JP2018134117A - Optical fiber bundle and lighting device for endoscope using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical fiber bundle that reduces unevenness of lighting used for a lighting device for an endoscope.SOLUTION: A lighting device 10 for an endoscope includes an LED light source 50 having a rectangular light emitting surface 52 formed in a roughly flat surface, and an optical fiber bundle 30 for guiding the light emitted from the LED light source 50 to the tip of an insertion part provided to the endoscope. The optical fiber bundle 30 is configured by bundling a large number of optical fibers 32. The optical fiber bundle 30 is configured so that the contour of the array of the large number of optical fibers 32 on an incident side end face 42 disposed facing the light emitting surface 52 of the LED light source 50 is formed in a round corner rectangle.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an illumination device for an endoscope using an optical fiber bundle.

  As an illumination device for an endoscope, one using an optical fiber bundle is known. In such an illuminating device, in order to obtain a sufficient amount of light using the LED light source, the end face of the optical fiber bundle is arranged to face the light emitting surface of the LED light source, and the optical fiber bundle It is desirable that the outline of the arrangement of the many optical fibers has the same shape and size as the outline of the light emitting surface of the LED light source.

  An example of an optical fiber bundle that meets this purpose is disclosed in, for example, Japanese Patent Laid-Open No. 2001-343536.

JP 2001-343536 A

  In illumination for an endoscope, in addition to a sufficient amount of light, it is required that there is no illumination unevenness, which is one of the factors that degrade the observation performance of the endoscope.

  However, in an illumination device for an endoscope using the optical fiber bundle configured as described above, although a sufficient amount of light is obtained, the illumination is uneven, and further improvement is desired. ing.

  An object of the present invention is directed to improving illumination for an endoscope, and is to provide an optical fiber bundle that reduces the occurrence of illumination unevenness used in an illumination device for an endoscope.

  The present invention is an optical fiber bundle configured by bundling a large number of optical fibers, and the outline of the arrangement of the large number of optical fibers on one end face is formed in a rounded square shape.

  ADVANTAGE OF THE INVENTION According to this invention, the optical fiber bundle which reduces generation | occurrence | production of the nonuniformity of the illumination used for the illuminating device for endoscopes is provided.

FIG. 1 shows an embodiment of an illumination device for an endoscope. FIG. 2 shows an example (square lattice arrangement pattern) of multiple optical fibers on the incident side end face of the optical bundle fiber of FIG. FIG. 3 shows another example (hexagonal lattice arrangement pattern) of the arrangement pattern of many optical fibers on the incident side end face of the optical bundle fiber of FIG. FIG. 4 shows still another example (honeycomb structure arrangement pattern) of an arrangement pattern of many optical fibers on the incident side end face of the optical bundle fiber of FIG. FIG. 5 schematically shows the luminance distribution on the light emitting surface of the LED light source. FIG. 6 shows an LED light source surrounded by an alternate long and short dash line square shown in FIG. 5 on the optical fiber bundle of the square lattice arrangement pattern shown in FIG. 2 of the optical fiber bundle in accordance with the conventional idea. The upper left corner of the light emitting surface is shown enlarged. FIG. 7 is a diagram of an LED light source surrounded by a one-dot chain line square shown in FIG. 5 superimposed on the optical fiber array of the hexagonal lattice arrangement pattern shown in FIG. 3 of the optical fiber bundle in accordance with the conventional idea. The upper left corner of the light emitting surface is shown enlarged. FIG. 8 is a diagram of an LED light source surrounded by an alternate long and short dash line square shown in FIG. 5 overlaid on the optical fiber array of the honeycomb structure arrangement pattern shown in FIG. 4 of the optical fiber bundle in accordance with the conventional idea. The upper left corner of the light emitting surface is shown enlarged. FIG. 9 schematically shows an incident side end of the optical fiber bundle according to the embodiment. FIG. 10 schematically shows an incident side end of an optical fiber bundle according to another embodiment. FIG. 11 shows an enlarged incident side end face of the optical fiber bundle shown in FIG. FIG. 12 shows an LED light source surrounded by a dot-and-dash line square shown in FIG. 5 so as to be superimposed on an array of a plurality of optical fibers of the square lattice arrangement pattern shown in FIG. 2 of the optical fiber bundle according to the present embodiment. The upper left corner of the light emitting surface is shown enlarged. FIG. 13 is a diagram of the LED light source surrounded by the one-dot chain line square shown in FIG. 5 superimposed on the array of many optical fibers of the hexagonal lattice arrangement pattern shown in FIG. 3 of the optical fiber bundle according to the present embodiment. The upper left corner of the light emitting surface is shown enlarged. FIG. 14 shows an LED light source surrounded by a dot-and-dash line square shown in FIG. 5 so as to overlap with an arrangement of a plurality of optical fibers of the honeycomb structure arrangement pattern shown in FIG. 4 of the optical fiber bundle according to the present embodiment. The upper left corner of the light emitting surface is shown enlarged.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows an embodiment of an illumination device 10 for an endoscope (not shown). As shown in FIG. 1, the endoscope illumination apparatus 10 includes an LED light source 50 having a rectangular light emitting surface 52 formed in a substantially flat surface and light emitted from the LED light source 50 in the endoscope. The optical fiber bundle 30 led to the distal end portion of the inserted portion is provided.

