JP6145050B2 - Endoscope storage - Google Patents

Description

  The present invention relates to an endoscope storage for storing an endoscope having an internal conduit.

  An endoscope is used to observe an affected area of a patient and collect a tissue piece. The endoscope described in Patent Literature 1 includes an operation unit, an insertion unit extending from the operation unit, a connector to which a light source device, a pump, and the like are connected, and a universal cord that connects the connector and the operation unit. Inside the operation section, insertion section, connector, and universal cord, internal pipelines such as an air supply / water supply channel for supplying air and water and a suction / forceps channel for inserting suction and forceps are extended. Yes. Each opening of the air / water supply channel and the suction / forceps channel is exposed at the distal end surface of the insertion portion to be inserted into the patient's body.

  Endoscopes used for examinations and treatments are washed with a cleaning solution, disinfected with a disinfecting solution, and rinsed with sterilized water in order to remove attached blood, tissue pieces, and drugs. Then, it is stored in the endoscope storage until the next use. Here, if an insufficiently dried endoscope is stored in the endoscope storage, bacteria may propagate in the internal conduit. In order to prevent such bacterial growth, Patent Document 2 describes an endoscope storage that stores an endoscope housed in the storage while drying. The endoscope storage in the same document supplies air warmed by a heating device into the storage, and connects a hot air supply tube to a communication port that communicates with the internal conduit of the endoscope. Warm air is introduced into the internal pipe.

JP 2010-184023 A JP 2008-301875 A

  Endoscopes are used for multiple patients. Therefore, it is desirable to reliably prevent the propagation of bacteria in the internal duct and to avoid nosocomial infections mediated by endoscopes.

  In view of the above, an object of the present invention is to provide an endoscope storage that can reliably prevent the growth of bacteria in the internal duct of an endoscope.

  In order to solve the above-described problems, the present invention provides an endoscope that stores an endoscope that includes an operation unit, an insertion unit that extends from the operation unit, and an internal conduit that extends through the operation unit and the insertion unit. In an endoscope storage, an ozone generator, an ozone supply pipe extending through the ozone generator and detachably connected to a first communication port of the endoscope communicating with the internal conduit , An ozone decomposition catalyst for decomposing ozone, an ozone decomposition box detachably connected to a second communication port of the endoscope communicating with the internal conduit, and the ozone supply pipe being the first A gas flow path formed by the ozone supply pipe, the internal pipe line and the ozone decomposition box when connected to the communication port and the ozonolysis box is connected to the second communication port; In the flow path, the ozone generator, the inner pipe And characterized by having a, a pump for generating an air flow passing through the ozonolysis box in this order.

According to the present invention, ozone having a bactericidal action generated by an ozone generator can be circulated through the internal conduit of the endoscope. Therefore, even when an insufficiently dried endoscope is stored in the endoscope storage, it is possible to prevent bacteria from growing in the internal conduit before the internal conduit is dried. Here, the internal conduit of the endoscope is generally formed of a material having high chemical resistance such as stainless steel or a fluororesin. Therefore, even when ozone is circulated through the internal pipe, the internal pipe does not deteriorate. On the other hand, the outer surface of the endoscope is made of polyurethane or the like, and has lower chemical resistance than stainless steel or fluororesin. For this reason, when the outer surface of the endoscope is exposed to ozone for a long time, it may be deteriorated. With respect to such a problem, in the present invention, ozone flows through the gas flow path formed by the ozone supply pipe, the internal pipe line, and the ozonolysis box, and does not flow along the outer surface of the endoscope. In addition, ozone that has flowed through the gas flow path via the internal pipe is decomposed in the ozone decomposition box. Therefore, it is possible to prevent the outer surface of the endoscope from being deteriorated by ozone.

  In the present invention, it is preferable that a heater is provided and the pump introduces air heated by the heater into the gas flow path to generate the air flow. If it does in this way, the air warmed with ozone can be sent through an internal pipe line. Therefore, it is possible to dry the internal conduit while preventing bacterial growth.

  In the present invention, the ozonolysis box includes an exhaust port, and a fan that is disposed between the ozone decomposition catalyst and the exhaust port and generates an air flow toward the exhaust port via the ozone decomposition catalyst. Is desirable. If it does in this way, the pressure inside an ozonolysis box can be made lower than the exterior by driving a fan. Therefore, it is possible to prevent or suppress ozone from leaking from the ozonolysis box.

