JPH0529454Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to a device that adjusts the amount of illumination light for an endoscope according to the manner in which the endoscope is used.

(Prior Art) FIG. 5 shows a general endoscope 10' and a light amount adjustment device 1' that adjusts and supplies illumination light to the endoscope 10'.

The endoscope 10' includes an operating section 11 and an operating section 1.
It has an insertion section 12 and a light guide cable 13 extending from the operating section 11, and an eyepiece section 14 provided at an end of the operation section 11.

The insertion section 12 is flexible and designed to be inserted into a body cavity, and has a curved section 12a on the distal end side, and a hard distal end component 12 on the distal end side.
It has b. The bending portion 12a is configured to be bent via a wire within the insertion portion 12 by remote control using the operation portion 11.

A plug 13a is provided at the tip of the light guide cable 13.

An observation window and an illumination window (not shown) are provided on the end surface of the tip component 12b.

One end 16a of an optical fiber bundle 16 for image transmission is optically connected to the observation window via the objective optical system 15, and this optical fiber bundle 16 is connected to the insertion section 1.
2. The other end 16b passes through the operating section 11 and is optically connected to the eyepiece optical system 17 of the eyepiece section 14.

Further, one end portion 18a of an optical fiber bundle 18 for transmitting illumination light is optically connected to the illumination window,
This optical fiber bundle 18 includes an insertion section 12, an operation section 1
1. The light guide cable 13 is passed through, and the other end 18b reaches the tip of the plug 13a.

On the other hand, the light amount adjustment device 1' includes a pair of light source devices (light sources) 20 including a concave mirror 21 and a lamp 22 disposed in the center of the concave mirror 21, and an end portion of the lamp 22 and the optical fiber bundle 18. 18b, that is, at the position indicated by the dashed line X in FIG.

As shown in FIG. 6, the shielding device 50 has a pair of shielding plates 51 that are bilaterally symmetrical to each other and formed in a dogleg shape. A shielding portion 51a for shielding the light beam A is formed at the lower end. Note that R in the figure indicates the movement locus of the shielding part 51a.

A cam 5 connected to an output shaft 53 of a servo motor (not shown) is attached to the upper end of the shielding plate 51.
It has a pin 51b that slides relative to the cam surface 54a of No. 4.

Then, as the cam 54 is driven by the servo motor and rotates clockwise in FIG. 6, the distance from the output shaft 53 to each pin 51b gradually increases, and as a result, both shielding plates 51 are 51
a rotate toward each other, and the cam 54 rotates counterclockwise, so that, contrary to the above, the shielding plate 51 rotates so that the shielding portions 51a move away from each other.

When the shielding part 51a of the shielding device 50 is fully open, the light from the lamp 22 is reflected by the concave mirror 21, and all the light is supplied to the end 18b of the optical fiber bundle 18 while the luminous flux A is narrowed down. The light passes through the fiber bundle 18 and is irradiated into the body cavity from the illumination window.

The thus illuminated image of the inside of the body cavity is observed through the observation window, objective optical system 15, optical fiber bundle 16, and eyepiece optical system 17.

By the way, when the insertion section 12 of the endoscope 10 is inserted into a body cavity, for example, the digestive tract, the brightness of the image obtained by the eyepiece section 14 differs depending on its arrangement.

For example, as shown in FIG. 8, when the direction of the field of view is approximately in the longitudinal direction of the digestive tract T, the distance between the illumination window of the insertion section 12 and the wall of the digestive tract T is long, and this tube Since the irradiation angle with respect to the wall is small, the proportion of the constant amount of illumination light reflected back to the observation window is small.

On the other hand, as shown in Fig. 9, polyp P
When observing a convex lesion like this, the distance between the illumination window of the insertion section 12 and the wall of the gastrointestinal tract T is short, and the irradiation angle with respect to the wall of the gastrointestinal tract is large and close to a right angle, especially in the central part. Therefore, the proportion of a certain amount of illumination light that is reflected and returned to the observation window is large.

Therefore, when a constant amount of illumination light is used, the overall brightness of the image obtained by the eyepiece section 14 will vary depending on the manner in which the endoscope is used as described above.

The image at the eyepiece 14 needs to have appropriate brightness; if it is too dark or too bright, the image at the eyepiece 14
Obstructs observation and photography.

Therefore, in the case shown in FIG. 8, the shielding part 51
By widening the distance between a, for example, the light beam A is fully opened and the amount of illumination light supplied to the end portion 18b of the optical fiber bundle 18 is increased.

Further, in the case shown in FIG. 9, by narrowing the distance between the shielding portions 51a, a diaphragm state is established to reduce the amount of illumination light.

