JP2018102383A - Lens washing sheath for endoscope - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lens washing sheath for an endoscope that includes a tip constituting part at the tip part of an insertion part, can wash the whole surface of an objective lens by making a fluid jetted from a fluid jet port to an internal space surrounded by a wall part into a vortex flow of a predetermined force, and discharge the fluid in the internal space after the washing so that good endoscope observation can be performed.SOLUTION: A washing sheath 10 includes a tip constituting part 30 fixed to the tip part of a multi-lumen tube 20 for coating an insertion part 2 of an endoscope 1, a wall part 80 having an internal wall surface 81 that protrudes to a front side from a distal end surface 7f and surrounds the distal end surface 7f in a state where a distal end part 7 is disposed in the tip constituting part 30, a fluid jet port 71 provided to the internal wall surface 81, which regulates a jet direction so that the fluid can flow toward a partial region of the surface of an observation window 7a, a deflection surface 82 for deflecting a flow direction so that the fluid can flow toward another region of the observation window 7a when the fluid collides, and a fluid discharge part 83 for discharging the fluid jetted to an internal space S surrounded by the wall part 80.SELECTED DRAWING: Figure 6C

Description

  The present invention relates to an endoscope lens cleaning sheath that is attached to an insertion portion of an endoscope and cleans an observation window and the like.

  An observation window, an illumination window, and the like are provided at the distal end portion of the insertion portion of the endoscope. Good observation becomes difficult when dirt or the like adheres to the outer surface of the observation lens or the outer surface of the illumination lens. In order to solve this problem, a cleaning nozzle is provided at the distal end portion, or an endoscope lens cleaning sheath is attached to the distal end portion to remove dirt and the like on the outer surface of the lens.

  Patent Document 1 discloses an endoscope provided with a fluid ejection nozzle that cleans dirt and the like attached to an observation window provided on a distal end body of an endoscope, an endoscope with a tip cap, and an endoscope. A cleaning sheath is shown. The fluid jet nozzle joins gas and liquid to form a spray-like gas-liquid mixed fluid, and this mixed fluid is jetted from the jet port toward the observation window to efficiently clean the filth adhering to the observation window. To do.

  In recent years, the objective lens of an objective optical system of an endoscope has been increased in size as the image quality is improved or 3D is achieved. When the objective lens becomes large, it becomes difficult to spread the fluid ejected from the endoscope cleaning nozzle or the fluid ejection nozzle described above over the entire surface of the objective lens.

  In order to disperse the fluid over the entire surface of the objective lens for cleaning, the shape of the nozzle nozzle can be adjusted to widen the cleaning range of the nozzle, or the insertion portion in which an observation window is arranged It is conceivable to provide a wall portion surrounding the front surface of the front end surface of the liquid and to wash the fluid jetted from the fluid jet port by generating a vortex of a predetermined flow rate in the wall portion and uniformly cleaning the fluid.

Japanese Patent No. 5164644

  However, when the cleaning range is widened as described above, the flow of fluid ejected from the fluid ejection port of the nozzle is gradually attenuated as the cleaning range is widened. As the flow is attenuated, the cleaning power for removing dirt and the like attached to the lens surface is reduced, making it difficult to perform good endoscopic observation.

  On the other hand, when cleaning is performed by providing a wall portion surrounding the distal end surface of the insertion portion and generating a predetermined vortex in the wall portion, a liquid such as water enters the internal space surrounded by the wall portion after cleaning. There is a risk that it may remain and cause observation defects such as vignetting of the observation field.

  The present invention has been made in view of the above circumstances, and by disposing a tip constituent portion at the tip portion of the insertion portion, the fluid jetted from the fluid jet port to the internal space surrounded by the wall portion has a predetermined flow. A lens cleaning sheath for an endoscope that can clean the entire surface of an objective lens that has been enlarged in the form of a swirl of force, and discharges the fluid that has flowed through the internal space after the cleaning is complete so that good endoscopic observation can be performed. The purpose is to provide.

  An endoscope lens cleaning sheath according to an aspect of the present invention is fixed to a distal end portion of a tube body that covers an insertion portion of an endoscope that is inserted into a subject, and has a distal end having an observation window of the insertion portion A distal end configuration portion on which the portion is disposed, and in a state where the distal end portion is disposed on the distal end configuration portion, the distal end portion of the distal end configuration portion protrudes forward from the distal end portion distal end surface of the insertion portion. A wall portion having an inner wall surface provided so as to surround the tip surface of the tip portion, and a predetermined region which is provided at a predetermined position on the inner wall surface of the wall portion and is a part of the surface of the observation window Are provided at a predetermined position on the inner wall surface of the wall portion and a fluid jet port that defines a jet direction of the fluid so that the fluid flows in a predetermined direction. When the fluid ejected toward the A deflection surface for deflecting a flow direction so that the fluid flows toward another region different from the predetermined region on the surface of the observation window; and an internal space surrounded by the wall portion from the fluid ejection port And a fluid discharge part for discharging the fluid ejected to.

  According to the present invention, by disposing the tip constituent portion at the tip portion of the insertion portion, the fluid jetted from the fluid jet port to the internal space surrounded by the wall portion is converted into a vortex of a predetermined flow rate and is enlarged. In addition, it is possible to clean the entire surface of the objective lens, and it is possible to realize an endoscope lens cleaning sheath that can discharge the fluid that has flowed through the internal space and perform good endoscopic observation after the cleaning is completed.

