SU1708608A1 - Light-beam tool cutting device - Google Patents

Abstract

The invention relates to cutting tools and can be used as personal items, such as safety razors. The aim of the invention is to improve the operational characteristics and enhance operational capabilities. The cutting device of the light beam instrument contains a matrix with a bundle of light guides. The matrix in the area of the cutting edge has a rounded section of a wedge-shaped form with a ray-forming medium, including a number of refracting facets. The hair shafts in the process of shaving are cut off by the light cutting edge in the form of a wide-focal focal line in front of the matrix formed by the refractive facets. The refractive facets can be either solid microlenses, or gas. The device is equipped with a protective comb-like element fixed on the matrix, the length of the teeth of which exceeds the distance from the matrix to the focal line of the ray-focusing means. 3 hp ff. 5 il.

Description

The invention relates to cutting tools and can be used in the manufacture of personal items, in particular safety razors.

The aim of the invention is to improve the operational characteristics and enhance operational capabilities.

Figure 1 presents a General view of the light beam instrument; Fig. 2 is a view A in Fig. 1 with a cut-out along the solid-state microlens; in Fig. 3, view A in Fig. 1. gas microlens version; figure 4 is a view of And in figure 1 with a protective comb element; figure 5 - view B in figure 4.

The cutting unit of the light-beam instrument contains a matrix 1 with a bunch of 2 light guides 3, which, by end sections, form an input element 4 for the light beam generated by the source and an output element. consisting of a set of refractive facets 5. The matrix in the zone of the cutting part 6 has a rounded portion 7 of wedge-shaped shape. The refracting facets 5 are placed in a row, perpendicular to the geometric generator 8 in the center of the rounded wedge-shaped section 7 of the matrix to form from the foci of the light beam of each refracting facet 5 of the linear beam-forming means 9 - the focal light cutting line - edge 10, parallel to the longitudinal plane of the fixed wedge-shaped section 7 and near its surface.

The outer surface of each refracting facet 5 is rounded to form a single generatrix with fixed matrix sections 7.

Each of the refracting facets 5 can be either solid-state in the form of a microlens 1 of a transparent material based on fused alumina or formed by a hole 12 in the shape of a truncated cone facing the smaller base towards the generatrix 8 of the rounded portion 7 of the matrix. All holes 12 are connected by a channel 13 parallel to the longitudinal plane of the rounded section 7 and connected to an inert gas source for supplying it to each of the holes 12 and forming a refracting facet.

The cutting unit is provided with a protective comb element 14 with rounded ends 15 fixed on the outer outer surface of the matrix 1 perpendicularly geometrically forming 8. and its teeth 16 are placed between the refracting facets 5. The length of the teeth 16 is longer than the distance forming the 8 matrix to the focal line 10 Radiating agent 9.

Matrix 1 can be made by extrusion from powdered starting material. It may have a counter element of the optical connector 17 for attachment to the output tip 18 of the flexible light guide bundle 19.

The cutting apparatus of the light beam instrument works with the image.

To the input element 4 through the flexible harness 19 leads t light beam 20 generated by the source type of medical installation Scalpel-1. Through the light guides 3 in the matrix 1, the light beam enters the microlenses of the wide-grip refracting means 9 and is focused by them under the fictitious cutting edge 21 of the matrix 1 to form the focal line 10 that performs the function of the light cutting edge of the blade. In the process of shaving, the device is in contact with the skin surface with a part of its surface in the transition area of the rounded section 7 to the bottom surface 22 of the matrix 1. In this position, the cutting unit is moved in direction to the cutting hairs 23 on the skin tissue 24. When the cutting unit is moving, the focal line 10 is always above skin surface 25. In the focal zones 26 of the microlenses, the hair shafts are divided into parts by the light beam, the upper of which, in the form of a cut layer 27, converge along the front surface 28 of the matrix. 1. The intensity of the light beam in the focal zone of 0.5 ... 1.5 kW / cm. When the protective comb-like element 14 is present on the matrix, the tops 15 of the teeth 16 protect the light beam from reaching the skin surface 25, and the free space between them allows cutting the hair shafts with a focal line 10 in the area between the teeth. Linear ray-forming means 9 on the basis of solid-state microlenses 11 can cut the hair shafts with a light beam 20, which is separated in it by light guides 3 into a light comb on a comb-shaped element 14 with parallel directional focused beams. At the same time, it is possible to change the cutting mode in which the means 9 cuts the hair shafts, for example, of increased thickness, with a separate running focused beam of increased energy capacity, supplied by the optical fibers 3 to the microlenses 11 alternately one after the other in their row at the rounding 7. Radiation-detecting means 9 Based on gas microlenses 11, it operates predominantly in the mode of forming parallel directional emission of focused rays with simultaneous supply of an inert gas, for example argon, to each microlens 11 of the common gas channel 13, located along a rounded portion on the matrix 1. The resulting light-gas comb not only performs cutting of the hair shafts, but also non-contact removal with gas jets both during the cutting process and after the end of the cutting, when the light beam 20 is no longer supplied to the microlenses 11. The cutting unit can also work when installed directly on the body of a portable radiation source. In this case, the flexible light guide bundle 19 is not used.

The cutting apparatus is safe because it cannot be injured by cutting, it carries out the process of cutting with a light beam, which is completely sterile, since it cuts off the hair shafts without any mechanical effect on them, thus preventing the spread of the AIDS virus.

Claims (4)

Claims 1. A cutting apparatus of a light beam instrument comprising a matrix with a beam of optical fibers arranged therein, the end portions of which form an input element for a light beam generated by a source and an output element consisting of refracting facets, characterized in that. In order to improve performance and enhance operational capabilities, the matrix in the cutting zone has a rounded section of wedge-shaped forms, the refractive facets are placed in a row, perpendicular to the geometric generator in the center of the rounded wedge-shaped section of the matrix to form from the focuses of the light beam of each refractive facet of a linear radiating means - focal light cutting line - edge parallel to the longitudinal plane of the rounded wedge-shaped area, spread zhennoy over its surface, the outer surface of each refractive facets configured to form a single rounded with rounded portions forming the matrix. 2. An apparatus according to claim 1, characterized in that each refractive facet is made in the form of a solid microlens, for example, from a fused material based on fused alumina. 3. The apparatus according to claim 1, characterized in that each refracting facet is formed by a truncated hole a cone facing with its smaller base towards the generatrix of the rounded section of the matrix, all the holes being connected by a channel parallel to the longitudinal plane of the rounded section connected to the source of inert gas for feeding it into each hole and forming a refracting facet. 4. The apparatus according to claims 1 to 3, that is, it is equipped with a protective comb element with rounded ends, mounted on an external external lover. The matrix is perpendicularly geometrically forming its rounded wedge-shaped section, with its tooth placed between the refracting facets, and their length exceeds the distance from the surface of the geometrical forming to the focal line of the radiating agent. 9 and g 13 12 FiaZ 7 A 26 7 Buds Schig.5