DE2516663A1 - Optical fibre with large aperture angle - using optical fibre cores inside outer coating of methacrylate contg fluorine - Google Patents

Abstract

Optical fibres with large aperture angle for use in o tical waveguide devices, have a core of optical glass having high RI, covered by a coating of transparent organic m terial with low RI. The core consists of a bundle of several optical fibres with small dia. The core glass pref. has RI = 1.55-1.65, esp. flint glass (F2) with RI nd = 1.62 while the organic coating pref. has RI = 1.35-1.43, esp. (I) methacrylate contng. fluorine, nd = 1.36; (II) 1,1-dihydroperfluoro-hexylacrylate, nd = 1.356; (III) 1,1-dihydro-perfluoro-butylacrylate, nd = 1.367; or (IV) chlorotrifluoroethylene, nd = 1.39-1.43. Mfr. pref. uses core fibres each 30 u dia. coated with a soln. of (I) to (IV) then heated to 100-200 degrees C. Provides an image angle of 100 degrees for use in the visible light, and near IR regions, without the light turning yellow. Suitable for fibrescopes.

Description

Description Optical fiber with large aperture angle The invention relates to an optical fiber with a large aperture angle for use in light guide devices, with a core made of optical glass with a large refractive index and one around the transmitter Layered envelope made of organic, transparent material with a low refractive index. An optical fiber of this type is intended for use in a device for transmit light in the visible near infrared range.

An optical fiber widely used in fiber scopes is one Fiber that is made up of a flint glass with an index of refraction for the d-line nd = 1.62 existing soul, the one with barium-containing crown glass with nd = i> 52 is shifted. Such an optical fiber has a numerical aperture of about 0.56 and an aperture angle on the order of 680. The one that can actually be used However, the aperture angle is usually 550. In newer fiber scopes, a front lens is used aimed at having a large angle of view. For this purpose a lens was used, whose angle of view is in the order of 1000. This leads to a optical fiber with a large aperture angle for a light guide device for lighting is required.

A method of obtaining a large aperture angle of the light guide device has hitherto been to work the front end of the optical fiber so that it is expanded, or Lenses and the like in the front end used to diffuse the light. However, these conventional methods require complex manufacturing steps require a complicated structure and a space-consuming The size of the light guide device can still only reach limited aperture angles, so that a remarkably large aperture angle has not yet been achieved in this way became.

One way to avoid these disadvantages is to use the To enlarge the aperture angle of the optical fiber itself.

As is known, the numerical aperture of a fiber with a core and a cladding is given by: Numerical aperture = \ I c> 2 = 1 (refractive index of the core) 2 - (refractive index of the cladding) 2.

The aperture angle depends on the numerical aperture and is even more so larger, the larger the numerical aperture can be made. As from the above As can be seen in the formula, the aperture angle can be increased by increasing the refractive index the core is enlarged or the refractive index of the cladding is reduced, or both these methods are combined.

When the refractive index of the soul is increased, the glass composition has the effect of if the refractive index of the optical glass is increased, that of the short-wave Area of the transmitted light is noticeably absorbed, so that the light becomes clear turns yellowish. As a result, the optical fiber is useful for light guide devices for illuminating fiber scopes used in visible light and the like not suitable.

In the accompanying Fig. 1, curves 1 and 2 show the light penetration capacity of bundles of light-conducting fibers with a length of 1 m each. The curve 1 shows the light permeability of one of these bundles, which are made of flint glass is made with a refractive index nd of 1.62. The curve shows the light penetration capacity of another bundle, the soul of which is made of heavy flint glass with a refractive index nd of 1.67 is made. As can be seen from Fig. 1, absorb both bundles the short-wave range of light near 400 nm noticeably, which leads to that even if white light gets to the inlet end of the bundle, from the outlet end only yellow light is emitted from the bundle.