The figure explaining the endoscope and the lens cleaning sheath for endoscopes attached to the insertion part of the endoscope It is arrow Y2-Y2 sectional view taken on the line of FIG. 1, Comprising: The figure explaining the through-hole provided in the multi-lumen tube The figure explaining the tip composition part fixed to a multi-lumen tube The figure which looked at the tip composition part of Drawing 3A from the front FIG. 3B is a cross-sectional view taken along line Y3C-Y3C. 3B is a cross-sectional view taken along line Y3D-Y3D in FIG. The figure which looked at the tip composition part of Drawing 3A from the back The figure explaining the structure and effect | action of a fluid ejection nozzle and a deflection surface The figure explaining the state by which the front-end | tip part of the insertion part was mounted | worn in the front-end | tip structure part of a washing | cleaning sheath It is a front view of Drawing 5A, and is a figure explaining a fluid ejection direction and the 1st field. The figure explaining the flow of the gas-liquid mixed fluid which is ejected from a fluid ejection port and goes to a deflection surface The figure which shows the gas-liquid mixed fluid which flows in a vortex in the cleaning space in the wall after being ejected from the fluid ejection port The figure explaining the state where the gas-liquid mixed fluid in the cleaning space is discharged after the cleaning operation is completed The figure explaining the front-end | tip structure part which provided the 1st discharge part and the 2nd discharge part in the vicinity of the fluid jet nozzle The figure explaining the front-end | tip structure part which provided the notch groove near the fluid jet nozzle The figure explaining the front-end | tip structure part which provided the discharge part in the center of the wide part, and provided the fluid ejection port in the middle of the wide part and the narrow part. The figure explaining the other structural example of a discharge part The figure explaining another example of composition of a discharge part The figure explaining the structural example of the front-end | tip structure part provided with the suction path. FIG. 8B is a cross-sectional view taken along line Y8B-Y8B in FIG. The figure explaining the multi-lumen tube fixed to the front-end | tip structure part provided with the suction path The figure explaining the front-end | tip structure part which used the inner wall surface and the deflection surface as the water-repellent surface.

Embodiments of the present invention will be described below with reference to the drawings.
In each drawing used in the following description, the scale of each component may be different in order to make each component large enough to be recognized on the drawing. That is, the present invention is not limited only to the number of components, the shape of the components, the ratio of the sizes of the components, and the relative positional relationship between the components described in these drawings.

An endoscope 1 and an endoscope lens cleaning sheath (hereinafter, abbreviated as a cleaning sheath) 10 will be described with reference to FIG.
First, the endoscope 1 will be described.

  An endoscope 1 according to this embodiment shown in FIG. 1 is a rigid endoscope having a curved portion, for example. The endoscope 1 mainly includes an elongated insertion portion 2 along the longitudinal axis a <b> 2 and an operation portion 3 provided on the proximal end side of the insertion portion 2. Reference numeral 4 denotes a universal cord 4 that extends from the base end side of the operation unit 3. A connector (not shown) is provided at the end of the universal cord 4.

  The universal cord 4 is connected to an observation control unit 5 that is an external device via a connector. The observation control unit 5 includes, for example, an image processing unit (not shown) such as an image processor, and a light source unit (not shown) that supplies illumination light. Reference numeral 6 denotes a display device.

The insertion part 2 has a hard tip part 7, a bending part 8, and a hard pipe part 9 in order from the tip side. The bending portion 8 is provided between the distal end portion 7 and the tube portion 9, and is configured to bend in two directions perpendicular to the longitudinal axis a2 of the insertion portion 2, for example.
In addition, the bending part 8 is not limited to the structure which curves in two directions, The structure curved in four directions perpendicular | vertical with respect to the longitudinal axis a2 may be sufficient.

  For example, an observation window 7a that is one observation window and two illumination lenses 7b and 7c that are illumination windows are provided on the distal end surface 7f of the distal end 7 that is the distal end surface. Inside the distal end hard portion (not shown) constituting the distal end portion 7, an imaging device provided with an imaging element (not shown) such as a CCD, and the like are arranged so that the distal end surface faces the illumination lenses 7 b and 7 c. Two light guides (not shown) are provided. An imaging cable (not shown) extends from the imaging device.

  The imaging cable and the two light guides are arranged inside the insertion portion 2, inside the operation portion 3, and inside the universal cord 4. An end of the imaging cable and an end of the light guide are disposed in the connector.

  By connecting the connector to the observation control unit 5, the imaging device and the image processing unit are electrically connected, and illumination light emitted from the light source unit is guided to the light guide. The guided illumination light passes through the illumination lenses 7b and 7c and irradiates the subject.

  The optical image of the subject illuminated by the illumination light passes through the observation window 7a and forms an image on the imaging device of the imaging device. Then, the electrical signal converted by the imaging device is transmitted to the image processing unit via the imaging cable. The transmitted electrical signal is generated as an image signal by the image processing unit and output to the display device 6. As a result, an endoscopic image of the subject is displayed on the screen of the display device 6.

  The operation unit 3 is provided with a bending operation lever 3a as a bending operation device. The bending portion 8 is bent in accordance with the operation of the bending operation lever 3a. Reference numerals 3b, 3c, and 3d denote various switches, for example, a freeze switch that generates a freeze signal, a release switch that generates a release signal when taking a picture, an observation mode changeover switch that instructs an observation mode, and the like. is there.

Next, the cleaning sheath 10 will be described.
The cleaning sheath 10 shown in FIG. 1 includes a multi-lumen tube 20 that is a tube body. The multi-lumen tube 20 is a cleaning sheath body, and is formed of a soft material such as silicone or urethane and has flexibility.

