JP2009136494A - Irrigation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an irrigation system quickly removing adhesion objects stuck to an observation window or the like by spraying fluid mixture formed by mixing water and air to the observation window or the like of an endoscope without using a gas insufflator or the like or an air pump. <P>SOLUTION: This irrigation system 1 is provided with an irrigation sheath 20 mixing liquid and gas fed via a liquid supply pathway 2c and a gas supply pathway 2b and injecting the fluid mixture, a liquid pack 30 for storing the liquid to be sent to the irrigation sheath 20, a balloon 42 and belt 43 supplying an air, pressurizing the liquid pack 30 and sending the liquid stored in the liquid pack 30, and a balloon 42 sending the gas supplied to the balloon 42 to the irrigation sheath 20 for pressurizing the liquid pack 30, or a liquid energy conversion device 80 for sending the gas to the irrigation sheath 20 using the fluid energy of the liquid sent from the liquid pack 30 by the balloon 42 and the belt 43. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a cleaning system that sprays a mixed fluid toward an observation window or the like of an endoscope to remove deposits attached to the observation window or the like.

  If the mucus, blood, fat, filth, etc. in the living body adhere to the observation window, illumination window or the like provided in the endoscope during observation using the endoscope, good observation is hindered. In order to solve the problem due to the adhesion, for example, an endoscope cleaning system as shown in FIG. 13 is conceivable.

  FIG. 13 is a diagram illustrating a conventional configuration of an endoscope cleaning system.

  The endoscope cleaning system shown in FIG. 13 includes, for example, an endoscope 110, a cleaning sheath 120, two air pumps 131 and 132, a cleaning liquid tank 140, two filters-attached tubes 151 and 152, and a liquid feeding connector. 160, a liquid supply tube 170, an air supply tube 180, a foot switch 190, a liquid supply control switch 191, and an air supply control switch 192. Reference numeral 153 denotes a sterilization filter.

  The endoscope 110 includes an insertion portion 114 that continuously connects a distal end portion 111, a bending portion 112, and a rigid tube portion 113. An operation unit 115 is connected to the proximal end of the insertion unit 114. A universal cable 116 extends from the base end of the operation unit 115. An observation window and an illumination window (not shown) are disposed on the distal end surface of the distal end portion 111.

  The cleaning sheath 120 is formed as an elongated cylindrical member and has a cover part 121 and an attachment part 124. The cover part 121 is composed of, for example, a distal end constituting part 122 and a flexible part 123 and covers the insertion part 114 of the endoscope 110.

  The flexible portion 123 is provided with an insertion portion insertion portion (not shown) through which the insertion portion 114 of the endoscope 110 is inserted. Further, the soft part 123 is provided with a liquid supply path and a gas supply path (not shown). The distal end configuration part 122 is for ejecting fluid toward the distal end surface of the distal end part 111 of the endoscope 110 inserted into the cover part 121.

  The attachment portion 124 is provided at the proximal end of the cover portion 121 and is integrally attached to the distal end side portion of the operation portion 115 of the endoscope 110. The attachment portion 124 is provided with a liquid supply port portion 125 communicating with the liquid supply passage and a gas supply port portion 126 communicating with the gas supply passage. One end of a liquid supply tube 127 is attached to the liquid supply port 125 in advance, and one end of an air supply tube 128 is attached to the gas supply port 126 in advance.

  The attachment of the cleaning sheath 120 to the endoscope 110 will be described.

  When endoscopic observation is performed by attaching the cleaning sheath 120 to the endoscope 110, the user can use the cleaning sheath 120 and the two tubes 151 and 152 with a filter packed in a sterilization pack, and the cleaned and disinfected endoscope. A mirror 110 and a liquid feeding connector 160, a cleaning liquid tank 140 containing deaerated water as a cleaning liquid, two air pumps 131 and 132, a foot switch 190, and switches 191 and 192 are prepared.

  Next, the user in the clean area attaches the cover part 121 and the attachment part 124 of the cleaning sheath 120 to the insertion part 114 and the operation part 115 of the endoscope 110. Further, the user performs an operation indicated by an arrow A for connecting one end of the tube with filter 152 to the proximal connector 128a of the air supply tube 128, and an arrow for connecting the other end of the tube with filter 152 to the air supply control switch 192. The operation shown in B and the operation shown in arrow C for connecting the distal end portion of the air supply tube 180 to the air supply control switch 192 are performed. Further, the user performs an operation indicated by an arrow D to connect the proximal connector 127a of the liquid feeding tube 127 to the water feeding port 161 of the liquid feeding connector 160, and one end of the tube with filter 151 is the first of the liquid feeding connector 160. Work indicated by an arrow E connecting to the tube connection port 162, an operation indicated by an arrow F connecting the tip connector 142 provided at the tip of the cleaning tube 141 extending from the cleaning liquid tank 140 to the second tube connection port 163, The operation indicated by the arrow G for connecting the other end of the tube with filter 151 to the liquid supply control switch 191 and the operation indicated by the arrow H for connecting the tip of the liquid supply tube 170 to the liquid supply control switch 191 are performed.

  On the other hand, the user in the unclean area performs the work indicated by arrow J for connecting the connection cable 193 of the foot switch 190 to the liquid supply control switch 191, the work indicated by arrow K for connecting the connection cable 194 to the air supply control switch 192, and the liquid supply. The operation shown by the arrow L for connecting the pump connection connector 171 provided at the proximal end of the tube 170 to the tube connection port 134 of the air pump 132 and the pump connection provided at the proximal end of the air supply tube 180 The operation shown by the arrow M for connecting the connector 181 to the tube connection port 133 of the air pump 131 is performed.

  After these connection operations are completed, the air pump 131 and 132 are operated, and for example, the surgeon can appropriately operate the pedals 195 and 196 of the foot switch 190 to supply air and water.

  However, in the endoscope cleaning system having the configuration shown in FIG. 13, preparation of the apparatus and tubes, tube connection work, and the like are complicated, which is troublesome for the user.

