JP6757966B2 - Endoscope cleaning device - Google Patents

Description

The present invention relates to an endoscope cleaning device for cleaning and disinfecting a medical endoscope.

Medical endoscopes are used by inserting them into the body for the purpose of observing the inside of the human body. Therefore, it is necessary to perform cleaning and disinfection after its use, and an endoscope cleaning device is used as a device for that purpose.
Patent Document 1 discloses a technique relating to such an endoscope cleaning device, which is a type that injects a cleaning liquid or the like.

Special Publication No. 58-23152

The endoscope cleaning device of Patent Document 1 performs cleaning and disinfection by injecting a cleaning liquid or the like and spraying it onto the endoscope. However, at present, disinfection is basically to immerse the endoscope in a disinfectant solution, and by providing a cleaning disinfection tank, the cleaning solution and disinfectant solution are stored in the cleaning disinfection tank to clean and disinfect the endoscope. Is common.
On the other hand, in cleaning, by injecting the cleaning liquid as in Patent Document 1, the kinetic energy of the cleaning liquid can be utilized and the cleaning efficiency can be improved.

In view of the above points, the present invention provides an endoscope cleaning device provided with a cleaning and disinfecting tank (immersed) in which the cleaning efficiency of the endoscope is improved by applying kinetic energy to the cleaning liquid. The purpose is to provide.

(Structure 1)
A cleaning and disinfecting tank that is a tank for cleaning and disinfecting an endoscope, a first flow nozzle that is arranged in the cleaning and disinfecting tank and gives a first circulation to the liquid in the cleaning and disinfecting tank by a jet, and the cleaning. An endoscopic cleaning apparatus including a second flow nozzle which is arranged in a disinfection tank and gives a second flow in a rotation direction different from that of the first flow.

(Structure 2)
The endoscope according to configuration 1, wherein in the cleaning step of the endoscope, the jet flow from the first flow nozzle and the jet flow from the second flow nozzle are alternately ejected. Mirror cleaning device.

(Structure 3)
The endoscope cleaning apparatus according to configuration 2, wherein in the alternating ejection of the first flow nozzle and the second flow nozzle, the ejection time of each nozzle is 2 to 5 seconds.

(Structure 4)
It is characterized in that, in the disinfection step and the rinsing step of the endoscope, or both of them, the jet from the first flow nozzle and the jet from the second flow nozzle are simultaneously ejected. The endoscope cleaning device according to any one of configurations 1 to 3.

(Structure 5)
In the rinsing step of the endoscope, after simultaneous ejection from the first flow nozzle and the second flow nozzle is performed for a predetermined period, the jet from the first flow nozzle and the jet from the second flow nozzle are combined. The endoscopic cleaning apparatus according to configuration 4, wherein the endoscopes are configured to be ejected alternately.

(Structure 6)
The endoscope cleaning apparatus according to any one of configurations 1 to 5, wherein an overflow port is formed near the center of the first circulation or the second circulation.

(Structure 7)
The first flow nozzle and the injection port of the second flow nozzle are formed on the inner side surface of the cleaning and disinfecting tank at a position lower than the liquid level of the cleaning liquid in the cleaning step of the endoscope. The endoscope cleaning device according to any one of configurations 1 to 6.

(Structure 8)
The cleaning and disinfecting tank includes a deep bottom portion on which an operation portion and a connection portion of the endoscope are mainly placed, and a shallow bottom portion on which an insertion portion of the endoscope is mainly placed. The description in any one of configurations 1 to 7, wherein the injection ports of the nozzle and the second flow nozzle are formed on the inner side surface of the cleaning and disinfecting tank at a position higher than the shallow bottom portion. Endoscopic cleaning device.

(Structure 9)
The first flow nozzle has two jet nozzles arranged at positions substantially diagonal to the cleaning and disinfecting tank, and the second flow nozzle is located approximately diagonally to the other cleaning and disinfecting tank. The endoscopic cleaning apparatus according to any one of configurations 1 to 8, wherein the jet cleaning apparatus has two jet nozzles arranged in the same.

