JPH0197113A - Inspection device for cable entry hole - Google Patents

Abstract

PURPOSE:To facilitate the measurement of a step, by a method wherein a tubular window, which images the vicinity of an opening surface at the tip end of the tubular window, is provided so as to be projected from the tip end surface of the main body of an optical fiber scope equipped with an image guide by a predetermined dimension. CONSTITUTION:An inserting body 21 is inserted into a cable entry hole 1 and is abutted against a step 22. A tubular tip end window 10, having a predetermined length L, is formed at the tip end of the inserting body 21 and an object unit 6, consisting of object lenses 5, is formed before the tip end window 19. Clean water is made to flow through a flow passage 16 as shown by an arrow sign in a diagram while dirty water is discharged through the window 19 to wash the object unit 6. The inside of the cable entry hole is observed through an eye lense unit (not shown in the diagram) in an image guide 8 to obtain the ratio of the dimension E of an inner peripheral rim on an image to the dimension G of the step on the same image whereby the dimension A of the step is obtained by operating it from the predetermined length L. According to this method, the dimension of the step may be obtained easily.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to a cable entry hole inspection device.

[Conventional technology and its problems]

Generally, when inspecting conduits such as underground power transmission lines, underground distribution lines, and communication cables, if there are holes in the conduit, the holes are used to pass the test rod through or with an rTV camera. "Through"
etc.

However, if there are no holes (in the case of a so-called slot channel),
Currently, there is no effective inspection method and the equipment is left unattended.
The development of an effective inspection method was desired.

The present invention solves these conventional problems and allows the cable entry hole with the cable inserted to be easily and quickly inspected, and if there is a step in the wire entry hole, the step size can be accurately determined. The purpose of the present invention is to provide an inspection device for cable entry holes that can measure cable entry holes.

[Means for solving problems]

The cable entry hole inspection device of the present invention protrudes by a predetermined dimension from the distal end surface of the optical fiber body of an optical fiber scope equipped with an image guide, and at least projects the inner peripheral edge of the distal end of the distal opening thereof. , a distal end cylindrical window portion through which the observed portion is observed from the distal end opening via the optical fiber scope.

[Effect]

When inspecting the cable entry hole with the inspection device configured as described above, if the cable entry hole has a stepped portion, the step dimension of the stepped portion can be measured. That is, if the tip of the tip of the cylindrical window is placed against the step and the step is observed with an optical fiber scope, the inner periphery of the tip of the cylindrical window and the step will be reflected in the image. . Therefore, the diameter dimension of the inner periphery of the tip on this image and the step dimension on the image (the step dimension in this case is the dimension on the image obtained by subtracting the wall thickness of the cylindrical window from the correct step dimension) Therefore, if you add this wall thickness dimension to this step dimension, you will get the correct step dimension.) Since the actual diameter and wall thickness dimensions of the inner periphery of the tip are known, the actual diameter can be calculated by proportional calculation. The step size can be determined.

〔Example〕

Hereinafter, the present invention will be explained in detail based on drawings showing examples.

FIG. 1 shows the present invention, where 21 is a cable entry hole inserter of an inspection device according to the present invention, and the inserter 21 is inserted into the cable line hole 1 (see FIGS. 3 and 4). The optical fiber scope 4 includes an insertion guide tube 2 and an optical fiber main body 3 inserted into the insertion guide tube 2.

The optical fiber scope 4 consists of the optical fiber main body 3 and an eyepiece (not shown) provided on the proximal end side of the optical fiber main body 3, and an objective lens at the distal end of the optical fiber main body 3. 5 is provided with an objective section 6. The optical fiber main body 3 also includes an insertion tube 7, an image guide 8 inserted into the insertion tube 7, and a plurality of light guides 9. are installed in succession. The image guide 8 consists of an image guide body made up of a large number of pixels, and a coating layer covering the body, and each pixel consists of a core and a cladding. Further, the light guide includes an optical fiber strand consisting of a core and a cladding, and a coating layer covering the strand.

Therefore, this optical fiber scope 4 has a light guide 9
irradiates the observed area with light, and the light reflected from the observed area enters the image guide 8 via the objective lens 5 of the objective unit 6 and is transmitted.Furthermore, the transmitted light is The light enters the eyepiece lens of the eyepiece section. Then, the light passing through the eyepiece reaches cameras connected via a mount (not shown), etc., and the part to be observed is observed. Note that you are free to observe with your own eyes without using a camera.