Patent Document 1 discloses a rigid endoscope apparatus that can be easily operated by cleaning and drying the lens at the distal end of the insertion portion during observation while the rigid endoscope is inserted into the sheath. In the sheath of this rigid endoscope apparatus, a connecting tube is provided at the proximal end portion of a cylindrical sheath body. A water supply line and an air supply line are provided on the inner wall of the sheath body in the axial direction. These conduits merge in the vicinity of the distal end of the sheath body, and communicate with a nozzle that can supply and supply water toward an objective lens or the like provided at the distal end portion of the sheath body. Since this rigid endoscope apparatus includes a gas cylinder as an insufflation gas supply source, the gas filled in the gas cylinder is reduced to a predetermined pressure, and sterilized water for liquid feeding is stored. It is designed to be supplied to containers. The container is provided with a liquid supply tube and an air supply tube, and ends of the tubes are connected to a water supply port body and an air supply port body provided in the sheath.
JP-A-5-199979

  However, the pneumoperitoneum device used in the rigid endoscope apparatus of Patent Document 1 is configured to include a first gas pipe corresponding to the cleaning pressure and a second gas pipe corresponding to the pneumoperitoneum. Expensive. In addition, when performing observation or the like that does not require an insufflation apparatus, an insufflation apparatus and a gas cylinder must be prepared in order to clean and dry the lens of the insertion portion of the endoscope during observation. Therefore, there has been a demand for a cleaning system that can easily remove dirt and the like attached to an observation window, an illumination window, and the like with a simple configuration.

  The present invention has been made in view of the above circumstances, and without using an insufflation apparatus or an air pump, a mixed fluid obtained by mixing water and air is sprayed on an observation window of an endoscope, and the observation window. It is an object of the present invention to provide a cleaning system that quickly removes deposits adhering to the like.

  The cleaning system of the present invention includes a liquid supply path for supplying a liquid and a gas supply path for supplying a gas, and the liquid and the gas supplied through the liquid supply path and the gas supply path are mixed to produce a mixed fluid. A cleaning sheath to be ejected, first storage means for storing a liquid to be delivered to a liquid supply path of the cleaning sheath, and supplying the gas to the first storage means to pressurize the first storage means. A pressurizing means for sending the liquid contained in the liquid supply passage, and a gas supplied to the pressurizing means for pressurizing the liquid contained in the first containing means is supplied to the cleaning sheath. An air supply means for supplying gas to the gas supply path of the cleaning sheath using the kinetic energy of the liquid sent out to the passage or from the first storage means by the pressurizing means. .

  According to this configuration, the liquid stored in the first storage unit is delivered to the liquid supply path of the cleaning sheath by the pressure of the pressurizing unit. On the other hand, the gas is supplied to the gas supply path of the cleaning sheath using the kinetic energy of the gas supplied to the pressurizing means by the air supply means or the liquid sent from the first storage means by the pressurizing means. Is done.

  According to the present invention, without using an insufflation apparatus or an air pump, a mixed fluid in which water and air are mixed is sprayed on an observation window or the like of an endoscope, and the adhered matter adhered to the observation window or the like It is possible to realize a cleaning system that quickly removes water.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 8 relate to a first embodiment of an endoscope cleaning system provided with a cleaning system, FIG. 1 is a diagram illustrating a cleaning system mounted on an endoscope, and FIG. 2 is a view taken along the line II-II in FIG. FIG. 3 is a rear view illustrating the configuration of the tip component, FIG. 4 is a diagram illustrating the configuration of the pressurizing device, FIG. 5 is a diagram illustrating the operation of the pressurizing device, and FIG. 6 is a non-operation state. FIG. 7 is a diagram illustrating a spray switch in a spray state, and FIG. 8 is a diagram illustrating a state in which a pressurizing device is attached to a stand.
As shown in FIG. 1, an endoscope cleaning system 1 according to this embodiment includes an endoscope 10, a cleaning sheath 20, and a physiological saline pack (hereinafter abbreviated as a liquid pack) 30 as a first storage means. And a pressurizing device 40.

  The endoscope 10 is, for example, a rigid endoscope and includes an insertion portion 14 configured by connecting a distal end portion 11, a bending portion 12, and a rigid tube portion 13. An operation unit 15 is connected to the proximal end of the insertion unit 14. A universal cable 16 extends from the base end of the operation unit 15. The end of the universal cable 16 is connected to a light source device and a video processor (not shown). An observation window and a light emitting end (not shown) are provided on the distal end surface of the distal end portion 11. The operation unit 15 is provided with a bending operation lever 17 for bending the bending unit 12. Note that the endoscope 10 is not limited to a rigid endoscope, and may be a flexible endoscope having a flexible insertion portion.

The cleaning sheath 20 is a disposable type and is discarded after use.
The cleaning sheath 20 is disposed so as to cover the insertion portion 14 of the endoscope 10 and the distal end side portion of the operation portion 15. The cleaning sheath 20 is configured by connecting, in order from the distal end side, a distal end constituting portion 21 that is a cylindrical body, a tube body 22 constituted by a multi-lumen tube, and an attachment portion 23.

  The multi-lumen tube constituting the tube body 22 is made of a soft material such as silicon, urethane, or Teflon (registered trademark), or a hard material such as polyamide, polyethylene, polypropylene, or polycarbonate.

  As shown in FIG. 2, the tube body 22 includes, for example, three holes 2a, 2b, and 2c. The hole 2a is an endoscope arrangement hole (hereinafter abbreviated as an endoscope hole), and the insertion portion 14 of the endoscope 10 is inserted therein. The central axis of the tube body 22 and the central axis of the endoscope hole 2a are parallel to each other and decentered downward in the figure on the vertical axis by a preset distance a.

  The hole 2b is a gas supply hole (hereinafter abbreviated as an air supply hole) that constitutes a gas supply path for supplying a gas such as air, and is formed at a predetermined position on the thick portion side of the tube body 22. ing.

  The hole 2c is a liquid supply hole (hereinafter abbreviated as a liquid feed hole) that constitutes a liquid supply path for supplying a liquid such as water or cleaning liquid, and is provided at a predetermined position on the thick wall portion side of the tube body 22. Is formed.

  The holes 2b and 2c have substantially the same shape and substantially the same cross-sectional area, and are formed in a symmetrical positional relationship across the vertical axis. The holes 2b and 2c are fluid holes for supplying a fluid such as gas or liquid, and the hole 2b may be a liquid feeding hole and the hole 2c may be a gas feeding hole.