A distal end configuration portion 30 that is a cylindrical body is fixed to the distal end portion of the multi-lumen tube 20, and an endoscope attachment portion 40 is fixed to the proximal end portion. The insertion portion 2 of the endoscope 1 is inserted into the cleaning sheath 10 from the proximal end side of the endoscope attachment portion 40 as shown by a two-dot chain line.
In the state where the multi-lumen tube 20 is covered with the insertion portion 2, the bending portion 8 of the insertion portion 2 is freely bendable.

  As shown in FIG. 2, the multi-lumen tube 20 includes an endoscope insertion portion hole 21 having a predetermined diameter, and an air supply hole 22 and a water supply hole 23 as fluid holes. . The endoscope insertion portion hole 21, the air supply hole 22, and the water supply hole 23 are longitudinal through holes provided along the central axis a <b> 20 of the multi-lumen tube 20. Therefore, the opening of each hole is formed in each end surface.

  The endoscope insertion portion hole 21 is a hole through which the insertion portion 2 of the endoscope 1 is inserted. Therefore, the diameter of the endoscope insertion portion hole 21 is set larger than that of the insertion portion 2. The central axis a <b> 21 of the endoscope insertion portion hole 21 is provided so as to be misaligned with respect to the central axis a <b> 20 of the multi-lumen tube 20. For this reason, the multi-lumen tube 20 has a constant thickness in the circumferential direction, and includes a thin portion 24 and a thick portion 25. An air supply hole 22 and a water supply hole 23 are provided at a predetermined position of the thick portion 25.

  The air supply hole 22 functions as an air supply conduit for supplying, for example, air as a fluid. On the other hand, the water supply hole 23 functions as a water supply conduit for supplying, for example, water as a fluid. On the front end surface of the multi-lumen tube 20 (reference numeral 26 in FIG. 3C), an air supply opening (reference numeral 22 m in FIG. 4) that is the front end opening of the air supply hole 22 and a water supply opening that is the front end opening of the water supply hole 23 (see FIG. 4 and 23m).

  1 is formed of a material harder than the multi-lumen tube 20, and does not have flexibility. A connecting hole 41h (not shown) for connecting the multi-lumen tube 20 and a control valve operation button 42 are provided on the distal end surface 41 of the endoscope mounting portion 40, and an insertion portion introduction port (not shown) is provided on the proximal end surface 43. Is provided. The control valve operation button 42 can be “fully pressed” or “half-pressed”. For example, when the control valve operation button 42 is fully pressed, a spray-like gas-liquid mixed fluid is ejected from a fluid outlet described later, and when pressed halfway, Air is ejected from the spout.

  In addition, an air supply tube connection port (not shown) to which one end of the air supply tube 44 is connected and a water supply tube connection to which one end of the water supply tube 45 is connected to a predetermined position of the endoscope mounting portion 40. A mouth (not shown) is provided. In addition, the endoscope attachment portion 40 is provided with an air supply path that communicates with the air supply tube connection port and a water supply path that communicates with the water supply tube connection port.

  An opening of the insertion portion hole communicating with the endoscope insertion portion hole 21 of the multi-lumen tube 20 fixed to the connection hole 41h is formed on the bottom surface (not shown) of the connection hole 41h. An opening of the air supply path that leads to the hole 22 is formed, and an opening of the water supply path that leads to the water supply hole 23 is formed.

  The other end of the air supply tube 44 is connected to the air supply unit 50, and the other end of the water supply tube 45 is connected to the water supply unit 60. The air supply unit 50 includes an air supply pump 51 and a pressure adjustment valve 52. The water supply unit 60 includes a water supply pump 61 and a water supply tank 62. When the air supply pump 51 and the water supply pump 61 are driven, fluid air is supplied into the air supply hole 22 via the air supply tube 44 and the air supply path, and water as the fluid is supplied to the water supply tube 45. The water is supplied into the water supply hole 23 through the water supply path.

The tip component 30 will be described with reference to FIGS. 3A-3E.
As shown in FIG. 3A, the distal end configuration portion 30 is provided at the distal end portion of the multi-lumen tube 20.

  As shown in FIGS. 3B to 3D, the tip component portion 30 is provided with a stepped through hole (hereinafter referred to as a stepped hole) 31. The stepped hole 31 has a large diameter hole 32 and a small diameter hole 33. The large diameter hole portion 32 is provided on the proximal end side of the distal end configuration portion 30, and the small diameter hole portion 33 is provided on the distal end side of the distal end configuration portion 30. Reference numeral 34 denotes a step surface.

  The large-diameter hole portion 32 is a multi-lumen tube disposing portion, and the tip portion of the multi-lumen tube 20 is disposed. The central axis a32 of the large-diameter hole portion 32 is coaxial with the central axis a30 of the tip component portion, that is, coaxial. The small diameter hole portion 33 is an insertion portion arrangement portion, and the distal end portion 7 of the insertion portion 2 is disposed. The central axis a33 of the small-diameter hole 33 is parallel to the tip component central axis a30 and is displaced in a predetermined direction.

For this reason, as shown in FIG. 3E, the stepped surface 34 between the large-diameter hole portion 32 and the small-diameter hole portion 33 has a narrow portion 36 where the distal end surface of the thin portion 24 of the multi-lumen tube 20 is disposed, and the tube 20 And a wide portion 37 in which the front end surface of the thick portion 25 is disposed.

