LV13940B - Laterally radiating/detecting optical fiber and its production method - Google Patents

Abstract

The invention refers to the optic, particularly to the optical signal transmission through the optical fiber end orthogonally to the fiber symmetry axis and can be applied in illumination engineering, phototherapy, fiber-optical endoscopy, laser surgery, optical tomography, optical instrument engineering and in other fields. The proposed laterally radiating/detecting optical fiber with total internal reflection interface oblique about the fiber axis and output/input plain parallel to the fiber axis, characterized in that, the reflecting surface and output/input plain form integrated continuous optical medium with the fiber core end, by filling the space against the reflective surface between output/input plain and cylindrical lateral surface of the core with fiber core material or with similar optically transparent material, at that the distance of the output/input plain from the fiber axis is equal or bigger, then the fiber outer radius. The proposed configuration provides several technical advantages, particularly, smaller size (which is more accessible in use and reduce the optical material consumption), shorter way of the ray bundle from to the fiber core (which assure more precise positioning accuracy of the emitted/detected radiation on the contact surface, as well as enhanced radiation collecting efficiency), solid optical assembly (which excludes radiation refraction during ray bundle deflection, minimize optical losses and assures more safe operation), as well as make it possible to get qualitative optical contact with parallel to the fiber axis contact surface without additional elements.

Description

SIDE-RADIATING / SAVING OPTICAL FIBER AND METHODS OF MANUFACTURING IT

Technical field

The invention relates to fiber optics and more particularly to the transmission of optical signals through the end of an optical fiber to or from the side, i.e. orthogonal to the fiber axis and can be used in lighting, phototherapy, endoscopy, laser surgery, optical tomography, optical instrument construction and other applications.

State of the art

Lateral emitting / detecting optical fibers can be used in a variety of irradiation and optical sensor applications. Such devices have several advantages over conventional radiation input / output through a fiber end perpendicular to the axis. For example, in optical tomography, laser dopplerography, skin spectrometry and many other in-vivo optical diagnostic devices, radiation is often transmitted or collected through optical fibers that are oriented perpendicular to the skin (GB 2132483). Such devices generally perform their purpose well, but optical fiber bands take up a lot of space and are unsafe to operate because of the possibility of optical fiber breakage and other defects due to folding.

Significantly more compact and reliable are devices using radiation-bending fiber optic tips. They are used, for example, in phototherapy and endoscopic laser surgery equipment, and the fibers with such tips are often referred to as "side-firing fibers". Several designs of such tips are known - with a flat flat or convex reflector opposite the fiber end (U.S. Pat. No. 5,366,456); U.S. Patents 5,537,499).

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In such "side-firing" fiber-optic tips, radiation after reflection from the beveled end of the mandrel is partially focused due to refraction through the cylindrical lateral surface of the mandrel. This increases the output power density near the nozzle, giving a positive effect, for example in the case of a laser scalpel. The presence of a cylindrical surface in prior art solutions has a negative effect when the nozzles of said design are used to collect radiation from the side, for example, in contact with a flat skin surface. Much of the injected radiation is then lost as a result of both reflection and refraction.

A probe for measuring blood flow is known (JP 2203838). According to this patent, a transparent polygonal microprism is added to the end of the optical fiber polished perpendicular to the axis of the fiber and the flat surface inclined at an angle of 45 ° serves as a reflector for rotation of the beam at full internal reflection. The fiber end and microprism are mounted in a specially designed nozzle body. Such a design provides a flat radiation input / output surface that provides good optical contact with the skin or other flat surface and significantly reduces optical losses compared to analog solutions. This design is also well suited for lateral emission devices, providing a tapered output beam shape similar to fiber with a traditional, perpendicular to the end. At the same time, the known fiber tip has a rather complex design with three basic elements (fiber optic, microprism and tip housing), labor-intensive fabrication (requires high precision assembly), relatively large size (approximately three times the fiber diameter), and low detection area skin accuracy , since the surface area of the prism lateral inlet is approximately four times the cross - section of the optical fiber core. This is also the reason for the relatively low efficiency of radiation collection - only a small part of the radiation introduced into the prism through the contact surface passes into the fiber core. The drawback is also the relatively high consumption of raw materials for making the prism and nozzle body. The high labor-intensity of manufacturing and the cost of basic components make the device expensive, which in turn limits its widespread use.