  The attachment portion 23 is fixed to the proximal end portion of the tube body 22. The attachment portion 23 is configured to be integrally attached to the distal end side portion of the operation portion 15 of the endoscope 10. As shown in FIG. 1, a gas supply port 24 and a liquid supply port 25 are provided on the side surface of the attachment portion 23. The gas supply port 24 is configured to communicate with the air supply hole 2b, and the liquid supply port 25 is configured to communicate with the liquid supply hole 2c.

  One end of a front-side air supply tube 26a is fixed to the gas supply port 24 in advance. One end of a distal end side liquid feeding tube 27a is fixed to the liquid supply port 25 in advance. The other ends of the distal end side air supply tube 26 a and the distal end side liquid supply tube 27 a are connected to the spray switch 50.

  A proximal end side air supply tube 26b and a proximal end side liquid supply tube 27b extend from the spray switch 50. At the end of the proximal air supply tube 26b, an air supply connection portion 29 is provided via a sterilization filter 28. A needle 4 is provided at the end of the proximal end side liquid feeding tube 27b.

  The diameter and length of the air supply tubes 26a and 26b and the liquid supply tubes 27a and 27b are set in consideration of the pressure for pressing the balloon 42 and the liquid pack 30 described later.

  The distal end configuration portion 21 is fixed to the distal end portion of the tube body 22. The distal end configuration portion 21 is for injecting the mixed fluid toward the distal end surface of the distal end portion 11 of the endoscope 10 inserted into the tube body 22.

  The tip constituting portion 21 is formed of, for example, a hard, transparent, or translucent resin member. As shown in FIG. 3, the light exit end and the observation window provided on the distal end surface of the insertion portion of the endoscope 10 are exposed on the distal end back surface 3 a, which is the back surface of the distal end surface of the distal end configuration portion 21. A notch 3b is formed.

A part of the distal end surface of the tube body 22 and a part of the distal end surface of the distal end portion 11 constituting the insertion portion 14 of the endoscope 10 abut on the distal end rear surface 3a. A T-shaped groove 3f, which is a substantially T-shaped recess, is formed in the front end back surface 3a. The T-shaped groove 3f includes two closed ends 3c and 3d and one open end 3e. The T-shaped groove 3f is one end that forms a liquid supply path formed along the inner peripheral surface 3g of the tip constituting portion 21. Closed liquid supply groove (hereinafter referred to as a liquid supply groove) 3h and a gas supply groove (hereinafter referred to as an air supply groove) closed at one end constituting a gas supply path formed along the inner peripheral surface 3g. 3i) and a mixed fluid supply groove (hereinafter referred to as an ejection groove) 3k constituting a mixed fluid supply path having an open end 3e constituting the jet outlet.

  The open end on the other end side of the liquid feed groove 3h and the open end on the other end side of the air feed groove 3i are set apart from each other by a predetermined distance so that the space where the liquid and the gas merge, that is, the mixed fluid is supplied. A fluid confluence portion 3m, which is a fluid mixing portion to be obtained, is configured.

  The ejection groove 3k extends from the fluid junction 3m toward the notch 3b. Specifically, the center line of the ejection groove 3k extends from the center of the fluid merging portion 3m so as to be orthogonal to the central axis of the tip constituting portion 21. In the present embodiment, the groove width of the ejection groove 3k is set so as to gradually increase from the fluid confluence portion 3m toward the ejection port that is the open end 3e.

  The position of the closed end 3c of the liquid feed groove 3h is set in consideration of the position of the liquid feed front end opening of the liquid feed hole 2c formed in the tube body 22. And the liquid sent out from the front-end | tip opening for liquid flows in into the liquid feeding groove | channel 3h.

  Similarly to the liquid supply groove 3h, the position of the closed end 3d of the air supply groove 3i is set in consideration of the position of the front end for air supply of the air supply hole 2b formed in the tube body 22. And the gas sent out from the front opening for air supply flows into the air supply groove 3i.

  In a state where a part of the distal end surface of the tube body 22 is in contact with (adhered to) the distal end rear surface 3 a of the distal end configuration portion 21, the liquid feeding groove 3 h is supplied via the liquid feeding hole 2 c of the tube body 22. The liquid is sent to the fluid junction 3m, and the gas supply groove 3i sends the gas supplied through the gas supply hole 2b of the tube body 22 to the fluid junction 3m.

  The fluid junction 3m mixes the liquid sent from the liquid feeding groove 3h and the gas sent from the air feeding groove 3i. The fluid mixed in the fluid junction 3m is sent to the ejection groove 3k.

  The open end 3e constitutes a spout in a state where the distal end surface of the tube body 22 and the distal end surface of the distal end portion 11 are substantially in contact with the distal end rear surface 3a of the distal end configuration portion 21. As a result, the mixed fluid mixed at the fluid merging portion 3m and delivered to the ejection groove 3k is ejected from the open end 3e toward the observation window or the like of the endoscope 10.

  The liquid pack 30 is a disposable type and is discarded for each case. For example, 1 liter of physiological saline 32 is stored in a storage body 31 constituting the liquid pack 30. The amount of the physiological saline 32 used in one case is extremely small compared to the capacity of the liquid pack 30, for example, 50 ml.

  The physiological saline 32 has been sterilized. A puncture portion 33 through which the needle 4 is punctured is provided at one end of the storage body 31. The physiological saline 32 is used after being preheated to a predetermined temperature before the operation.

  As shown in FIGS. 1 and 4, the pressurizing apparatus 40 includes an apparatus main body 41, a pressurizing balloon 42 that serves as a pressurizing unit and an air feeding unit, and a liquid pack holding belt 43. The apparatus main body 41 is, for example, a resin plate member, and a hanging part 41a is provided at the upper part in the drawing.

  The pressurizing balloon (hereinafter abbreviated as “balloon”) 42 serves both as a second storing means for storing gas and a pressing means for pressurizing the liquid pack 30. The balloon 42 is an elastic member such as a rubber member that can be expanded and contracted. In the balloon 42, one surface 42a of the balloon 42 is integrally fixed to, for example, one surface 41b of the apparatus main body 41.