  The optical fiber bundle 30 is configured by bundling a large number of optical fibers 32, and the large number of optical fibers 32 are accommodated inside a protective tube 34. One end portion of the optical fiber bundle 30 is disposed near the LED light source 50, and the other end portion is disposed at a distal end portion of an insertion portion provided in the endoscope. Hereinafter, the end portion of the optical fiber bundle 30 disposed near the LED light source 50 is referred to as an incident side end portion, and the end portion of the optical fiber bundle 30 disposed at the distal end portion of the insertion portion provided in the endoscope is referred to as an end portion. It will be called the exit side end. In addition, the end surface of the incident side end portion of the optical fiber bundle 30 is referred to as an incident side end surface, and the end surface of the emission side end portion of the optical fiber bundle 30 is referred to as an emission side end surface.

  A sleeve 36 surrounding a large number of optical fibers 32 is provided at the incident side end of the optical fiber bundle 30. The sleeve 36 defines the pattern and contour of the arrangement of a large number of optical fibers 32 on the incident side end face 42 of the optical fiber bundle 30. Further, a sleeve 38 surrounding a large number of optical fibers 32 is provided at the exit end of the optical fiber bundle 30. The sleeve 38 defines the pattern and contour of the arrangement of a large number of optical fibers 32 on the exit side end face 44 of the optical fiber bundle 30. The sleeves 36 and 38 are not disposed inside the protective tube 34.

  The incident side end face 42 of the optical fiber bundle 30 is disposed to face the light emitting face 52 of the LED light source 50. In one example, the incident side end face 42 of the optical fiber bundle 30 may be arranged in parallel to the light emitting surface 52 with a slight gap from the light emitting surface 52 of the LED light source 50. In another example, the incident side end surface 42 of the optical fiber bundle 30 may be disposed in contact with the light emitting surface 52 of the LED light source 50.

  For example, as shown in FIG. 2, the end faces of all the optical fibers 32 may be arranged in a square lattice pattern. Hereinafter, such an arrangement pattern is referred to as a square lattice arrangement pattern for convenience.

  In another example, as shown in FIG. 3, the multiple optical fibers 32 may be arranged such that the end faces of all the optical fibers 32 are most dense on a plane, that is, in a hexagonal lattice pattern. Hereinafter, such an arrangement pattern is referred to as a hexagonal lattice arrangement pattern for convenience.

  In another example, the multiple optical fibers 32 may be arranged in a honeycomb structure as shown in FIG. Hereinafter, such an arrangement pattern is referred to as a honeycomb structure arrangement pattern for convenience. The optical fiber bundle 30 having such a honeycomb structure array can be manufactured, for example, by heating and melting a large number of optical fibers 32 arrayed in a hexagonal lattice array.

