JPS5898705A - Fiber light guide for infrared light - Google Patents

Abstract

PURPOSE:To enable the transmission of an infrared light image or the like by using a bundle of metallic halide fibers transmitting infrared light as a fiber light guide such as an infrared light image guide and by forming a clad layer with a specified polymer. CONSTITUTION:Mixed crystals of TlBr-TlI selected from metallic halides are melted and spun by means of an extruder to form bundles 1, 11 of fibers transmitting infrared light. A polymer for clad layers for the bundles 1, 11 is selected from polyethylene resin and tetrafluoroethylene resin. For example, both ends 2 of the image guide or the whole outside 12 is coated with molten tetrafluoroethylene resin to form a clad layer. Thus, a fiber light guide for infrared light is obtd.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an infrared fiber light guide used for an infrared light imager guide 4 and the like.

Conventional optical fibers use a core material such as glass or a single polymer material such as plastic, whose main component is SiO□, and a cladding material that covers the core from the outside with a refractive index lower than that of glass or polymer material. materials have been used, but all of these fibers have large absorption in the infrared region and cannot be used. However, in recent years, research has progressed on making inorganic materials into fibers that can penetrate the area outside the door.1. It has become possible to manufacture fibers with a diameter of about 0.1 to 1 mm. However, when selecting the cladding material and the adhesive used for fixing the fiber bundle, all conventionally used cladding materials and polymeric materials used as adhesives emit infrared light. It was impossible to use for absorption.

The present invention provides a fiber light guide for infrared light in which an infrared optical fiber 9 is fixed with a polymeric material that transmits infrared light, and the polymeric material acts as a cladding material for the infrared optical fiber. be.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings. FIG. 1 shows a first embodiment of the invention. 1 is an infrared optical fiber bundle, and 2 is a polymer material for fixing both ends of the infrared optical fiber bundle 1. In this example, the infrared optical fiber bundle was manufactured using an extrusion method with a diameter of 5 mm and a length of 30 mm.
(1'771 TtBr-T/!I mixed crystal (KH2-5)
A bundle of 20 fibers was used. This KH2
- When 20 fibers are bundled at both ends, the diameter is approximately 3 m.
It becomes a fiber bundle of m. This fiber bundle is fixed,
Polyethylene resins, polystyrene resins, and tetrafluoroethylene resins are the only polymer materials that are currently available that transmit infrared light at a wavelength of around 10 μm, so in this example, polyethylene resin was used. Both ends of this fiber bundle are immersed in molten polyethylene resin, gas is removed during melting, and after cooling and hardening, both ends are cut and polished to produce the infrared fiber light guide shown in FIG. The characteristics of this red, external fiber light guide were measured. The infrared light used for the measurement was CO2 laser infrared light with a wavelength of 1000 μm. KH2-5 (TtBr-TtI mixture) for its infrared light wavelength
The transmittance of a single fiber is 7 including reflection loss at the end face.
It is 0%. Also, the opening area of the eastern part of the KH2-5 fiber on the end face of this infrared fiber light guide is 56 mm.
%. A 5W infrared light beam from a CO□ laser is connected to such an infrared fiber light guide with a diameter of approximately 2 mm.
When the beam was focused on a spot of 37 cm, a transmittance of 37 cm was obtained. Considering the transmittance of the single fiber and the aperture area of the fiber bundle, this is a fairly appropriate value, and the fiber light guide functions satisfactorily as an infrared fiber light guide. There was also a slight amount of heat generated from the polyethylene resin used, but this did not affect the use. Furthermore, when the spot position of the incident Co2 laser was moved from side to side within a range of approximately 1 mm, the pattern of the emitted infrared light also moved slightly. Furthermore, when the incident C02 laser beam is made into a slit shape with a width of one dragon, the pattern of the incident infrared light does not have a clear boundary, but it becomes a turn that is close to the slit shape. From the above, It was confirmed that it has a function as an infrared light guide and can be used as an infrared image guide.

We also conducted experiments using different resins. For polystyrene resin, the above KR8-5 wire bundle was immersed in liquid polystyrene resin dissolved in a solvent, and then dried.
I fixed the phi bundle. The CO2 laser light transmission experiment results show 42. Unfortunately, slightly better permeation properties were obtained than polyethylene resin. Regarding the polytetrafluoroethylene resin, the above Phino Z-bundle was fixed by hot pressing at 250°C using finely powdered polytetrafluoroethylene resin. In the C02 laser light transmission experiment, a value of transmittance of 25% was obtained.

In addition, in experiments in which the material of the infrared light fiber was changed, C.
Core eye i7- manufactured by extrusion method of sBr-C5I mixed crystal (total length 30c + 5 diameter Q, CO2 laser light transmittance 54% at phi/4- of 51+llI!), TtBr-TtC
Fiber produced by extrusion of 4 mixed crystals (total length 30cIIL)
Similar results were obtained by performing the above experiment using a sail diameter of 5 ml (D7 eyebar with a transmittance of CO2 laser light of 65%).

FIG. 2 is an example of another embodiment of the fiber optic light guide for infrared light according to the present invention. This is an infrared fiber light guide obtained by dipping the entire bundle of KH2-5 fibers in polyethylene resin and polishing the end faces. The measurement results were similar to those obtained in the previous example.

FIG. 3 is an example of another embodiment of the infrared light guide of the present invention. In this example, KH2-5 fibers were fixed in two rows and 20 rows, and after being fixed with polyethylene, the end faces were cut and polished. In this example, it was confirmed that by utilizing the flexibility of the infrared light Phi iZ-light guide, it could be used as a line image guide capable of changing the axial direction.

As described above, the fiber light guide for infrared light of the present invention fixes the optical fiber bundle and the optical fiber bundle of non-logonized metal that transmits infrared light, and also has an optical fiber glue that functions as a rad material. It is made of polymer material that transmits external light, and uses its flexibility to transmit power of infrared light.
It can also be widely used as a fiber light guide for transmitting infrared images.

[Brief explanation of drawings]

FIGS. 1, 2, and 3 are schematic diagrams of embodiments of the infrared fiber light guide of the present invention, respectively. 1.11.21...Infrared light transmitting optical fiber, 2.1
2.22...Infrared light transmitting polymer material.

Claims (4)

[Claims] (1) A fiber light f''id for infrared light, characterized in that a plurality of optical fibers that transmit infrared light are fixed with a polymeric material that transmits infrared light. (2) The fiber light guide for infrared light according to claim (1), wherein the optical fiber is made of metal halide. (3) the metal halide is CsBr r CsI,
TtBr. TtI, TLCL, TtBr-TtI, T
The fiber light guide for infrared light according to claim (2), characterized in that the material is selected from the group consisting of LBr-TLCI. (4) The fiber for infrared light according to claim (1), wherein the polymer material is a material selected from the group consisting of polyethylene resin, polystyrene resin, and tetrafluoroethylene resin. light guide.