It is known to have a fiber optic having a configuration of the output end of the optical signal providing radiation bending and output perpendicular to the longitudinal axis of the optical fiber through the optical surface of the optical fiber outlet end (U.S. Pat. No. 6,856,728). The invention described in the above-mentioned patent also discloses a method of processing optical fiber. This technique includes the steps of removing a portion of the fiber end surface such that the fiber end surface becomes inclined relative to the optical fiber axis; polishing the end surface of an optical fiber to form a profiled surface; and applying a reflective coating to the profiled surface. The disadvantage of the known technique is the presence of a cylindrical side surface, which has a negative effect when a nozzle of such construction is used to collect radiation from the side. In this case, much of the injected radiation is lost both by reflection and refraction.

A laterally radiating optical fiber end structure is known (U.S. Pat. No. 5,772,657), wherein the optical fiber output end has a sloping surface that provides axial beam bending as a result of complete internal reflection transversely to the optical fiber axis. In order to provide divergence of the output beam in a direction perpendicular to the axis, a fiber optic envelope shape has been modified in the region 10 of the radiation outlet by removing a portion of the optical envelope to form a flat, parallel axis axis. However, such an exit surface design does not exclude unwanted refraction on the cylindrical interface of the core / sheath. In practice, this technique is difficult to implement because the optical sheath thickness of multimode optical fibers is usually many times smaller than the core diameter. In order for the optical sheath to have a flat slit width greater than the fiber core diameter (as proposed in the patent), it is necessary to artificially increase the thickness of the optical sheath, which is technologically very difficult. Since the fragment of the flat radiation output surface is located between the outer protective sheath of the fiber and the core, there is always a gap between the fiber output plane and this surface in mechanical contact with the outer flat surface, so that no optical contact occurs. These drawbacks prevent this solution from being effectively used to introduce radiation into the optical fiber from an axis parallel to the outer flat surface, such as skin.

Disclosure of the Invention

The object of the invention is to overcome the drawbacks of analogs, including the creation of a smaller end of a simplified structure of a fiber optic or tip, which provides a higher accuracy of localization of the emitting / receiving area and increases the efficiency of collecting the received radiation.

This object is achieved by providing an end-to-end internal full-surface reflection boundary and a flat, axially parallel radiation output / input plane inclined to the axis of the fiber optic by filling the space between the output / input plane and the cylindrical mandrel side surface with fiber core material or thus integrating the optical monoliths at the end of the fiber core with the reflector and the output / input plane.

a brief description of the drawings

FIG. 1A is an axial sectional view of a prior art end-beam of an optical fiber.

FIG. 1B shows an end section of a prior art side-emitting optical fiber.

FIG. Fig. 2 shows the end structure of a side emitting / receiving optical fiber with an optical signal output / input area.

FIG. 3 illustrates a sequence for manufacturing a laterally emitting / receiving optical fiber according to one embodiment of the invention.

FIG. 4 illustrates a manufacturing order for a side emitting / receiving optical fiber according to a second embodiment of the invention.

FIG. 5 illustrates a sequence for manufacturing a laterally emitting / receiving optical fiber according to a third embodiment of the invention.

FIG. 6 illustrates a method for manufacturing a lateral emitting / receiving optical fiber according to the fourth embodiment of the invention.

FIG. 7 illustrates a method for manufacturing a lateral emitting / receiving optical fiber according to the fifth embodiment of the invention.

FIG. Figure 8 illustrates a method of manufacturing a side emitting / perceptual optical fiber that provides attachment of a separately manufactured sleeve to the end of the optical fiber.

In order to achieve this object, the construction illustrated in FIG. 2. Radiation deflection at the end of the optical fiber is achieved by integrated full internal reflection, with the addition of a smooth flat inlet / outlet side surface 10 parallel to the axis of symmetry of the fiber. The end surface 20 of the core cleaned of the outer casing shall be inclined such that at all points its angle of reference to the axis of symmetry of the surface is greater than the angles of full internal reflection are sin (nj / nfi where ni and « ₂ are The surfaces 10 and 20 are smoothly polished to prevent radiation scattering.The area of the space between the surfaces 10 and 20, which is outside the cylindrical side surface of the core, is completely filled with core material or other translucent material with a refractive index of n; The area of the inlet / outlet surface 10 is proportional to the cross-sectional area of the optical fiber core 30, but its distance to the axis of the fiber is equal to or greater than the radius R of the outer sheath of the fiber.