  In the endoscope illumination device 10 shown in FIG. 1, the light emitted from the LED light source 50 enters a large number of optical fibers 32 through the incident side end face 42 of the optical fiber bundle 30. The light that has entered a large number of optical fibers 32 is guided to the distal end portion of the insertion portion provided in the endoscope by the optical fibers 32, is emitted from the emission side end face 44 of the optical fiber bundle 30, and is provided in the endoscope. The periphery of the distal end portion of the insertion portion, for example, the front of the distal end portion of the insertion portion is illuminated.

The inventors of the present invention have noticed that the luminance distribution of the light emitting surface 52 is uneven in the LED light source 50 generally used in such an endoscope illumination device 10. FIG. 5 schematically shows the luminance distribution on the light emitting surface 52 of the LED light source 50. As shown in FIG. 5, the light emitting surface 52 of the LED light source 50 may be divided into three regions, a central region A ₁ , a peripheral region A _2, and a corner region A ₃ , according to the light emission luminance. Each region of the center region A ₁ and the surrounding area A ₂ and the corner area A ₃ may be considered to be substantially uniform brightness. In FIG. 5, L ₁ indicates the boundary line of the outline of the central area A ₁ , L ₂ indicates the boundary line of the outline of the surrounding area A ₂ , and L ₅₂ indicates the light emitting surface of the LED light source 50. 52 shows the boundary lines of the contours.

The central region A ₁ is a region located at the center of the light emitting surface 52 and has a shape similar to the shape of the light emitting surface 52. The corner region A ₃ is a region located at the four corners of the light emitting surface 52, and each corner region A ₃ has a shape obtained by cutting a 90-degree sector having a radius equal to the length of one side from a square. doing. Surrounding region A ₂ is an area which is located around the central area A _1, the light-emitting surface 52 has a shape obtained by cutting the central region A ₁ and the four corners region A _3.

Central area _{A 1} of the light emitting surface 52 of the LED light source 50 indicating the highest luminance. To 100% the brightness of the central area _{A 1} as a reference for relative evaluation. The luminance when no light is emitted is set to 0%. In contrast, in the peripheral region A ₂ of the light emitting surface 52 located outside the central region A _1, the luminance is about 80%. In contrast, in the corner area _{A 3} located at the four corners of the light-emitting surface 52 of the LED light source 50, the luminance is at most about 20%.

The area ratio of the center region _{A 1} and the surrounding area _{A 2} and the corner area _{A 3,} for example, the central region _{A 1} is about 60% of the area of the light emitting surface 52, peripheral region _{A 2} is the area of the light emitting surface 52 About 38%, the corner area A ₃ may be about 2% of the area of the light emitting surface 52.

In FIG. 5, the light emitted from the central area A ₁ is most suitable as illumination light, and the light emitted from the surrounding area A ₂ is not so inferior in brightness as the light emitted from the central area A ₁ . It may be used well as illumination light. Hereinafter, if necessary, to fit a central region A ₁ and the peripheral region A ₂ is referred to as the effective light emission region A _12. In contrast, light emitted from the corner area A _3, compared to the light emitted from the effective light emitting area A ₁₂ for extremely low luminance is not worthy of use as illuminating light. The reason is as follows.

In the optical fiber bundle 30, a large number of optical fibers 32 are accommodated in the protective tube 34 and then fixed to the sleeves 36 and 38 at the incident side end face 42 and the emission side end face 44. Many optical fibers 32 accommodated in the protection tube 34 are twisted or shifted in the protection tube 34. Therefore, when the multiple optical fibers 32 are fixed to the sleeves 36 and 38, the positions of the multiple optical fibers 32 on the incident side end face 42 are the same as the positions of the multiple optical fibers 32 on the exit side end face 44. Are generally different. That is, the arrangement pattern of the many optical fibers 32 on the incident side end face 42 is not held over the entire length of the optical fiber bundle 30. Therefore, if the optical fiber 32 facing the corner region A ₃ are distributed in different parts of the exit end face 44, the emission-side end face 44 of the optical fiber bundle 30, a collection of bright light-emitting point A luminance distribution is generated in which dark light emitting points are sparsely present. Such a luminance distribution causes unevenness in illumination.