  In the present invention, a storage chamber in which the endoscope is accommodated, a machine room in which the ozone generator, the pump, and the heater are accommodated, and air heated by the heater from the machine chamber. It is desirable to have a blower fan sent out to the storage room. If it does in this way, the air warmed with the heater can be supplied to a storage room, and an endoscope can be dried from the outside.

  In the present invention, the insertion portion has a holding plate that can hold the operation portion as a state in which the insertion portion hangs downward from the operation portion, and the holding plate is cut out from the side and penetrates in the vertical direction. The groove portion is a bulging portion having a groove width larger than that of both sides sandwiching the intermediate portion, and an outer peripheral edge portion of the bulging portion of the holding plate is the operation portion. It is desirable to hold from the lower part the part which is tapering toward the insertion part in the part. If it does in this way, an operation part can be hold | maintained to a holding | maintenance board by inserting an operation part into a bulging part from upper direction. Moreover, the operation part can be removed from the holding plate by lifting the operation part upward. Therefore, it becomes easy to store and take out the endoscope in the cabinet. Further, since the endoscope is stored in a state where the insertion portion hangs downward from the operation portion, moisture remaining in the internal conduit can be discharged to the outside from the opening provided at the distal end of the insertion portion.

  According to the endoscope storage of the present invention, the bactericidal ozone generated by the ozone generator can be distributed to the internal pipe of the endoscope, so that bacteria in the internal pipe of the endoscope Can be reliably prevented from breeding.

It is the perspective view and explanatory drawing of the endoscope storage warehouse to which this invention is applied. It is a schematic block diagram which shows the internal structure of an endoscope storage. It is explanatory drawing of a holding plate. It is a schematic block diagram which shows the internal structure of the endoscope storage warehouse of a modification.

  Hereinafter, an endoscope storage to which the present invention is applied will be described with reference to the drawings.

(overall structure)
FIG. 1A is a perspective view of an endoscope storage, and FIG. 1B is an explanatory view showing a state of the endoscope stored in the endoscope storage. In FIG.1 (b), in order to understand the state where the endoscope was stored, a part of the opening / closing door on the front of the endoscope storage is cut out to show the interior. FIG. 2 is a schematic configuration diagram showing the internal structure of the endoscope storage.

  As shown in FIG. 1A, the endoscope storage 1 has a rectangular parallelepiped shape. A rectangular opening / closing door 2 is attached to the front surface of the endoscope storage 1. The open / close door 2 rotates around one end portion in the width direction X of the endoscope storage 1 around the rotation center axis L extending in the vertical direction, and is a storage chamber partitioned inside the endoscope storage 1. 4 is opened and closed.

  A handle 3 is provided at the center in the vertical direction of the other end portion of the opening / closing door 2 in the width direction X. A rectangular vent 5 that is long in the width direction X is provided at the upper end portion of the open / close door 2. A louver 6 in which a plurality of inclined plates extending in the width direction X are arranged in the vertical direction is attached to the vent hole 5. Each inclined plate is inclined upward toward the rear. A control unit 10 including an operation switch 7, a timer 8, and an indicator 9 such as an LED is attached to the central portion of the open / close door 2.

  A rectangular intake port 11 that is long in the width direction X is provided below the open / close door 2 on the front surface of the endoscope storage 1. A louver 12 in which a plurality of inclined plates extending in the width direction X are arranged in the vertical direction is attached to the intake port 11. Each inclined plate is inclined upward toward the rear. The air inlet 11 communicates with a machine room 13 (see FIG. 2) partitioned inside the endoscope storage 1. Casters 14 are attached to the four corners of the bottom surface of the endoscope storage 1 respectively.

(Internal structure)
As shown in FIG. 2, the interior of the endoscope storage 1 is partitioned into a machine room 13 and a storage room 4 by a horizontal partition plate 21 attached to a lower end side portion thereof. The machine room 13 is located below the storage room 4 and is a narrow space compared to the storage room 4. The endoscope 100 is stored in the storage room 4.

  In the machine room 13, a high efficiency particulate air (HEPA) filter 22, a heater 23, a pump 24, an ozone generator 25, and a blower fan 26 are installed. In the storage chamber 4, a holding plate 30, a holding plate support mechanism 31 (see FIG. 1B), an ozonolysis box 32, and a receiving tray 33 are installed. Further, an ozone supply pipe 34 is installed inside the endoscope storage 1. The ozone supply pipe 34 extends from the machine room 13 through the horizontal partition plate 21 into the storage room 4.