The integrated structure of the two optical surfaces at the fiber end thus performs its function well without any additional elements.

Depending on the technical capabilities and the materials of the fiber optic core and casing, several methods of realizing this constructive solution are offered. They all provide a homogeneous space filling between work surfaces 10 and 20 with optically transparent material.

FIG. 3 illustrates a method for manufacturing a lateral emitting / sensing optical fiber which provides for the extension of the optical fiber end with subsequent grinding and / or polishing. This technique is applicable, for example, to optical fibers with a glass core, including S1O2 glass core. The core is cleaned of its sheaths close to the end of the fiber, for example 3 cm long. Next, a fiber end extension is formed in the form of a sphere or a similar shape having a diameter greater than the core diameter, for example by melting the core material with a gas burner. The two opposite edges of the extension are sanded / polished parallel to each other so that they are parallel to the fiber axis and equal (approximately the radius of the optical fiber core). Perpendicular to these planes, incline / polish the internal reflecting surface 20 so that it passes through the cylindrical surface of the core at the point where the extension begins. The remainder of the untreated extension is sanded / polished perpendicular to both side edges and parallel to the fiber axis at a distance> Rno to form an inlet / outlet surface 10. Alternatively, the end extension of the mandrel is made of another optically transparent material with an appropriate refractive index, e.g. optical polymer.

FIG. 4 illustrates a method for manufacturing a lateral emitting / perceptual optical fiber, wherein the portion of the fiber optic core is superimposed near the tip opposite to the inclined polished reflecting surface with subsequent polishing and / or polishing. This technique involves filling the space between the inlet / outlet plane 10 and the cylindrical side surface of the core opposite to it by either additionally supplied material of the core itself or other transparent material with an appropriate refractive index, such as an optical polymer or optical glue. For the manufacture of lateral emitting / perceptual optical fibers, according to the proposed process, the core is cleaned from the sheaths near the end of the fiber, e.g., 1 cm. Internal reflecting surface 20 inclined / polished. Opposite to the surface 20, behind the lateral surface of the core, the corresponding material is expanded into the width of the core, for example by pouring a liquid optical polymer or glue into a pre-formed limiting form. Providing additional hardening of the applied material, for example by heating or polymerizing with UV light, provides good optical contact with the cylindrical side surface of the core. Further, the cured filler is mechanically treated, including grinding / polishing parallel to the fiber axis to form an inlet / outlet surface 10. A modification of this technique is also possible, using a non-hardening immersion liquid in the vessel during the extension phase of the mandrel. flat transparent I / O window.

FIG. 5 illustrates a method for manufacturing a lateral emitting / perceptual optical fiber that involves thermoforming the end of the optical fiber by pressure. This technique is suitable for the processing of optical fiber ends made of plastic, easily meltable materials such as polymeric optical fibers. Compared to the previous two, it is more economical in terms of reducing manual labor, automating mass production and reducing material wastage. For producing the lateral emitting / sensing optical fiber, a thermal mold with an inner cavity according to the embodiment of FIG. 2 for the form shown. The core is cleaned of its sheaths close to the fiber end, for example 1 cm long. The cleaned end of the fiber is introduced into a thermal die. By raising the temperature of the mold and pressing the fiber end in the axial direction accordingly, it is melted and given the desired shape. Further, the die is cooled to the curing temperature of the core material and the end of the modified die core is released from the die.

FIG. 6 illustrates a method of manufacturing a lateral emitting / perceptual optical fiber using a portion of the fiber itself (with a flat polished end perpendicular to the axis of the fiber) to fill the space between the two working planes. The technique involves making a flat cut of the cleaned fiber core at an angle to the fiber axis near the end, for example at an angle of 45 °. After polishing and / or other processing of both cut surfaces, where necessary to provide good optical contact, the severed end piece is rotated 180 ° about an axis perpendicular to the cut plane and again attached to the beveled fiber end, e.g., by gluing with an optical glue. The end reflecting plane 20 is then inclined and polished to an axis according to Figs. 2 illustrates the fiber end structure.

