JP3958509B2 - Endoscope device with sterilization function - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an endoscope apparatus including a scope that is inserted into a body cavity and captures an image of an observation site, and more particularly, to an air supply / water supply process for sending air or water into the body cavity.
[0002]
[Prior art]
Endoscopic devices include those that optically transmit an image of an observation site and observe it with an eyepiece lens, and those that convert an image signal and display an image on a monitor. For example, in the case of an electronic scope having an image sensor The scope is connected to a processor that processes an image signal read from the image sensor. The processor is provided with a light source unit, and light emitted from the light source unit is transmitted in the direction of the observation site via a light guide (illuminating light optical fiber bundle) in the electronic scope. On the other hand, in the case of a fiberscope that optically transmits an image of an observation site using a fiber, the scope is connected to a light source device.
[0003]
In addition, an air supply / water supply channel through which water and air are passed to clean the objective lens provided at the tip of the scope is formed inside the scope. Water or air is sent from the processor or light source device to the scope. It is done. Further, not only the cleaning of the objective lens but also the body cavity can be cleaned using the water supply channel for ejection.
[0004]
[Problems to be solved by the invention]
By the way, when air / water is fed into a body cavity for cleaning, etc., it is necessary to sterilize bacteria contained in the outside air or tap water, and conventionally, a sterilization device separate from the endoscope device has been used. .
[0005]
However, when sterilizing using a sterilizer, sterilization treatment for air supply / water supply must be performed in advance, and work other than the endoscope must be performed. Furthermore, the sterilization process takes time, and the working efficiency using the endoscope is reduced.
[0006]
Accordingly, an object of the present invention is to provide an endoscope apparatus capable of performing a sterilization process using ultraviolet rays without reducing work efficiency in a medical practice using an endoscope and obtaining a stable sterilization effect. And
[0007]
[Means for Solving the Problems]
In the processor of the electronic endoscope apparatus of the present invention, an electronic scope provided with an optical fiber bundle for transmitting light and provided with a transport pipeline through which a fluid flows is detachably connected, and is connected to the transport pipeline. A flow tube, a pump that sends fluid to the transport line through the flow tube, and radiates ultraviolet rays to sterilize the fluid flowing through the flow tube, and illuminates the distal end of the electronic scope through the optical fiber bundle A light source that emits visible light, and a half mirror that guides visible light and ultraviolet light emitted from the light source in a direction in which the incident end of the optical fiber bundle and the flow tube exist are provided. The fluid is sterilized by irradiating the fluid in the flow tube with ultraviolet rays emitted from the light source. Therefore, it is sterilized in the process of sending the fluid into the body cavity without reducing the working efficiency. In addition, by using the light source provided to send the illumination light into the body cavity through the optical fiber bundle as a sterilization lamp, it is not necessary to provide a sterilization lamp separately from the conventional light source, and the configuration inside the processor is simplified. Is done.
[0008]
In order to extract only ultraviolet rays and visible rays, it is provided between the optical fiber bundle and the half mirror along the direction in which the ultraviolet rays and visible rays travel, and selectively transmits only visible rays of ultraviolet rays and visible rays. It is desirable to further include a visible light filter and an ultraviolet filter that is provided between the flow tube and the half mirror in a direction in which ultraviolet rays and visible rays travel, and transmits only ultraviolet rays and visible rays. By providing the filter in this way, only ultraviolet rays reach the fluid flowing through the flow tube, and only visible light enters the optical fiber bundle. Therefore, the fluid can be effectively sterilized, and only visible light necessary for photographing the subject reaches the body cavity.
[0009]
Transparent flow tube for irradiation because at least a part of the flow tube transmits ultraviolet light, and the flow direction of ultraviolet light and visible light guided by the half mirror toward the flow tube by the half mirror It is desirable that the pipe is spirally wound along a circumference substantially perpendicular to the pipe. By being arranged in a spiral shape so that it is exposed to ultraviolet rays, the ultraviolet rays are uniformly and effectively irradiated while the fluid is flowing.