  A first rubber tube 45a, a second rubber tube 45b, and a gas supply tube 45c extend from the balloon. A pressure gauge 46 is attached to the proximal end portion of the first rubber tube 45a. A rubber ball 47 is attached to the base end portion of the second rubber tube 45b. The rubber ball 47 is provided with an intake hole 47c having an exhaust valve 47a and a check valve 47b. A gas supply connector 48 is provided at the proximal end of the gas supply tube 45c. The gas supply connector 48 is detachably connected to the gas supply connector 29.

  The balloon 42 is inflated by operating the rubber ball 47 and supplying air into the balloon 42. Specifically, when the balloon 42 is inflated, the exhaust valve 47a is closed and the rubber ball 47 is operated. Then, after air is supplied into the rubber ball 47, the air is supplied into the balloon 42 and gradually expands. The pressure in the balloon 42 is measured by a pressure gauge 46. After confirming that the pressure in the balloon 42 has reached a desired value, the supply of air by the rubber ball 47 is stopped. As a result, the balloon 42 is maintained in an inflated state with a desired internal pressure. The check valve 47b of the rubber ball 47 is opened when air is supplied into the rubber ball 47. In other states, the check valve 47b prevents the air inside the rubber ball 47 from leaking outside. It is configured to be in a closed state.

  When the air in the balloon 42 maintained in the inflated state is exhausted, the exhaust valve 47a is switched from the closed state to the open state. Then, the air in the balloon 42 is discharged from the exhaust valve 47a by the elastic force of the balloon 42, and the balloon 42 changes from the inflated state to the contracted state.

  The liquid pack holding belt (hereinafter abbreviated as a belt) 43 is a pressurizing unit that pressurizes the liquid pack 30 and the balloon 42, and is composed of a rubber member having a predetermined elastic force. Both end portions of the belt 43 are configured to be integrally fixed to the longitudinal side surface portion 41c of the apparatus main body 41 or the vicinity thereof.

  A space 44 with a gap w is formed between the inner surface of the belt 43 and the other surface 42 b of the balloon 42. The liquid pack 30 is arranged in the space 44 as shown by the arrow in FIG.

  The rubber ball 47 is operated with the liquid pack 30 placed in the space 44. Then, the balloon internal pressure increases as the balloon 42 expands. When the internal pressure of the balloon 42 reaches a predetermined internal pressure, the liquid pack 30 and the balloon 42 held between the one surface 41b of the apparatus main body 41 and the inner surface of the belt 43 are pressed at a desired pressure as shown in FIG. It becomes a state. That is, when the balloon 42 is expanded from the state shown by the two-dot chain line in FIG. 5 to the state shown by the solid line, the liquid pack 30 disposed in the space 44 is pressed by the other surface 42 b of the balloon 42 and the inner surface of the belt 43. On the other hand, the balloon 42 is pressed by the liquid pack 30 and the one surface 41b of the apparatus main body 41, and the liquid pack 30 and the balloon 42 are pressed with a desired pressure.

  The volume of air filled in the balloon is set so that a sufficient pressure and supply amount can be obtained in consideration of the maximum amount of air used in one procedure. Since the amount of the physiological saline 32 used is extremely small as compared with the capacity of the liquid pack 30 as described above, the pressure for pressing the balloon 42 and the liquid pack 30 is substantially maintained at the initial set value. .

  As shown in FIG. 6, the spray switch 50 includes an exterior body 51 and a switch body 52. A cylindrical body 53 is provided at the lower end of the exterior body 51 in the figure. The cylindrical body 53 is integrally fixed to the exterior body 51 by, for example, screwing. An O-ring (not shown) is provided between the exterior body 51 and the cylindrical body 53, and the inside and the exterior constituted by the exterior body 51 and the cylindrical body 53 are watertight.

  A switch sliding hole 54 extending in the longitudinal axis direction is formed in the exterior body 51. A rod-like switch body 52 is slidably disposed in the switch sliding hole 54. Therefore, a preset gap is formed between the inner surface of the switch sliding hole 54 and the outer surface of the switch body 52.

  Communication holes 55 a, 55 b, 55 c, 55 d that communicate with the switch sliding hole 54 are formed on the side of the exterior body 51. The first communication hole 55a is connected to the first base 56a to which the distal end side air supply tube 26a is connected, and the second communication hole 55b is connected to the second base 56b and the third communication hole 55c to which the front end side liquid supply tube 27a is connected. The third base 56c to which the base end side air supply tube 26b is connected is fixed, and the fourth base 56d to which the base end side liquid supply tube 27b is connected is fixed to the fourth communication hole 55d.

  A recess 57 is provided at one end of the exterior body 51. A spring 58 for urging the switch body 52 upward in the drawing is disposed in the recess 57.

  The switch body 52 is a shaft body and is provided with flanges 52a and 52b that prevent the switch body 52 from coming off. In the present embodiment, for example, the lower flange portion 52b in the drawing is integrally fixed to the switch body 52 by screwing.

  The switch body 52 is formed with a plurality of circumferential grooves 59a, 59b, 59c, 59d. An O-ring 60 is disposed in each of the circumferential grooves 59a, 59b, 59c, 59d. The O-ring 60 disposed in the circumferential grooves 59a, 59b, 59c, 59d is in close contact with the inner surface of the switch sliding hole 54.

  The spring 58 has an urging force that pushes up the switch body 52 against an adhesion force that is in close contact with the inner surfaces of the switch sliding holes 54 of the plurality of O-rings 60. The state in which the switch body 52 is pushed up is a no-operation state. In this non-operating state, the first base 56a provided in the spray switch 50 includes an O-ring 60 disposed in the second circumferential groove 59b and an O-ring 60 disposed in the third circumferential groove 59c. Located between and. The second base 56b is located between the O-ring 60 and the space 63 disposed in the fourth circumferential groove 59d. The third base 56c is located between the O-ring 60 disposed in the first circumferential groove 59a and the O-ring 60 disposed in the second circumferential groove 59b. The fourth base 56d is located between the O-ring 60 disposed in the third circumferential groove 59c and the O-ring 60 disposed in the fourth circumferential groove 59d.

