DE2516663B2 - Flexible optical fiber with a core made from a bundle of light-conducting fibers and a method for manufacturing the optical fiber - Google Patents

Description

The invention relates to a flexible optical fiber according to the preamble of claim 1. The invention further relates to a method for producing the fiber according to the preamble of AnspmJis 3.

A known generic flexible optical fiber (US-PS 31 90 735) has an oil from a Small diameter bundle of optical fiber optic glass with a high refractive index, the The individual fibers of the Bundles are completely embedded in the glass of the cladding. The known fiber is produced in that several glass rods are arranged within a glass tube and the whole The arrangement is then stretched while heating, whereby the glass tube melts the space between the Fills glass rods and reduce the diameter of the glass rods according to the expansion.

The known optical fiber is only slightly flexible, since the individual fibers of the bundle also have the Cladding forming glass are connected to one another so that they are no longer mutually displaceable, as it is necessary for great flexibility with regard to the choice of materials that for satisfactory optical properties Properties of the known fiber is to be met, jo there is little freedom of choice So namely one optical fiber that is composed of various glasses can be used satisfactorily in practice must have physical properties such as thermal expansion coefficient, softening

Γ) temperature, viscosity at high temperature, etc. the be roughly the same for both types of glass. Furthermore may no devitrification occurs and must be the optical fiber be chemically stable.

So it is difficult to find a G'is with a small

To find the refractive index that is suitable as a cladding for the soul Among the optical glasses that are used as Cladding glass can be selected, shows the so-called FK3 glass and the so-called FK5-GIas, which are the smallest Refractive index has a tendency to devitrify. Quartz glass

■ π or Vycor glass (coming glass) with a low refractive index have a melting point that is too high and too small a coefficient of thermal expansion to match a glass with a high refractive index to be combinable. The one with the well-known optical

The maximum aperture that can be achieved by the fiber is therefore relative kiein.

If the aperature is to be even somewhat satisfactory, the glass of the fibers of the bundle must be one have the largest possible refractive index

(numerical aperalur = [/ (refractive index of the fiberglass) ² - (refractive index of the cladding material) ² ).

Using glass with the highest possible refractive index as the glass for the fibers of the bundle this is opposed by the fact that the glass is then no longer colourfast. The short-wave range of the transmitted light is then noticeably absorbed so that the transmitted light is clearly yellowish. As a result of which is the optical fiber for light guide devices for illuminating fiber scopes, those in the visible Light can be used, and the like is not suitable

In the attached Fig. 1 shows curves 1 and 2

the light conductivity of bundles of light-conducting _M ) fibers with a length of 1 meter each. Curve 1 shows the light conductivity of a bundle of flint glass with a refractive index n _d of 1.62. Curve 2 shows the light conductivity of a bundle of heavy flint glass with a refractive index n1 of _h - 1.67. Both bundles noticeably absorb the short-wave range of light near 400 nm, which means that the white light that is radiated in is emitted as yellow light.

In practice, light guide devices for illuminating fiberscopes have a length of about 2 to 3 meters so that the light emitted from the exit end of such a bundle is noticeably yellowish

An optical fiber, which is a fiber bundle made of glass with the maximum refractive index n </ = 1.65 and a cladding made of a glass with the minimum possible refractive index Dd = 1.494 (borosilicate glass), has an aperture angle of about 90 °. Such an optical fiber is not suitable for a light guide bundle for illuminating fiberscopes which are equipped with a lens with an angle of view of approximately 100 °.

The invention is based on the object of a to create the high flexibility with optical fiber large aperture and low color cast (yellow cast) combined

This object is achieved with the features of claim »1

Because the sheathing of the fiber according to the invention is made of plastic, its refractive index is relatively small, so that there is extensive freedom of choice with regard to the refractive index of the glass. An aperture of 100 ° can easily be achieved without a glass having an extreme high refractive index must be used. As a result, there is extensive freedom of choice with regard to the selection of glasses with a dispersion below that of flint glass (F 2) , so that in addition to a large aperture, satisfactory color fastness of the fiber is achieved.

The individual fibers of the bundle are mutually displaceable inside the soul, whereby the optical The fiber has high flexibility The fibers can directly abut one another, so they must not be surrounded by organic material all around.

The effective cross section of the fiber, i.e. H. the ratio of the total cross-sectional area of the fiber to the cross-sectional area of the individual glass fiber is advantageously very large because the individual Glass fibers are not completely encased by organic material, which means that the fiber conducts a lot of light

Regarding the state of the art, reference should also be made to GB-PS 11 55 795, in which a fiber optic bundle is described, of which each individual glass fiber is coated with a plastic sheath such composite optical fiber faces opposite the fiber according to the invention has a lower packing density and thus a lower specific Light conductivity on. Furthermore, the diameter of the individual, in the composite, optical Fiber contained fibers because of the sheathing of each individual milling cutter larger than Lei of the invention Fiber, resulting in a larger bending radius, d. H. a lower flexibility of the fiber results

Claim 2 identifies organic materials that are advantageously used for the covering.

The solution of the part of the The object of the invention is specified in claim 3. This claim characterizes a simple method for Manufacture of the fiber according to the invention, this method, as characterized in claim 4, rapidly can be carried out so that the fiber can be produced in an economical manner.

The invention is explained in more detail below on the basis of a schematic representation Drawings for example and explained with further details.