  FIG. 5 shows an example of an LED light source having a square light emitting surface. However, in the case of an LED light source having a rectangular light emitting surface, the shape of the light emitting surface is changed to a rectangle, and similarly, only the corner regions at the four corners are used. It was confirmed that the brightness was remarkably lowered at.

  Further, FIG. 5 shows the luminance distribution of a single LED light source, but even in a configuration in which a plurality of LED light sources are arranged in a matrix, in the entire composite light emitting region constituted by a plurality of LED light sources, Similar to the single light-emitting area of a single LED light source, it was confirmed that the luminance was significantly reduced only in the corner areas of the four corners.

  In the illuminating device 10 shown in FIG. 1, the shape and size of the outline of the array of the many optical fibers 32 on the incident side end face 42 of the optical fiber bundle 30 are the same as the shape and size of the light emitting surface 52 of the LED light source 50 so far. It was thought that it was good to agree with. 6, 7, and 8 show the light emission of the LED light source 50 that is superimposed on the array of the many optical fibers 32 of the optical fiber bundle 30 in accordance with this idea and that is surrounded by the dashed-dotted square shown in FIG. 5. The upper left corner of the surface is shown enlarged. 6 shows an arrangement of a large number of optical fibers 32 in the square lattice arrangement pattern shown in FIG. 2, and FIG. 7 shows an arrangement of a large number of optical fibers 32 in the hexagonal lattice arrangement pattern shown in FIG. FIG. 8 shows an arrangement of a large number of optical fibers 32 in the honeycomb structure arrangement pattern shown in FIG.

6, 7, and 8, in any of the examples shown in the drawings, the optical fiber bundle 30 includes the boundary line L ₅₂ of the contour of the light emitting surface 52 of the LED light source 50 and the contour of the surrounding area A ₂ . It is understood that a large number of optical fibers 32 facing the region surrounded by the boundary line L ₂ (that is, the corner region A ₃ ) are included. Such an optical fiber bundle 30 causes unevenness in illumination by light emitted from the emission side end face 44 of the optical fiber bundle 30 for the reason described above.

  9 and 10 schematically show the incident side end of the optical fiber bundle 30 in the illumination device 10 of the present embodiment. In the illumination device 10 according to the present embodiment, as shown in FIGS. 9 and 10, the optical fiber bundle 30 has an outline of an array of a large number of optical fibers 32 on the incident side end face 42 formed in a rounded square shape. For example, for a configuration in which the LED light source 50 has a square light emitting surface 52, the optical fiber bundle 30 has an outline of an array of a plurality of optical fibers 32 on the incident side end surface 42, as shown in FIG. Is formed in a rounded square. For the configuration in which the LED light source 50 has a rectangular light emitting surface 52, the optical fiber bundle 30 has an outline of an arrangement of a large number of optical fibers 32 on the incident side end surface 42 as shown in FIG. Is formed in a rounded rectangle.

  FIG. 11 shows the incident side end face of the optical fiber bundle 30 shown in FIG. 9 in an enlarged manner. 12, 13, and 14 are superimposed on the array of a plurality of optical fibers 32 of the optical fiber bundle 30 according to the present embodiment, and the LED light source 50 surrounded by a one-dot chain line square shown in FIG. 5. The upper left corner of the light emitting surface is shown enlarged. 12 shows an arrangement of a large number of optical fibers 32 in the square lattice arrangement pattern shown in FIG. 2, and FIG. 13 shows an arrangement of a large number of optical fibers 32 in the hexagonal lattice arrangement pattern shown in FIG. FIG. 14 shows an arrangement of a large number of optical fibers 32 in the honeycomb structure arrangement pattern shown in FIG.