  The distal end surface 7 f of the distal end portion 7 of the insertion portion 2 is arranged in the small diameter hole portion 33 so as to be located in the middle of the distal end surface 30 a and the stepped surface 34 of the distal end configuration portion 30. Since the distal end surface 7f of the distal end portion 7 is located in the middle of the small-diameter hole 33, the inner surface is provided so as to protrude forward from the distal end surface 7f of the distal end portion 7 so as to surround all or a part of the distal end surface 7f. A wall portion 80 having a wall surface 81 appears on the distal end side of the distal end configuration portion 30.

  As shown in FIGS. 3A to 3D, there are fluid outlets 71, a deflecting surface 82, and a fluid discharge part (hereinafter abbreviated as a discharge part) 83 at a predetermined position of the inner wall surface 81 of the wall part 80. An opening 83m is provided. The discharge opening 83m is formed in the vicinity of the fluid jet 71 and on the side in the circumferential direction.

The fluid ejection port 71 and the discharge opening 83m are provided across a vertical line L that connects the substantially central portion of the wide portion 37, the central axis a33 of the small-diameter hole portion 33, and the central axis a30 of the tip component portion. When the distal end portion 7 of the insertion portion 2 is mounted in the small-diameter hole portion 33 of the distal end configuration portion 30, the fluid ejection port 71 and the discharge opening 83m are positioned and arranged below the observation window 7a. Yes. Reference numeral S denotes a cleaning space, which is an internal space surrounded by the wall 80. The cleaning space S includes a front end surface 7f, an inner wall surface 81, and a deflection surface 82.
3B, FIG. 3C, and FIG. 3E, the code | symbol 72 is a mixed fluid ejection path, the code | symbol 73 is a gas-liquid mixing path, and the code | symbol 74 is a fluid guide groove.

  As shown in FIG. 3C, a mixing path central axis a73, which is the central axis of the gas-liquid mixing path 73, is provided along the hole central axis a33. The ejection path center axis a72, which is the central axis of the mixed fluid ejection path 72, is provided so as to intersect at the angle θ1 with respect to the distal end surface 7f of the distal end portion 7 disposed at a predetermined position in the small diameter hole portion 33. . The angle θ1 is an acute angle. The mixed fluid ejection path 72 is a communication path that communicates with the space of the mixing path end 73 b and the inside of the small diameter hole 33.

As shown in FIG. 3D, the discharge portion 83 is a through-hole having a predetermined diameter that passes through the cleaning space S and the outside of the wall portion 80, and has a discharge opening 83m on the inner wall surface 81 side and has an outer peripheral surface side. Has a drain outlet 83e. The proximal end side surface 83a of the discharge opening 83m is formed to be flush with the distal end surface 7f of the distal end portion 7 disposed in the small diameter hole portion 33.
The cross-sectional shape of the through hole is not limited to a circle, and may be a long hole, a square hole, or the like.

  As shown in FIG. 3E, the wide portion 37 of the step surface 34 is provided with a fluid guide groove 74 having an opening in the wide portion 37. The fluid guide groove 74 is an arc-shaped groove and includes a first end portion 74a and a second end portion 74b at predetermined positions. Specifically, the first end portion 74a and the second end portion 74b are in a symmetrical positional relationship with a first axis y30 orthogonal to the mixing path central axis a73 and the central axis a30 of the gas-liquid mixing path 73 interposed therebetween.

  Reference numeral 73m in FIG. 3C denotes a mixed fluid ejection path inlet (hereinafter referred to as an inflow opening). The center of the inflow port 73m is located on the first axis y30, and the mixing channel central axis a73 is orthogonal to the first axis y30. As a result, the fluid guide groove 74 has a first guide groove 74c extending from the first end 74a side to the inflow port 73m, and a second guide groove 74d extending from the second end portion 74b side to the inflow port 73m. It has become.

  The arrow YB in FIG. 4 is the fluid ejection direction. It is defined that the gas-liquid mixed fluid or air is ejected from the fluid ejection port 71 toward the deflection surface 82 with a predetermined flow. The mixed fluid ejection path 72 is formed to be inclined at a predetermined angle with respect to the first axis y30.

  In the large-diameter hole 32 described above, the tip of the multi-lumen tube 20 is fixed as shown by the two-dot chain line in FIGS. 3C and 3D. In a state where the distal end portion of the multi-lumen tube 20 is fixed in the large-diameter hole portion 32, the distal end surface 26 of the multi-lumen tube 20 is disposed in close contact with the step surface 34. The distal end surface of the thin portion 24 of the multi-lumen tube 20 is fixed to the narrow portion 36 of the step surface 34, and the distal end surface of the thick portion 25 of the tube 20 is fixed to the wide portion 37 of the step surface 34.

  As a result, the opening of the fluid guide groove 74 provided in the wide portion 37 is blocked by the distal end surface 26 of the multi-lumen tube 20. Then, the first guide groove 74 c of the fluid guide groove 74 becomes the first flow path 75, while the second guide groove 74 d becomes the second flow path 76.

  As shown by the broken line in FIG. 4, the air supply port 22 m provided in the distal end surface 26 of the multi-lumen tube 20 is disposed in the first flow path 75, and the water supply port 23 m is disposed in the second flow path 76. . Thus, air can be supplied from the air supply port 22m to the first flow path 75, and water can be supplied from the water supply port 23m to the second flow path 76.

Here, the fluid ejection nozzle 70 and the wall portion 80 will be described with reference to FIGS. 3C, 3D, and 4.
First, the fluid ejection nozzle 70 will be described.
As shown in FIGS. 3C and 4, the fluid ejection nozzle 70 includes a fluid ejection port 71, a mixed fluid ejection path 72, a gas-liquid mixing path 73, a first fluid path 75, and a second fluid path 76.

