JPS59111606A - Fiber transmission line - Google Patents

Abstract

PURPOSE:To save space and simplify a supporting structure and to eliminate the need for an optical coupling system for both visible light and far infrared light by transmitting the visible light and far infrared light through one linear fiber transmission line. CONSTITUTION:Four fibers 6 for visible light are stranded around a fiber 3 for far infrared light and they are covered with a sheath 11 for protecting them. The far infrared light is incident to the fiber 3 and propagates therein. Visible light propagates in the four fibers 6 respectively. Therefore, both lights propagate coaxially. The position of the far infrared light which can not be seen is confirmed by the visible light. When the visible light projected from the fibers 6 is converged toward the center of a quadrate, its convergence point coincides with the position of the far infrared light, confirming the position of the far infrared light securely.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a fiber transmission line, and more particularly to a fiber transmission line including a far-infrared fiber and a visible light fiber.

Description of Prior Art Recently, there has been an increase in the number of laser scalpels and laser processing devices that transmit far-infrared light through fibers. However, since far-infrared light is invisible to the human eye, the direction and position of the laser cannot be determined, which poses a problem. To prevent this, a visible guide light is emitted coaxially with the far-infrared laser, and this is used as a clue to confirm the position of the far-infrared laser. Therefore, as described above, in a device that uses far-infrared light, it is necessary to transmit visible light in addition to far-infrared light. Silver halide, alkali halide, and thallium halide fibers are used as far-infrared fibers, but these fibers have poor transmittance for visible light and large light losses.
Usually, a quartz fiber or a plastic fiber is used as a fiber for visible light to transmit it separately from far-infrared light.

FIG. 1 is a schematic diagram of such a conventional fiber transmission line.

In FIG. 1, far-infrared light 1 having high energy and used for laser scalpels, laser processing, etc. is focused by a lens 2 and enters a far-infrared light fiber 3. The far-infrared light 1 is transmitted via the far-infrared fiber 3. On the other hand, visible light 4 is focused by lens 5 and enters visible light fiber 6 . Visible light 4 is transmitted via visible light fiber 6 . In this way, it is preferable that far-infrared light and visible light are sent separately through fibers made of materials suitable for each, as described above, because of their different wavelengths.

Far-infrared light 1 and visible light 4 exit from respective fibers 3 and 6 and are emitted coaxially by coupling optical system 7. The far-infrared light 1 and visible light 4 thus emitted are used for work while confirming the direction of the far-infrared light 1 using the visible light 4.

However, in the above configuration, since two separate fiber transmission lines are used, the mechanism for supporting the fiber transmission lines becomes complicated. Further, since the visible light 4 and the far-infrared light 1 are transmitted with different optical axes, a coupling optical system 7 is required at the output end of each fiber, making the output end large and complicated. This is extremely disadvantageous when considering applications such as laser scalpels and fine processing. Furthermore, fibers suitable for far-infrared light are
Mechanical strength is poor, for example, the tensile strength of metal halide fiber for far infrared light is about 1 to 3 Ki11/
+11112, so a protection II layer and a reinforcing layer are required.

OBJECTS OF THE INVENTION An object of the present invention is to provide a fiber transmission line that eliminates the above-mentioned drawbacks.

In summary, this invention includes a visible light fiber installed outside a far infrared light fiber, and a sheath provided roughly outside the far infrared light fiber and the visible light fiber. , is a fiber transmission line formed into a single linear body.

DESCRIPTION OF THE EMBODIMENTS FIG. 2 is a partially cutaway perspective view showing an embodiment of the fiber transmission line of the present invention.

Four visible light fibers 6 are braided and provided around the far-infrared light fiber 3. Further, a sheath 11 is provided around the far-infrared fiber 3 and the visible light fiber 6 to protect them. In this way, the far-infrared fiber 3 and the visible light fiber 6 are
It is made into one linear body.

The use of the fiber transmission line configured as described above will be described. Far-infrared light enters the far-infrared light fiber 3,
propagate through it. Further, visible light is incident on each of the four visible light fibers 6 and propagated therein. Therefore, as shown in FIG. 2, due to the configuration of the far-infrared light fiber 3 and the visible light fiber 6, far-infrared light and visible light propagate coaxially. The far-infrared light propagated in this way is emitted from the far-infrared fiber 3, and
Used for laser scalpels and micro-processing.

