JP3947730B2 - Endoscope cleaning and disinfection device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an endoscope cleaning / disinfecting apparatus for cleaning / disinfecting an endoscope.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, endoscopes have been widely used for examinations and treatments in body cavities, and various pipes for performing air supply, water supply, suction, and the like are incorporated therein. Each time the endoscope is used, the outer surface and the inner conduit are cleaned and disinfected.
[0003]
Various types of endoscope cleaning / disinfecting devices used for cleaning / disinfecting endoscopes have been known in the past. Basically, the endoscope is cleaned with cleaning water. It cleans and disinfects the endoscope in the washing tank through a series of processes consisting of a process, a disinfection process that uses a disinfectant solution to disinfect the endoscope after washing, and a rinsing process and a drying process. is there.
[0004]
By the way, the diameter of the internal pipe line of the endoscope to be cleaned and disinfected is different for each pipe line, and therefore the pipe resistance is also different for each internal pipe line. In particular, the forceps riser channel (elevator wire channel) for manipulating the protruding direction of the forceps protruding from the distal end of the endoscope is an extremely narrow internal channel compared to the diameter of other internal channels. is there. Since the pipe resistance of such an internal pipe is very large compared to that of other internal pipes, the amount of fluid that can be sent into the pipe is very small. Therefore, when water is removed from the inside of the forceps raising conduit, the remaining water accumulated in the forceps raising conduit must be removed by supplying air for a long time.
[0005]
[Patent Document 1]
JP 2000-126125 A
[0006]
[Patent Document 2]
JP 2000-287924 A
[0007]
[Problems to be solved by the invention]
When water is removed from the forceps riser pipe, the conventional cleaning and disinfecting device uses the remaining water accumulated in the connection line leading to the forceps riser duct in addition to the remaining water accumulated in the forceps riser duct. In addition, water must be drained through the tip of the forceps raising conduit, which is a very thin conduit. For this reason, it takes a considerable amount of time for the inside of the forceps raising duct to be replaced with water (air is replaced with water from air in other seconds). On the other hand, replacement takes, for example, more than 1 minute in the forceps raising duct).
[0008]
  The present invention has been made paying attention to the above circumstances, and the object is as follows.The user's work can be guided correctly when the bottle filled with the disinfectant concentrate is attached to the bottle holder, and no leak of disinfectant occurs regardless of what kind of work is done.An object of the present invention is to provide an endoscope cleaning and disinfecting device.
[0009]
[Means for Solving the Problems]
    In order to solve the above problems,TomorrowA washing tub that can store an endoscope inside, and for cleaning and disinfecting the endoscope in the washing tubfluidSupplyRuA feeding means and an endoscope housed in the washing tub.fluidIn an endoscope cleaning and disinfecting apparatus having cleaning means for cleaning withReportSupply means insideConcentrateA bottle filled with a bottle, a bottle receiving part that is inserted from the inlet and attached to the set position, and an insertion of the bottle into the bottle receiving part arranged at an appropriate interval along the insertion direction of the bottle With at least two sensors to detect the conditionAt least one of the sensors is formed by a bottle insertion state detection sensor that detects a state in which the bottle is inserted between the inlet of the bottle receiver and the set position. A bottle lock mechanism that prevents the bottle from being pulled out from the inlet of the bottle receiving portion when the bottle insertion state detection sensor detects the insertion of the bottle.It is characterized by havingEndoscope cleaning and disinfection device.
[0010]
  Also,TwoOf the sensorsotherOne is that the bottle is in a set position where the bottle is mounted and set in the bottle receiving portion.The endoscope cleaning / disinfecting apparatus according to claim 1, wherein the endoscope cleaning / disinfecting apparatus is formed by a bottle set detection sensor for detection.
[0011]
  Also,The bottle lock mechanism includes a lock arm that operates when the bottle insertion state detection sensor detects the bottle and prevents the bottle from moving to the inlet side of the bottle receiving portion. The endoscope cleaning / disinfecting apparatus according to claim 1.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows a schematic configuration of an endoscope cleaning / disinfecting apparatus 100 according to the present embodiment. As shown in the figure, the endoscope cleaning / disinfecting apparatus 100 has a cleaning tank 1 that forms a cleaning room, and the endoscope 2 can be set in the cleaning tank 1 to be cleaned and disinfected. It has become. A lid 40 forming a ceiling surface of the washing room is attached to the washing tub 1 so as to be openable and closable, and the endoscope 2 can be set in the washing tub 1 by opening the lid 40. ing.
