razor head itself may be part of a razor. The blade may be movably mounted in a razor head, and mounted on springs which urge it toward a rest position. The blade may be fixed, notably welded to a support 29, notably a metal support with a L-shaped cross-section, as shown in
This application is a continuation application of U.S. application Ser. No. 15/535,984, filed Jun. 14, 2017, which is a National Stage application of International Application No. PCT/EP2014/079091, filed on Dec. 22, 2014, each of which is hereby incorporated by reference in its entirety for all purposes.
Number | Date | Country | |
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Parent | 15535984 | Jun 2017 | US |
Child | 17551841 | US |