  According to this configuration, when the control valve operation button 42 is fully pressed, air is supplied to the air supply hole 22 and water is supplied to the water supply hole 23. The air supplied to the air supply hole 22 is supplied to the first flow path 75 from the air supply port 22m. Further, the water supplied to the water supply hole 23 flows from the water supply port 23 m to the second flow path 76. Then, the air that has flowed into the first fluid path 75 flows toward the inflow port 73m. On the other hand, the water flowing into the second fluid path 76 also flows toward the inflow port 73m.

  As a result, the air flowing through the first fluid path 75 and the water flowing through the second fluid path 76 merge at the inlet 73m. The inflow port 73m is a confluence portion of water and air. At the inflow port 73m, the air and water merge (collision) to form a turbulent flow and mix to form a spray-like gas-liquid mixed fluid. It flows into the mixing path 73. The gas-liquid mixed fluid that flows in from the inflow port 73m flows toward the mixing path end 73b of the gas-liquid mixing path 73, flows into the mixed fluid ejection path 72, and then flows on the surface of the observation lens 7 in the direction indicated by the arrow YB. It comes to be ejected by force.

  Note that air is supplied to the air supply hole 22 when the control valve operation button 42 is half-pressed. As a result, as described above, the air is supplied from the air supply port 22m to the first flow path 75 and flows toward the inlet 73m, and then passes through the gas-liquid mixing path 73 from the inlet 73m. It flows into the ejection path 72 and is ejected from the fluid ejection port 71 on the surface of the observation lens 7 with a flow force determined in the direction of arrow YB.

Next, the wall 80 will be described.
As shown in FIGS. 3D and 4, the deflection surface 82 provided on the inner wall surface 81 of the wall portion 80 is a flat surface and is set so as to intersect the fluid ejection direction indicated by the arrow YB at an angle θ2. It is. The deflection surface 82 is a fluid collision surface, and the direction in which the fluid that is ejected from the fluid ejection port 71 in a predetermined flow direction in the direction of arrow YB and collides with it flows in the direction of the predetermined arrow YB1 without dropping the flow direction. The angle θ2 is set to 90 degrees or more.

  According to this configuration, the fluid ejected from the fluid ejection port 71 flows in the direction of the arrow YB with a predetermined flow force, and then collides with the deflection surface 82 and is deflected in the direction of the arrow YB1 to flow. Continue to flow in S vigorously.

  Part of the fluid that continues to flow in the cleaning space S passes through the discharge portion 83 from the discharge opening 83m of the discharge portion 83 and is discharged to the outside from the drainage port 83e.

Here, the operation of the fluid ejection nozzle 70 and the wall 80 will be described.
As described above, the distal end portion 7 of the insertion portion 2 of the endoscope 1 extends from the insertion portion introduction port of the endoscope attachment portion 40 into the endoscope insertion portion hole 21 of the multi-lumen tube 20 as shown in FIG. After that, it passes through the endoscope insertion portion hole 21 and is arranged in a predetermined state in the small diameter hole portion 33 of the distal end constituting portion 30 as shown in FIGS. 5A and 5B. As a result, the entire insertion portion 2 of the endoscope 1 is covered with the cleaning sheath 10.

  The insertion part 2 covered with the cleaning sheath 10 is inserted into the body of the patient, and the affected part or the like is displayed on the screen of the display device for observation and treatment. During observation or treatment, fat, body fluid, blood, etc. adhere to the observation window 7a and the visual field is obstructed, or fat, body fluid, blood adheres to the illumination lenses 7b, 7c and the illuminance decreases. In this case, the user performs lens cleaning.

  The user, for example, pushes the control valve operation button 42 fully to supply air and simultaneously supply liquid. Then, the air supplied as described above is supplied to the first fluid path 75 via the air supply hole 22, and the supplied water is supplied to the second fluid path 76 via the water supply hole 23. Is done.

  Thereafter, the air supplied from the first fluid passage 75 and the water supplied from the second fluid passage 76 merge at the inflow port 73m to form a spray-like gas-liquid mixed fluid. It is erupted at a prescribed flow.

  At this time, the gas-liquid mixed fluid is ejected from the impingement fluid ejection port 71 in the direction of the arrow Y5A in FIG. 5A and blown to the observation window 7a. Most of the gas-liquid mixed fluid ejected from the fluid ejection port 71 passes through the discharge opening 83m of the discharge portion 83 without being discharged outside.

  The gas-liquid mixed fluid sprayed on the observation window 7a flows through a predetermined region in the cleaning space S toward the deflecting surface 82 located in a predetermined direction. That is, the gas-liquid mixed fluid flows toward the deflection surface 82 on the surface of the observation window 7a while expanding at the ejection angle θ3 in the arrow YB direction in FIG. 5B. Then, the gas-liquid mixed fluid reaches the deflection surface 82 as shown in FIG. 5C.

  As a result, as shown in FIG. 6A, the gas-liquid mixed fluid cleans the first area A1 indicated by cross-hatching, which is part of the surface of the observation window 7a, the surface of the illumination lens 7b, and the like.

  In addition, the gas-liquid mixed fluid that has cleaned the first region A1 and the like collides with the deflection surface 82. Thereafter, the flow direction is deflected in the direction of the arrow YB1, and as shown in FIG. 6B, it collides with the inner wall surface 81 and is deflected in the direction of the arrow YB2. It flows in the direction of arrow YB3 so as to clean A2, and becomes a vortex in the cleaning space S. As a result, the entire surface of the observation window 7a and the entire surface of the illumination lens 7b are cleaned.