[0015]
A diaphragm 4 is installed at the bottom of the washing tank 1. The diaphragm 4 has, for example, a Langevin type ultrasonic transducer 3 attached to the bottom surface thereof, and can oscillate ultrasonic vibrations in the cleaning liquid stored in the cleaning tank 1.
[0016]
The washing tank 1 is provided with a washing water inlet 21. For example, a water supply line 35 connected to a faucet 37 of a water supply source such as a water supply system is connected to the washing water inlet 21, and the cleaning water is supplied into the washing tank 1 through the water supply line 35. Can be done. A water supply valve 36 and a standard sterilization filter (sterilization grade (0.2 μm) filter) 38 are interposed in the middle of the water supply pipe 35. The sterilization filter 38 is detachably mounted in a filter storage chamber in the main body of the cleaning / disinfecting apparatus 100, and is a water supply filter housing 38a and a replaceable filter that is detachably set in the housing 38a. And the cartridge 38b.
[0017]
A washing liquid spout 7 is provided on the side wall of the washing tank 1, and a circulating liquid suction port 8 is provided at the bottom of the washing tank 1. A first liquid supply line 9 a connected to the discharge side of the first liquid supply pump 10 is connected to the washing liquid discharge port 7, and a suction side of the first liquid supply pump 10 is connected to the circulating liquid suction port 8. Is connected to the second liquid supply pipe 9b. The first and second liquid supply pipes 9a and 9b collect the liquid in the washing tank 1 and return it to the washing tank 1 again. And a first circulation path 9 is formed.
[0018]
Further, channel connection ports 13a, 13b, and 13c to which first to third connection tubes (connection pipe lines) 30a, 30b, and 30c are connected are provided on the side wall of the washing tub 1. In this case, the connection tubes 30a, 30b, and 30c are detachably connected to connection ports that are provided in the operation unit of the endoscope 2 and communicate with the internal conduit (channel) of the endoscope 2. Yes. Specifically, the first channel connection port 13a is connected to the first connection port portion 2a of the endoscope 2 via the first connection tube 30c. The first connection port portion 2a communicates with a forceps raising conduit that is a very narrow conduit having an inner diameter smaller than that of a general internal conduit of the endoscope 2. Even in the case of an endoscope having a sub-water supply pipe having a small inner diameter, the first channel connection port 13a is connected to the sub-water pipe. On the other hand, the second and third channel connection ports 13b and 13c are connected to the general internal conduit (the inner diameter of the forceps raising conduit) of the endoscope 2 via the second and third connection tubes 30b and 30c. The second and third connection ports 2b and 2c communicating with the pipe having a larger inner diameter).
[0019]
In the present embodiment, this route is provided in the middle of the route from the connection portion between the first connection tube 30a and the main body of the cleaning / disinfecting device 100 to the connection between the first connection tube 30a and the endoscope 2. A minute gap or hole is provided for allowing the fluid flowing through the outside to escape to the outside. Specifically, as shown in FIG. 4, in the vicinity of the first joint portion 90 of the first connection tube 30a connected to the first connection port portion 2a of the endoscope 2 (indicated by a broken line in the drawing). A portion shown), a central portion of the tube main body 91 of the first connection tube 30a (B portion region shown by a broken line in the drawing), and the first channel connection port 13a of the endoscope cleaning / disinfecting apparatus 100. A minute gap or hole is provided in at least one of the vicinity of the second joint portion 92 of the first connection tube 30a (the C portion region indicated by a broken line in the drawing).
[0020]
FIG. 5 shows an example in which a gap or a hole is provided in the area A. As shown in the figure, the first joint portion 90 includes a base portion 93 and a protective body 94 that is mounted on the outer periphery of the base portion 93. The base portion 93 is formed with a minute first hole 61 communicating with the inside of the tube 30a, and the protector 94 is provided with a second hole (for example, the first hole 61 communicating with the outside). A hole 62 having a diameter larger than that of the first hole 61 is formed. The inner diameter of the first hole 61 is set to 0.5 mm, for example.
[0021]
FIG. 6 shows an example in which a gap or a hole is provided in the B portion region. As shown in the figure, a joint 64 is attached in the middle of the tube main body 91, and a minute hole 63 that allows the inside of the tube main body 91 to communicate with the outside is formed in the joint 64.
[0022]
FIG. 7 shows an example in which a gap or a hole is provided in the area C. As shown in the drawing, the second joint portion 92 has a minute hole 66 communicating with the tube 30a.
[0023]
Of course, a minute hole may be provided not only in the first connection tube 30a but also in the first channel connection port 13a and the first connection port portion 2a connected thereto.