In practice, the light guide device has to illuminate fiberscopes a length of about 2 to 3 m, so that the starting end of such a long one The light emitted from the bundle becomes noticeably yellowish. It turned out that the upper limit of the refractive index of optical glass that is in the core of a light guide device can be used for illuminating fiberscopes, should preferably be 1.65.

When reducing the refractive index of the cladding, fluorine-containing Crown glass with a small refractive index can be used. An FK3 glass has that smallest refractive index, which is 1.46. Such a fluorine-containing crown glass but can react with the flint glass of the sea; there is also the risk that it degasses. Consequently, fluorine-containing crown glass is used for the cladding of the optical Fiber not suitable.

The optical glass with the lowest refractive index that is used for cladding suitable for the optical fiber is borosilicate glass, the refractive index of which is nd = 1.494. The lower limit of the refractive index of the cladding material is thus given by the composition of the glass.

An optical fiber that consists of one made of a glass with the maximum Refractive index nd = 1.65 existing transmission and a cladding made of a glass with the minimum refractive index n = 0d 1.494 has an aperture angle from about 90. Such an optical fiber is for a light guide bundle for lighting Not suitable for fiberscopes with a lens with an angle of view of about 1000 are equipped.

As can be seen from the above, it is not possible to use an optical Fiber with an angle of view of about 1000 from one out optical Glass existing soul, which is coated with a cladding made of an optical glass is to manufacture. So far it has been proposed to use an optical fiber for guiding to create ultraviolet light consisting of a SeRe made of quartz and a is composed of organic substances envelope. The index of refraction the organic substance can be relatively small, so the optical fiber whose Soul is covered with such an organic substance, a large aperture angle may have. When layering the organic matter around the optical fiber it is but impossible to noticeably reduce the diameter of the soul. On the other On the side, the light guide bundle for illuminating the fiberscope must be flexible. An optical one Fiber for such a flexible light guide bundle must have a small diameter of the order of 30 /. An optical fiber with such a small one Diameter might not be satisfactorily covered with the organic matter will.

The invention is based on the object of providing an optical fiber with a large angle of view of 100, suitable for use in light guide devices is suitable where there is no risk of yellowing, the light in the visible, near infrared and which is highly flexible.

This task is accomplished with an optical fiber of the type described in the opening paragraph Genus solved according to the invention in that the set is a bundle of several, light-conducting Small diameter fibers is.

The refractive index of the optical glass is preferably the core of the optical fiber is between 1.55 and 1.65 and has the refractive index of the organic Optical fiber cladding material between 1.35 and 1.43.

The invention is described below with reference to schematic drawings for example and explained with further details.

They represent: Fig. 1, as already mentioned, the light permeability optical fibers suitable for use in light guide devices and Have cores made of different types of optical glass, FIG. 2 shows a cross section a light guide bundle with three optical fibers bundled together according to the invention Fibers, Fig. 3 shows a cross section of a light guide bundle with seven according to the invention optical fibers bundled together; and FIG. 4 is a diagram showing the manufacturing steps of the optical fibers shown in FIG.

In Fig. 2 an embodiment of the optical fiber is shown, one of three bundled, thin optical fibers 11, 12, 13, of which each composed of an optical glass with a large refractive index Has soul and a layered envelope 21 around the soul, which consists of a transparent organic material with a small refractive index.

In Fig. 3 is another embodiment of the optical fiber shown. This has a soul made up of seven, thin optical fibers 11, 12, 13, 14, 15, 16, 17 is composed around a central optical fiber 11 are bundled together and each made of an optical glass with a large Refractive index exist. The optical fiber also has a cladding 21, which consists of transparent, organic material with a low refractive index and is layered around the surface of the soul.