  Thus, in the present embodiment, the first region A1 of the observation window 7a is a gas-liquid ejected from the fluid ejection port 71 provided on the inner wall surface 81 at a predetermined flow force in the arrow YB direction as shown in FIG. 6A. Washed with mixed fluid.

  On the other hand, the second region A2, which is the remaining region different from the first region A1 of the observation window 7a, is ejected from the fluid ejection port 71 and collides with the deflection surface 82 provided on the inner wall surface 81, and then the direction of the arrow YB1 The gas-liquid mixed flow which has flowed in the direction of the arrow YB2 and the direction of the arrow YB3 and changed into a vortex flow is washed.

  When the user releases the full press of the control valve operation button 42, the ejection of the gas-liquid mixed fluid from the fluid ejection port 71 is stopped. Then, the gas-liquid mixed fluid that has been swirled around the cleaning space S is guided into the discharge portion 83 from the discharge opening 83m as shown in FIG. 6C, and passes through the discharge portion 83 to be discharged. The liquid is discharged from the liquid port 83e.

That is, the gas-liquid mixed fluid that has been cleaned by flowing in the cleaning space S is immediately discharged to the outside from the discharge unit 83 at the same time as the ejection of the gas-liquid mixed fluid is stopped, and the water in the cleaning space S is drained. Is done smoothly.
As a result, it is possible to eliminate the problem that observation failure such as vignetting of the observation field occurs due to the gas-liquid mixed fluid remaining in the cleaning space S.

In the embodiment described above, one discharge portion 83 that passes through the cleaning space S and the outside is provided in the vicinity of the fluid ejection port 71. However, as shown in FIG. 7A, a plurality of, for example, a first discharge part 83A and a second discharge part 83B may be provided in the vicinity of the fluid jet 71.
In FIG. 7A, two discharge parts 83A and 83B are provided with the fluid jet 71 interposed therebetween. The two discharge portions 83A and 83B may have the same shape or different shapes.

As described above, by providing the plurality of discharge portions 83A and 83B on the inner wall surface 81 in the vicinity of the fluid ejection port 71, it is possible to further improve drainage.
Note that the plurality of discharge units is not limited to two, and may be two or more.

  In the above-described embodiment, the discharge portion 83 is a through hole that passes through the cleaning space S and the outside. However, the discharge portion 83 is not limited to the through hole, and may be, for example, a notch (also referred to as a groove) 83C shown in FIG. 7B. Reference numeral 83d denotes a notch bottom surface, which is formed at the same surface as the distal end surface 7f of the distal end portion 7 disposed in the small-diameter hole 33, like the base end side surface 83a described above.

  According to this configuration, the gas / liquid mixed fluid that has been cleaned by flowing through the cleaning space S with a larger opening area than the discharge parts 83, 83A, etc. is quickly discharged to the outside from the notch groove 83C. Draining in S can be performed smoothly.

  Further, in the above-described embodiment, when the distal end portion 7 of the insertion portion 2 is mounted in the small diameter hole portion 33 of the distal end configuration portion 30, the fluid ejection port 71 and the discharge opening 83m are positioned below the observation window 7a. It was a configuration to be arranged. However, a configuration in which only the discharge portion 83 is provided below the observation window 7a when the distal end portion 7 of the insertion portion 2 is mounted in the small diameter hole portion 33 of the distal end configuration portion 30 may be employed.

In the present embodiment shown in FIG. 7C, the discharge part 83 is a notch groove 83C. The notch groove 83C is provided so that the groove center line is positioned on the vertical line L in the center of the wide portion 37 on the lower side in the drawing. On the other hand, the fluid ejection port 71 of the fluid ejection nozzle 70 is provided so as to be positioned between the wide portion 37 and the narrow portion 36.
The width dimension of the notch groove 83 </ b> C is appropriately set in consideration of the cleaning property and draining property.

  In the present embodiment, the discharge portion 83 is a notch groove 83C. However, the discharge part 83 is not limited to the notch groove 83C. Further, the position of the deflection surface 82 is changed in accordance with the position of the fluid ejection nozzle 70. Further, although not shown, the arrangement position of the air supply hole 22 and the position of the water supply hole 23 of the multi-lumen tube are also changed in accordance with the position of the fluid ejection nozzle 70.

  According to this configuration, when the distal end portion 7 of the insertion portion 2 is mounted in the small diameter hole portion 33 of the distal end configuration portion 30, the notch groove 83C is disposed in the downward direction of the observation window 7a. Therefore, the gas-liquid mixed fluid that has been cleaned by flowing in the cleaning space S is more quickly discharged to the outside through the notch groove 83C located directly below the observation window 7a, thereby further draining the cleaning space S. It can be done smoothly.

  Note that after the user stops the ejection of the gas-liquid mixed fluid, the control valve operation button 42 is pressed halfway to supply air to the air supply hole 22. Then, the air flows in the cleaning space S in a vortex and the water droplets adhering to the first region A1 and the second region A2 of the observation window 7a and the illumination lenses 7b and 7c, and the distal end surface of the insertion portion 2 It is possible to secure a better observation visual field by blowing off the gas-liquid mixed fluid remaining between 7f and the inner wall surface 81.

  In the embodiment described above, the base end side surface 83a of the discharge opening 83m of the through-hole which is the discharge portion 83 is flush with the front end surface 7f of the front end portion 7 disposed in the small diameter hole portion 33. Further, the notch bottom surface 83d of the notch groove 83C is flush with the tip surface 7f of the tip portion 7 disposed in the small diameter hole portion 33.