[0024]
As shown in FIG. 1, a third liquid supply line 19a is branched from the middle of the second liquid supply line 9b, and the third liquid supply line 19a is a second liquid supply pump. 14 is connected to the suction side. In addition, a fourth liquid supply line 19b is connected to the second liquid supply pump 14. The fourth liquid supply line 19b is connected to the fluid supply line 15 connected to the channel connection ports 13a, 13b, and 13c via the check valve 12. That is, the third and fourth liquid supply pipes 19a and 19b collect the liquid in the washing tank 1 and secondly feed it back to the washing tank 1 through the internal pipe of the endoscope 2. A path 19 is formed.
[0025]
An air supply line 18 is connected to the fluid supply line 15 through a check valve 16. A compressor 17 is connected to the air supply pipe 18 so that compressed air from the compressor 17 can be sent to the fluid supply pipe 15 via the air supply pipe 18.
[0026]
Further, the fluid supply line 15 is branched into two on the downstream side of the connection part with the air supply line 18. Of these, the first branch pipe 15a is connected to the first channel connection port 13a. The other second branch pipe 15b is connected to the second and third channel connection ports 13b and 13c. Note that an on-off valve 31 is interposed in the middle of the second branch pipe line 15b.
[0027]
Further, a disinfecting liquid injection port 22 is provided on the side wall of the cleaning tank 1, and a drainage port 23 is provided at the bottom of the cleaning tank 1. The disinfecting liquid inlet 22 is connected to a disinfecting liquid tank 32 and is connected to a disinfecting liquid supply pipe 33 b that supplies the disinfecting liquid from the disinfecting liquid tank 32 into the cleaning tank 1 by the suction action of the pump 34. . Further, a disinfectant return line 33 a and a drain line 27 are connected to a line extending from the drain port 23 via a line switching valve 24. The disinfectant return line 33 a is connected to the disinfectant tank 32 and collects the disinfectant in the washing tank 1 in the disinfectant tank 32. A diluent supply line 39 extends from the disinfectant tank 32, and the diluent supply line 39 is connected to the water supply line 35 through a line switching valve 41. That is, in this embodiment, the pipe switching valve 41 and the diluent supply pipe 39 constitute a diluent supply means for supplying the wash water flowing through the water supply pipe 35 to the disinfectant tank 32 as a diluent.
[0028]
A drainage pump 28 is interposed in the drainage conduit 27. The operations of the ultrasonic transducer 3, the pumps 10, 14, 28, 34, the compressor 17, the pipe switching valves 24, 41, and the water supply valve 36 are all controlled by the control unit 42.
[0029]
Next, the disinfecting liquid tank 32 of this embodiment and the bottle body 50 that is detachably attached to the disinfecting liquid tank 32 will be described in detail.
[0030]
As shown in FIG. 2, the disinfectant tank 32 is disposed in the apparatus main body 100 </ b> A of the cleaning / disinfecting apparatus 100. On the upper surface of the disinfecting liquid tank 32, a cap-shaped bottle mounting part 43 to which the bottle body 50 containing the concentrated liquid of the disinfecting liquid is detachably mounted is provided. The bottle attaching portion 43 is bent at the upper side so that the opening is directed to the side.
[0031]
As shown in detail in FIG. 3, the bottle body 50 attached to the bottle attachment portion 43 includes a bottle-shaped main body portion 51 in which liquid is stored and a cap 52 attached to the mouth portion 51 a of the main body portion 51. The cap 52 includes a cylindrical cap body 52a, a mounting portion 52b formed at the base end of the cap body 52a and attached to the body portion 51, and formed at the distal end of the cap body 52a and protruding outward in the radial direction of the cap 52. And a detachable portion 60 that is detachably attached to the bottle attaching portion 43 on the disinfecting liquid tank 32 side. The cap 52 is positioned at the boundary between the attachment portion 52b and the cap body 52a, and is a thin film that closes the mouth portion 51a when the cap 52 is attached to the mouth portion 51a of the body portion 51 via the attachment portion 52b. A portion 54 is provided.
[0032]
On the other hand, the bottle attaching portion 43 to which the bottle body 50 is detachably attached forms an inlet for injecting the concentrated liquid of the disinfecting liquid into the disinfecting liquid tank 32, and the closed mouth of the bottle body 50. 51a is received in an airtight and liquid-tight state (in this embodiment, the mouth 51a is received in an airtight and liquid-tight manner via the cap 52) and a pair of bottle receiving portions 43a and an injection for introducing the concentrated liquid into the disinfectant tank 32 The bottle 51 is opened by opening the mouth portion 51a of the bottle body 50 in a state where the mouth portion 51a of the bottle body 50 is airtightly and liquid-tightly received by the hole 43c and each bottle receiving portion 43a (the state of FIG. 3C). The body 50 has a pair of protrusions 43b that communicate with the disinfectant tank 32 through the injection hole 43c.