Therefore, the insertion guide tube 2 has a metal tip tube portion 10,
a guide tube main body 12 connected to the cylindrical portion 10 via a connecting tube 11; the tip of the optical fiber main body 3 is fixed to the cylindrical portion 10 via an intervening member 13;
The intervening member 13 allows fluid such as fresh water flowing in from the proximal end of the guide tube 2 between the inner circumferential surface 15 of the insertion guide tube 2 and the outer circumferential surface 14 of the insertion tube 2 of the optical fiber main body 3. A flow path 16 is formed through which the fluid flows out from the tip of the guide tube 2. The guide tube main body 12 is made of flexible and seamless synthetic resin, such as crosslinked polyethylene. Further, the connecting pipe 11 is made of synthetic resin or metal.

Further, the intervening member 13 is made of a cylindrical body, and its peripheral wall 17
As shown in FIG. 2, through holes 18 in the axial direction are provided at equal pitches around the circumference. This intervening member 13 is fixed to the proximal large diameter portion 37 of the distal end tube portion 10, into which the distal end portion of the optical fiber main body 3 is inserted and fixed. Reference numeral 25 indicates a screw hole provided in the distal end tube portion 10 for fixing the intervening member 13 and the distal end tube portion 10; 29 indicates a screw hole provided in the intervening member 13; This is for fixing the intervening member 13 and the tip of the optical fiber main body 3. In addition, each screw hole 25.2
9 are screwed into each other, but are omitted in the illustration. Furthermore, a protruding wall 26 at the distal end of the connecting tube 11 is interposed between the intervening member 13 and the distal end tube portion 19 .

Then, the guide tube main body 1 is attached to the base end small diameter portion 30 of the connecting tube 11.
2 are fitted to form an insertion guide tube 2 in which the optical fiber main body 3 is placed. In this case, the axis of the image guide and the axis of the window portion 19 are the same axis, and the outer surface 3 of the guide tube body 12, the outer surface 32 of the connecting tube 11, and the outer surface of the tip tube portion 10 are The surface 33 is continuous. 27 and 28 are the guide tube main body 12 and the connecting tube 11, respectively.
This is a threaded hole provided in the guide tube 12 and the connecting tube 11.

In this case as well, the screws that are screwed into the screw holes 27 and 28 are not shown.

Therefore, if configured as described above, the tip cylindrical window portion 1 protrudes from the tip surface 3a of the optical fiber main body 3 by a predetermined amount.
9 is formed, and the portion to be observed can be observed from the tip opening 35 of the intervening member 13 through the window 34 .

Further, in this case, the observation of the observed portion through the optical fiber scope 4 is made to have a fixed field of view. That is, the viewing angle of the optical fiber scope 4 is α, and the optical fiber scope 4
As shown in FIG. 5, the setting is made so that at least the inner peripheral edge 36 of the tip of the window portion 19 appears in the image displayed. Note that 24 shown in FIG. 5 is the inner circumferential surface of the window portion 19.

Next, an inspection method for inspecting the cable entry hole 1 using the inspection device configured as described above will be explained.

First, as shown in FIG. 3, insert the cable entry hole pusher 21 into the cable entry hole 1 into which the cable 20 has been inserted, and as shown in FIG. , the fluid flows out from the window portion 19 via the intervening member 13. That is, by injecting the fluid into the outflow 16, it is possible to wash away the stagnant water in the cable line hole 1 and wash the tip of the optical fiber scope 4, and the cable input by the optical fiber scope 4 can be washed away. The image of the observation part of the drilling machine can always be made clear.

However, in order to use this inspection device to measure the step dimension A of the cable manhole hole where a step as shown in Fig. 4 has occurred, it is necessary to
The distal end surface 2a of the insertion guide tube 2 is brought into contact with this stepped portion 22, and as described above, the fluid is caused to flow out from the distal opening 34 of the window portion 19 to wash the vicinity of this stepped portion 22, and then,
This stepped portion 22 is observed using the optical fiber scope 4. Therefore, the image at this time shows the inner circumferential surface 24 of the window I9 and the stepped edge 38 of the cable entry hole 1, as shown in FIG.
appears, and the step dimension A can be determined. That is,
Dimension G obtained by subtracting the wall thickness dimension F of the window portion 19 from the step dimension A
(that is, the dimension from point 0 to point D) is the dimension Ga on the image, and the diameter dimension E of the tip inner peripheral edge 36 of the window portion 19 (that is, the dimension from point 0 to point B) is the dimension Ga on the image. Dimension Ea
In addition, since the diameter E and the wall thickness F of the inner peripheral edge 36 of the tip of the window 19 are known, the actual size can be determined by finding the ratio of the dimension Ea and the dimension Qa from the image and performing a proportional calculation. G
can be found. Then, by adding the wall thickness dimension F of the window portion 19 to this actual dimension G, this step dimension A can be determined. Of course, even if the axis of the image guide of the optical fiber scope 4 and the axis of the window part 19 are misaligned, the inner peripheral edge 36 of the tip of the window part 19 and the step edge 38 of the step part 22 will be reflected in the image. Therefore, the step size A can be determined.

