JPH0217024A - Cooling jig for electronic endoscope - Google Patents

Abstract

PURPOSE:To effectively cool a solid-state imaging element without increasing the diameter of an insert part by inserting a cooling jig in the treatment jig insert channel formed to the insert part to blow a cooling fluid toward the arrangement position of the solid-state imaging element. CONSTITUTION:A cooling jig 30 is inserted in a treatment jig insert channel 17 until the fluid jet orifice 42 formed to the leading end part of the main body tube 31 thereof reaches the arrangement position of the solid-state imaging element 16 mounted to a leading end hard part 2c. In this state, a cooling fluid is supplied to the supply passage 33 of a main body tube 31 from a cooling fluid supply source 35 to be injected toward the arrangement position of the solid-state imaging element 16 of a leading end part main body 6. As a result, the solid-state imaging element 16 is cooled from the outside and, even when said solid-state imaging element 16 is driven under a high temp. state as S/N ratio is not lowered and an image of high image quality can be obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an electronic endoscope used for industrial or medical purposes. [Prior art 1] An electronic endoscope is equipped with a solid-state image sensor at the tip of its insertion section, forms an image of the observation target area on the solid-state image sensor, and converts this information into an electrical signal. Take it out and bromo
This is a type of video that has been subjected to predetermined signal processing using a sensor, and is then played back on a display device such as a cathode ray tube.It can be observed by a large number of people at the same time, can be image processed, and has excellent recordability and storage stability. For this reason, it has been rapidly gaining popularity in recent years. Due to the temperature characteristics of solid-state image sensors, under high-temperature conditions such as 40'C or higher, noise may occur due to dark current, resulting in a decrease in the S/N ratio, malfunctions, or If used under extremely high temperature conditions, there is a risk of damaging the device. However, for example, an endoscope for industrial use may be inserted into equipment that is in a high temperature state, such as the inside of an aircraft engine. Furthermore, even in medical endoscopes, the temperature may be extremely high due to the heat of illumination light, etc. Under such high-temperature conditions, in order to drive the solid-state image sensor stably, it is necessary to provide a mechanism to cool the solid-state image sensor. Conventionally, there have been known ones that are provided with a cooling fluid supply passage for sending a cooling wave body toward the position, and ones that are equipped with an electronic cooling element f. [Problems to be Solved by the Invention] Generally, in endoscopes, rJJl of the insertion section
In order to improve the ease of insertion into the part to be inspected,
This insertion portion needs to be made as thin as possible. However,
As mentioned above, forming a cooling fluid supply passage for the cooling fluid in the insertion section increases the diameter of the entire insertion section, which makes it difficult to operate the insertion toward the observation target. There is a drawback to that. In addition, when using electronic cooling 2'f, only the distal end of the insertion tube will have a large diameter, or if there is a narrow part in the insertion path, it will not be possible to pass through this distal end. If the electronic cooling element is made smaller in order to avoid this problem, the problem arises that sufficient cooling effect cannot be obtained. The present invention has been made in view of the above points, and its purpose is to prevent the insertion portion from increasing in diameter.
An object of the present invention is to provide a cooling system for an electronic endoscope that can effectively cool a solid-state image sensor. [Step 1 for Solving the Problems] In order to achieve the above-mentioned object, the present invention provides a method for inserting a treatment instrument into a treatment instrument insertion channel formed in an insertion section and cooling it toward a position where a solid-state image sensor is disposed. Its feature is that it sprays a cleaning fluid. [Effect 1] As mentioned above, since the treatment instrument insertion channel normally provided in the endoscope is used to insert the cooling device, there is no need to increase the number of built-in items in the insertion section, and the insertion section can be made thinner. The diameter becomes the gyri. Moreover, since the cooling fluid is sprayed toward the location where the solid-state image sensor is disposed, the solid-state image sensor can be effectively cooled. [Example J Hereinafter, an example of the present invention will be described in detail based on the drawings. Generally, as shown in Fig. 5, an electronic endoscope has a main body operating section 1 for performing operations, an insertion section 2 inserted into the observation target section, and a built-in light source, processor, etc. A cord 4 connected to the control device 3 is connected in series. Most of the insertion section 2 is a flexible section 2a from the section connected to the main body operation section 1, and the flexible section 2a has an angled section 2b.
, by connecting and sinking the hard tip portion 2c. FIG. 6 shows a cross section of the hard tip portion 2c of the insertion portion 2. As is clear from the figure, the hard tip portion 2c has an outer sleeve vibe 5, into which the tip body 6 is inserted. 1 In this tip body 6,
2 illumination windows 10.1131 observation windows 11 as shown in Figure 7.
．． A treatment instrument outlet 12 and the like are formed. An illumination lens 13 is attached to the illumination window 10, and the output ends of a light guide (not shown) made of an optical fiber bundle extending from a position facing the light source in the control unit 3 are arranged opposite to each other. I'm being forced to do it. Further, an objective lens 15 is disposed in the observation window 11, and a C
A solid-state image sensor 16 made of a CD or the like is installed. Furthermore, the treatment instrument outlet 12 includes a treatment instrument insertion channel 1.
7 is connected, and the other end of the treatment instrument insertion channel 17 is connected to a treatment instrument introduction section 18 provided in the main body operation section 1. Here, the solid-state image sensor 16 described above has an objective lens 15.