  The HEPA filter 22 is attached so as to cover the air inlet 11 from the inside of the machine room 13. The heater 23 is disposed at a position adjacent to the rear of the HEPA filter 22 in the front-rear direction Y of the endoscope storage 1. The heater 23 heats the air flowing into the machine room 13 from the intake port 11 through the HEPA filter 22.

The pump 24 and the ozone generator 25 are connected by an ozone supply pipe 34. The pump 24 introduces the air heated by the heater 23 into the ozone supply pipe 34, passes through the ozone generator 25, and sends warm air containing ozone to the storage chamber 4 side through the ozone supply pipe 34. Send it out.

  The blower fan 26 is attached to a blower port 27 provided at the rear end portion of the horizontal partition plate 21. The blower fan 26 causes the air heated by the heater 23 to flow into the storage chamber 4 through the blower port 27. A louver 28 in which a plurality of inclined plates are arranged in the front-rear direction Y is attached to the air outlet 27. Each inclined plate is inclined forward and upward.

  In the storage chamber 4, the endoscope 100 is stored in a state of being suspended from the holding plate 30. Here, the endoscope 100 includes an operation unit 101, an insertion unit 102 extending from the operation unit 101, a connector 103 to which a light source device, a pump 24, and the like are connected, and a universal cord 104 that connects the connector 103 and the operation unit 101. Is provided. The insertion part 102 is a part inserted into the patient's body. Inside the operation unit 101, the insertion unit 102, the connector 103, and the universal cord 104, an air / water supply channel (internal conduit) 105 for supplying and supplying air, and a suction for inserting suction and forceps A forceps channel (inner conduit) 106 extends. The operation unit 101 is provided with an air / water supply cylinder (first communication port) 107 communicating with the air / water supply channel 105. Further, the operation unit 101 is provided with a forceps plug port (first communication port) 108 communicating with the suction / forceps channel 106. On the distal end surface of the insertion portion 102, a nozzle (second communication port) 109 serving as one end opening of the air / water feeding channel 105 and a forceps opening (first opening) serving as one end opening of the suction / forceps channel 106 are provided. 2 communication ports) 110 are exposed. The connector 103 includes an air supply / water supply port (second communication port) 111 serving as the other end opening of the air supply / water supply channel 105 and a suction port (first connection) serving as the other end opening of the suction / forceps channel 106. 2 communication ports) 112 are provided.

  The holding plate 30 holds the endoscope 100 in a state where the insertion unit 102 hangs downward from the operation unit 101. FIG. 3A is a plan view of the holding plate 30, and FIG. 3B is a partially enlarged view showing a state where the operation unit 101 of the endoscope 100 is held by the holding plate 30. The holding plate 30 has a rectangular shape that is elongated in the front-rear direction Y as a whole, and is disposed with its thickness direction directed upward and downward. In this example, three holding plates 30 are arranged in the width direction X as shown in FIG. Therefore, the endoscope storage 1 can store three endoscopes 100 in the storage room 4.

  As shown in FIG. 3A, each holding plate 30 is notched from one side (side) in the width direction X to the front side slightly from the center in the front-rear direction Y and penetrates in the up-down direction. The groove part 36 to be provided is provided. In the groove portion 36, a central portion in the notch direction (width direction X) is a bulging portion 37 having a larger groove width than both sides sandwiching the central portion. Here, as shown in FIG. 3B, in the endoscope 100, the tapered portion 101 a that is tapered toward the insertion portion 102 side in the operation portion 101 is inserted into the bulging portion 37 from above. It is held on the holding plate 30 in a state. That is, the holding plate 30 holds the tapered portion 101a of the operation portion 101 from the lower side at the outer peripheral edge portion of the bulging portion 37 of the holding plate 30.

  A front notch 38 and a rear notch 39 are provided on both sides of the holding plate 30 in the front-rear direction Y with the groove 36 interposed therebetween. The front notch 38 and the rear notch 39 are provided by notching the holding plate 30 from the same direction as the groove 36. The tip portions of the cutout portions 38 and 39 in the cutout direction have an arc shape when viewed from above and below. A through hole 40 is formed in the front end portion on the other side in the width direction X of the holding plate 30. When the operation unit 101 is held by the holding plate 30, the universal cord 104 is locked to the rear notch 39.