However, as described above, the far-infrared light is invisible, so the position of the far-infrared light can be confirmed by the visible light propagated through the visible light fiber 6.

That is, in this example, the far-infrared light emitted from the far-infrared fiber 5 - the far-infrared light emitted from the external light fiber 3 is reflected by the four visible light fibers emitted in the same direction from the four visible light fibers 6 located on a concentric circle around it. be surrounded by beams of light. Therefore, it can be seen that the center of far-infrared light is located at the center of the square formed by the four visible light centers. This allows the position of the far-infrared light to be easily confirmed and the work to be carried out without any trouble. Note that if the visible light emitted from the visible light fiber 6 is focused toward the center of the square as described above, the focusing point will match the position of the far-infrared light, and the position of the far-infrared light will be reliably determined. You can check it.

FIG. 3 is a partially cut away perspective view of another embodiment of the invention. In this example, 4
A book fiber 6 for visible light is wound in a spiral, and a sheath 11 is provided on top of the fiber 6 for visible light.

As the material of the far-infrared light fiber 3 of the fiber transmission line configured as described above, for example, A! J.C.Q.

Silver halides such as AQ Br and mixed crystals thereof,
KH2-5, KH2-6, TllBrnato (7) Evening 1
．． Possible examples include those using alkali halides such as J'76-muhalide and CsBr. Further, the structure of the far-infrared fiber 3 is a loose clad type, or a step index type in which a core is made of a material with a high refractive index and a cladding is made of a material with a low refractive index among the above-mentioned materials. etc. are possible.

On the other hand, visible light fiber including core and cladding is
Possible materials include plastic or quartz. Since plastic fibers are extremely flexible, they can be braided and provided around the far-infrared fiber 3 as shown in the example shown in FIG. In addition, plastic fibers have high tensile strength (approximately 1
0K (1/n+m') and has a low tensile strength, it functions satisfactorily as a reinforcing layer for the far-infrared fiber 3. Although quartz fiber has little flexibility, it has a very high tensile strength (approximately 300 Ω/ll2), and for example, by winding it spirally around a far-infrared fiber 3 as shown in FIG. , fully functions as a reinforcing layer.

Note that if a material such as plastic whose refractive index is lower than the refractive index of the core material of the visible light fiber is used as the material of the sheath, the cladding of the visible light fiber becomes unnecessary.

In the above embodiment, four visible light fibers 6 are used, but the present invention is not limited to this. Moreover, the visible light fiber 6 may be directly provided around the far-infrared light fiber 3, or a protective layer may be provided around the far-infrared light fiber 3 and provided thereon.

According to this invention, visible light and far-infrared light are transmitted through a single fiber transmission line, so two independent fibers can be used. It takes up less space than if it were used, and the mechanism for supporting the transmission line becomes simpler. In addition, since visible light and far-infrared light are transmitted coaxially, there is no need for an optical system to combine these lights at the output end of the fiber transmission line, and the output end can be made extremely compact. It is advantageous for applications such as laser scalpels and fine processing. Furthermore, the visible light fiber provided around the far-infrared fiber can be made of a material that is particularly resistant to tension, and can serve as a very good reinforcing layer for the far-infrared fiber.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram showing an example of a conventional fiber transmission line. FIG. 2 is a partially cutaway view of one embodiment of the present invention. FIG. 3 is a partially cut away perspective view of another embodiment of the invention. In the figure, 3 is a fiber for infrared light, 6 is a fiber for visible light, and 11 does not show a sheath. 9-

Claims (3)

[Claims] (1) A visible light fiber is numbered on the outside of the far infrared light fiber, and a sheath is provided on the outside of the far infrared light fiber and the visible light fiber, so that one A fiber transmission line made into a linear body. (2) The fiber transmission line according to claim 1, wherein the visible light fiber is braided around the far infrared light fiber. (3) The fiber transmission line according to claim 1, wherein the visible light fiber is spirally wound around the far-infrared light fiber.