FIG. 7 illustrates a method of manufacturing a side emitting / perceptual optical fiber that provides an inclined reflecting surface at the end of the fiber 20 (e.g., by grinding and polishing) and attaching (e.g., using an optical glue) a portion of a translucent material with an appropriate refraction. factor. The shape of this part is the one occupied by the additional material provided

FIG. 4. This technique is more suitable for mass production.

FIG. Figure 8 illustrates a method of manufacturing a side emitting / perceptual optical fiber that provides attachment of a separately manufactured sleeve to the end of the optical fiber. This technique of forming both surfaces 10 and 20 as a monolithic integral element in the fiber core coaxial sleeve is technologically advantageous for mass production. According to the proposed method, a sleeve of transparent material with the end shape shown in Fig. 2 is fabricated, for example, using an appropriately designed thermal optical polymer mold. Next, clean the fiber core near its flat (perpendicular to the axis) end at a distance and attach the coupling to the end of the optical fiber, for example, using optical glue.

Thus, unlike known technical solutions, the following technical advantages are provided:

- smaller side-emitting / perceptual optical fiber size, which is more convenient to use and reduces the use of optical materials,

- a shorter path of radiation propagation between the fiber core and the input / output plane, which provides a more accurate localization of the incoming / perceived radiation at the contact surface, such as the skin, and increases the efficiency of radiation collection,

- a monolithic optical design that eliminates refraction during the bending process, minimizes optical losses and is more reliable in operation,

- the ability to create a high-quality optical contact directly from the mechanical contact with the contact surface parallel to the fiber axis without any additional elements.

Claims (8)

Claims 1. Side-emitting / perception optical fiber having a biased end-to-end full internal reflectivity surface and a parallel axis output / input 5, characterized in that the reflecting surface and the outlet / inlet plane are optically monolithic at the end of the integrated fiber core, filling the space opposite the reflecting surface between the outlet / inlet plane and the cylindrical side surface of the fiber core material or the like. 10th A side emitting / receiving optical fiber according to claim 1, characterized in that the output / input plane is disposed at an outer radius of the optical fiber or at a greater distance from the fiber axis. A method for making an optical fiber according to claim 1 or 2, comprising 15 extending the end of the previously cleaned fiber optic core, for example, by melting it into a sphere having a diameter greater than the diameter of the core, and forming this extension in an appropriate form, such as by grinding and / or polishing. 20th A method for making an optical fiber according to claim 1 or 2, comprising forming a full internal reflection boundary surface at the end of a previously cleaned optical fiber core, for example by polishing it obliquely to the fiber axis, adding an opaque material from the outside to the cylindrical side surface the reflective boundary surface and the flat inlet / outlet surfaces of the material being supplied 25, for example, by grinding and / or polishing. A process for the manufacture of an optical fiber according to claim 1 or 2, which comprises melting and curing the core material under pressure in a matrix of a corresponding shape to form an optical fiber core end, 30, for example, in a polymer thermoforming mold. A method for making an optical fiber according to claim 1 or 2, wherein the space between the two working surfaces is filled with a portion of the fiber core itself pre-separated by a flat cut near the end, inclined at an angle of, e.g., 45 °, and rotated 180 ° about an axis perpendicular to the plane of cut, reconnected to the oblique end of the fiber, for example by gluing with an optical glue, followed by the formation of a full internal reflecting surface of the end, e.g. 5 polishing inclined to fiber axis. A method for producing an optical fiber according to claim 1 or 2, which, after forming a full internal reflection boundary surface of the core end, for example by polishing it obliquely to the fiber axis, opposes this boundary to the side of the cylindrical core. 10 surfaces are attached, for example, an adhesive optical element of a homogeneous transparent material having a shape corresponding to the shape of the added optical material of claim 4 and an appropriate refractive index. A method for making an optical fiber according to claim 1 or 2, wherein: The 15 reflective and exit / entry surfaces are monolithic integrated fiber core coaxial sleeve made of a transparent material with an appropriate refractive index and attached to a flat, perpendicular to the fiber axis oriented end, for example, by means of optical glue.