Here, as shown in FIG. 1B, each holding plate 30 is supported by the holding plate support mechanism 31 in a state in which it can slide in the front-rear direction Y. Further, as shown in FIG. 2, each holding plate 30 is supported by a holding plate support mechanism 31, and a storage position 30 </ b> A where the entire storage plate is located in the storage chamber 4 and a rear notch 39. Is movable between the drawer positions 30B located in front of the storage chamber 4. As shown in FIG. 1B, each holding plate support mechanism 31 includes a guide rail 41 extending horizontally in the front-rear direction Y, and the holding plate 30 is supported by the guide rail 41 on the other edge portion. In the state, it moves along the guide rail 41.

  The ozone supply pipe 34 includes a rigid piping part 45 and three flexible tube parts 46. The piping portion 45 is made of stainless steel, and the tube portion 46 is made of a fluororesin. The piping part 45 is bent upward after passing through the pump 24 and the ozone generator 25 and extends through the horizontal partition plate 21 into the storage chamber 4. In addition, the piping part 45 extends along the rear wall surface 4a in the storage chamber 4 to reach the vicinity of the ceiling surface 4b, and extends in the width direction X along the ceiling surface 4b.

  As shown in FIG. 1B, the three tube portions 46 are connected to the upper end portions of the piping portions 45 whose rear ends extend in the width direction X, respectively. Each tube portion 46 is pulled out forward above the holding plate 30 while being supported by a tube locking mechanism 44 (see FIG. 2) integrally attached to each holding plate 30. Each tube portion 46 includes a slack portion 47 that curves downward at a rear end portion close to the piping portion 45. Furthermore, each tube portion 46 is drawn downward and then drawn downward, and passes through the through hole 40 provided in each holding plate 30 from above to below. Here, when the holding plate 30 moves from the storage position 30A to the drawing position 30B, the slack portion 47 extends in the front-rear direction Y along the ceiling surface 4b and the holding plate 30 moves in the front-rear direction Y. Is acceptable.

  In each tube portion 46, a valve 48 is attached to a portion on the distal end side with respect to a portion penetrating the through hole 40. Further, each tube portion 46 includes a first branch tube portion 49 and a second branch tube portion 50 that are bifurcated at the tip side of the valve 48. A first connector 51 is attached to the tip of the first branch tube portion 49, and the first branch tube portion 49 is detachably connected to the air / water supply cylinder 107 via the first connector 51. A second connector 52 is attached to the distal end of the second branch tube portion 50, and the second branch tube portion 50 is connected to the forceps plug port 108 via the second connector 52. Here, as shown in FIG. 3B, when the operation portion 101 is held by the holding plate 30, the first branch tube portion 49 is inserted into the front cutout portion 38.

  As shown in FIG. 2, the ozonolysis box 32 is disposed at a position below the insertion portion 102 and the connector 103 of the endoscope 100 when the endoscope 100 is held by the holding plate 30. The ozonolysis box 32 includes a rectangular parallelepiped housing 60 that is elongated in the width direction X as a whole, and an ozonolysis catalyst 61 is accommodated therein. The housing 60 includes a front plate 62 extending in the width direction X and the vertical direction, a top plate 63 extending rearward from the upper end of the front plate 62, and a back plate 64 extending downward from the rear end of the top plate 63; A bottom plate 65 extending forward from the lower end of the back plate 64, and a pair of side plates 66, 67 disposed on both sides in the width direction X of the front plate 62, the top plate 63, the back plate 64, and the bottom plate 65 (FIG. 1B )). An exhaust port 68 is formed above the center portion of the front plate 62 in the width direction X. A net 69 is stretched at the exhaust port 68. The bottom plate 65 is inclined downward toward the front, and a gap is formed between the front end of the bottom plate 65 and the front plate 62. This gap serves as a drain port 70 for discharging water droplets dropped from the endoscope 100 into the ozone decomposition box 32.

The ozonolysis box 32 includes a first connection tube 71 detachably attached to the distal end of the insertion portion 102 of each endoscope 100 held by each holding plate 30, and an air / water supply port 111 of the connector 103. And a third connection tube 73 attached to the suction port 112 of the connector 103. That is, the ozonolysis box 32 is connected to the endoscope 100 as a first connection tube 71, a second connection tube 72, and a third connection tube 7.
Three sets of three are provided. Further, the ozonolysis box 32 is disposed between the ozonolysis catalyst 61 and the exhaust port 68, and a connection portion (first connection tube 71, second connection tube 72) with the endoscope 100 in the ozonolysis box 32. And a fan 74 for generating an air flow from the third connection tube 73) to the exhaust port 68 via the ozone decomposition catalyst 61.