However, as shown in FIG. 7D, for example, the notch bottom surface 83 d may be formed so as to be located on the proximal side from the distal end surface 7 f of the distal end portion 7 disposed in the small diameter hole portion 33. In other words, the front end surface 7f may be projected from the cutout bottom surface 83d by the dimension a. 7D, the bottom surface 83d of the discharge opening 83m may be formed so as to be positioned closer to the base side than the front surface 7f.
According to this configuration, the gas-liquid mixed fluid that has flowed through the cleaning space S and cleaned in the same manner as in the above-described embodiment can be quickly discharged to the outside to smoothly drain the water in the cleaning space S.

Further, as shown in FIG. 7E, for example, the notch bottom surface 83d may be formed so as to project the dimension b from the tip surface 7f of the tip portion 7 disposed in the small diameter hole portion 33.
According to this configuration, the gas-liquid mixed fluid that has flowed through the cleaning space S and cleaned in the same manner as in the above-described embodiment can be quickly discharged to the outside to smoothly drain the water in the cleaning space S. Further, as described above, after the user stops the ejection of the gas-liquid mixed fluid, by supplying air, the gap between the inner wall surface 81 in the vicinity of the cutout bottom surface 83d of the cutout groove 83C and the distal end surface 7f of the insertion portion 2 is reduced. A good observation field of view can be secured by blowing off the gas-liquid mixed fluid that has remained.

  As shown in FIG. 8A, the distal end constituting portion 30A has a fluid ejection port 71, a mixed fluid ejection passage 72, a gas-liquid mixing passage 73, a fluid guide groove 74, a discharge portion 83E, and a suction passage 77 that constitute the fluid ejection nozzle 70 described above. Is provided. The discharge portion 83E is a hole having a bottom surface 83f, and is provided in the vicinity of the vertical line L at the center of the wide portion 37 on the lower side in the drawing.

As shown in FIG. 8B, the suction conduit 77 is a fluid suction hole and is a long hole parallel to the center axis a30 of the tip component portion. One opening which is one end side of the suction path 77 communicates with the hole space of the discharge portion 83E which is a hole. One opening of the suction passage 77 is formed on the surface of the step 34.
In addition, the fluid ejection port 71 of the fluid ejection nozzle 70 is provided so that it may be located in the middle of the wide part 37 and the narrow part 36 similarly to FIG. 7C. The discharge part 83E may be either a round hole or a square hole.

  As shown in FIG. 8C, the multi-lumen tube 20A fixed to the distal end constituting portion 30A has a fluid suction hole in addition to the endoscope insertion portion hole 21, the air supply hole 22, and the water supply hole 23 described above. The suction hole 27 is provided. The suction hole 27 is also a longitudinal through hole provided along the central axis a <b> 20 of the multi-lumen tube 20.

  The multi-lumen tube 20 </ b> A is not uniform in the circumferential direction, and an air supply hole 22, a water supply hole 23, and a suction hole 27 are provided at predetermined positions of the thick portion 25. The front end surface 26 is formed with openings on the front end side of the respective holes 21, 22, 27.

  The distal end surface 26 of the multi-lumen tube 20 </ b> A is disposed in close contact with the step surface 34. As a result, the opening of the fluid guide groove 74 and the opening of the suction path 77 provided in the wide portion 37 are closed by the distal end surface 26 of the multi-lumen tube 20. As described above, the air supply port 22m of the air supply hole 22 and the water supply port 23m of the water supply hole 23 are disposed in the fluid guide groove 74, and the suction port of the suction hole 27 (see FIG. (See reference numeral 77m).

  Although not shown, one end of a suction tube (not shown) is connected to the opening of the suction hole 27 opposite to the suction port 27m. A suction unit (not shown) is connected to the other end of the suction tube. The suction unit includes a suction pump (not shown) and a storage tank (not shown) for storing water or the like used for cleaning.

  In the present embodiment, the ejection of the gas-liquid mixed fluid from the fluid ejection port 71 is stopped when the user releases the full press of the control valve operation button 42. Then, the gas-liquid mixed fluid that has been swirling around the cleaning space S is guided into the discharge portion 83E and flows into the suction passage 77. Here, for example, when the user operates the foot switch to drive the suction pump, the gas-liquid mixed fluid that has flowed into the suction path 77 is sucked from the suction port 27 m and flows into the storage tank through the suction hole 27. .

  That is, the gas-liquid mixed fluid that has been cleaned by flowing in the cleaning space S is quickly discharged to the outside by the suction pump that is driven after the ejection of the gas-liquid mixed fluid is stopped, so that the inside of the cleaning space S is discharged. Drained. As a result, it is possible to eliminate the problem that observation failure such as vignetting of the observation field occurs due to the gas-liquid mixed fluid remaining in the cleaning space S.

In the state where the tip surface 26 of the multi-lumen tube 20A is in close contact with the stepped surface 34, the air supply port 22m of the air supply hole 22 and the water supply port of the water supply hole 23 are inserted into the fluid guide groove 74 provided in the wide portion 37. In addition to 23 m, the suction port 27 m of the suction hole 27 may be arranged so that the fluid ejection port 71 is also used as the fluid suction port.
In this configuration, an opening / closing valve is provided in the middle of the suction tube. During the cleaning, the on-off valve is closed to prevent the gas-liquid mixed fluid or the like from being discharged through the suction hole 27.