[0033]
The bottle receiving portion 43a has a double tube structure including an outer tube a and an inner tube b arranged coaxially with each other. In this case, the annular gap between the outer tube a and the inner tube b is set to be approximately the same as the dimension in which the cap 52 of the bottle body 50 can be fitted, for example, the thickness of the cap body 52a. The protrusion 43b is provided on the inner side of the inner tube b. The tip surface of the protrusion 43b is tapered, and the inner hole communicates with the injection hole 43c.
[0034]
As shown in FIG. 2, a plurality of level sensors 44, 45, 46 are provided in the disinfecting liquid tank 32 to detect in stages the amount of disinfecting liquid stored in the disinfecting liquid tank 32. . Among these, the first level sensor 44 detects a specified amount of the concentrate to be injected into the disinfectant tank 32 via the bottle body 50. In addition, the second level sensor 45 is configured to supply a dilute solution to be supplied in order to dilute a prescribed amount of concentrate injected into the disinfectant solution tank 32 to a predetermined concentration (in practice, the tank 32 already The total amount of the disinfectant having a prescribed concentration composed of the concentrated solution and the diluted solution injected into the inside is detected. Further, the third level sensor 46 is a minimum amount necessary for lifting the disinfectant liquid to the cleaning tank 1 located on the upper side when operating the apparatus (in order to sufficiently disinfect the endoscope 2 in the cleaning tank 1). Detect the minimum amount of disinfectant required). The detection information from each level sensor 44, 45, 46 is transmitted to the control unit 42.
[0035]
Next, a case where the endoscope 2 is cleaned and disinfected using the endoscope cleaning / disinfecting apparatus 100 having the above-described configuration will be described.
[0036]
First, the used endoscope 2 is set in the washing tub 1, and the connection ports 2a, 2b, 2c of the endoscope 2 and the channel connection ports 13a, 13b, 13c are connected by connection tubes 30a, 30b, 30c. Connecting. Thereafter, cleaning, disinfection, rinsing, and air feeding processes are automatically performed by operating various operation switches (not shown).
[0037]
In the washing step, first, the water supply valve 36 is opened, and the washing water from the water supply source 37 is supplied into the washing tank 1 from the washing water inlet 21 through the water supply line 35 and the filter 38. In addition, before this washing | cleaning process, the detergent of the liquid quantity preset by the user is inject | poured in the washing tank 1. FIG.
[0038]
When a certain amount of water is supplied into the washing tub 1, the water supply valve 36 is closed, and the first and second liquid feed pumps 10, 14 are driven. At this time, the pipe switching valve 24 is closed.
[0039]
As a result, a part of the cleaning liquid in the cleaning tank 1 circulates in the first circulation path 9 and is sprayed from the cleaning liquid outlet 7 to the outer surface of the endoscope 2 at a high pressure, and the second circulation path 19. It circulates through and is sent to the internal conduit of the endoscope 2. That is, the washing liquid in the washing tank 1 is sucked into the first liquid feeding line 9b by the suction action of the first liquid feeding pump 10 from the circulating liquid suction port 8, and via the second liquid feeding line 9b. It is injected from the washing liquid outlet 7. A part of the washing liquid sucked into the first liquid feeding line 9b is sucked into the third liquid feeding line 19a by the suction action of the second liquid feeding pump 14, and the fourth liquid feeding pipe. It is sent from the channel connection ports 13a, 13b, and 13c to the internal conduit of the endoscope 2 through the passage 19b and the fluid supply conduit 15. In addition, the washing liquid sent to the internal pipeline of the endoscope 2 is returned to the washing tank 1 through the opening of the distal end of the endoscope 2 and circulates again in the first circulation path 9 or the second circulation path 19. become.
[0040]
Due to the flow of the cleaning liquid, large dirt, soft dirt, light dirt, and the like attached to the endoscope 2 are washed away. In particular, such dirt is removed from the outer surface of the endoscope 2 due to the impact force of the washing liquid ejected from the washing liquid ejection port 7 and the vortex flow in the washing tank 1 formed thereby.
[0041]
When cleaning by the circulating action of the cleaning liquid is performed for a predetermined time, the diaphragm 4 is subsequently operated to perform ultrasonic cleaning. In this ultrasonic cleaning, hard dirt attached to the endoscope 2 or dirt attached to a complicated shape portion of the endoscope 2 is strongly removed by ultrasonic vibration emitted from the diaphragm 4.