  The tray 33 is placed on the horizontal partition plate 21. The endoscope 100 held by the ozonolysis box 32 and the holding plate 30 is located inside the tray 33 when viewed from above. The tray 33 receives moisture dripped from the endoscope 100 and the ozonolysis box 32.

  Here, the heater 23, the pump 24, the ozone generator 25, the blower fan 26, and the fan 74 of the ozonolysis box 32 are driven and controlled by the control unit 10. That is, the heater 23, the pump 24, the ozone generator 25, the blower fan 26, and the fan 74 start driving when the operation switch 7 of the control unit 10 is operated. Then, when a preset driving time has elapsed, the driving is stopped by the timer 8. Further, the control unit 10 acquires the temperature of the storage chamber 4 by a temperature detector (not shown), and drives and controls the heater 23 so that the temperature in the storage chamber 4 is about 40 ° C. Furthermore, the control unit 10 monitors the temperature state of the heater 23, and stops driving when the temperature of the heater 23 exceeds a preset abnormal value. Further, the control unit 10 lights up the display unit 9 while driving the heater 23, the pump 24, the ozone generator 25, the blower fan 26 and the fan 74.

(Storage operation)
The endoscope 100 used for diagnosis and treatment is subjected to cleaning with a cleaning liquid, disinfection with a disinfecting liquid, and rinsing with sterilized water in order to remove adhering blood, tissue pieces, and drugs. And it is stored in the endoscope storage 1 until it is used next time.

  When storing the endoscope 100 in the endoscope storage 1, the door 2 is opened, and the holding plate 30 is pulled out to the pulling position 30 </ b> B as indicated by an imaginary line in FIG. 2. Then, the operation unit 101 of the endoscope 100 is inserted into the bulging portion 37 from above, whereby the operation unit 101 is held by the holding plate 30. Further, the universal cord 104 of the endoscope 100 is locked to the rear notch 39 of the holding plate 30. Further, the first branch tube portion 49 of the ozone supply pipe 34 is connected to the air / water supply cylinder 107, and the first branch tube portion 49 is locked to the front cutout portion 38. Further, the second branch tube portion 50 is connected to the forceps plug port 108. Then, the valve 48 provided in the tube portion 46 connected to the endoscope 100 is opened. Thereafter, the holding plate 30 is moved from the drawer position 30B to the storage position 30A.

  Next, the first connection tube 71 of the ozonolysis box 32 is connected to the distal end portion of the insertion portion 102 of the endoscope 100. That is, the nozzle 109 serving as the end opening of the air / water supply channel 105 and the ozonolysis box 32 are connected, and the forceps port 110 of the suction / forceps channel 106 and the ozonolysis box 32 are connected. In addition, the second connection tube 72 of the ozonolysis box 32 is connected to the air / water supply port 111 of the connector 103, and the third connection tube 73 is connected to the suction port 112 of the connector 103. As a result, a first gas flow path A is formed from the ozone supply pipe 34 to the ozone decomposition box 32 via the air / water supply cylinder 107, the air / water supply channel 105, the nozzle 109 and the air / water supply port 111. . A second gas flow path B is formed from the ozone supply pipe 34 to the ozone decomposition box 32 through the forceps plug port 108, the suction / forceps channel 106, the forceps port 110, and the suction port 112.

  Thereafter, the door 2 is closed and the driving time is set by the timer 8. And the operation switch 7 is operated and the heater 23, the pump 24, the ozone generator 25, the ventilation fan 26, and the fan 74 are driven.

  Accordingly, the blower fan 26 supplies the air (warm air) heated by the heater 23 from the machine room 13 to the storage room 4. And the inside of the storage chamber 4 is maintained at around 40 ° C. Further, the pump 24 generates an air flow that passes through the ozone generator 25, the air / water supply channel 105, and the ozone decomposition box 32 in this order in the first gas flow path A, and generates ozone in the second gas flow path B. An air flow is generated through the container 25, the suction / forceps channel 106, and the ozonolysis box 32 in this order. That is, the pump 24 flows the sterilizing ozone generated by the ozone generator 25 into the air / water supply channel 105 and the suction / forceps channel 106 together with the air (warm air) heated by the heater 23.