In this way, the overall brightness of the image at the eyepiece section 14 is adjusted.

Incidentally, when considering the above-mentioned prior art and the present invention, the transmission principle of illumination light shown in FIG. 7 is important.

That is, from the lamp 22 to the end 1 of the optical fiber bundle 18
The light supplied to the optical fiber bundle 8b passes through the optical fiber bundle 18 and is irradiated into the body cavity from the end 18a through the illumination window, and this illumination light forms a ring shape with a solid angle of 2Θ.

Therefore, as shown in FIG.
Of the luminous flux A at
Assuming that Ac is the area around which the incident angle Θ is large and the peripheral area Ar is the surrounding area Ar, for example, when a part of the peripheral area Ar is shielded by the shielding part 51a, the peripheral area of the illumination light irradiated into the body cavity is The amount of light in the center area decreases, but the amount of light in the center area does not decrease. On the contrary, the central part
When part of Ac is shielded, only the amount of light in the central part of the illumination light irradiated into the body cavity decreases.

Furthermore, in terms of the light diffusion characteristics of the optical fiber bundle, it is normal that the amount of light is greater in the central part than in the peripheral part.

(Problems to be Solved by the Invention) However, in the conventional light amount adjustment device 1' described above, although it is possible to adjust the overall brightness of the image obtained by the eyepiece section 14, Sufficient consideration was not given to the distribution of brightness.

That is, when the shielding device 50 is narrowed down as shown in FIG. 6, for example, the central part Ac, which has a large amount of light, of the luminous flux A of the illumination light is not blocked at all, and the peripheral part Ar, which has a small amount of light,
A part of it will be obscured.

Therefore, although the overall amount of light decreases, in the image obtained by the eyepiece 14, the central part remains the same, but the brightness in the peripheral part decreases, further promoting non-uniformity. result.

(Means for solving the problem) This invention was made to solve the above problem, and its gist is to pass illumination light from a light source to the end of the insertion section of the endoscope through an optical fiber bundle. A device for adjusting the amount of the illumination light when irradiating it from an illumination window provided in the section, the device comprising: a first light source disposed on an extension of an end of the incident side of the optical fiber bundle; a second light source disposed offset by a predetermined angle with respect to an extension line of the incident side end; and a light amount control means for independently controlling the amount of light of the first light source and the second light source. A light amount adjustment device for an endoscope is provided.

(Function) Each illumination light from the first and second light sources is transmitted to the illumination window via the optical fiber bundle and irradiated from there. In this case, since the first light source is arranged on the extension line of the incident side end of the optical fiber bundle, the 10th light source
As shown in the figure, a predetermined area centered on the extension line of the illumination window is irradiated. On the other hand, since the second light source is disposed offset by a predetermined angle with respect to the extension line of the incident side end of the optical fiber bundle, it irradiates a wider range than the range irradiated by the first light source. Moreover,
The amount of light irradiated by the first light source increases in a predetermined range centered on the extension line of the illumination window, while the amount of light irradiated by the second light source increases outside of this range. Therefore, if the amount of light from the first light source is increased and the amount of light from the second light source is decreased, a predetermined area centered on the extension of the irradiation window will become brighter, and areas outside of that area will become darker. Conversely, if the amount of light from the first light source is decreased and the amount of light from the second light source is increased, a predetermined area centered on the extension line of the illumination window will become dark, and areas outside of it will become brighter.

In this way, the brightness of a predetermined range centered on the extension line of the illumination window and the range outside of that can be adjusted independently, so the brightness distribution of the observed image can be adjusted to the center. It is possible to make it almost uniform between the area and the periphery.

(Example) Hereinafter, an example of this invention will be described with reference to FIGS. 1 to 3.

In FIG. 1, reference numeral 10 is an endoscope, and reference numeral 1A is a light amount adjustment device.

Since the basic structure of the endoscope 10 is the same as the conventional one, the same reference numerals are given to the same parts in FIG. 1 as in FIG. 5, and the explanation thereof will be omitted, and only the different points will be explained below.

End portion 16b of optical fiber bundle 16 and eyepiece optical system 17
A semi-transparent mirror 40 is provided between the
This semi-transparent mirror 40 transmits the light from the optical fiber bundle 16 and enters the eyepiece optical system 17, and also reflects the light and enters the central sensor 41 and peripheral sensor 42 via the convex lens 43. It is something.

The central sensor 41 has a circular shape, and the peripheral sensor 42 has a donut shape, and the central sensor 41 is disposed within the peripheral sensor 42.