(Structure 10)
The endoscope cleaning device according to any one of configurations 1 to 9, wherein the axis of the first flow nozzle and the axis of the second flow nozzle are not made the same straight line.

According to the endoscopic cleaning device of the present invention, since the cleaning liquid is provided with a first flow nozzle and a second flow nozzle that give circulation to the liquid in the cleaning and disinfecting tank in different directions, the cleaning liquid is provided with kinetic energy due to circulation in different directions. It is possible to apply an endoscope cleaning device that can provide and enhance the cleaning efficiency of the endoscope.

A perspective view showing the appearance of the endoscope cleaning device according to the embodiment of the present invention. It is a figure which shows the cleaning and disinfection tank part of the endoscope cleaning apparatus which concerns on embodiment, (a) is a top view, (b) is a sectional view along the line AA of FIG. A perspective view showing a cleaning and disinfecting tank portion of the endoscope cleaning device according to the embodiment. Fluid system diagram according to the present invention of the endoscope cleaning device according to the embodiment A flowchart showing an outline of the cleaning / disinfecting processing operation in the endoscope cleaning device according to the embodiment. It is a flowchart which shows the outline of the processing operation of the endoscope cleaning apparatus which concerns on embodiment, (a) is the flowchart which shows the cleaning operation, (b) is the flowchart which shows the rinsing operation after cleaning. It is a flowchart which shows the outline of the processing operation of the endoscope cleaning apparatus which concerns on embodiment, (a) is a flowchart which shows the disinfection operation, (b) is the flowchart which shows the rinse operation after disinfection respectively.

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings. The following embodiment is an embodiment of the present invention, and does not limit the present invention to the scope thereof.

FIG. 1 is a perspective view showing the appearance of the endoscope cleaning device according to the embodiment of the present invention. As shown in the figure, the endoscope cleaning device 1 is provided with a cleaning and disinfecting tank 11 having an island 111 in the center at the upper part of a rectangular body, and the cleaning and disinfecting tank 11 is provided with an endoscope ( This is a device for cleaning and disinfecting the endoscope after setting (not shown) and closing the cleaning tank cover 13 (when opening the cleaning tank cover 13, the opening / closing pedal 14 can be opened).
When setting the endoscope in the cleaning and disinfecting tank 11, the pipes (cleaning liquid, disinfecting liquid, rinsing water, and air) of the cleaning and disinfecting tank 11 are connected to the suction port, air supply / water supply port, and forceps port of the endoscope. The tube supplied into the endoscope) is connected, and the endoscope is placed so as to be wrapped around the island 111 in the central portion.
As a result, the outside of the endoscope is cleaned and disinfected with the cleaning liquid and the disinfecting liquid accumulated in the cleaning and disinfecting tank 11, and the inside is also cleaned and disinfected at the same time.