  As a result, each of the caps 56a, 56b, 56c, and 56d communicates only with the respective spaces that are separated and sealed by the O-ring 60.

  When switching from the non-operating state to the spraying state, the switch body 52 is pushed down against the urging force of the spring 58 and the close contact force with which the O ring 60 is in close contact with the inner surface of the switch sliding hole 54. Then, the spray switch 50 is in the spray state shown in FIG.

  In the spray state, the second cap 56b and the fourth cap 56d provided in the spray switch 50 are disposed in the O-ring 60 and the fourth circumferential groove 59d disposed in the third circumferential groove 59c. It is arranged between the O-ring 60. As a result, the fourth base 56 d and the second base 56 b communicate with each other through a gap formed between the inner surface of the switch sliding hole 54 and the outer surface of the switch body 52.

  On the other hand, the first base 56a and the third base 56c are disposed between the O-ring 60 disposed in the first circumferential groove 59a and the O-ring 60 disposed in the second circumferential groove 59b. As a result, the third base 56d and the first base 56b communicate with each other through a gap formed between the inner surface of the switch sliding hole 54 and the outer surface of the switch body 52.

  As described above, the fourth base 56d and the second base 56b communicate with each other through the gap between the inner surface of the switch sliding hole 54 and the outer surface of the switch body 52, and the third base 56d and the first base 56b. A state in which the air is communicated through a gap between the inner surface of the switch sliding hole 54 and the outer surface of the switch body 52 is a spray state.

  Here, a procedure in the case where the cleaning sheath 20 is attached to the endoscope 10 to perform endoscopic observation and the operation of the endoscope cleaning system 1 including the pressurizing device 40 will be described.

  In performing the endoscopic observation, the user performs a cleaning sheath 20 packed in a sterilization pack, a liquid pack 30, a cleaned and disinfected endoscope 10, a pressure gauge 46, a rubber ball 47, and a gas supply connector. 48 prepares the pressure device 40 attached to the first rubber tube 45a, the second rubber tube 45b, and the gas supply tube 45c.

  The user attaches the tube body 22 and the distal end configuration portion 21 of the cleaning sheath 20 taken out from the sterilization pack to the insertion portion 14 of the endoscope 10, and attaches the attachment portion 23 to the distal end side portion of the operation portion 15 of the endoscope 10. Install in the prescribed state.

  Next, the user arranges the liquid pack 30 in the space 44 configured in the pressurizing device 40. Then, the belt 43 is set in a predetermined winding state.

  Next, as shown in FIG. 8, the pressurizing device 40 in which the liquid pack 30 is arranged is suspended from the pressurizing device holding base 70. That is, the suspending portion 41 a provided in the device main body 41 of the pressurizing device 40 is hooked on the hanging tool 71 provided in the pressurizing device holding base 70.

  Next, the user punctures the puncture portion 33 provided at one end portion of the storage body 31 with the needle 4 provided at the end portion of the proximal end side liquid feeding tube 27b. In addition, the user connects the gas supply connector 29 provided at the end of the proximal end side air supply tube 26 b to the gas supply connector 48.

  This completes the connection work. After the connection work is completed, for example, the surgeon operates the rubber ball 47 to inflate the balloon 42. Then, the surgeon stops the air supply by the rubber ball 47 when the measured value of the pressure gauge 46 reaches a desired value. Thereby, the balloon 42 and the liquid pack 30 are maintained in a predetermined pressing state set in advance.

  In this state, the operator inserts the insertion portion 14 of the endoscope 10 to which the cleaning sheath 20 is attached into the body cavity in order to observe the inside of the body cavity. If an adherent such as mucus, blood, or fat in the living body adheres to the distal end surface of the distal end portion 11 during endoscopic observation, the defect may reduce the irradiation range of illumination light due to the adherent, or the observation visual field cannot be secured. A malfunction occurs.

  In such a case, the surgeon switches the switch body 52 of the spray switch 50 from the non-operation state to the spray state. That is, the switch body 52 is pushed down against the urging force of the spring 58 and the like.

  Then, the fourth cap 56d and the second cap 56b communicate with each other through a gap between the inner surface of the switch sliding hole 54 and the outer surface of the switch body 52, so that the physiology in the pressurized liquid pack 30 is obtained. The saline solution 32 is sent to the liquid feed hole 2 c through the base end side liquid feed tube 27 b, the fourth base 56 d, the gap, the second base 56 b, the distal end side liquid feed tube 27 a, and the liquid supply port 25. At the same time, the third cap 56d and the first cap 56b communicate with each other through a gap between the inner surface of the switch sliding hole 54 and the outer surface of the switch body 52, so that the air in the pressurized balloon 42 is supplied. The sterilization filter 28, the proximal end side air supply tube 26 b, the third base 56 c, the gap, the first base 56 a, the distal end side air supply tube 26 a, and the gas supply port 24 are sent to the air supply hole 2 b.

  And the air sent out to the air supply hole 2b is supplied to the air supply groove | channel 3i from the front-end | tip opening for air supply of this air supply hole 2b, and is supplied toward the fluid confluence | merging part 3m. On the other hand, the water sent to the liquid feed hole 2c is supplied from the liquid feed front end opening of the liquid feed hole 2c to the liquid feed groove 3h and is supplied toward the fluid junction 3m.

  In the fluid merging portion 3m, the air supplied through the air supply groove 3i and the water supplied through the liquid supply groove 3h merge and are mixed to supply the mixed fluid to the ejection groove 3k. .

  The mixed fluid supplied to the ejection groove 3k is ejected in a sprayed state from an ejection port which is an open end 3e of the ejection groove 3k to an observation window (not shown) provided on the distal end surface of the distal end portion 11 and a light exit end. .

  As a result, the adhering matter adhering to the distal end surface of the distal end portion 11 is removed by the spray-like mixed fluid, and the irradiation range of the illumination light and the observation visual field are returned to the original state to obtain a normal endoscopic image. It is done.