  Thereafter, when the set drive time has elapsed, the timer 8 stops the driving of the heater 23, the pump 24, the ozone generator 25, the blower fan 26 and the fan 74. Further, the display 9 is turned off. The endoscope 100 is stored in the endoscope storage 1 until it is next used.

(Function and effect)
In this example, warm air is supplied to the storage room 4, and the inside of the storage room 4 is maintained at around 40 ° C. Therefore, even when the insufficiently dried endoscope 100 is stored in the endoscope storage 1, the outer surface of the endoscope 100 is dried. Further, in this example, warm air containing ozone flows through the air / water supply channel 105 and the suction / forceps channel 106. Therefore, it is possible to prevent bacteria from breeding in the internal conduit before the internal conduit is dried. Furthermore, in this example, the air introduced into the machine room 13 through the HEPA filter 22 is heated and supplied to the storage room 4 and the ozone supply pipe 34. Therefore, bacteria in the air at the place where the endoscope storage 1 is installed do not adhere to the endoscope 100 being stored and propagate. Therefore, it is possible to avoid nosocomial infections mediated by endoscopes.

  Here, the internal conduits of the endoscope 100 such as the air / water supply channel 105 and the suction / forceps channel 106 are generally formed of a material having high chemical resistance such as stainless steel or fluorine resin. . Therefore, even when ozone is circulated through these internal pipelines, the internal pipelines are not deteriorated. On the other hand, the outer surface of the endoscope 100 is made of polyurethane or the like, and has low chemical resistance compared to stainless steel or fluororesin. For this reason, when the outer surface of the endoscope 100 is exposed to ozone for a long time, it may be deteriorated.

  In order to deal with such a problem, in this example, ozone is a first gas flow path A formed by the ozone supply pipe 34, the internal pipe line (the air / water supply channel 105 and the suction / forceps channel 106), and the ozone decomposition box 32. And it flows through the second gas flow path B and does not flow along the outer surface of the endoscope 100. In addition, ozone that has flowed through the internal conduit is decomposed in the ozone decomposition box 32. Further, when the fan 74 is driven, the inside of the ozonolysis box 32 is at a lower pressure (negative pressure) than the outside, so that ozone is prevented or suppressed from leaking outside from the ozonolysis box 32. Therefore, it is possible to prevent the outer surface of the endoscope 100 from being deteriorated by ozone.

(Modification)
FIG. 4 is a schematic configuration diagram showing the internal structure of the endoscope storage according to the modification. In the endoscope storage 1 </ b> A of this example, the ozone decomposition box 32 has a first duct as a connection portion to the endoscope 100 instead of the first connection tube 71, the second connection tube 72, and the third connection tube 73. 75 and a second duct 76 are provided. In addition, since the other part is the same as said endoscope storage, the same code | symbol is attached | subjected to a corresponding part and the description is abbreviate | omitted.

The first duct 75 extends upward from the top plate 63 of the housing 60 of the ozonolysis box 32. The first duct 75 has an inner diameter that allows the distal end portion of the insertion portion 102 of each endoscope 100 to be inserted from above. The second duct 76 is located behind the first duct 75 in the housing 6.
It extends upward from the top plate 63 of zero. The second duct 76 has an inner diameter dimension that allows the connector 103 of each endoscope 100 to be inserted from above and accommodated entirely. The ozonolysis box 32 includes three sets of first ducts 75 and second ducts 76.

  As shown in FIG. 4, when the distal end portion of the insertion portion 102 of the endoscope 100 is inserted into the first duct 75, the nozzle 109 serving as the end opening of the air / water supply channel 105 and the ozonolysis box 32 are connected. At the same time, the forceps port 110 of the suction / forceps channel 106 and the ozonolysis box 32 are connected. When the entire connector 103 of the endoscope 100 is inserted into the second duct 76, the air / water supply port 111 of the air / water supply channel 105 and the ozone decomposition box 32 are connected, and the suction / forceps channel 106 is connected. The suction port 112 and the ozonolysis box 32 are connected. As a result, a first gas flow path A is formed from the ozone supply pipe 34 to the ozone decomposition box 32 via the air / water supply cylinder 107, the air / water supply channel 105, the nozzle 109 and the air / water supply port 111. . A second gas flow path B is formed from the ozone supply pipe 34 to the ozone decomposition box 32 through the forceps plug port 108, the suction / forceps channel 106, the forceps port 110, and the suction port 112.