by moving it back and forth in the direction of the optical axis. It is configured so that it can be focused. For this purpose, a slide block 19 is connected and fixed to the back side of the substrate portion of the solid-state image sensor 16. An operating wire 20 is attached to this slide block 19, and the operating wire 20 extends into the main body operating section 1 so that the operator can operate the slide block 19 at will. A spring receiver 21 is fixedly provided on the operation wire 20, and a spring 23 is elastically loaded between the spring receiver 21 and the partition wall 22 of the rigid tip portion 2a. 16 is held at a position close to the objective lens 15. On the other hand, when the operating wire 20 is pulled, the solid-state image sensor 16 is separated from the objective lens 15, and the focal length can be adjusted. When the endoscope having the above-mentioned configuration is used under high temperature conditions, the solid-state image sensor 1 provided in the hard tip portion 2C
In order to cool the treatment instrument insertion channel 17,
A cooling device 30 shown in Figure 5H can be inserted. The cooling device 30 has a main body tube 31, and the main body tube 31 is provided with a partition wall 32 for partitioning the inside of the main body tube 31 or a passage section in the upper part f.
The upper passage in the figure serves as a cooling fluid supply passage 33, and the lower passage in the figure serves as a cooling fluid recovery passage 3.1. A cooling fluid supply pipe 38 is provided at the base end of the main body tube 31 through a pressure regulating valve 36 and a filter 37 from a cooling fluid supply source 35 made of nitrogen gas or the like.
A supply pipe connection part 39 is provided to connect the supply pipe connection part 39, and the supply pipe connection part 39 communicates with the supply passage part 33. Further, a suction pipe connection part 41 connected to a suction pipe 40 is provided adjacent to this pipe connection part 39, and this suction pipe connection part 41 communicates with the recovery passage part 34. On the other hand, a fluid ejection port 42 for ejecting cooling fluid toward the solid-state image sensor 16 is provided in the upper surface portion of the tip side of the main body tube 31 in the figure, and a fluid recovery port 43 is provided in the lower surface portion. has been established. Here, the cross-sectional shape of the main body tube 31 is shown in FIG. 2(a).
As shown in the figure, the cross section may be circular, or the second
As shown in Figure (b), if it is formed into an oval shape, it becomes easy to control the direction of the fluid jet port 42, and it is possible to reliably direct it to the location where the solid-state image sensor 16 is disposed. It's convenient. The cooling device 30 configured as described above is inserted into the treatment device insertion channel 17 via the treatment device introduction section 16 provided in the main body operation section 1 of the electronic endoscope, and the
is inserted until the fluid spout 42 formed at the tip reaches the position where the solid-state image sensor 16 attached to the rigid tip 2c is placed. In this state, the cooling fluid supply source 35
The cooling fluid is supplied to the supply passage 33 of the main body tube 31 from
supply within. The cooling fluid thus supplied is ejected from the fluid ejection port 42 toward the position where the solid-state image sensor 16 is disposed in the tip body 6. As a result, the solid-state image sensor 16 is cooled from the outside, and even under high temperature conditions, the solid-state image sensor 16
Even if you drive 6, you will be able to obtain high-quality images without lowering the S/N ratio, and you will be able to protect it. After cooling the solid-state image sensor 16 as described above, the cooling fluid is passed from the fluid recovery port 43 in the main body tube 31 to the suction pipe 41 via the recovery passage 34.
The treatment instrument outlet 12 will not leak out from the treatment instrument outlet 12. However, if the observation target area is a non-closed space and the cooling fluid may leak, the main body tube 31 is not divided into the supply passage 33 and the recovery passage 34, and is simply It is also possible to provide a supply passage section 33. Furthermore, if the cooling device 30 is removed from the treatment instrument insertion channel 17, the treatment instrument can be inserted into the treatment instrument insertion channel 17 for appropriate treatment (when used as a medical endoscope) or repair (when used as an industrial endoscope). Needless to say, when used as an endoscope), it can be inserted through the endoscope. Next, FIGS. 3 and 4 show a second embodiment of the present invention, and a cooling tool 50 in this embodiment uses the treatment tool insertion channel 17 itself as a flow path for cooling fluid. The base end of this cooling device 500 has an FT
Cooling fluid supply pipe 38 in the first embodiment described above
The pipe connection section 51 has a connecting pipe 5 for connecting to the treatment instrument introducing section 18.
2 are fitted. One end of a connecting wire 5:l is attached to this piping connection portion 51 (or connecting pipe 52), and the other end of the connecting wire 53 directs the cooling fluid toward the solid-state image sensor f-IG. A guide member 54 is fixedly attached to guide the spray. As is clear from FIG. 4, this guide member 54 has a guide surface 54
A is an inclined surface facing forward in the F direction. Furthermore, if the connecting wire 53 is formed of a band-shaped member, the guide member 54 can reliably direct the cooling fluid to the solid-state image sensor 16.
It becomes possible to control the guide so that it faces the installation position. Even with this configuration, the cooling fluid supplied through the treatment instrument insertion channel 17 can be sprayed toward the disposed position of the solid-state image sensor IG attached to the tip main body 6 in the rigid tip portion 2a. Therefore, the solid-state image sensor 16 can be cooled. 8 In each of the above-described embodiments, the solid-state image sensor is configured to be able to move along the optical axis of the objective lens, but the solid-state image sensor is fixed to the tip body. In addition, the solid-state imaging device can be inserted into a treatment instrument insertion channel in not only a direct-viewing endoscope but also a side-viewing endoscope to cool the solid-state imaging device. In addition to the nitrogen gas mentioned above, various gases or liquids can be used as the cooling fluid, but an inert fluid is preferable since it is used in an endoscope. 11 effects in one shot] As explained above, the cooling device of the present invention utilizes the treatment instrument insertion channel provided in the insertion section to cool the solid-state imaging device provided at the distal end of the insertion section. Since the structure is configured to spray the cleaning fluid, there is no need to provide a separate cooling mechanism inside the insertion section, and the number of built-in objects in the insertion section P can be reduced, making it possible to reduce the diameter of the insertion section P. The insertability towards the end becomes better.