  In the embodiment described above, a through-hole, a notch, or a hole is provided in the wall portion 80 in order to discharge the gas-liquid mixed fluid that has flowed in the cleaning space S in a vortex to the outside after cleaning. . However, as shown in FIG. 9, the water repellent treatment surface 78 may be formed by subjecting the inner wall surface 81 and the deflection surface 82 constituting the inner surface of the wall 80 on the cleaning space S side to a water repellent treatment.

  According to this configuration, when the user releases the full press of the control valve operation button 42, the ejection of the gas-liquid mixed fluid from the fluid ejection port 71 is stopped, and at the same time, the cleaning space S is cleaned. The gas-liquid mixed fluid is discharged to the outside through the inner wall surface 81 and the deflection surface 82.

  In addition, after the user stops the ejection of the gas-liquid mixed fluid, the gas-liquid mixed fluid flows into the fluid ejection port 71 by pressing the control valve operation button halfway to eject air from the fluid ejection port 71. While preventing the air from flowing in the cleaning space S in a vortex, the water droplets adhering to the observation window 7a and the illumination lenses 7b and 7c can be blown off to ensure a better observation field.

  In addition, after the user releases the full press of the control valve operation button 42, the gas-liquid mixed fluid flowing in the cleaning space S is operated by appropriately operating the bending portion 8 to direct the opening of the cleaning space S downward. Can be discharged to the outside through the inner wall surface 81 and the deflection surface 82.

  The present invention is not limited to the embodiments described above, and various modifications and changes are possible, and these are also within the technical scope of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Endoscope 2 ... Insertion part 3 ... Operation part 4 ... Universal cord
5 ... Observation control unit 6 ... Display device 7 ... Tip 7a ... Observation window
7b, 7c ... Illumination lens 7f ... Tip surface 8 ... Curved portion 9 ... Tube portion 10 ... Cleaning sheath
20, 20A ... Multi-lumen tube 21 ... Endoscope insertion hole 22 ... Air supply hole
22m ... Air supply port 23 ... Water supply hole 23m ... Water supply port 24 ... Thin part 25 ... Thick part
27: Suction hole 30, 30A ... Tip component 31 ... Stepped hole 32 ... Large diameter hole
33 ... Small-diameter hole 34 ... Step surface 36 ... Narrow part 37 ... Wide part 40 ... Endoscope attachment part
41h ... Connection hole 70 ... Fluid ejection nozzle 71 ... Fluid ejection port 72 ... Mixed fluid ejection path
73 ... Gas-liquid mixing path 73m ... Inlet 74 ... Fluid guide groove 74a ... First terminal portion
74b ... 2nd terminal part 74c ... 1st guide groove 74d ... 2nd guide groove 75 ... 1st flow path
76 ... Second flow path 77 ... Suction passage 78 ... Water repellent treatment surface 80 ... Wall portion 80f ... Wall distal end surface 81 ... Inner wall surface 81a ... Front end side peripheral surface 81b ... Base end side peripheral surface 82 ... Deflecting surface
83 ... discharge part 83C ... notch groove 83d ... notch bottom face 83f ... bottom face
83m ... Drain opening 83e ... Drain outlet

Claims (8)

A distal-end component portion fixed to the distal end portion of the tube body covering the insertion portion of the endoscope to be inserted into the subject, and having a distal end portion having an observation window of the insertion portion; and
In a state where the distal end portion is disposed on the distal end configuration portion, it is provided on the distal end side of the distal end configuration portion so as to protrude forward from the distal end portion distal end surface of the insertion portion and surround the distal end portion distal end surface. A wall portion having an inner wall surface,
It is provided at a predetermined position on the inner wall surface of the wall portion, and the ejection direction of the fluid is set so that the fluid flows in a predetermined direction which is a part of the surface of the observation window in a predetermined direction. A defined fluid outlet;
The fluid is provided at a predetermined position on the inner wall surface of the wall portion, and the fluid ejected in a predetermined direction from the fluid ejection port collides with the fluid on the surface of the observation window. A deflection surface that deflects the flow direction so as to flow toward another region different from the predetermined region;
A fluid discharge portion for discharging the fluid jetted from the fluid jet port into the internal space surrounded by the wall portion;
A lens cleaning sheath for an endoscope.   The endoscope for an endoscope according to claim 1, wherein the fluid ejection port is disposed below the observation window of the endoscope when the distal end configuration portion is attached to the endoscope. Lens cleaning sheath.   The endoscope lens cleaning sheath according to claim 2, wherein the fluid discharge portion is formed on a side in a circumferential direction in the vicinity of the fluid ejection hole.   4. The endoscope lens cleaning sheath according to claim 3, wherein the fluid discharge portion is a through-hole or a notch formed in the wall portion and communicating with the space inside the wall portion and the outside.   2. The endoscope according to claim 1, wherein the fluid ejection port is disposed in a direction other than a lower direction of the observation window of the endoscope when the distal end configuration portion is attached to the endoscope. Lens cleaning sheath.   6. The endoscope lens cleaning sheath according to claim 5, wherein the fluid discharge portion is formed at a position corresponding to a lower side of the observation window on a side in a circumferential direction of the fluid ejection hole. . The tip component includes a fluid suction hole capable of sucking the fluid,
6. The endoscope lens cleaning sheath according to claim 2, wherein one end of the fluid suction hole is formed so as to communicate with a space of the fluid discharge portion. 7.   The lens cleaning sheath for an endoscope according to claim 1, wherein a water repellent finish is applied to an inner surface of the wall portion on the side of the inner space of the wall portion.

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