[0010]
In order to prevent ultraviolet rays from leaking to the outside, it is desirable to further include a light shielding casing that houses the light source and the irradiating flow tube. Furthermore, in order to prevent ultraviolet rays from the light source from leaking out of the light shielding casing along the irradiation flow tube, the light shielding casing desirably has a light shielding member that blocks the ultraviolet rays. Further, the transport conduit is preferably a conduit that is formed along the optical fiber bundle and is a conduit for sending fluid toward the objective lens provided on the distal end side of the electronic scope. The fluid delivered from the processor is sent as it is through the electronic scope into the body cavity.
[0011]
For example, the fluid is a liquid including water. In this case, the processor further includes a tank for storing the liquid. Alternatively, the fluid is a gas including air.
[0012]
The processor of the electronic endoscope apparatus according to the present invention is provided with an optical scope provided with an optical fiber bundle that transmits light for irradiating a subject and a transport pipe through which a fluid flows. A feed pipe communicating with the pipe, a pump for sending fluid to the transport pipe through the feed pipe, an ultraviolet ray for sterilizing the fluid flowing through the feed pipe, and an electronic scope through the optical fiber bundle And a light source that emits visible light to illuminate the distal end side of the optical fiber, and the light source is arranged so that light from the light source reaches the incident end of the optical fiber bundle and the flow tube.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an endoscope apparatus according to an embodiment of the present invention will be described with reference to the drawings.
[0014]
FIG. 1 is a diagram schematically illustrating an endoscope apparatus according to the first embodiment. The endoscope apparatus according to the first embodiment is an electronic endoscope apparatus including an electronic scope having an image sensor, and includes a processor that processes an image signal and a monitor that displays an image together with the electronic scope. In particular, in the first embodiment, the processor is configured to send air into the body cavity.
[0015]
A cable 118 that is a part of the electronic scope 110 is connected to the connection portion 112 of the processor 120 via a connector portion 119, and an image sensor 113 such as a CCD is provided on the distal end side of the electronic scope 110. . The processor 120 is connected to a monitor 130 on which an image of the observation region is displayed. An image signal corresponding to the image of the observation region read from the image sensor 113 is converted into a video signal such as an NTSC signal in the processor 120. Sent to the monitor 130. In addition, a keyboard 140 is connected to the processor 120, and image processing can be performed on an image displayed on the monitor 130 by operating the keyboard 140.
[0016]
A light guide fiber bundle 115 for guiding light emitted from a light source unit (not shown) provided in the processor 120 to the distal end of the scope 110 is provided in the electronic scope 110, and the light guide fiber bundle 115 is provided. The light that has passed through is emitted from the distal end portion 117 of the electronic scope 110. As a result, the observation region is irradiated with light, and an observation region image is formed on the image sensor 113.
[0017]
In addition, pipes such as an air / water supply channel 116, a forceps channel 112, and an ejection flow pipe 114 are formed in the electronic scope 110, and these are used as necessary. The air / water supply channel 116 is formed along the light guide fiber bundle 115, and is formed from the connector part 119 to the tip part 117 of the electronic scope 110.
[0018]
The air / water supply channel 116 is a conduit for supplying water or air for cleaning an objective lens (not shown) interposed between the distal end portion 117 and the image sensor 113, and the operation portion 110 </ b> M of the electronic scope 110. By operating the air supply switch 110 </ b> A and the water supply switch 110 </ b> B, water or air flows from the processor 120 toward the distal end portion 117 of the electronic scope 110.
[0019]
FIG. 2 is a schematic diagram showing a schematic internal configuration of the processor. Here, components related to the sterilization treatment for air sent into the body cavity are mainly shown.
[0020]
The processor 120 is provided with flow pipes 210 and 215 for sending the air A to the air / water supply channel 116, and the flow pipe 210 is provided with an air / water supply base provided in the connector portion 119 of the electronic scope 110. 119A is connected.
[0021]
In the processor 120, the flow tube 210 is connected to a sterilizer 230 provided with a flow tube inside, and the sterilizer 230 supplies air A to the electronic scope 110 side via the flow tube 215. Connected to pump 250. That is, the pump 250 communicates with the air / water supply channel 116 of the electronic scope 110 via the flow pipe 215, the sterilizer 230, and the flow pipe 210. When the pump 250 is operated, the sucked air A Is sent to the air / water channel 116 of the electronic scope 110.