They represent:

Fi p. 1, as already mentioned, the light conductivity optical fibers, which are suitable for use in light guide devices and cores made of different, have optical types of glass,

F i g. 2 shows a cross section of an optical fiber with three optical fibers bundled together;

Fig.3 shows a cross section of an optical fiber with seven bundled optical fibers and

F i g. FIG. 4 shows a diagram to illustrate the manufacturing steps of the FIG. 2 optical fibers shown.
2 shows an embodiment of the optical fiber which has a core composed of three bundled, thin optical fibers 11, 12, 13, each of which consists of an optical glass with a large refractive index, and a cladding 21 that accommodates the core is made of a clear organic material with a low refractive index

In Figure 3, another embodiment of the optical fiber is shown This has a core, the bundled seven, thin optical fibers 11, 12, 13, 14, 15, 16, 17 is composed of the medium on an optical fiber 11 around and each consist of an optical glass with a high refractive index. Furthermore, the optical fiber has a cladding 21 which consists of transparent, organic material with a low refractive index and is layered around the surface of the core

The following table shows preferred combinations

jo tions of optical glass for the soul and the organic substance for the coating of the optical fiber and the aperture angle achieved in each case specified.

^r 'Optical glass
the soul

Organic material
the wrapping

Aperture angle

Flint glass F2 fluorine-containing 123 °

(η ,, = 1.62) methacrylate (more than

30% by weight fluorine)

π ,, = 1.36

Flint glass F 2 1,1-dihydroperfluoro- 125 °
(η, ι = 1.62) hexyl acrylate

4-, // ,, = 1.356

Flint glass F2 1,1-dihydroperfluor- Ι2Γ
(η, ι = 1.62) butyl acrylate

η ,, = 1.367

Rintglas F2 chlorotrifluor- 112 ° to 99 °

'" in, = 1.62t ethylene

η, = 1.39 to 1.43

! • ι the F i g. 4 are the stages for making the in

r, F i g. 2 shown schematically. First, the optical fiber made of flint glass with a diameter of 30 μ is wound around three reels 31, 32, 33. These reels 31, 32 and 33 are rotatably mounted on a shaft S

mi become three optical fibers 34, 35, 36 of these Reels 31, 32, 33 unwound and to form a Bundle bundled together The bundle thus formed is placed in a FJnIaB 38 of a container 37 with a solution of fluorine-containing methacrylate in solution

Kj medium initiated. With ι Durrhleiten through the solution the surface of the bundle is coated with the solution and the so coated with the solution optical fibers are emitted from the outlet 39 of the

Container 37 led out. Then, the coated optical fiber is passed through a heating chamber 40 which is maintained at a temperature of 100 to 200 ⁰ C, to evaporate the solvent contained in the solution, so that an optical fiber shown in Figure 4 is produced. The optical fiber thus obtained is wound around a bobbin 41.

As explained above, the three optical fibers 34, 35, 36 bundled together and then coated with the organic material so that the optical Fiber is easy to manufacture and the organics are effectively layered around the bundle can be. This leads to the fact that the three optical fibers 34,35, 36 of the reels 31,32,33 with relative high speed, for example 2 m / min can be unwound. In addition is the diameter each optical fiber 31, 32, 33 small, on the order of 30 μ, so that the optical fiber is sufficiently flexible. Light can travel from any optical fiber to neighboring optical fibers; this however, does not preclude the use of the optical fiber according to the invention because it is used as a ι Air guiding device is used and not as one Image transfer device capable of accurately transferring an optical image from one place to another to transfer a

A number of possible changes to the invention

Ui training is that the number of optical fibers is not three or seven amounts to in the one shown in Fig.4 Embodiment, additional optical fibers prepared and wound around associated reels be unwound. There can be several to one reel

ι ι spooled optical fibers simultaneously unwound and are bundled together to form a bundle of optical fibers, which can then be subjected to the coating treatment.

Iiicr / ii 2 Biiiii

Claims (4)

Patent claims: 1. Flexible optical fiber with a core made of a bundle of light-conducting fibers with a small diameter made of optical glass with a high refractive index and a sheath accommodating the core made of transparent material with a smaller refractive index, characterized in that the sheath (21) made of organic ι ο material with a refractive index between 1.35 and 1.43 and that the optical glass of the fibers (U, 12, 13; 11 to 17) has a dispersion no greater than flint glass (F2) and a refractive index between 1.55 and 1.65 , the respective pair of values of refractive index fiber glass and refractive index cladding material yielding an aperture of the individual fiber £ 100 ° 2. Optical fiber according to claim 1, characterized in that the organic material consists of which the envelope (21) consists, is selected from the following group of substances: fluorine-containing methacrylate with a refractive index n </ of 1.36, 1,1-dihydroperflourhexyl acrylate with a refractive index Dd of 1.356, 1,1-dehydroperflourobutyl acrylate with a refractive index na of 1367 and chlorotrifluoroethylene with a refractive index λ «/ from 1.39 to 1.43. 3. The method of manufacturing an optical fiber according to claim 1 or 2, wherein a plurality of continuously running glass fibers are bundled together to form a soul and with a cladding made of a material with a lower refractive index than the glass of the glass fibers has to be provided, characterized in that the core made of glass fibers (34, 35, 36) with a Diameter of each in the order of 30 μ is bundled together, the bundled soul to form the envelope by a solution of organic material with a solvent is conducted and the enveloped soul is heated to a temperature of 100 ° to 200 ° C 4. The method according to claim 3, characterized in that the speed of the expiring Glass fibers is about 2 m / sec