The following table shows preferred combinations of optical glass for the core and the organic substance for the cladding of the optical fiber, as well as the aperture angle achieved in each case. Optical glass Organic material of the aperture angle enveloping the soul Flint glass F2 fluorine-containing metha- o (nd = 1.62) acrylate (more than 30 Ge 123 weight% fluorine) nd = 1.36 II 1,1 -dihydroperfluorohexyl- 1250 acrylate nd = 1.356 1! 1,1 -dihydoperfluorobutyl 1210 acrylate nd = 1.367 n chlorotrifluoroethylene 1120 bis nd = 1.39 to 1.43 99 In FIG. 4, the stages for manufacturing the optical fiber shown in FIG. 2 are shown schematically. First, the optical fiber made of flint glass with a diameter of 30 / e is wound around three reels 31, 32, 33. These reels 31, 32 and 33 are rotatably mounted on a shaft S.

Then three optical fibers 34, 35, 36 from these reels 31, 32, 33 unwound and bundled together to form a bundle. The one so trained Bundle is in an inlet 38 of a container 37 with a solution of fluorine-containing Methacrylate initiated in solvent. When passing through the solution the surface of the bundle coated with the solution and the so coated with the solution optical fibers are led out from the outlet 39 of the container 37. Thereupon the coated optical fiber is passed through a heating chamber 40 that is 0 on a temperature of 100 to 200 C is kept to the contained in the solution To evaporate solvent, so that an optical fiber shown in Fig. 4 is manufactured will. The optical fiber thus obtained is wound around a bobbin 41.

As explained above, the three optical fibers 34, 35, 36 are bundled together and then coated with the organic material, making the optical fiber easy is producible and the organic substances are effectively layered around the bundle will can. This causes the three optical fibers 34, 35, 36 to come off the reels 31, 32, 33 are unwound at a relatively high speed, for example 2 m / min can. In addition, the diameter of each optical fiber 31, 32, 33 is small, in of the order of 30 /, so that the optical fiber is sufficiently flexible. Light can travel from any optical fiber to adjacent optical fibers; However, this does not prevent the use of the optical fiber according to the invention, because it is used as a light guide device rather than an image transfer device, which is able to accurately take an optical image from one place to another transferred to.

A number of possible variations of the invention are that the number of optical fibers is not three or seven. In the in Fig. 4 illustrated embodiment can be additional prepared and related to Reels of wound optical fibers are unwound. There can be several to one Reel-wound optical fibers are unwound and bundled together at the same time to form a bundle of optical fibers, which is then subjected to the coating treatment can be subjected.

Claims =

Claims (5)

Claims Optical fiber with a large aperture angle for use in light guide devices with a core made of optical glass with a high refractive index and a covering made of organic, transparent material, layered around the soul with a small refractive index, due to the fact that the soul a bundle of several light-conducting fibers (11, 12, 13; 11 to 17) with a small diameter is. 2. Optical fiber according to claim 1, characterized in that g e k e n n -z e i c h n e t that the refractive index of the optical glass of the soul is between 1.55 and 1.65 and the refractive index of the organic material of the cladding (21) is between 1.35 and 1.43. 3. Optical fiber according to claim 1, characterized in that g e k e n n -z e i c h n e t that the optical glass of the soul flint glass (F2) with a refractive index nd is 1.62. 4. Optical fiber according to claim 1, characterized in that g e k e n n -z e i c h n e t that the organic material from which the envelope (21) consists of the following The selected substance group is: fluorine-containing methacrylate with a refractive index nd of 1.36, 1,1-dihydroperfluorohexyl acrylate with a refractive index nd of 1.356, 1,1-dehydroperfluorobutyl acrylate with a refractive index nd of 1.367 and chlorotrifluoroethylene with a refractive index nd from 1.39 to 1.43. 5. A method for manufacturing an optical fiber according to claim 1, by the fact that several glass fibers (34, 35, 36) int a diameter of each on the order of 30/4 of at least a reel (31, 32, 33) are unwound at a speed of about 2 m / min, the glass fibers are bundled together to form a bundle, the bundle in a solution of organic matter in a solvent is passed to it to coat with the solution, and the coated bundle to a temperature of 1000 to 2000C is heated.