[0022]
A dust removal filter 270 is attached to the pump 250, and a vent hole 120 </ b> T is provided on a side surface of the processor 120 for sucking air A. The air A sucked by the pump 250 is purified by the dust removal filter 270 and then sent to the sterilizer 230. As the pump 250, a pump of a type that is unlikely to contaminate a fluid such as a diaphragm pump or a rotary pump is used here.
[0023]
The light source unit 600 provided so as to be in contact with the upper part of the sterilizer 230 includes a lamp 620 that emits light to be transmitted to the distal end side of the electronic scope 110. The light emitted from the lamp 620 is guided to the electronic scope 110 side via the relay fiber bundle 610 connected to the light guide fiber bundle 115 in the connector part 119. Further, as will be described later, the light emitted from the lamp 620 is also guided toward the sterilizer 230.
[0024]
In the present embodiment, the sterilizer 230, the pump 250, the light source unit 600, and the dust removal filter 270 are integrated as a unit 300 so that maintenance and inspection can be performed integrally during maintenance. The power / control unit 315 is provided to supply power to or control the circuits in the processor 120, and supplies power to the unit 300 and controls the light source unit 255 and the unit 300. The power supply / control cable 330 is a line connecting the power supply / control unit 315 and the connector 350, and in the unit 300, control signals and power are sent from the connector 350 to the sterilizer 230 and the pump 250. The light source unit 600 is connected to a power source / control unit 315 by a control cable 290, and a control signal is transmitted so that the lamp 620 is lit.
[0025]
The power supply / control unit 315 is electrically connected to the electronic scope 110 via a cable (not shown), and a signal generated when the air supply switch 110A (see FIG. 1) is pressed is transmitted from the electronic scope 110. It is sent to the power / control unit 315. The power source / control unit 315 outputs a control signal to the unit 300, the light source unit 600, and the like based on the transmitted signal. A signal processing circuit (not shown) for processing an image signal read from the image sensor 117 of the electronic scope 110 and outputting a video signal to the monitor 130, or an aperture for adjusting the amount of light irradiated into the body cavity A control signal is also sent from the power supply / control unit 315 to (not shown).
[0026]
FIG. 3 is a vertical cross-sectional view showing the configuration of the light source unit 600 and the sterilizer 230.
[0027]
The light source unit 600 includes a lamp 620 that collectively emits ultraviolet rays together with visible light, and a half mirror for causing the emitted visible rays and ultraviolet rays to travel in two directions. The lamp 620 emits light having a wavelength of 100 to 280 nm (UV-C as a section) having a bactericidal action in ultraviolet rays, and at the same time, emitting light of visible light (wavelength 380 to 800 nm). The light source unit 600 is covered with a light shielding casing 615.
[0028]
The light emitted from the lamp 620 travels in parallel along the direction of the relay fiber bundle 610. The path of light composed of visible light and ultraviolet light emitted from the lamp 620 is divided in two directions by the half mirror 630. One light is guided toward the sterilization device 230 to perform sterilization treatment with ultraviolet rays, and the other light travels toward the relay fiber bundle 610 for irradiation of the observation site.
[0029]
A visible light filter 645 that transmits only visible light is disposed on the incident end 650 of the fiber bundle 600. Therefore, only visible light among visible light and ultraviolet light passing through the half mirror 630 passes through the visible light filter 645 and enters the incident end 650.
[0030]
On the other hand, a circular opening 410 is formed between the sterilizer 230 and the light source 600, and an ultraviolet filter 640 that transmits only ultraviolet light is provided above the opening 410. It has been. The light reflected by the half mirror 630 passes through the ultraviolet filter 640 and proceeds into the sterilizer 230. At this time, only ultraviolet rays are guided into the sterilizer 230 by the ultraviolet filter 640.