  Therefore, in this state, when the operation switch 7 is operated to drive the heater 23, the pump 24, the ozone generator 25, and the fan 74, the pump 24 enters the first gas flow path A into the ozone generator 25, the air supply. An air flow that passes through the water supply channel 105 and the ozonolysis box 32 in this order is generated, and an air stream that passes through the ozone generator 25, the suction / forceps channel 106 and the ozonolysis box 32 in this order in the second gas flow path B. generate. That is, the pump 24 flows the sterilizing ozone generated by the ozone generator 25 into the air / water supply channel 105 and the suction / forceps channel 106 together with the air (warm air) heated by the heater 23. Therefore, also in the endoscope storage 1A of the present example, bacteria are propagated in the internal conduit until the internal conduit (the air / water supply channel 105 and the suction / forceps channel 106) is dried. Can be prevented.

  Here, the fan 74 generates an air flow from the connecting portion (the first duct 75 and the second duct 76) with the endoscope 100 through the ozone decomposition catalyst 61 to the exhaust port 68 in the ozone decomposition box 32. . As a result, the inside of the ozonolysis box 32 is at a lower pressure (negative pressure) than the outside, so that leakage of ozone from the first duct 75 and the second duct 76 is prevented or suppressed. Therefore, also in this example, it is possible to prevent the outer surface of the endoscope 100 from being deteriorated by ozone.

DESCRIPTION OF SYMBOLS 1 ... Endoscope storage 4 ... Storage room 13 ... Machine room 23 ... Heater 24 ... Pump 25 ... Ozone generator 26 ... Blower fan 30 ... Holding plate 32 ... Ozone decomposition box 34 ... Ozone supply pipe 36 ... Groove 37 ... Swelling portion 61 ... Ozone decomposition catalyst 68 ... Exhaust port 74 ... Fan 100 ... Endoscope 101a ... Tapered portion 101 ... Operation part 102 ... Insertion part 105 ... Air / water supply channel (inner conduit)
106 ... Suction / forceps channel (inner conduit)
107 ... Air / water cylinder (1st communication port)
108 ... Forceps plug (first communication port)
109 ... Nozzle (second communication port)
110 ... Forceps port (second communication port)
111 ... Air supply / water supply port (second communication port)
112 ... Suction port (second communication port)
A ... 1st gas flow path B ... 2nd gas flow path

Claims (5)

In an endoscope storage for storing an endoscope including an operation unit, an insertion unit extending from the operation unit, and an internal conduit extending through the operation unit and the insertion unit,
An ozone generator;
An ozone supply pipe extending through the ozone generator and detachably connected to a first communication port of the endoscope communicating with the internal conduit;
An ozone decomposition box that contains an ozone decomposition catalyst that decomposes ozone, and is detachably connected to a second communication port of the endoscope that communicates with the internal conduit;
When the ozone supply pipe is connected to the first communication port and the ozone decomposition box is connected to the second communication port, the ozone supply pipe is formed by the ozone supply pipe, the internal conduit, and the ozone decomposition box. A gas flow path,
A pump for generating an airflow passing through the ozone generator, the internal pipe line and the ozonolysis box in this order in the gas flow path;
Endoscope storage characterized by having. In claim 1,
Have a heater,
The endoscope storage unit, wherein the pump introduces air heated by the heater into the gas flow path to generate the air flow. In claim 1 or 2,
The ozonolysis box includes an exhaust port, and a fan that is disposed between the ozone decomposition catalyst and the exhaust port and generates an air flow toward the exhaust port via the ozone decomposition catalyst. Endoscope storage. In claim 2,
A storage room for storing the endoscope;
A machine room containing the ozone generator, the pump, and the heater;
An endoscope storage, comprising: a blower fan for sending air heated by the heater from the machine room to the storage room. In any one of claims 1 to 4,
A holding plate capable of holding the endoscope as a state in which the insertion portion hangs downward from the operation portion;
The holding plate is provided with a groove portion that is cut out from the side and penetrates in the vertical direction,
The groove part is a bulging part having a groove width larger than the both sides sandwiching the intermediate part in the middle part in the notch direction,
An endoscope storage, wherein an outer peripheral edge portion of the bulging portion of the holding plate holds from the lower side a portion of the operation portion that is tapered toward the insertion portion.

Images