JPH0381716A - Fiberscope for very low temperature - Google Patents

Abstract

PURPOSE:To always obtain a normal image without bubble remaining on the surface of a front window by constituting a fiberscope so that the front window for sealing an objective lens barrel may be allowed to spherically protrude to a reflection mirror side and a through hole may be provided on the side wall of the lens barrel. CONSTITUTION:The front window 15 of the fiberscope is spherically curved and protrudes to the reflection mirror 6 side. When the bubble caused in a cryogenic medium reaches the surface 15a of the front window 15, the bubble is guided to the peripheral part 15b of the surface 15a of the window 15 because the window 15 spherically protrudes to the reflection mirror 6 side. The bubble guided to the peripheral part 15b of the surface 15a passes slit-like holes 17, 17... provided on the side wall 16a of the lens barrel 16 and successively goes out to the outside of the lens barrel 16, so that the bubble dies not remain near the surface 15a of the window 15. Thus, the normal image is always obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a cryogenic fiberscope used for observation in a cryogenic medium such as liquefied gas.

"Prior Art" Since it is not possible to directly observe the behavior of materials in cryogenic media such as liquid nitrogen, liquid helium, and liquefied natural gas, observation using a fiberscope has conventionally been performed. FIG. 3 shows a conventional cryogenic fiberscope used for such applications.

This one has eyepiece tube parts 2 at both ends of the image fiber l.
and a sensor probe 3 is attached,
The sample S is observed by immersing the sensor probe 3 into the cryogenic medium.

The eyepiece tube section 2 is provided with an eyepiece lens 4, so that the image of the sample S transmitted through the image fiber 1 can be viewed.

As shown in FIG. 4, the sensor sub-a-p 3 consists of a generally cylindrical objective barrel portion 5 made of stainless steel or the like, and a lens barrel 7 provided with a reflecting mirror 6.

Objective [rti! 181 (5) has one end sealed by a flange 8, and houses an objective lens 9.9 inside, and the other end is sealed by a front window IO made of transparent quartz glass or the like. Yes. Also,
The image fiber I passes through the flange 8 in a fluid-tight manner, and the tip 1a of the image fiber I penetrates the space 15a of the objective barrel 5 while keeping the space 12 inside the objective barrel 5 airtight. It is inserted through and fixed by this lid 5a. Also, here is the tip surface of the above image fiber l! b is mirror-polished and is in contact with the space 12 so as to be parallel to the objective lens 9.9.

Further, objective lenses 9.9 are fixed in the objective lens barrel section 5 by lens fixing rings +3, 13, and 13 so that they are parallel to each other. The space 12 inside the objective lens barrel 5 is maintained at a reduced pressure (lO-- to 10-'Torr), so that even when immersed in a cryogenic medium, the image stored therein is This makes it possible to prevent dew condensation on the distal end surface 1b of the fiber 1, the objective lens 9.9, and the front window IO.

A metal lens barrel 7 holding a reflection mirror 6 for viewing the sample S from the side is attached to the tip 5b of the objective lens barrel portion 5 so as to be rotatable along the circumferential direction. This sample S
A reflecting mirror 6 provided for viewing from the side is held and fixed by a lens barrel 7 so that the angle A formed with respect to the mirror parallel to the front window 10 is 45 degrees. The image reflected from this reflection mirror 6 is the front window l.
The image fiber ! It is designed to be incident inside.

"Problem to be Solved by the Invention" However, bubbles are constantly generated in cryogenic media such as liquid nitrogen, liquid helium, and liquefied natural gas. If immersed vertically in a cryogenic medium, bubbles will form! 4 accumulates near the surface 10a of the front window 10 of the fiberscope. Further, as shown in FIG. 5, the wall 7a of the lens barrel 7 prevents the air bubbles 14 from moving from the surface 10a of the front window 10 to the outside of the lens barrel 7, and the air bubbles 14 move near the surface 10a of the front window 10. Since a large amount accumulates, the image sent from the reflection mirror 6 is sent to the front window 1.
There is a problem that observation with a fiberscope becomes impossible because it becomes impossible to pass through 0.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a fiberscope for cryogenic use that can always obtain normal images without causing bubbles to accumulate near the surface of the front window in a cryogenic medium. With the goal.