If the surgeon determines that the removal of the adhering matter adhering to the distal end surface has been completed from the endoscopic image, the amount of force to push down the switch body 52 is reduced. Then, the switch body 52 is switched from the sprayed state to the non-operating state by the urging force of the spring 58, and the physiological saline 32 in the pressurized liquid pack 30 is sent out to the feeding hole 2c and pressurized. The air in the balloon 42 is blocked from being sent to the air supply hole 2b, and the spraying of the ejected fluid is stopped.
After the endoscopic observation is completed, the cleaning sheath 20 and the liquid pack 30 used for the endoscopic observation are discarded. Thus, the physiological saline pack in which the physiological saline is stored is disposed in a pressurizing device including a balloon and a belt, and the balloon is inflated. As a result, the physiological saline pack and the balloon are pressed at a predetermined pressure and the physiological saline in the liquid pack is sent to the liquid feeding hole, and the air in the balloon is sent to the air feeding hole, and the observation window of the endoscope and A cleaning system for spraying the mixed fluid on the light emitting end can be configured simply. This frees you from the cumbersome task of preparing multiple devices and multiple tubes.

  In addition, while connecting the gas supply connector provided at the proximal end of the proximal-side air supply tube included in the cleaning sheath to the gas supply connector of the balloon, the needle provided at the proximal end of the proximal-end liquid supply tube A cleaning system can be constructed by puncturing the puncture portion of the liquid pack. This frees you from the troublesome connection work of connecting a plurality of tubes.

  In this embodiment, the heat-insulated liquid pack 30 is disposed in the space 44, but the liquid pack 30 is covered with a heat-insulating sheet for the purpose of preventing the temperature of the liquid pack 30 from decreasing. It may be arranged in the space 44. Further, a heating means for heating the liquid pack 30 in the pressurizing device 40 may be provided in the space 44.

  FIGS. 9 to 12 relate to a second embodiment of the endoscope cleaning system including the cleaning system, FIG. 9 is a diagram for explaining another configuration of the cleaning system mounted on the endoscope, and FIG. FIG. 11 is a cross-sectional view taken along the line XI-XI of the fluid energy conversion device provided in the pressurizing apparatus of FIG. 10, and FIG. 12 is a cross-sectional view taken along the line XII-XII of FIG. It is.

  As shown in FIG. 9, the endoscope cleaning system 1 </ b> A of the present embodiment includes an endoscope 10, a cleaning sheath 20 </ b> A, a liquid pack 30, and a pressurizing device 40 </ b> A having a fluid energy conversion device 80. Has been.

  In the cleaning sheath 20A of this embodiment and the like, the connecting tube 26c extends from the proximal end side of the sterilizing filter 28 provided at the proximal end of the proximal end side air supply tube 26b. Further, the needle 4 is not attached to the end of the proximal end side liquid feeding tube 27b.

  As shown in FIGS. 9 and 10, the pressurizing device 40 </ b> A includes a balloon 42 and a belt 43 that are pressurizing means and a fluid energy converting device (hereinafter referred to as a conversion device) that is a fluid energy converting means on a plate-like device body 41 </ b> A. 80 (abbreviated as device). Also in the present embodiment, the liquid pack 30 changes to a state in which the liquid 42 is sandwiched between the inflated balloon 42 and the belt 43 and pressed with a predetermined pressure when the balloon 42 is inflated.

  The conversion device 80 is an air supply means, and includes a conversion unit main body 81, a first lid 82, and a second lid 83 as shown in FIGS. When the first lid 82 is fixed to the conversion unit main body 81, the first lid 82 and the conversion unit main body 81 are configured to be watertightly held by, for example, an O-ring (not shown). Further, when the second lid 83 is fixed to the conversion unit main body 81, the second lid 83 and the conversion unit main body 81 are watertightly held by an O-ring (not shown). .

  The conversion portion main body 81 is provided with a first space portion 84 and a second space portion 85. Reference numeral 86 denotes a partition wall, which divides the space in the conversion unit main body 81 into a first space portion 84 and a second space portion 85. A first communication hole 87 a and a second communication hole 87 b are provided on the side wall of the conversion unit main body 81 to communicate the outside with the first space 84. A protrusion 88a that is a tube connecting portion is provided on the outer side wall of the first communication hole 87a, and a protrusion 88b is provided on the outer side wall of the second communication hole 87b.

Further, a third communication hole 87 c that communicates the outside with the second space 85 is provided on the side wall of the conversion unit main body 81. A protrusion 88c is provided on the outer side wall of the third communication hole 87c.
In the present embodiment, one end of a liquid delivery tube 89 is detachably connected to the protrusion 88a. The other end of the liquid delivery tube 89 is provided with a needle 4 a that is pierced into the puncture portion 33 of the liquid pack 30. An end of the proximal end side liquid feeding tube 27b is detachably connected to the protrusion 88b, and an end of the connecting tube 26c is detachably connected to the protrusion 88c.
The protrusions 88 a, 88 b, 88 c are structures that are integrated with the conversion unit main body 81, even if they are integrated with the conversion unit main body 81. It may be.

  An impeller 91 having a plurality of liquid receiving portions 91a, that is, a so-called water wheel is disposed in the first space 84. The impeller 91 is integrally fixed to the first shaft portion 92 a of the shaft body 92. The shaft body 92 is sandwiched between the first lid body 82 and the partition wall 86 and is rotatably supported. The first space portion 84 includes a first flow path 84a formed counterclockwise from the first communication hole 87a to the second communication hole 87b, and a first flow path formed clockwise from the first communication hole 87a to the second communication hole 87b. 2 flow paths 84b. The distance between the outer surface of the impeller 91 constituting the first flow path 84a and the inner surface of the first space 84 is the distance between the outer surface of the impeller 91 constituting the second flow path 84b and the inner surface of the first space 84. It is wider.

  Therefore, the rotatable impeller 91 is configured so that the physiological saline 32 in the liquid pack 30 flows into the first space 84 from the first communication hole 87a through the liquid delivery tube 89, and then the first flow path 84a. Rotate in the direction of arrow P by being sent out from the second communication hole 87b through the second communication hole 87b. Reference numeral 82a denotes a recess, and the end of the first shaft portion 92a is disposed in the recess 82a.