[0042]
When the ultrasonic cleaning is completed, the above-described cleaning by the circulation action of the cleaning liquid is performed again. At this stage, the dirt that has been wiped off by the ultrasonic cleaning and has been peeled off from the endoscope 2 is removed.
[0043]
When the above washing process is completed, a rinsing process is subsequently performed. In this rinsing step, first, the driving of the liquid feeding pumps 10 and 14 is stopped, and the drainage pump 28 is driven to switch the conduit switching valve 24 to the draining conduit 27 side. As a result, the cleaning liquid in the cleaning tank 1 is discharged from the drain port 23 to the outside through the drain line 27. When the washing liquid in the washing tank 1 is completely discharged, the water supply valve 36 is then opened and new water is supplied into the washing tank 1. Then, the first and second liquid feeding pumps 10 and 14 are driven again, and the internal conduit and the outer surface of the endoscope 2 are rinsed by the circulation action described above.
[0044]
When rinsing with the rinsing water is completed, draining is performed in a state where the rinsing water is completely discharged from the washing tank 1. In this draining, the driving of the liquid feed pumps 10 and 14 is stopped and the compressor 17 is driven, and the air from the compressor 17 is sent to the fluid supply line 15 through the air supply line 18. The air sent to the fluid supply pipe 15 is sent to the internal pipe of the endoscope 2 through the channel connection ports 13a, 13b, 13c, and drains the internal pipe of the endoscope 2. At this time, the residual water remaining in the first branch pipe 15a and the first connection tube 30a of the fluid supply pipe 15 connected to the forceps rise-up pipe which is an extremely thin internal pipe of the endoscope 2 is It flows out into the washing tank 1 through the minute holes. That is, for example, in the configuration shown in FIG. 5, the residual water remaining in the first branch pipe 15 a and the first connection tube 30 a is a very small first with a small pipe resistance just before the forceps raising pipe. Flows out into the washing tank 1 through the first hole 61 and the second hole 62. Even after water from the first branch pipe 15a of the fluid supply pipe 15 is removed, there is some air leakage from the hole 61, but the hole 61 is very small and the air supply capacity of the compressor 17 is high. The air pressure acting on the forceps raising duct is substantially the same as that when the hole 61 is not formed. Therefore, drainage in the forceps raising duct can be performed without any problem. Therefore, the air feeding time of the forceps raising conduit can be shortened. In addition, when draining the forceps raising conduit as described above, it is desirable to close the on-off valve 31 and supply air to the forceps raising conduit only at a high pressure.
[0045]
When the above rinsing process is completed, a disinfection process is subsequently performed. In this disinfection process, first, the pipe switching valve 24 is closed and the pump 34 is driven. As a result, the disinfecting liquid in the disinfecting liquid tank 32 is injected into the washing tank 1 from the disinfecting liquid injection port 22 through the disinfecting liquid supply conduit 33b. When a predetermined amount of the disinfecting liquid is injected into the washing tank 1 and the endoscope 2 is completely immersed in the disinfecting liquid, the driving of the pump 34 is stopped, and then the liquid feeding pump 14 is driven. As a result, the disinfecting liquid in the washing tank 1 is sent to the internal pipeline of the endoscope 2 and the internal pipeline of the endoscope 2 is also sterilized.
[0046]
After such sterilization is performed for a predetermined time, the pipe switching valve 24 is switched to the sterilizing liquid return pipe 33a side, and the sterilizing liquid in the washing tank 1 passes through the sterilizing liquid return pipe 33a into the sterilizing liquid tank 32. To be recovered. Thereafter, the disinfecting liquid in the endoscope 2 and the cleaning / disinfecting apparatus 100 is drained again by the same method as described above. Thereafter, the disinfectant is rinsed by the rinsing process described above.
[0047]
After the sterilizing solution is thoroughly rinsed by the rinsing process, the air feeding process is performed. This air supply process is performed in the same procedure as the draining performed in the latter half of the above-described rinsing process. Then, after a predetermined time has elapsed, the drainage pump 28 is stopped.