12, 13, and 14, the arrangement of the multiple optical fibers 32 of the optical fiber bundle 30 according to the present embodiment is located inside the boundary line L ₂ of the outline of the surrounding area A ₂ , do not overlap in the corner region _{a 3} surrounded by the boundary line _{L 2} of the contour of the boundary line _{L 52} of the contour of the light-emitting surface 52 surrounding region _{a 2} of the LED light source 50. That is, all of the many optical fibers 32 of the optical fiber bundle 30 according to the present embodiment are opposed to the effective light emitting region A ₁₂ of the light emitting surface 52 of the LED light source 50. In other words, the optical fiber bundle 30 according to the present embodiment does not include any optical fiber facing the corner region A ₃ of the light emitting surface 52 of the LED light source 50.

Also if capture from a different point of view, the shape and size of the large number of sequences of optical fibers 32 at the incident side end surface 42 of the optical fiber bundle 30, the shape of the effective light emitting area A ₁₂ of the light emitting surface 52 of the LED light source 50 and the size It can be said that the same. Thus, many areas of the contour of the array of optical fiber 32 at the incident side end surface 42 of the optical fiber bundle 30 is substantially equal to a value obtained by subtracting the area of the corner area A ₃ from the area of the light emitting surface 52 of the LED light source 50.

  For this reason, the unevenness resulting from the reason mentioned above does not occur in the illumination by the light emitted from the emission side end face 44 of the optical fiber bundle 30.

  Below, the result of conducting an experiment in which light emitted from the light emitting surface 52 of the LED light source 50 is guided to the distal end portion of the insertion portion provided in the endoscope by the optical fiber bundle 30 under some conditions is shown. . In the experiment, an optical fiber bundle 30 having optical fibers 32 having a hexagonal lattice arrangement pattern was used, and the difference in the result with respect to the difference in the radius of the corner of the contour of the optical fiber 32 was evaluated. The evaluation of the experimental results was performed based on the quality of the brightness and the quality of the illumination unevenness.

  Table 1 below shows the outline of the arrangement of the optical fibers 32 of the optical fiber bundle 30 with respect to the LED light source 50 having the light emitting surface 52 of 3 mm × 3 mm in a rounded square shape with a side a = 3 mm. R0.05 (radius 0.05mm) at the corner, R0.1 (radius 0.1mm) at the corner, R0.5 (radius 0.5mm) at the corner, R0.8 (radius 0.8mm) at the corner ) Shows the results for each of the above.

  From Table 1, the following can be said. The brightness is good in the range of R0.05 to R0.5, but the brightness is insufficient in R0.8. On the other hand, in the range of R0.1 to R0.8, the illumination is not uneven, but in R0.05, the illumination is uneven.

  Table 2 below shows the outline of the arrangement of the optical fibers 32 of the optical fiber bundle 30 with respect to the LED light source 50 having the light emitting surface 52 of 5 mm × 5 mm in a rounded square shape with a side a = 5 mm. About corner R0.1 (radius 0.1mm), corner R0.2 (radius 0.2mm), corner R0.8 (radius 0.8mm), corner R1 (radius 1mm) Shows the results.

  From Table 2, the following can be said. The brightness is good in the range of R0.1 to R0.8, but the brightness is insufficient in R1. On the other hand, in the range of R0.2 to R1, there is no unevenness in illumination, but in R0.1, unevenness in illumination occurs.

  In Table 3 below, the outline of the arrangement of the optical fibers 32 of the optical fiber bundle 30 with respect to the LED light source 50 having the light emitting surface 52 of 3 mm × 5 mm has a short side a = 3 mm and a long side b = 5 mm. R0.05 (radius 0.05 mm) at the corner, R0.1 (radius 0.1 mm) at the corner, R0.5 (radius 0.5 mm) at the corner, R0 at the corner .8 (radius 0.8 mm) and corner R1 (radius 1 mm).