Each of the sensors 41 and 42 has a large number of light receiving diodes as photoelectric conversion elements, and is capable of detecting the total amount of light received in each area.

As shown in FIGS. 2 and 3, the detected voltages Vf ₁ and Vf ₂ (feedback voltages) of these sensors 41 and 42 are sent to amplifiers 45 and 46, respectively, where the detected voltages Vf ₁ ，
The voltage differences between Vf ₂ and the set voltages Vd ₁ and Vd ₂ are each amplified, and each amplified voltage difference is fed back to the voltage control circuits 23a and 23b, respectively, so that the voltages applied to the lamps 22a and 22b, which will be described later, are independently controlled. It is becoming more and more controlled.

On the other hand, the light amount adjustment device 1A has first and second light source devices (light sources) 20a and 20b, and each light source device 2
0a and 20b are concave mirrors 21a and 21b, respectively.
, lamps 22a, 22b arranged in the center of each concave mirror 21a, 21b, and each lamp 22a, 2
The voltage control circuit 23 electrically connected to 2b
a, 23b.

One of the light source devices 20a is arranged on an extension line of the other end 18b of the optical fiber bundle 18, and the other light source device 20b has an incident angle that is different from the light source device 20.
It is arranged to be shifted by a predetermined angle with respect to the extension line of the other end portion 18b so as to be different from the incident angle of a.

In the above configuration, the light from the lamps 22a and 22b of the light source devices 20a and 20b is transmitted through the concave mirror 21, respectively.
a, 21b, each reflected light is transmitted to the end 18b of the optical fiber bundle 18 while being condensed, and is irradiated from the irradiation window. In this case, since one light source device (first light source) 20a is arranged on the extension line of the other end 18b of the optical fiber bundle 18, the amount of light from the first light source device 20a is as shown in FIG. In contrast, the amount increases in a predetermined range centered on the extension line of the irradiation window (the location where the distance is 0 in the figure). Since the other light source device (second light source) 20b is arranged to be shifted by a predetermined angle with respect to the extension line, the amount of light emitted by the light source device 20b increases outside the predetermined range.

The thus illuminated image of the inside of the body cavity is observed through the observation window, objective optical system 15, optical fiber bundle 16, and eyepiece optical system 17.

Further, a part of the light from the optical fiber bundle 16 is reflected by the semi-transparent mirror 40 and supplied to the sensors 41 and 42.

The center sensor 41 detects the amount of light at the center of the image obtained by the eyepiece 14 as a voltage, and this detected voltage Vf ₁ is sent to the amplifier 45 .

In this amplifier 45, the voltage difference between the set voltage Vd ₁ corresponding to the optimum brightness and the detected voltage Vf ₁ is amplified, and this amplified voltage is fed back to the voltage control circuit 23a to control the voltage applied to the lamp 22a. be done.

For example, if the detection voltage Vf ₁ is larger than the set voltage Vd ₁ , that is, if the brightness at the center of the image obtained by the eyepiece 14 is too bright compared to the optimal brightness, the lamp 22a The applied voltage is lowered to reduce the amount of light in the center.

At the same time, the amount of light at the periphery of the image obtained by the eyepiece 14 is detected as a voltage by the peripheral sensor 42, and this detected voltage Vf ₂ is sent to the amplifier 46.
sent to.

In this amplifier 46, the difference voltage between the set voltage Vd ₂ and the detection voltage Vf ₂ corresponding to the optimum brightness (same level as the set brightness at the center) is amplified, and this amplified voltage is sent to the voltage control circuit 23b. The voltage applied to the lamp 22b is controlled based on the feedback.

For example, if the detection voltage Vf ₂ is larger than the set voltage Vd ₂ , that is, if the brightness of the peripheral part of the image obtained by the eyepiece 14 is too bright compared to the optimal brightness, the lamp 22b The applied voltage is lowered to reduce the amount of light in the peripheral area.

In this way, since the voltage applied to each lamp 22a, 22b is controlled independently, the amount of light incident on the end 18b of the optical fiber bundle 18 is adjusted independently, and as a result, the irradiation area is Since the amount of light is adjusted separately for the periphery and the endoscope, the brightness distribution of the image obtained at the eyepiece can be made almost uniform in accordance with all usage modes of the endoscope.

For example, when the insertion portion 12 of the endoscope 10 is arranged as shown in FIG. 9, the voltage applied to the lamp 22a is adjusted to be lower than the voltage applied to the lamp 22b.

As a result, the amount of light at the center can be reduced, and the brightness of the image at the eyepiece 14 in the usage mode shown in FIG. 9 can be distributed almost uniformly.

