DE3526951A1 - Shearing blade for razors and method for the production thereof - Google Patents

Abstract

The shearing blade consists of a silicon disk (1) having a monocrystalline structure into which square, rectangular or diamond-shaped holes (11), which serve as hair entry holes, are formed by anisotropic etching. <IMAGE>

Description

The invention relates to a shaving blade for shaving devices and a process for its manufacture.

Shaving blades for shavers, especially electric shavers are known. With modern Elektrora siergeräte consists of a per perforated nickel foil. The perforation has on the a protrusion on the side facing the shear knife, which serves as a cutting edge and on the z. B. the beard hair is cut. The supernatant rounds off in Operation in a relatively short time off, which reduces the quality of the cut.

The cut or shaving quality is not at used cutters by the thickness of limited to approx. 50 µ.  

The object of the invention is to provide a foil with ver better cut quality and longer life create.

This task is by the in claim 1 and to claim 2 marked invention solved.

Advantageous refinements of the invention result itself from the subclaims.

Anisotropic etching techniques in connection with single crystal Linem silicon are known. You will e.g. B. attached turns to micromechanical components, such as trenches, To create holes, free-standing tongues, etc., which for Creation of ultra-small sensors and actuators are required (see K.E. Petersen / SILICON AS A MECHANICAL MATERIAL / IEEE, Vol. 70, No. 5, MAY 1982).

The basic idea of the invention consists of egg ner monocrystalline silicon wafer by means of a single etch to create a hole pattern where in the case of commercially available silicon wafers, the crystal orientation (100), (110) can be used. Through the Choice of crystal orientation, geometry, the Pattern and the orientation of the etching mask can be both the shape of the serve as bar entry openings the openings as well as the inclination of the cutting edges influence.

In the case of commercially available silicon wafers, the crystal Orientation (100) can have openings of rectangular or square cross section. Due to the physical nature of the etching process lukewarm the perforated edges towards each other so that the  Tapered hole (e.g. py with square openings ramidenike), with oblique on all four hole sides Shear edges of diamond-like quality the. With commercially available silicon wafers the crystal Orientation (110) arise through the etching process with a diamond-like cross-section, in which except in the acute-angled corners of the rhombus too the cross-sectional opening does not changes. It is caused by the etching process vertical cutting edges, where however, at the acute-angled corners of the diamond-shaped diagonally towards openings with increasing etching depth running cutting edges arise.

Embodiments of the invention are in the drawing tion and are described in more detail below purifies. Show it:

FIG. 1a is a sectional view of a monocrystalline (100) oriented silicon wafer before the etching ,;

FIG. 1b is a sectional view of a monocrystalline (100) oriented silicon wafer after etching;

Fig. 1c is a perspective view of egg nes shear blades made with the inventive method;

Fig. 2 is a plan view of a monocristal line (100) oriented silicon wafer; and

Fig. 3 is a perspective view of a monocrystalline (110) oriented silicon wafer with a diamond-shaped opening formed therein.

In the following the manufacturing process for the generation of He shear blades and a shear blade produced with it is described. Fig. 3 shows a commercially available (100) silicon wafer which is subjected to an anisotropic etching to produce a hole pattern. In the exemplary embodiment shown, the hole cross section is square. It can also be rectangular or, as will be explained below, diamond-shaped.

Due to the physical nature of the etching process lukewarm the punch cards face each other like pyramids. The Holes taper towards the shear knife and produce sloping cutting edges of diamond-like Quality. By simultaneous form etching of the shear the frame is created in an etching process corridor.

Fig. 1 shows a non-scale representation of the section of the (100) oriented silicon plate 1 , the surfaces 2 of which were oxidized with hot water steam in a known manner to SiO ₂ . By coating with positive photoresist 3 , laying on etching masks, exposure, development and opening of the oxide layer by means of buffered hydrofluoric acid, the windows 4 and 5 are produced. In this case, the window 4 corresponds to an opening serving as a hair entry opening and the window 5 corresponds to the rear side of the cutter blade, that is to say the side facing the cutting blades.

The pure silicon window surfaces on the (100) silicon wafer are oriented parallel to the (110) planes. They offer the following main etching process of anisotropic etching, here z. B. KOH, the ability to penetrate into the silicon until reaching the (111) planes and thereby form edges in the directions 6 , 7 , 8 shown . After He reach the desired shaving blade thickness D , the etching process is stopped and the remaining photoresist ent removed. FIG. 1b shows the same section of the Si liziumscheibe after etching.

One can see a blade part 9 , a blade edge 10 and the opening 11 designed as a hair entry opening with the cutting edges 12 produced .

Fig. 1c shows a spatial representation in a larger section of the shear blade. It goes without saying that the hole pattern can be arbitrarily offset, as far as the basic directions given by the (110) planes of the edges of the openings are maintained. Instead of square openings, as already mentioned above, short slots can be advantageous. The shear blade edge 10 left for stiffening in the original disk thickness can be provided with fastening holes and usefully shaped by the same etching process.

A typical exemplary embodiment of the shear blade has the dimensions shown in FIG. 2: thickness of the silicon wafer W = 250 μ, shear blade thickness D = 30 μ, width of the opening A = 542 μ serving as hair entry opening, cutting width B = 500 μ, web width a = 30 µ, web width x = 72.5 µ and percentage / cutting opening K _% = 32.7%.

With the invention, a novel shear blade is ver better cutting quality, the longer one Has lifespan and advantageously skin allergies, e.g. B. nickel allergies prevented.

Claims (7)

1. shaving blade for razors, characterized in that it consists of a monocrystalline, for the formation of serving as hair entry openings qua dratic, rectangular or diamond-shaped openings ( 11 ) anisotropically etched silicon wafer ( 1 ). 2. A process for producing a shaving blade for razors, characterized by anisotropic etching of a silicon pure crystal wafer ( 1 ) to produce a thin membrane with a hole pattern. 3. The method according to claim 2, characterized in that, depending on the geometry and arrangement of the etching mask in local relation to the orientation of the crystal structure, both the shape and the edge inclination of the opening openings ( 11 ) of the hole pattern as hair entry openings is designed to be variable . 4. The method according to claim 3, characterized in that the orientation is carried out so that the edges of the holes of (111) planes are formed, which are only minimally changeable by the etching, so that without destroying the outer geometry the hole pattern of the openings ( 11 ) the thickness of the shear blade is determined by the duration of the etching, at the same time producing sharp cutting edges ( 12 ) of diamond-like hardness. 5. The method according to any one of claims 2 to 4, characterized in that the shear blade edge and the fastening geometry of the shear blade are produced from the same silicon wafer ( 1 ). 6. The method according to any one of claims 2 to 5, characterized in that the silicon pure crystal wafer has a (110) crystal orientation, square or rectangular openings serving as hair entry openings ( 11 ), the edges of which are produced by the ( 110) - planes given basic directions match so that pyramid-like tapered depressions are formed, which are truncated pyramid-like by an etching front coming from the opposite side, so that cutting edges ( 12 ) arise and at the same time the shear blade the desired thickness (D) holds, as well as stiffening edges and the mounting geometry of the shaving blade are generated. 7. The method according to any one of claims 2 to 5, characterized in that the silicon pure crystal wafer ( 1 ) has a (110) -Kristallorienti tion, diamond-shaped openings serving as Haarein openings ( 11 ) who who who at the acute-angled Corners have oblique shear edges and otherwise have shear edges ( 12 ) running perpendicular to the surface of the pane ( 2 ).