FIG. 2 is a view showing mainly the vicinity of the cleaning and disinfecting tank 11 of the endoscope cleaning device 1, FIG. 2A: top view, FIG. 2B: line AA of FIG. 2A. It is a cross-sectional view along. Further, FIG. 3 is a perspective view showing the cleaning and disinfecting tank 11 (and the cleaning tank cover 13).
As shown in FIGS. 2 and 3, the cleaning and disinfecting tank 11 is formed mainly on the operation unit and connection of the endoscope formed on the front side (left side in FIG. 2) of the island 111 formed near the center. It includes a deep bottom portion 112 on which the portion is placed, and a shallow bottom portion 113 formed on the back side of the device (right side in FIG. 2) on which the insertion portion of the endoscope is mainly placed.
The operation part and connection part of the endoscope are bulky, but since the insertion part is basically just a tube, it is deep enough to store (immerse) each. In addition, when the endoscope, which is basically a long tube, is housed in the cleaning and disinfecting tank 11, it is wound in a hollow shape, and a space is created in the center of the endoscope. It fills the space. As a result, in the endoscope cleaning device 1 of the present embodiment, the amount of liquid for immersing the endoscope can be minimized, and the running cost (the amount of disinfectant and the like required) can be reduced. , Cleaning / disinfection time can be shortened (water injection and drainage time can be shortened).
In the cleaning and disinfecting tank 11, the back surface of the cleaning tank cover 13 and the circulation nozzle 20 (forward rotation nozzle 201, reverse rotation nozzle 202) that gives circulation to the cleaning liquid and the like stored in the cleaning and disinfecting tank 11 in the cleaning process and the like are cleaned. A lid back nozzle 21 for disinfection, a disinfection faucet 18 for supplying a disinfectant solution to the cleaning disinfection tank 11, and a water supply port 19 for supplying water (tap water supplied from a water supply source) to the cleaning disinfection tank 11 are provided.
A circulation port 114 is formed in the deep bottom 112 of the washing and disinfecting tank 11, and a float switch 17 for detecting the liquid level of the washing and disinfecting tank is arranged in the shallow bottom 113.
In addition, the cleaning and disinfecting tank 11 is also provided with various members such as a cleaning liquid, a disinfecting liquid, rinsing water, and various couplers for connecting a tube for supplying air into the endoscope, which is directly related to the present invention. Since it is not related to, the description here is omitted.

The circulation nozzle 20 has a forward rotation nozzle 201, which is a first circulation nozzle that gives a first circulation to the liquid in the cleaning and disinfecting tank 11 by a jet, and a second circulation whose rotation direction is opposite to that of the first circulation. It has a reverse jet nozzle 202, which is a second jet nozzle to give.
As shown in FIG. 2 (a), the forward-rotating jet nozzle 201 is arranged at a position substantially diagonal to the cleaning and disinfecting tank 11 to provide a first jet (counterclockwise in FIG. 2 (a)). It has two jet nozzles, and the reverse circulation nozzle 202 is arranged at a position substantially diagonally on the other side of the cleaning and disinfecting tank to provide a second circulation (clockwise in FIG. 2A). It has a jet nozzle.
Further, as shown in FIG. 2B, the injection port of the forward rotation nozzle 201 and the reverse rotation nozzle 202 is set to be lower than the liquid level LL of the cleaning liquid in the cleaning step of the endoscope. It is arranged so as to be higher than the shallow bottom 113 of the washing and disinfecting tank 11.
Further, as shown in FIG. 2A, the axes of the forward rotation nozzle 201 and the axis of the reverse rotation nozzle 202 are arranged so as not to be in the same straight line.

As shown in FIGS. 2 and 3, the island 111 formed near the center of the washing and disinfecting tank 11 is formed in a substantially cylindrical shape in a basic manner, and an overflow having an opening / closing lid (OF valve 121) is provided on the upper surface thereof. A mouth is provided. As shown in FIG. 2B, an OF valve unit 12 provided with an OF valve 121 which is an opening / closing lid is provided on the inner side of the device of the island 111. The OF valve unit 12 is provided with an opening / closing mechanism for opening / closing the OF valve 121 (a mechanism for opening / closing the OF valve in response to an instruction from a control unit (microcomputer or the like) by providing a solenoid or the like), and overflow. Form a drainage path for the liquid that flows out of the mouth (connect to the drainage pipe that connects to the drainage tank).
Further, on the island 111, a lid back nozzle 21 for ejecting a cleaning liquid, a disinfecting liquid, or the like onto the back surface of the cleaning tank cover 13 is arranged in order to clean and disinfect the back surface of the cleaning tank cover 13.