[0048]
As described above, in the endoscope cleaning / disinfecting apparatus 100 according to the present embodiment, the connection between the first connecting tube 30a and the endoscope 2 is performed from the connecting portion between the first connecting tube 30a and the cleaning / disinfecting apparatus 100. In the middle of the path up to this point, a minute gap or hole for allowing the fluid flowing through this path to escape to the outside is provided. Therefore, when the endoscope 2 is supplied with air after washing, the residual liquid in the apparatus pipe line can be removed from the minute gap or hole with low resistance. In addition, since the gap is very small, there is almost no decrease in the air pressure, and water removal of the internal conduit of the endoscope 2 can be performed effectively and in a short time. In general, since the air supply process is performed three times during the cleaning and disinfecting process, if the time required for one air supplying process can be shortened in this way, the entire process time of the cleaning and disinfecting can be greatly shortened. Further, since efficient water removal can be performed with a simple configuration in which a gap or a hole is provided in the path from the apparatus 100 to the endoscope 2, it can be said that it is extremely excellent in practical use.
[0049]
By the way, in the endoscope cleaning and disinfecting apparatus 100 described above, when the bottle body 50 containing the concentrated liquid is attached to the disinfecting liquid tank 32, the process automatically proceeds to the disinfecting liquid dilution process. Has pointed out one conventional problem. Hereinafter, this will be briefly described with reference to FIGS.
[0050]
When the bottle body 50 is attached to the disinfectant tank 32, first, the bottle body 50 whose mouth part 51a is closed by the thin film part 54 (with the concentrated disinfectant liquid inside) is placed below the mouth part 51a. In the state of being placed on the side, it is inserted into the bottle insertion hole 63 (see FIG. 2), and the cap 52 of the bottle body 50 is inserted into the bottle mounting portion 43 on the disinfectant tank 32 side as shown in FIG. It is made to oppose the bottle receiving part 43a. Subsequently, when the bottle body 50 is further pushed into the bottle insertion hole 63, first, the cap body 52a of the cap 52 of the bottle body 50 is fitted into the annular space between the outer tube a and the inner tube b. The bottle receiving portion 43a receives the closed mouth portion 51a of the bottle body 50. At this time, the seal portion 52c is pressed by the inner surface of the outer tube a to be elastically deformed, and the mouth portion 51a is kept airtight and liquid-tight with respect to the outside (see FIG. 3B). When the bottle body 50 is further pushed into the bottle insertion hole 63 from this state, as shown in FIG. 3C, the thin film is formed by the protrusion 43b while the mouth 51a is received in an airtight and liquid tight manner. The part 54 is torn and the mouth part 51a is opened. Thereby, the inside of the bottle body 50 communicates with the disinfecting liquid tank 32 through the injection hole 43 c, and the liquid in the bottle body 50 is injected without remaining in the disinfecting liquid tank 32.
[0051]
When the bottle body 50 is inserted in this manner, the process proceeds to the concentrate dilution step. Conventionally, there has been only one sensor for detecting whether the bottle body 50 has been inserted into the bottle insertion hole 63. It was. Therefore, the following phenomenon was considered.
[0052]
In other words, if the insertion of the bottle body 50 is detected in the state of FIG. 3B with the mouth portion 51a remaining unopened without the thin film portion 54 being broken, There is a problem that the dilution process does not start indefinitely.
[0053]
Further, even when the insertion of the bottle body 50 is detected in the state of FIG. 3C in which the thin film portion 54 is broken and the mouth portion 51a is completely opened, the bottle body is in a halfway position by the user. When the operation of pulling out 50 in the reverse direction is performed, liquid leakage may occur.
[0054]
Therefore, in the endoscope cleaning / disinfecting apparatus 100 according to the above-described embodiment, as shown in FIG. 2, separate sensors that can detect the two states are provided, so that the user's work can be correctly guided. (No leakage of disinfectant occurs no matter what work is done).
[0055]
That is, as shown in FIG. 2, when the bottle body 50 is inserted into the bottle insertion hole 63 of the apparatus main body 100A, the sensor 67 detects the insertion of the bottle body 50 in the state of FIG. When the sensor 67 detects the insertion of the bottle body 50, the lock arm 65 operates and the bottle body 50 is locked by the lock arm 65 so that the user cannot pull out the bottle body 50. Thereafter, when the bottle body 50 is further slid into the bottle insertion hole 63 and inserted, the sensor 62 detects further insertion of the bottle body 50 in the state of FIG. The process proceeds to the next dilution step.
[0056]
FIG. 8 shows means for installing the endoscope cleaning / disinfecting apparatus 100 in a horizontal state in a simple manner. As illustrated, at least a wall surface of the washing tub 1 is provided with a mark 104 parallel to the bottom surface of the washing tub 1. As clearly shown in (b) of FIG. 8, the marks 104 are installed at least on the front, rear, left and right of the wall surface of the washing tub 1. The mark 4 may be a label that does not peel off due to washing or disinfection, and may be molded on the wall surface of the washing tub 1.