However, when the inside of the cable line hole 1 is filled with water, the refractive index of light is different between the atmosphere and underwater, so the viewing angle of the optical fiber scope 4 is α in the atmosphere. , becomes β in water.And this β
In this case, as shown in FIG. 6, the setting is made so that a part of the inner circumferential surface 24 of the window portion 19 is not displayed on the image from the optical fiber scope 4.

Therefore, while inspecting the cable entry hole 1 with this inspection device, the inner circumferential surface 24 of the window portion 19 is shown in the image as shown in FIG.
If is not displayed, it can be seen that the cable entry hole 1 is filled with water. Of course, in this case as well, points B and 0 of the window portion 19, point D of the step portion 22, etc. are displayed on the image, and the step dimension A can be measured. That is, by finding the ratio of the dimension Fa and the dimension Ga, finding the actual dimension G from that ratio, and adding the wall thickness dimension F of the window portion 19 to the dimension G, the step dimension A can be determined.

According to the above-mentioned embodiment, since the tip tube portion 1° is made of gold B, the tip tube portion 1o is connected to the cable entry hole 1.
Even when it comes into sliding contact with the inner circumferential surface 23, it does not wear out and is highly durable. Further, fluid can be allowed to flow into the wire entry hole 1, and the image of the observed area can be made clear. Furthermore, it can be determined whether or not the inside of the cable line hole 1 is filled with water, which is very convenient.

It should be noted that the present invention is not limited to the above-described embodiments, and is free to make design changes without departing from the gist of the present invention. The cylindrical portion 10 and the connecting tube 11 may be made of the same synthetic resin as the guide tube main body 12 and may be integrated.Furthermore, the tip cylindrical portion 10 may be made detachable, so that the tip cylindrical portion 10 of various sizes can be formed. By aligning them, it is possible to correspond to various stepped portions 22 of the cable entry hole 1.

〔Effect of the invention〕

In the cable entry hole inspection device of the present invention, if the tip of the distal end cylindrical window portion 19 is brought into contact with the step portion 22 of the cable entry hole 1, the end surface of the optical fiber main body 3 will pass through the step portion 22.
The length dimension up to a becomes the predetermined dimension. If the stepped portion 22 is observed with the optical fiber scope 4 in this state, the image includes the inner peripheral edge 36 of the tip of the cylindrical window portion 19.
is displayed, and the stepped portion 22 is also displayed. Therefore, the ratio between the inner peripheral edge dimension on the image and the step dimension (in this case, it is not the correct step dimension, but the dimension on the image obtained by subtracting the wall thickness dimension F of the window portion 19 from the step dimension A). Once determined, the actual step size A can be determined by proportional calculation.

That is, if this inspection device is used, even if the cable entry hole 1 has a stepped portion 22, the tip of the cylindrical window portion 19 can be abutted against this stepped portion 22 and observed with an optical fiber scope. For example, the step size A of the step portion 22 can be easily and quickly determined.
can be measured, making inspection of the wire entry hole extremely easy.

[Brief explanation of the drawing]

Fig. 1 is an enlarged sectional view of main parts showing one embodiment of the present invention;
The figures are a sectional view taken along line nn in Fig. 1, Fig. 3 is a simplified cross-sectional view showing the state in which the cable is inserted into the cable entry hole, Fig. 4 is a simplified cross-sectional view of the main part in the state of measuring the step dimension, and Fig. 5 is a simplified cross-sectional view showing the cable inserted into the cable entry hole. 6 and 6 are simplified diagrams of images obtained by a fiber optic scope, respectively. 3... Optical fiber body, 3a... Tip surface, 4...
Optical fiber scope, 8... Image guide, 19.
... Tip cylindrical window, 35... Tip opening, 36...
Inner edge of tip.

Claims (1)

[Claims] 1.Protrudes by a predetermined dimension from the distal end surface of the optical fiber body of an optical fiber scope equipped with an image guide, and
A cable characterized in that it is provided with a cylindrical window portion at the tip end through which the area to be observed is observed through the optical fiber scope from the tip opening portion in a state where at least the inner peripheral edge of the tip portion of the tip opening portion is reflected. Inspection device for wire entry hole.