FIG. 4 is a fluid system diagram of the endoscope cleaning device 1 according to the present invention.
As shown in the figure, the endoscope cleaning device 1 stores a disinfection tank 22 in which a disinfectant solution (detergent) is stored, a drainage tank 23 which is a buffer for temporarily storing a drainage liquid, and a cleaning solution (detergent). Detergent tank 24, alcohol tank 25 for storing alcohol, suction port of endoscope, air supply / water supply port, forceps port, pipe of cleaning / disinfecting tank 11 (cleaning liquid / disinfectant / rinse water, air) Each connection coupler 26 or the like for connecting the tube supplied into the mirror) is provided.
In addition, various valves (electromagnetic valve, motor valve, hand valve, check valve, pressure adjustment valve) represented by SV, MV, HV, CV, RV and each pump represented by P (P, YP are liquid pumps). , AP includes an air pump), each filter represented by Fr, each float switch (liquid level sensor) represented by Fts, each pressure sensor represented by PsM, and the like.
Each valve (excluding the manual valve) and the pump are controlled by a control unit (microcomputer or the like) (not shown), and signals from each sensor are input to the control unit.

Next, the outline of the cleaning / disinfecting processing operation of the endoscope cleaning device 1 having the above configuration will be described with reference to each flowchart. Although the description of the main body of the process is omitted in each process, the opening / closing of the OF valve 121 and the control of each valve and each pump are controlled by the control unit (microcomputer or the like) as described above. ..

FIG. 5 is a flowchart showing an outline of the entire cleaning / disinfecting processing operation.
After manually cleaning the used endoscope, it is set in the cleaning and disinfecting tank 11 of the endoscope cleaning device 1, the cleaning tank cover 13 is closed, and when the start button is pressed, first, cleaning and disinfecting is performed. Water is injected into the tank 11 (step 501). In the water injection treatment, after closing the valves (MV1 and MV2) of the drainage path, the water supply from the water supply port 19 (opening SV1) and the supply of a predetermined amount of cleaning liquid from the detergent tank 24 (pump YP1 operation) are performed. When the liquid level measured by the float switch 17 reaches a predetermined level, the water injection is stopped.

When the water injection is completed, a circulating cleaning process is performed (step 502).
FIG. 6A is a flowchart showing an outline of the circulation cleaning process (step 502).
The circulating cleaning process is executed for a preset cleaning time (usually about 1 to 2 minutes, which may be arbitrarily set by the user) (loop 1).
Cleaning is performed by circulating the cleaning liquid stored in the cleaning and disinfecting tank 11 by the pump P3. In the circulation, when the cleaning liquid is returned to the cleaning and disinfecting tank 11, the cleaning liquid is ejected from the circulation nozzle 20 and the lid back nozzle 21, and the cleaning liquid is sent from each connecting coupler 26 to the inside of the endoscope. The liquid is constantly sent to the inside of the endoscope (each valve of the path to each connection coupler 26 is opened), and the cleaning liquid is ejected from the circulation nozzle 20 (forward rotation nozzle 201, reverse rotation nozzle 202) and the lid back nozzle 21. Are alternated. That is, injection from the lid back nozzle 21 (step 601) for t ₁ hour (about 10 to 15 seconds), injection from the forward rotation nozzle 201 for t ₂ hours (about 3 seconds) (step 602), t ₃ hours. The injection (step 602) from the reverse rotation nozzle 202 (about 3 seconds) is alternately repeated (switching between opening and closing of SV2 to SV4). In the injection of each nozzle in steps 601 to 603, injection is not performed from nozzles other than the corresponding nozzle (note that liquid is always sent from each connecting coupler 26 inside the endoscope).
As a result, the cleaning liquid is alternately ejected from the forward rotation / reverse flow nozzle 201 and the reverse rotation nozzle 202, and the cleaning liquid in the cleaning / disinfecting tank 11 alternately generates forward rotation and reverse rotation, so that a high cleaning effect can be obtained.
When the cleaning time has elapsed, the loop 1 is exited to complete the cleaning.
Although t ₁ , t ₂ , and t ₃ may be set as appropriate, it is preferable to switch the circulation (t ₂ , t ₃ ) for about 2 to 5 seconds. If it is too short (less than 2 seconds), the circulation changes drastically and the cleaning liquid may foam excessively, which is suppressed. On the other hand, a higher cleaning effect can be expected when the flow is dynamically changing than when the flow is steady (circulation). Therefore, the cleaning effect can be enhanced by switching within 5 seconds. ..