[Brief explanation of the drawing]

1 and 2 show a first embodiment of the present invention, FIG. 1 is a sectional view of the cooling device, and FIG. 2(a) is a sectional view of the cooling device.
2(b) is a sectional view similar to FIG. 2(a) showing a modified example of the main body tube of the cooling device, and FIGS. 3 and 4 are the second cross-sectional view of the present invention. This shows an example of the third example.
Figure 4 is an overall configuration diagram of the cooling system, Figure 4 is an explanatory diagram of its operation, Figure 5 is an overall configuration diagram of the electronic endoscope, Figure 6 is a sectional view of the rigid tip of the TF endoscope, and Figure 7 is FIG. 3 is an IL view of the hard tip portion. 1-Main operation section, 2: Insertion section, 2C: Hard tip section, 6:
Tip body, 16. Solid-state image sensor, 17: Treatment instrument insertion channel, 18: Treatment instrument introduction part, '+0, 50: Cooling silicon, 31: Main body tube, 32: Partition wall, 33: Cooling fluid supply passage tool , 3 Cooling fluid recovery passage section, 35: Cooling fluid supply source, 38: Cooling fluid supply piping, 42: Fluid spout, 43: Fluid recovery [j, 51: Piping connection section, 52
: Connecting pipe, 53: Connecting wire, 54 Nigite member, 54
a Ni guide surface.

Claims (3)

[Claims] (1) In an electronic endoscope in which a solid-state imaging device is attached to the distal end of an insertion section, the instrument is inserted into a treatment instrument insertion channel formed in the insertion section and directed toward the placement position of the solid-state imaging device. A cooling device for electronic endoscopes that sprays cooling fluid. (2) A fluid distribution tube is connected to a fluid connection portion connected to a cooling fluid supply source, and a fluid jet is used to jet cooling fluid from the tip of the tube toward the location where the solid-state image sensor is disposed. The cooling device for an electronic endoscope according to claim 1, characterized in that the cooling device is configured to form an outlet. (3) Comprising a fluid connecting portion connected to a cooling fluid supply source, a cooling fluid guide member, and a connecting member connecting the guide member and the fluid connecting portion, the guiding member is The cooling fluid inserted through the instrument insertion channel and guided to the placement position of the solid-state imaging device, and supplied from the fluid connection portion through the treatment instrument insertion channel, is guided to the location of the solid-state imaging device by the guide member. The cooling device for an electronic endoscope according to claim 1, characterized in that the device is configured to be guided toward the installation position.