"Means for Solving the Problems" In the present invention, a fiber scope for cryogenic use has a sensor probe equipped with an objective barrel provided with an objective lens and a lens barrel that holds a reflection mirror at the tip of the objective barrel. The above-mentioned problem was solved by making the front window that seals the objective lens barrel protrude spherically toward the reflecting mirror, and by providing a through hole in the side wall of the lens barrel.

``Function'' In a fiberscope with this configuration, the front window protrudes spherically toward the reflecting mirror, and a through hole is provided in the side wall of the lens barrel, so air bubbles are always kept in the front window. Air bubbles are guided from the surface to the periphery of the front window, and then to this periphery through the through holes provided in the side wall of the lens barrel, and then exit to the outside of the lens barrel.
Air bubbles will not accumulate on the front window surface.

"Embodiments" Hereinafter, the fiberscope of the present invention will be described in detail with reference to the drawings.

1 and 2 show a fiberscope sensor probe of the present invention, and the same components as the conventional fiberscope sensor probe shown in FIGS. 4 and 5 are denoted by the same reference numerals. The explanation will be omitted.

The difference between the fiberscope of the present invention and the conventional fiberscope shown in FIGS. 3 to 5 is the shape of the front window IO of the sensor probe 3 and the side wall 7a of the lens barrel 7.

No.! In the figure, the front window 15 of the fiberscope of the present invention is curved into a spherical shape and protrudes toward the reflecting mirror 6 side. and firrJ that holds the reflection mirror 6
As shown in FIG. 2, the +6 side wall 16a is provided with a plurality of slit-shaped holes 17, 17, .

When the air bubbles 14 generated in the cryogenic medium reach the surface 15a of the front window 15 by rubbing in this way, the air bubbles 14 are removed because the front window 15 protrudes spherically toward the reflecting mirror 6. Front window 1
5 to the peripheral edge 15b of the surface 15a. Then, the air bubbles 141 guided to the peripheral edge 15b are transferred to a slit-shaped hole 17A7 provided in the side wall 16a of the lens barrel 16.
Since the air bubbles 14 sequentially exit to the outside of the lens barrel 16 through .

Further, in the above embodiment, a slit-shaped hole is shown as the through hole, but the through hole provided in the side wall 16a of the lens barrel 16 of the present invention is not limited to this shape, and in short, it has a spherical shape. Front window 1 that protrudes like a
A through-hole of any shape for letting air bubbles escape may be provided near the peripheral edge 15b of the surface 15a of 5.

"Effects of the Invention" As explained above, the present invention provides a sensor probe for cryogenic use that has a sensor probe that includes an objective lens provided with an objective lens and a lens barrel that holds a reflection mirror at the tip of the objective lens. This fiberscope has a front window that seals the objective barrel that protrudes spherically toward the reflecting mirror, and a through hole is provided in the side wall of the barrel, so air bubbles are always present in the front window. The air bubbles are guided from the surface to the periphery of the front window, and then to the periphery of the front window from the through hole provided in the side wall of #1tti, and then exit to the outside of the lens barrel. No air bubbles accumulate in the camera, and normal images can always be obtained.

[Brief explanation of drawings]

FIG. 1 is a sectional view of the sensor probe of the fiber scope of the present invention, FIG. 2 is a perspective view of the main part of FIG. 1, FIG. 3 is a schematic configuration diagram showing a conventional fiber scope, and FIG. 5 is a cross-sectional view of a sensor probe of a conventional fiberscope, and FIG. 5 is a perspective view of the main part of FIG. 4. 3...Sensor probe, 5...Objective barrel section, 5b...Tip of objective barrel section, 6...Reflection mirror 9...Objective lens, I5...Front window, 16... - Lens barrel, 16a... Side wall of lens barrel, 17... Slit-shaped hole (through hole).

Claims (1)

[Scope of Claims] A cryogenic fiberscope having a sensor probe including an objective barrel provided with an objective lens and a lens barrel holding a reflecting mirror at the tip of the objective barrel, A cryogenic fiberscope characterized by having a front window that seals the tube protrude in a spherical shape toward the reflecting mirror, and further having a through hole in the side wall of the tube.