  The shaft body 92 includes a second shaft portion 92b. The second shaft portion 92 b passes through a through hole 86 a formed in the partition wall 86 and protrudes into the second space portion 85 by a predetermined amount. An O-ring 90 is provided in the through hole 86a of the partition wall 86 so as to be in close contact with the outer peripheral surface of the second shaft portion 92b to ensure water tightness.

  The 2nd space part 85 is comprised by the rotating plate arrangement | positioning hole 85a and the sliding hole 85b. A rotating plate 93 and a crankshaft 94 are disposed in the rotating plate disposing hole 85a, and a crankshaft 94 and a piston 95 are slidably disposed in the sliding hole 85b.

  The rotating plate 93 is integrally fixed in the vicinity of the distal end portion of the second shaft portion 92b protruding into the rotating plate disposing hole 85a. On one surface side of the rotating plate 93, a transmission portion 93 a that transmits the rotation of the rotating plate 93 to the crankshaft 94 and moves the crankshaft 94 forward and backward is provided protruding.

  A cam hole 94a through which the transmission portion 93a is movable is formed at the end of the crankshaft 94 located in the rotary plate disposing hole 85a. The transmission portion 93a disposed in the cam hole 94a moves in the cam hole 94a as the rotating plate 93 rotates, so that the piston 95 in the sliding hole 85b moves in the arrow Q direction or the arrow R direction. It has become.

  The piston 95 is fixed to the tip of the crankshaft 94. An elastic member 96 such as an O-ring that is in close contact with the inner surface of the sliding hole 85b is disposed on the outer peripheral surface of the piston 95.

  Then, when the physiological saline 32 flows into the first space portion 84, the impeller 91 is rotated, and the rotating plate 93 is rotated with the rotation of the impeller 91, so that the crankshaft 94 and the piston 95 are moved forward and backward. Operate. As a result, the fluid energy of the physiological saline 32 is converted into kinetic energy for moving the piston 95 forward and backward.

When the piston 95 moves in the arrow Q direction, the air in the sliding hole 85b is moved through the third communication hole 87c, the connecting tube 26c, the proximal-side air supply tube 26b, the spray switch 50, and the distal-side air supply tube 26a. Through the air supply hole 2b.
Other configurations are the same as those of the first embodiment, and the same members are denoted by the same reference numerals and description thereof is omitted.

  An operation of the endoscope cleaning system 1A including the pressurizing device 40A configured as described above will be described.

  In performing endoscopic observation, the user prepares the cleaning sheath 20A packed in a sterilization pack, the liquid pack 30, the endoscope 10 that has been cleaned and disinfected, and the pressurizing device 40A.

  The user attaches the tube body 22 and the distal end configuration portion 21 of the cleaning sheath 20A taken out from the sterilization pack to the insertion portion 14 of the endoscope 10, and attaches the attachment portion 23 to the distal end side portion of the operation portion 15 of the endoscope 10. Install in the prescribed state.

  Next, the user places the liquid pack 30 in the space 44 configured in the pressurizing apparatus 40 </ b> A, and then hangs the pressurizing apparatus 40 </ b> A in which the liquid pack 30 is disposed on the pressurizing apparatus holding base 70.

  Next, the user connects the end of the proximal end side liquid feeding tube 27b to the protrusion 88b and connects the connecting tube 26c to the protrusion 88c. Thereafter, the user connects one end of the liquid delivery tube 89 to the protrusion 88a, and then punctures the puncture portion 33 with the needle 4a.

  This completes the connection work. After the connection work is completed, for example, the surgeon operates the rubber ball 47 to inflate the balloon 42. Then, the surgeon stops the air supply by the rubber ball 47 when the measured value of the pressure gauge 46 reaches a desired value. As a result, the liquid pack 30 is maintained in a predetermined pressed state.

  In this state, the operator performs observation by inserting the insertion portion 14 of the endoscope 10 to which the cleaning sheath 20A is attached into the body cavity. During endoscopic observation, when an adherent such as mucus, blood, or fat in the living body adheres to the distal end surface of the distal end portion 11, the operator switches the switch body 52 of the spray switch 50 from the non-operating state to the spraying state. .

  Then, as described above, the fourth base 56d and the second base 56b communicate with each other through a gap, so that the physiological saline 32 in the pressurized liquid pack 30 is supplied to the liquid delivery tube 89 and the first communication hole. 87 a, first space 84, second communication hole 87 b, base end side liquid feeding tube 27 b, fourth base 56 d, gap, second base 56 b, tip side liquid feeding tube 27 a, and liquid supply port 25 It is sent out to the liquid hole 2c.

  The fourth cap 56d and the second cap 56b communicate with each other through a gap, and the delivery of the physiological saline 32 to the distal end side liquid feeding tube 27a is started. At the same time, the impeller 91 rotates in the direction of arrow P. Then, with the rotation of the impeller 91, the rotating plate 93 of the second space 85 is rotated, and the piston 95 moves forward and backward. Then, when the piston 95 moves in the direction of the arrow Q, the air in the sliding hole 85b becomes the third communication hole 87c, the connecting tube 26c, the sterilizing filter 28, the proximal end side air supply tube 26b, the third base 56d, The air is sent to the air supply hole 2b through the gap, the first base 56b, and the tip side air supply tube 26a.

  Thus, the air sent to the air supply hole 2b is supplied to the air supply groove 3i from the air supply front end opening of the air supply hole 2b, while the water sent to the liquid supply hole 2c is supplied to the liquid supply hole 2c. Is supplied to the liquid feed groove 3h from the liquid feed front end opening, and air and water join at the fluid junction 3m, and the mixed fluid is supplied to the ejection groove 3k. The mixed fluid supplied to the ejection groove 3k is ejected in a sprayed state from an ejection port which is the open end 3e to an observation window (not shown) provided on the distal end surface of the distal end portion 11 and a light emitting end.

  In this way, by configuring the pressurizing device having the fluid energy conversion device, the physiological saline of the liquid pack pressed by the balloon is sent to the liquid feeding hole through the first space portion of the fluid energy conversion device, and The kinetic energy of the physiological saline sent to the liquid feeding hole through the first space is converted into the kinetic energy for moving the piston forward and backward, and the air in the second space is sent to the air feeding hole, and the observation window of the endoscope And the washing | cleaning system which sprays mixed fluid on the light-projection end can be made into a simple structure. This frees you from the troublesome work of preparing a plurality of devices and a plurality of tubes and the troublesome connection work of connecting a plurality of tubes.