The explanation will be continued by returning to FIG.
After the circulating cleaning process of step 502 is completed, a rinsing process is performed (steps 503 to 505). The basic operation of the rinsing process after cleaning is performed by opening the OF valve 121 and continuing the supply of water from the water supply port 19 (step 503) while circulating the water by the pump P3 (step 504).
FIG. 6B is a flowchart showing an outline of the post-cleaning rinsing process (step 504).
The post-cleaning rinsing process has different operations in the first half (loop 2: initial rinsing time) and the second half (loop 3: late rinsing time).
In the first half, during the initial rinsing time (time to be diluted until there is no risk of foaming, for example, about 60 seconds), injection from the lid back nozzle 21 (step 611) for t ₁ hour (about 10 to 15 seconds), and Simultaneous injection (step 612) from the forward rotation nozzle 201 and the reverse rotation nozzle 202 for ₄ hours (about 3 seconds) is alternately performed, and after the initial rinse time elapses, the loop 2 is exited and the loop 3 (late rinse) is performed. ).
In the latter half, during the late rinsing time, ejection from the forward rotation nozzle 201, the reverse rotation nozzle 202, and the lid back nozzle 21 is alternately performed (the same process as loop 1 in the above-mentioned circulation cleaning process (steps 601 to 603)). Therefore, the explanation here is omitted).
In both the first half (loop 2: initial rinse time) and the second half (loop 3: late rinse time), liquid is constantly sent from each connecting coupler 26 into the endoscope.
By the above treatment, in the first half of rinsing, the forward rotation nozzle 201 and the reverse rotation nozzle 202 are simultaneously injected so as not to cause circulation in the cleaning and disinfecting tank 11. This is because the concentration of detergent is high at the beginning of rinsing, so the rinsing liquid foams in the cleaning and disinfecting tank 11 by repeating the generation of reflux and its forward and reverse rotation, and the foam breakage becomes worse. This is to suppress (since the pressure is also reduced by the simultaneous injection of the forward rotation flow nozzle 201 and the reverse rotation flow nozzle 202, foaming can be further reduced). Further, in the rinsing process, the overflowed cleaning liquid is discharged to the drain tank by opening the overflow port while continuing to supply water. This is because the dirt and dust floating on the liquid surface (dirt and dust removed from the endoscope during the cleaning process) are also discharged together with the liquid discharged by the overflow. Centrifugal force causes the liquid level to tilt, which may reduce the discharge function from the overflow port in the center, and this is suppressed.

The explanation will be continued by returning to FIG.
When the rinsing process is completed after cleaning in step 504, the water supply is stopped (SV1 is closed), the valve MV2 of the drainage path is opened, and the cleaning and disinfecting tank 11 is drained (step 505).
After the drainage is completed, the valves MV2 and OF valve 121 of the drainage path are closed, the disinfectant liquid is supplied from the disinfection faucet 18 (pump P1 is operated), and the chemical liquid level measured by the float switch 17 reaches a predetermined level. , The injection is stopped (step 506), and the disinfection treatment (immersion in the disinfectant solution) is performed (step 507).
FIG. 7A is a flowchart showing an outline of the disinfection treatment (step 507).
The disinfection treatment involves injection from the lid back nozzle 21 and forward rotation nozzle 201 during a preset disinfection time (a time determined for each disinfectant, which may be arbitrarily set by the user). Simultaneous injection from the reverse circulation nozzle 202 is performed alternately (loop 4). Since the processing in the loop 4 (steps 611 to 612) is the same as that in the loop 2, the description thereof is omitted here.
The reason for the simultaneous injection from the forward rotation nozzle 201 and the reverse rotation nozzle 202 is to enhance the disinfection effect by giving physical energy while suppressing the foaming of the disinfectant solution.