[0057]
In the endoscope cleaning and disinfecting apparatus 100, the water level is managed by the water level sensor 105 installed in the cleaning tank 1, and the detergent and the chemical solution are stored. At this time, if the cleaning / disinfecting apparatus 100 is tilted, the liquids cannot be stored at an appropriate water level. If the water level is low, the cleaning / disinfecting is poor, and if the water level is high, the cleaning / disinfecting apparatus 100 starts. May lead to flooding. Therefore, it is necessary to install the cleaning / disinfecting apparatus 100 as horizontally as possible. As a method of installing horizontally, there is a method of using a level, but it is necessary to always carry it at the time of installation. In addition, when a level is incorporated in the cleaning / disinfecting apparatus 100, the design of the cleaning / disinfecting apparatus 100 is restricted or the cost is increased.
[0058]
On the other hand, according to the means shown in FIG. 8, the mark 104 can be easily and accurately incorporated into the cleaning / disinfecting apparatus 100, and when the apparatus is installed, water is stored in the cleaning tank 1. If the surface of the water is applied to the mark 104 on the wall surface of the washing tub 1, the horizontal state of the washing / disinfecting apparatus 100 can be easily confirmed.
[0059]
9 to 12 show details of a lid (hereinafter referred to as a top cover) 40 in the endoscope cleaning and disinfecting apparatus 100 of the above-described embodiment. In general, the top cover 40 prevents liquid and gas from being released from the cleaning tank 1, but is opened when a cleaning / disinfecting product such as the endoscope 2 is taken in and out. The top cover 40 is connected to the apparatus main body 100A on the back surface of the apparatus 100 by a hinge unit using a spring. Therefore, the top cover 40 is automatically opened and held in the open state when the lock that holds the closed state is released.
[0060]
FIG. 9 shows a hinge unit using a conventional torsion spring. The top cover 40 is attached to the cover attaching plate 203, and the hinge body 204 is fixed to the cleaning / disinfecting apparatus X. As the top cover 40 is closed, the torsion spring 201 is tightened around the hinge shaft 202, and energy for generating torque around the hinge shaft 202 when the top cover 40 is opened is stored. However, in this case, torque around the hinge shaft 202 due to the weight of the top cover 40 draws a sine curve with respect to the change in the opening angle of the cover 40, whereas torque around the hinge shaft 202 due to the spring pressure of the torsion spring 201. Increases linearly with changes in the opening angle of the cover 40. Therefore, when the cover 40 is closed, extra energy is stored to open the cover 40.
[0061]
FIG. 10 shows the hinge unit of the endoscope cleaning / disinfecting apparatus 100 in the above-described embodiment. Similarly to FIG. 9, the top cover 40 is attached to the cover attachment plate 207, and the hinge main body 210 is fixed to the apparatus main body 100 </ b> A of the cleaning / disinfecting apparatus 100. As the top cover 40 is closed, the linear spring 205 is pulled, and energy for generating torque around the hinge shaft 206 when the top cover 40 is opened is stored.
[0062]
In such a configuration, by setting the attachment position of the linear spring 205 to a proper position on the rear side of the hinge shaft 206, the torque around the hinge shaft 206 due to the weight of the top cover 40 against the change in the opening angle of the cover 40. Since the sine curve is drawn and the torque curve around the hinge shaft 206 due to the spring pressure of the linear spring 205 also draws the sine curve, when the cover 40 is tightened, an unnecessary force is not applied to the top cover 40 or the like.
[0063]
FIG. 11 is a graph comparing the torque curve in the conventional torsion spring 201, the torque curve in the linear spring 205 of this configuration, and the torque curve due to the weight of the top cover 40. As shown in the figure, in the case of the linear spring 205, since it is possible to take a line that is slightly wasteful than the torque of the cover 40, it is very efficient and no wasteful force is applied to the cover 40 or the like. 40 deformation and breakage can be prevented.
[0064]
In addition, the conventional hinge unit is designed to stop at an angle (for example, 70 °) at which the user can easily work with a fixed stopper. However, if the user accidentally pushes the cover 40 in the direction of further opening, The cover 40 may be damaged. Therefore, in this configuration, the stopper 208 is semi-fixed at a position of 70 ° by the stopper spring 209.