  From Table 3, the following can be said. The brightness is good in the range of R0.05 to R0.5, but the brightness is insufficient in R0.8. On the other hand, in the range of R0.1 to R0.8, the illumination is not uneven, but in R0.05, the illumination is uneven.

From the above, it can be considered as follows. If the radius of the corners of the contour of the array of optical fibers 32 of the optical fiber bundle 30 is too large, the brightness in the light utilization emitted from the effective light emitting area A ₁₂ of the light emitting surface 52 of the LED light source 50 is reduced Shortage occurs. Enters Conversely, if the radius of the corners of the contour of the array of optical fibers 32 of the optical fiber bundle 30 is too small, the light emitted from the corner area A ₃ of the light emitting surface 52 of the LED light source 50 to the optical fiber bundle 30 As a result, illumination is uneven.

Thus, the radius of the corners of the contour of the array of optical fibers 32 of the optical fiber bundle 30 is set to a suitable value in accordance with the size and shape of the effective light emitting area A ₁₂ of the light emitting surface 52 of the LED light source 50 to be used It is considered good.

  For example, the radius of the corner of a rounded square is a / 30 to a with respect to the length a of one side, and the radius of the corner of a rounded rectangle is a length a of the short side. It is good to set to the range of / 6.

  The embodiments of the present invention have been described above with reference to the drawings. However, the present invention is not limited to these embodiments, and various modifications and changes can be made without departing from the scope of the present invention. Also good.

DESCRIPTION OF SYMBOLS 10 ... Illuminating device, 30 ... Optical fiber bundle, 32 ... Optical fiber, 34 ... Protection tube, 36 ... Sleeve, 38 ... Sleeve, 42 ... Incident side end surface, 44 ... Emission side end surface, 50 ... LED light source, 52 ... Light emitting surface , A ₁ ... central area, A ₂ ... surrounding area, A ₁₂ ... effective light-emitting area, A ₃ ... corner area, L ₂ ... boundary line, L ₅₂ ... boundary line.

Claims (10)

  An optical fiber bundle configured by bundling a plurality of optical fibers, wherein an outline of the array of the plurality of optical fibers on one end face is formed in a rounded square shape.   The optical fiber bundle according to claim 1, wherein an outline of the array of the plurality of optical fibers is formed in a rounded square shape.   The optical fiber bundle according to claim 1, wherein an outline of the array of the plurality of optical fibers is formed in a rounded rectangle.   When the length of the shortest side of the rounded square sides is a, the corner radius of the rounded square is set in a range of a / 30 to a / 6, The optical fiber bundle according to claim 1. In an endoscope illuminating device including an LED light source having a rectangular light emitting surface formed in a substantially flat surface and an optical fiber bundle for guiding light emitted from the LED light source to a distal end portion of an insertion portion provided in the endoscope ,
The optical fiber bundle is configured by bundling a large number of optical fibers, and one end surface of the optical fiber bundle is disposed to face the light emitting surface of the LED light source, and the end surface of the optical fiber bundle is formed. An illumination device for an endoscope, wherein the outline of the array of the plurality of optical fibers is formed in a rounded square shape.   6. The lighting device according to claim 5, wherein an outline of the array of the plurality of optical fibers is formed in a rounded square shape.   6. The illumination device according to claim 5, wherein an outline of the array of the plurality of optical fibers is formed in a rounded rectangle.   When the length of the shortest side of the rounded square sides is a, the corner radius of the rounded square is set in a range of a / 30 to a / 6, The lighting device according to claim 5.   The area of the outline of the array of the plurality of optical fibers on the end face of the optical fiber bundle is approximately the value obtained by subtracting the area of the corner of the light emitting surface where the light emission luminance is low from the area of the light emitting surface of the LED light source. 6. Illumination device according to claim 5, characterized in that they are equal.   The lighting device according to claim 9, wherein the end surface of the optical fiber bundle is disposed in contact with the light emitting surface of the LED light source.