The explanation will be continued by returning to FIG.
After the disinfection treatment in step 507 is completed, the valve MV1 is opened and the disinfectant solution is collected in the disinfection tank 22 (step 508).
After collecting the disinfectant solution, a rinse treatment after disinfection is performed (step 509).
FIG. 7B is a flowchart showing an outline of the post-sterilization rinsing process (step 509).
In the rinsing treatment after disinfection, first, the treatment of pouring and draining water into the washing and disinfecting tank 11 is repeated twice (loop 5). For water injection, the valves (MV1 and MV2) of the drainage path are closed, and then water is supplied from the water supply port 19 (step 711). When the liquid level reaches a predetermined level, subjected to injection from Futaura nozzle 21, for simultaneous injection from forward rotation flow nozzle 201 and the reverse rotation circumfluence nozzle 202 of t ₅ hours (several seconds) (step 712). After that, the cleaning and disinfecting tank 11 is drained (step 713).
By repeating pouring and draining into the cleaning and disinfecting tank 11 (loop 5), the concentration of the disinfectant can be quickly reduced. In addition, although the example in which water injection and drainage are repeated twice is taken as an example, it may be repeated a plurality of times of two or more times. Further, if the concentration of the disinfectant can be reduced to a desired level at one time, it may be performed once.
After pouring and draining water into the washing and disinfecting tank 11, the same treatment as the washing and rinsing treatment (FIG. 6 (b)) is performed (loop 5 → loop 2 → loop 3). Since the processing of loops 2 and 3 is the same as that of FIG. 6B, description and illustration thereof are omitted here.

The explanation will be continued by returning to FIG.
After the rinsing process after disinfection in step 509 is completed, a predetermined amount (about several tens of ml) of alcohol is ejected from each connection coupler 26 into the endoscope (pump YP2 is operated), and then the endoscope is ejected from each connection coupler 26. Air is supplied to the inside (air pump AP1 is operated) to dry the inside of the endoscope (step 510). Alcohol is passed through the endoscope to disinfect and promote drying.

As described above, according to the endoscope cleaning device 1 of the present embodiment, the circulation can be dynamically changed by alternately applying the forward rotation and the reverse rotation to the cleaning liquid or the like in the cleaning and disinfecting tank. It is possible to improve the efficiency of cleaning the endoscope.
Further, since a cylindrical island 111 is provided near the center of the cleaning and disinfecting tank 11, circulation around the island 111 is more likely to be formed, and efficient cleaning and the like can be performed.
Further, two jet nozzles (forward rotation nozzle 201) that give the first circulation are arranged at positions that are substantially diagonal to the cleaning and disinfecting tank 11, and the second circulation is given to the other positions that are substantially diagonal. Since two jet nozzles (reverse circulation nozzle 202) are arranged, circulation is efficiently formed by this, and cleaning and the like become highly efficient.
In addition, the circulation nozzle 20 (forward rotation nozzle 201, reverse rotation nozzle 202) has an injection port so that the injection port is lower than the liquid level LL of the cleaning liquid in the cleaning step of the endoscope, and the cleaning and disinfecting tank 11 Since it is arranged so as to be higher than the shallow bottom 113, the jet energy can be efficiently propagated to the liquid in the cleaning and disinfecting tank 11 (when it is higher than the liquid level, it is difficult for the energy to propagate to the liquid and it is deep. If the nozzle at the bottom is lower than the shallow bottom, the jet flow hits the wall surface and energy is dissipated). The liquid level LL of the cleaning liquid is also the liquid level of the disinfectant liquid, and is also advantageous in that the nozzle is immersed in the disinfectant liquid and the nozzle is disinfected.
Further, since the axis of the forward rotation nozzle 201 and the axis of the reverse rotation nozzle 202 are arranged so as not to be in the same straight line, direct collision of the injection flows is suppressed when both are simultaneously injected, and foaming occurs. It will be reduced.