[0031]
The sterilizer 230 is a miniaturized device that sterilizes a fluid by irradiating the air A with ultraviolet rays, and is covered with a light shielding casing 430. The gas A sent from the pump 250 (see FIG. 2) through the flow pipe 215 is a flow pipe (irradiation flow pipe) piped into the sterilizer 230 via the connection connector 490 and the light shielding member 470. ) 420. The flow tube 420 is a transparent tube to sufficiently irradiate ultraviolet rays, and is also spirally piped around an axis substantially perpendicular to the traveling direction of light irradiated from the direction of the light source unit 620. Yes. The air A sent by the air supplied by the pump 250 proceeds upward along the flow pipe 420 arranged in a spiral shape, and moves toward the flow pipe 210. The length of the diameter of the flow pipe arranged in a spiral shape is equal to or less than the length of the diameter of the opening 410. The spiral flow pipe 420 is held by a transparent mesh mat (not shown) extending along the side wall of the light shielding casing 430. Although not shown in FIG. 3, a pipe is connected between the first part 420A and the second part 420B of the flow pipe 420, and a third part 420C and a fourth part 420D are also connected.
[0032]
When the air supply switch 110A is pressed, the pump 250 is activated. While the gas A sent to the sterilizer 230 passes through the spiral flow pipe 420, the ultraviolet light that has passed through the ultraviolet filter 640 is irradiated onto the gas A. Thereby, the gas A is sterilized. The sterilized gas A passes through the light shielding member 460 and the connection connector 480 from the flow pipe 420 and is sent to the flow pipe 210 outside the sterilizer 230.
[0033]
The light shielding casings 430 and 615 are casings for preventing ultraviolet rays radiated from the lamp 620 from leaking out of the sterilizer 230, and are members that block the ultraviolet rays (for example, black-colored metal or black silicon rubber). ). A diaphragm (not shown) is provided between the half mirror 630 and the visible light filter 645, and is driven as necessary.
[0034]
FIG. 4 is a longitudinal sectional view showing the light shielding member 460. The light shielding members 460 and 470 are similarly configured, and only the light shielding member 460 will be described here.
[0035]
The light shielding member 460 includes covers 500 and 510 attached to the inner and outer surfaces of the light shielding casing 430, and the covers 500 and 510 have through holes for penetrating the flow pipe 420 at corresponding (opposite) positions. 520 and 530 are formed. The light shielding casing 430 is provided with through holes 540 at positions shifted from the positions of the through holes 520 and 530 with respect to the through holes 520 and 530. As a result, the flow pipe 420 is curved between the through holes 520 and 530.
[0036]
A bolt 550 is inserted into the cover 510 from the outside, and the bolt 550 passes through the casing 530 and is screwed into the cover 500. Accordingly, the covers 500 and 510 are fixed to the light shielding casing 430. In the connection connector 480 outside the light shielding member 460, the flow tube 420 and the flow tube 210 are detachably connected, and when the sterilizer 230 is separated from other members, the flow tube 420 flows. Removed from tube 210.
[0037]
As described above, according to the first embodiment, the sterilizer 230 is provided in the processor 120, and the ultraviolet light out of the light emitted from the light source unit 600 having the lamp 620 is guided to the sterilizer 230. Is sent to the air / water supply channel 116 and sterilized by ultraviolet rays, and the sterilized air A is sent to the electronic scope 110. By providing the sterilization device 230 in the processor 120, it is not necessary to prepare a sterilization device separately as in the prior art, and the air A is sterilized in the process of air supply. You can save time and effort. Further, by using the lamp 620 provided for irradiating the observation site with illumination light as a lamp for sterilization treatment, it is not necessary to prepare a new sterilization lamp other than the lamp 620, and the configuration within the processor 120 is improved. Simplified.
[0038]
The external shapes of the sterilizer 230 and the light source unit 600 are formed by light shielding casings 430 and 615, and the lamp 620 is housed in the light shielding casing 615 that blocks ultraviolet rays. Thereby, the external leakage of ultraviolet rays is prevented, and the human body is not harmed. Furthermore, the sterilizer 230 includes light shielding members 460 and 470, and the flow pipe 420 is curved. This prevents ultraviolet rays from leaking out along the flow pipes 420 and 210 or the flow pipes 420 and 215.