  In the above-described embodiment, the balloon is inflated with a rubber ball. However, the balloon is configured to supply the gas of an air supply device provided in the operating room to the balloon and maintain the balloon in a desired inflated state. May be. In the embodiment described above, the liquid is physiological saline, but the liquid is not limited to physiological saline, and may be sterilized water or the like.

  The present invention is not limited to the embodiments described above, and various modifications can be made without departing from the spirit of the invention, and the embodiments described above are partially combined. Embodiments and the like belong to the present invention.

1 to 8 relate to a first embodiment of an endoscope cleaning system provided with a cleaning system, and FIG. 1 is a diagram illustrating a cleaning system attached to the endoscope. II-II sectional view of FIG. Rear view explaining the configuration of the tip component The figure explaining the composition of a pressurizing device The figure explaining the operation of the pressurizing device The figure explaining the spray switch of the non-operation state The figure explaining the spray switch of a spray state The figure explaining the state which attached the pressurization device to the stand FIGS. 9 to 12 relate to a second embodiment of the endoscope cleaning system provided with the cleaning system, and FIG. 9 is a diagram illustrating another configuration of the cleaning system mounted on the endoscope. The figure explaining the structure of the pressurization apparatus provided with the fluid energy converter XI-XI sectional view of the fluid energy conversion device provided in the pressurizing device of FIG. XII-XII line sectional view of FIG. The figure explaining the conventional structure of an endoscope cleaning system

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Endoscope cleaning system 2b ... Air supply hole 2c ... Liquid supply hole 3h ... Liquid supply groove 3i ... Air supply groove 3k ... Jet groove 3m ... Fluid confluence | merging part 4 ... Needle 10 ... Endoscope 14 ... Insertion part 15 ... Operation Section 20 ... Cleaning sheath 21 ... Tip configuration section 22 ... Tube body 24 ... Gas supply port 25 ... Liquid supply port
26a: distal end side air supply tube 26b: proximal end side air supply tube
27a ... distal end side liquid supply tube 27b ... proximal end side liquid supply tube 29 ... air supply connection part 30 ... liquid pack 33 ... puncture part 40 ... pressure device 41 ... apparatus main body 42 ... balloon 43 ... belt 48 ... for gas supply Connector 50 ... Spray switch

Claims (8)

A cleaning sheath that includes a liquid supply path that supplies liquid and a gas supply path that supplies gas, mixes the liquid and gas supplied through the liquid supply path and the gas supply path, and ejects the mixed fluid;
First storage means for storing liquid to be delivered to the liquid supply path of the cleaning sheath;
Pressurizing means for supplying gas to pressurize the first storage means, and for sending the liquid stored in the first storage means to the liquid supply path;
In order to pressurize the liquid stored in the first storage means, the gas supplied to the pressurization means is sent out to the gas supply path of the cleaning sheath, or is sent out from the first storage means by the pressurization means. An air supply means for sending a gas to the gas supply path of the cleaning sheath using the kinetic energy of the liquid to be discharged;
A cleaning system comprising:   The air supply means is a second storage means for storing a gas that also serves as the pressurizing means, and pressurizes the second storage means in which the gas is stored to a predetermined pressure so that the gas in the cleaning sheath The cleaning system according to claim 1, wherein the gas is delivered to a supply path. A first storage means for storing a liquid;
A second storage means for storing gas;
A liquid supply path for liquid delivered from the first storage means and a gas supply path for gas delivered from the second storage means, and the liquid supplied via the liquid supply path and the gas supply path; A cleaning sheath for mixing a gas and ejecting a mixed fluid;
The first storage means and the second storage means are simultaneously pressurized to send the liquid stored in the first storage means to the liquid supply path of the cleaning sheath, and the second storage means Pressurizing means for delivering the gas stored in the cleaning sheath to the gas supply path;
A cleaning system comprising:   The second storage means is a pressurizing balloon that serves as both the pressurizing means and the air supply means, and the gas in the pressurizing balloon is expanded to a predetermined pressure by inflating the pressurizing balloon to a predetermined pressure. The cleaning system according to claim 2, wherein the cleaning system is sent to a gas supply path.   The air supply means is fluid energy conversion means for converting the kinetic energy of the liquid delivered from the first storage means by the pressurizing means into kinetic energy for sending gas to the gas supply path of the cleaning sheath. The cleaning system according to claim 1. A cleaning sheath that includes a liquid supply path for supplying a liquid and a gas supply path for supplying a gas, and mixes the liquid and gas supplied through the liquid supply path and the gas supply path to inject a mixed fluid;
First storage means for storing liquid to be delivered to the liquid supply path of the cleaning sheath;
A pressurizing unit including a pressurizing balloon, and inflating the pressurizing balloon to a predetermined pressure to send out the liquid stored in the first storing unit;
Fluid energy conversion means for converting the kinetic energy of the liquid delivered from the first storage means by the pressurizing means into kinetic energy for sending gas to the gas supply path of the cleaning sheath;
A cleaning system comprising: The fluid energy conversion means includes a first conversion unit that converts kinetic energy of the liquid into rotational motion;
A second converter that sends the gas to the gas supply path of the cleaning sheath by converting the rotational motion into a reciprocating motion;
The cleaning system according to claim 6, further comprising: The cleaning sheath is
An endoscope arrangement hole into which an elongated insertion portion of an endoscope having at least an observation window is inserted and arranged on the distal end surface of the insertion portion, a liquid supply path for supplying the liquid, and a gas supply path for supplying gas A tube body,
A cylindrical body fixed to the distal end portion of the tube body, wherein the liquid supply is applied to an abutting surface on which a part of the distal end surface of the tube body and a part of the distal end surface of the insertion portion of the endoscope abut. The fluid mixing unit that mixes the liquid sent through the channel and the gas sent through the gas supply channel to mix the liquid and the gas, and the mixed fluid mixed in the fluid mixing unit A tip constituting portion having a recess that constitutes a spout that is ejected toward the observation window of the mirror;
The cleaning system according to claim 1, wherein the cleaning system is provided.

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