[0065]
12A shows a state where the cover 40 is closed, and FIG. 12B shows a state where the cover 40 is stopped at a position of 70 °. As shown in the drawing, since the force of the stopper spring 209 is stronger than the force of the linear spring 205 that attempts to open the cover 40, the cover 40 stops at a position of 70 °. However, even if the user accidentally pushes open the cover 40 by 70 ° or more, the stopper 208 moves until the opening angle of the cover 40 reaches 90 ° as shown in FIG. And let the power escape. Therefore, breakage of the cover 40 can be prevented.
[0066]
According to the embodiment described above, the following configuration is obtained.
[0067]
1. Endoscope cleaning / disinfecting apparatus for cleaning / disinfecting the internal pipe by passing at least a liquid for cleaning / disinfecting through the internal pipe of the endoscope and a gas for removing water from the pipe. And a cleaning tube that connects the endoscope's internal conduit, and there is a small amount of water in either the endoscope cleaning / disinfecting device and the connecting portion between the cleaning tube and the connecting portion of the cleaning tube and the endoscope. An endoscope cleaning and disinfecting apparatus having a gap or a hole.
[0068]
2. 2. The endoscope cleaning / disinfecting apparatus according to claim 1, wherein the hole is formed with a hole of about φ0.5 in the vicinity of a connection portion of the cleaning tube with the endoscope.
[0069]
【The invention's effect】
  As explained above,ClearlyAccording toEndoscope washing and disinfection that can guide the user's work correctly when attaching the bottle filled with the disinfectant concentrate to the bottle holder, and does not cause any disinfectant leakage. Providing equipmentbe able to.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an endoscope cleaning / disinfecting apparatus according to an embodiment of the present invention.
FIG. 2 is a schematic configuration diagram of a disinfecting liquid tank which is a main part of the endoscope cleaning / disinfecting apparatus of FIG.
FIG. 3 is a cross-sectional view of an attachment portion between a bottle and a disinfectant tank.
FIG. 4 is a side view of a connection tube that connects an endoscope and a cleaning / disinfecting device main body.
5 is a cross-sectional view of a portion A in FIG.
6 is a cross-sectional view of a portion B in FIG.
7 is a cross-sectional view of a portion C in FIG.
8 shows a means for providing a mark for horizontal installation on the endoscope cleaning and disinfecting apparatus of FIG. 1, wherein (a) is a schematic perspective view of the endoscope cleaning and disinfecting apparatus, and (b) is a cleaning tank. FIG.
9A is a side view of a hinge unit in a top cover of a conventional endoscope cleaning / disinfecting apparatus, and FIG. 9B is a front view of the hinge unit of FIG. 9A.
10A is a side view of a hinge unit in the top cover of the endoscope cleaning and disinfecting apparatus of FIG. 1, and FIG. 10B is a front view of the hinge unit of FIG.
11 is a graph comparing the torque curve of a conventional torsion spring, the torque curve of the linear spring of FIG. 10, and the torque curve due to the weight of the top cover.
12 is a view showing the operation state of the hinge unit of FIG. 10 in stages.
[Explanation of symbols]
1 ... Washing tank
2. Endoscope
30a, 30b, 30c ... Connection tube (connection line)
61, 62, 63, 66 ... hole
100: Endoscope cleaning / disinfecting device
100A ... Main unit

Claims (3)

A washing tub that can house an endoscope inside;
A supply means that to supply fluid for washing and disinfecting the endoscope into the cleaning tank,
In the endoscope cleaning and disinfecting apparatus, comprising: a cleaning means for cleaning the endoscope housed in the cleaning tank with the fluid ;
Before bellflower supply means includes a bottle interior to the concentrate is filled,
A bottle receiving part in which this bottle is inserted from the entrance and mounted in the set position;
Be placed in appropriate intervals along the insertion direction of the bottle possess at least two sensors for detecting the insertion state of the bottle relative to the bottle receiving portion,
At least one of the sensors is formed by a bottle insertion state detection sensor that detects a state in which the bottle is inserted between the inlet of the bottle receiving portion and the set position.
The bottle receiving portion has a bottle lock mechanism that prevents the bottle from being pulled out from the inlet of the bottle receiving portion when the insertion of the bottle is detected by the bottle insertion state detection sensor. Endoscope cleaning and disinfection device. Another one of the two said sensors claims, characterized in that it is formed by a bottle set detecting sensor for detecting that the bottle is in a mounted in the set the set position to the bottle receiving portion The endoscope cleaning / disinfecting apparatus according to Item 1. The bottle lock mechanism includes a lock arm that operates when the bottle insertion state detection sensor detects the bottle and prevents the bottle from moving to the inlet side of the bottle receiving portion. the endoscope washing and disinfecting apparatus according to 請 Motomeko 1 you.

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