[0039]
The sterilizer 230 is compactly packed and downsized due to the fact that the flow pipe 420 is provided in a spiral shape, and thus the sterilizer 230 can be incorporated without increasing the size of the processor 120. is there. The sterilizer 230 is connected to the flow pipes 210 and 215 via the connectors 480 and 490, and can be separated from other components. Therefore, maintenance work is easy. Further, by making the light shielding casings 430 and 615 separable, the ultraviolet lamp 400 can be detachably attached to the light shielding casing 430, so that the lamp can be easily replaced as necessary.
[0040]
In this embodiment, in order to effectively sterilize, the feed pipe 420 is spirally piped. However, other pipes may be used as long as the ultraviolet rays emitted from the lamp 620 are efficiently irradiated. May apply. For example, it may be piped in a toggro shape (a mixed shape of a spiral shape and a spiral shape) with the traveling direction of ultraviolet rays as an axis.
[0041]
Next, an electronic endoscope apparatus according to the second embodiment will be described with reference to FIG. In the second embodiment, unlike the first embodiment, a liquid such as water is sent to the electronic scope 110. Other configurations are the same as those in the first embodiment.
[0042]
FIG. 5 is a diagram schematically illustrating components related to water supply in the processor 120 according to the second embodiment.
[0043]
The processor 120 includes a light source unit 600, a sterilizer 240, a pump 260, and a tank 280. The sterilizer 240 is disposed between the flow pipes 225 and 235, and the tank 280 and the flow pipe 225 are arranged. A pump 260 is disposed between the two. The flow tube 225 is connected to the air / water channel 116 of the electronic scope 110 (not shown here), as in the first embodiment. The sterilizer 240 and the pump 260 are configured as a unit 320, and the power source / control unit 315 supplies power to the unit 320 through the cable 340 and the connector 360 and controls the unit 320. The configurations of the pump 260 and the sterilizer 240 are the same as the configurations of the pump 250 and the sterilizer 230 in the first embodiment, respectively.
[0044]
The water W is stored in the tank 280, and the water W is sucked up by operating the pump 260 by operating the water supply switch 110B (see FIG. 1). The sucked water W is conveyed to the sterilizer 240 through the flow pipe 225. And in the sterilizer 240, the water W is sterilized with the ultraviolet-ray of the light radiated | emitted from the lamp | ramp 620 similarly to 1st Embodiment. The sterilized water W is sent to the air / water channel 116 of the electronic scope 110 via the flow pipe 235.
[0045]
As described above, according to the second embodiment, the water W is sterilized while the water W is being sent from the tank 280 to the air supply / water supply channel of the electronic scope 110, and the water W is sterilized without lowering the work efficiency. be able to. The tank 280 may be provided outside (side surface) of the processor 120.
[0046]
As shown in the first and second embodiments, the sterilizer 230 and the pump 250, and the sterilizer 240 and the pump 260 are configured as units 300 and 320, respectively. Such unitization makes it easy to replace parts during maintenance. In particular, when changing from air supply to water supply, it is only necessary to replace the unit 300 with the unit 320, which facilitates the replacement. In addition, since the connection between the power source / control unit 315 and the units 300 and 320 is unified, the circuit configuration is simplified.
[0047]
In the first and second embodiments, water W or air A is sent to the distal end side of the electronic scope 110 via the air / water supply channel 116. The forceps channel 112 and the ejection water supply channel 114 (see FIG. 1). May be used to send air A and water W into the body cavity. In this case, a tube that connects the forceps port 112N of the forceps channel 112 or the water supply port 114N of the ejection water supply channel 114 and a flow pipe for supplying air or water in the processor 120 is provided.
[0048]
Next, a third embodiment will be described with reference to FIG. The third embodiment is different from the first and second embodiments in that an endoscope apparatus including a fiberscope and a light source device is applied.
[0049]
FIG. 6 is a diagram showing a fiberscope and a light source device.