FIG. 4 shows another embodiment, and this light amount adjustment device 1B includes two sets of light source devices, namely, a light source device (first light source) 30a for illuminating the center area and a It has a light source device (second light source) 30b for illuminating the peripheral area.

Condensing lenses 34a, 34b are arranged at predetermined positions between each light source device 30a, 30b and the end portion 18b of the optical fiber bundle 18, and furthermore, each light source device 30a, 30b and the condensing lens 34a, 3
4b, that is, the dashed line X ₁ in FIG.
A shielding device 50 used in the conventional light amount adjusting device 1' is arranged at the position _X2 .

Lamps 32a, 32 of light source devices 30a, 30b
The light b is reflected by the concave mirrors 31a and 31b, and each reflected light becomes a parallel light beam, and the condensing lens 34
The light beams are respectively narrowed down and incident on the end portion 18b of the optical fiber bundle 18.

As in the first embodiment, the center sensor 41 and the peripheral sensor 42 detect the eyepiece 14.
The amount of light at the center and periphery of the image obtained is detected as a voltage, and each shielding device 50 is adjusted according to the magnitude of the voltage difference between the set voltages Vd ₁ and Vd ₂ .
A servo motor for operating the cam 54 is driven, and the shielding portions 51a of the respective shielding plates 51 are opened and closed as appropriate to adjust the amount of light of each.

Also in the second embodiment, each lamp 22a,
The amount of light incident on the end 18b of the optical fiber bundle 18 from 22b is adjusted independently, and as a result,
Since the irradiation area is divided into a central part and a peripheral part and the amount of light is adjusted, the brightness distribution of the image obtained at the eyepiece can be made almost uniform, as in the first embodiment.

Note that this invention is not limited to the above-mentioned embodiments, and various embodiments can be adopted.

For example, although only two light sources are used in the above embodiment, another light source may be used, and the light source may be larger than the second light source with respect to the extension of the entrance end of the optical fiber bundle. It may also be placed at an angle.

Furthermore, a configuration in which a solid-state image sensor is placed near the objective optical system at the tip of the insertion section of the endoscope, and an image of the inside of the body cavity is projected on the screen of a receiver based on the image signal from the solid-state image sensor, is also applicable. The present invention can be applied. In this case, the brightness of the central and peripheral parts of the image to be observed can be detected from the image signal, and the amount of light can be adjusted based on the detection results.

(Effect of the invention) As explained above, according to this invention, the first
A second light source is arranged on the extension line of the optical fiber bundle, and a second light source is arranged at a predetermined angle with respect to the extension line, and further, the amount of light incident on the end of the illumination light transmission optical system from each light source is By controlling each of them independently, the amount of light in each of the irradiation areas is independently adjusted.

Therefore, the brightness distribution of the image to be observed can be made uniform, and observation and photography using an endoscope can be performed under optimal lighting conditions.

[Brief explanation of the drawing]

The drawings in FIGS. 1 to 3 show one embodiment of this invention, and FIG. 1 is a schematic sectional view of the light amount adjustment device and endoscope of this invention, and FIGS. 2 and 3 show the light amount. 1 is a schematic circuit diagram showing a control system for regulation;
FIG. 4 is a sectional view of a main part showing another embodiment.
Further, the drawings from FIG. 5 to FIG. 9 show the prior art, and FIG. 5 is a sectional view of a conventional light amount adjustment device and an endoscope corresponding to FIG. 1, and FIG. 6 is a conventional light amount adjustment device. FIG. 7 is a diagram explaining the principle of illumination light transmission in an optical fiber bundle; FIGS. 8 and 9 are cross-sectional views showing different usage modes of the insertion section of an endoscope in a body cavity; FIG. 10 is a diagram showing the amount of light in the area irradiated by the light amount adjusting device of this invention. 1A, 1B... Light amount adjustment device, 10... Endoscope, 12... Insertion section, 18... Optical fiber bundle (illumination light transmission optical system), 18a... End, 20a... Light source device (first light source), 20b... light source device (second light source), 30a... light source device (first light source),
30b...Light source device (second light source), 22a, 2
2b, 32a, 32b...Lamp.

Claims (1)

[Scope of utility model registration request] In a device for adjusting the amount of illumination light when illumination light from a light source is irradiated from an illumination window provided at the distal end of an insertion section of an endoscope via an optical fiber bundle, the incident light of the optical fiber bundle a first light source disposed on an extension line of the side end; a second light source disposed offset by a predetermined angle with respect to an extension line of the input side end of the optical fiber bundle; and the first light source. 1. A light amount adjustment device for an endoscope, comprising: a light amount control means for independently controlling the amounts of light of the second light source and the second light source.