[0050]
The fiberscope 810 includes an image fiber bundle 811 that optically sends an image of an observation site to the eyepiece 814, an air / water channel 816, a forceps channel 812, an air switch 810A, a water switch 810B, and a light guide fiber bundle 815. Have. The fiberscope 810 is connected to the light source device 800 via a cable 818, and the air / water supply channel 816 is connected from the light source device 800 to the tip of the fiberscope 810, as in the first and second embodiments. It is formed across. The light source device 800 is provided with a light source unit (not shown) as in the conventional light source device, and light emitted from the light source unit is sent to the tip of the fiber scope 810 via the light guide fiber bundle 815. It is done.
[0051]
In addition, the light source device 800 incorporates the unit 300 in the first embodiment or the unit 320 in the second embodiment, and the configuration of the other air / water supply is the same as that of the first and second embodiments. Substantially the same components are incorporated.
[0052]
As described above, according to the third embodiment, when the unit 300 or the unit 320 is incorporated in the light source device 800, the water W or the air A is sterilized even when a treatment is performed using the fiberscope 810. can do.
[0053]
In the first to third embodiments, the parallel light radiated from the lamp 620 is guided by the half mirror 630 in the direction of the sterilizer 230 and the two directions of the relay fiber bundle 610. However, the half mirror 630 is not provided. The lamp 620 for diffusing light may be arranged at the position of the half mirror 630 in FIG. In this case, even without the half mirror, the ultraviolet light travels into the sterilizer 230 and the visible light is incident on the incident end 650 of the relay fiber bundle 610.
[0054]
【The invention's effect】
As described above, according to the present invention, it is possible to effectively perform sterilization without reducing work efficiency in medical practice using an endoscope.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an electronic endoscope apparatus according to a first embodiment.
FIG. 2 is a schematic diagram showing a schematic internal configuration of a processor.
FIG. 3 is a longitudinal sectional view showing a sterilization apparatus and a light source unit.
FIG. 4 is a longitudinal sectional view showing a light shielding member.
FIG. 5 is a diagram showing an electronic endoscope apparatus according to a second embodiment.
FIG. 6 is a diagram showing a fiberscope and a light source device according to a third embodiment.
[Explanation of symbols]
110 Electronic Scope 115, 815 Light Guide Fiber Bundle (Optical Fiber Bundle)
116,816 Air / water supply channel (transportation pipeline)
120 Processor 210, 215 Flow tube 225, 235 Flow tube 230, 240 Sterilizer 250, 260 Pump 280 Tank 300, 320 Unit 420 Flow tube (irradiation flow tube)
430, 615 Shading casing 460, 470 Shading member 600 Light source 610 Relay fiber bundle (optical fiber bundle)
620 lamp (light source)
630 Half mirror 640 UV filter 645 Visible light filter 810 Fiber scope 811 Image fiber bundle (Optical fiber bundle for image)

Claims (12)

An electronic scope provided with an optical fiber bundle for transmitting light for irradiating a subject and a transport pipeline through which a fluid flows is detachably connected,
A flow pipe communicating with the transport pipeline;
A pump for sending the fluid to the transport line via the flow pipe;
A light source that emits ultraviolet light to sterilize the fluid flowing through the flow tube and emits visible light to illuminate the distal end side of the electronic scope via the optical fiber bundle;
A half mirror that guides the visible light and ultraviolet rays radiated from the light source in a direction of an irradiation current tube that is at least a part of the incident end of the optical fiber bundle and transmits the ultraviolet light ;
A first light shielding casing for accommodating the light source, the half mirror, and an incident end of the optical fiber bundle;
A second light shielding casing that is adjacent to the first light shielding casing so as to be integrated, and that accommodates the irradiation flow pipe;
A processor for an electronic endoscope apparatus, wherein an opening is formed between the first light shielding casing and the second light shielding casing .   A visible light filter that is provided between the optical fiber bundle and the half mirror along a direction in which the ultraviolet rays and visible rays travel, and selectively transmits only visible rays of the ultraviolet rays and visible rays; The processor of the electronic endoscope apparatus according to claim 1. The processor of the electronic endoscope apparatus according to claim 1, further comprising an ultraviolet filter provided between the opening and the half mirror and transmitting only the ultraviolet rays of the ultraviolet rays and visible rays. . The irradiation feed flow tube, said plumbed wound spirally along the axis perpendicular direction around the traveling direction of the ultraviolet and visible light guided to the direction of the irradiation feed flow tube by the half mirror The processor of the electronic endoscope apparatus according to claim 1, wherein The second light-shielding casing covers a through-hole formed in the second light-shielding casing so as to allow the flow-feed pipe to pass from both the outside and the inside of the second light-shielding casing. The processor of the electronic endoscope apparatus according to claim 1 , further comprising a light shielding member in which a pair of through-holes for passing is formed . 6. The processor of an electronic endoscope apparatus according to claim 5 , wherein the position of the through hole is deviated from the position of the pair of through holes so that the flow tube is curved .   The transport pipe is a pipe for sending the fluid in a direction of an objective lens provided on a distal end side of the electronic scope, and is formed along the optical fiber bundle. The processor of the electronic endoscope apparatus according to 1.   The processor of the electronic endoscope apparatus according to claim 1, wherein the fluid is a liquid containing water and further includes a tank for storing the liquid.   The processor of the electronic endoscope apparatus according to claim 1, wherein the fluid is a gas containing air. A fiberscope having an optical fiber bundle for transmitting light for illuminating a subject and an optical fiber bundle for images for optically transmitting images and provided with a transport pipeline through which fluid flows is detachably connected,
A flow pipe communicating with the transport pipeline;
A pump for sending the fluid to the transport line via the flow pipe;
A light source that emits ultraviolet light to sterilize the fluid flowing through the flow tube and emits visible light to illuminate the distal end side of the fiberscope through the optical fiber bundle;
A half mirror that guides the visible light and ultraviolet rays radiated from the light source in a direction of an irradiation current tube that is at least a part of the incident end of the optical fiber bundle and transmits the ultraviolet light ;
A first light shielding casing for accommodating the light source, the half mirror, and an incident end of the optical fiber bundle;
A second light shielding casing that is adjacent to the first light shielding casing so as to be integrated, and that accommodates the irradiation flow pipe;
An endoscope light source device , wherein an opening is formed between the first light shielding casing and the second light shielding casing . An electronic scope provided with an optical fiber bundle for transmitting light for irradiating a subject and a transport pipeline through which a fluid flows is detachably connected,
A flow pipe communicating with the transport pipeline;
A pump for sending the fluid to the transport line via the flow pipe;
A light source that emits ultraviolet light to sterilize the fluid flowing through the flow tube and emits visible light to illuminate the distal end side of the electronic scope via the optical fiber bundle ;
A first light shielding casing for accommodating the light source and an incident end of the optical fiber bundle;
A second light shielding casing that is adjacent to the first light shielding casing so as to be integrated, and that accommodates an irradiation current transmission pipe that is at least a part of the flow transmission pipe and transmits ultraviolet rays ;
The light source is arranged so that light from the light source reaches the incident end of the optical fiber bundle and the irradiation flow tube ,
A processor for an electronic endoscope apparatus, wherein an opening is formed between the first light shielding casing and the second light shielding casing . A fiberscope having an optical fiber bundle for transmitting light for illuminating a subject and an optical fiber bundle for images for optically transmitting images and provided with a transport pipeline through which fluid flows is detachably connected,
A flow pipe communicating with the transport pipeline;
A pump for sending the fluid to the transport line via the flow pipe;
A light source that emits ultraviolet light to sterilize the fluid flowing through the flow tube and emits visible light to illuminate the distal end side of the fiberscope through the optical fiber bundle ;
A first light shielding casing for accommodating the light source and an incident end of the optical fiber bundle;
A second light shielding casing that is adjacent to the first light shielding casing so as to be integrated, and that accommodates an irradiation current transmission pipe that is at least a part of the flow transmission pipe and transmits ultraviolet rays ;
The light source is arranged so that light from the light source reaches the incident end of the optical fiber bundle and the irradiation flow tube ,
An endoscope light source device , wherein an opening is formed between the first light shielding casing and the second light shielding casing .

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