According to the endoscope cleaning device 1 of the present embodiment, in the first half of the rinsing process, the forward rotation nozzle 201 and the reverse rotation nozzle 202 are simultaneously injected so as not to cause circulation in the cleaning and disinfecting tank 11. Therefore, it is possible to prevent the foam from becoming worse due to foaming.
In addition, it is possible to prevent the discharge function from the overflow port from being deteriorated. At the time of cleaning, dirt and dust removed from the endoscope by cleaning float on the liquid surface, but there is a problem that such dirt and dust on the liquid surface are difficult to be discharged (drainage of cleaning liquid etc. is at the bottom of the washing tank. Since it is done from the outlet provided, dirt and dust floating on the liquid surface tend to remain until the end). With respect to such a problem, the overflow is very effective because it can efficiently discharge dirt and dust floating on the liquid surface. According to the endoscope cleaning device 1 of the present embodiment, the overflow is very effective. The function can be effectively maintained.
Dirt and dust floating on the liquid surface can be discharged relatively easily (early) by overflow, and the cleaning liquid etc. will be diluted and foaming will be difficult as the rinsing process progresses to some extent. In the endoscope cleaning device 1 of the present embodiment, the rinsing effect is enhanced by alternately applying forward rotation and reverse rotation in the latter half of the rinsing process (also, the endoscope cleaning device 1 of the present embodiment). In the latter half of the rinsing process, in order to secure the pressure to be pumped into the endoscope, the liquid sent into the endoscope and the injection from each nozzle are based on the same power (pump P3). Simultaneous injection from the forward rotation nozzle 201 and the reverse rotation nozzle 202 is not performed).

According to the endoscope cleaning apparatus 1 of the present embodiment, in the disinfection process, the forward rotation nozzle 201 and the reverse rotation nozzle 202 are simultaneously injected to generate physical energy while suppressing foaming of the disinfectant solution. The disinfecting effect can be enhanced by giving.

In the present embodiment, forward rotation and reverse rotation are taken as examples of the first and second circulations, but the configuration is not limited to this, and the circulations in different directions can be given, in other words, the circulations are dynamically changed. Anything that can be done is sufficient. Further, in addition to the first and second circulations, a third circulation or more may be given (the nozzle arrangement position and the angle of the ejection port thereof may be appropriately determined according to the desired circulation. All you need is).

Further, in the present embodiment, an example is provided in which a lid back nozzle 21 for cleaning and disinfecting the back surface of the cleaning tank cover 13 is provided, but it may not be provided. In the alternating injection of the circulation nozzle 20 (forward rotation nozzle 201, reverse rotation nozzle 202), the one in which the lid back nozzle 21 is ejected in order is taken as an example, but the circulation nozzle 20 and the lid back nozzle 21 are separately injected. Of course, the injection control may be used.

In the present embodiment, in order to suppress foaming, simultaneous injection processing (loop 2 in the rinsing step after cleaning or disinfection, loop 4 in the disinfection treatment) is performed from the forward rotation nozzle 201 and the reverse rotation nozzle 202. However, if the risk of foaming is low depending on the characteristics of the cleaning liquid or disinfectant, instead of simultaneous injection from the forward rotation nozzle 201 and the reverse rotation nozzle 202, the forward rotation nozzle 201 and the reverse rotation nozzle 201 and the reverse rotation The nozzles 202 may be alternately ejected.

1. 1. .. .. Endoscope cleaning device 11. .. .. Cleaning and disinfection tank 111. .. .. Island 112. .. .. Deep bottom 113. .. .. Shallow bottom 12. .. .. OF valve unit 13. .. .. Cleaning tub cover 20. .. .. Circulation nozzle 201. .. .. Forward rotation nozzle (1st flow nozzle)
202. .. .. Reverse circulation nozzle (2nd flow nozzle)
21. .. .. Nozzle on the back of the lid

Claims (7)

A cleaning and disinfecting tank, which is a tank for cleaning and disinfecting endoscopes,
A first flow nozzle, which is arranged in the cleaning and disinfecting tank and gives a first circulation to the liquid in the cleaning and disinfecting tank by a jet.
A second flow nozzle arranged in the cleaning and disinfecting tank and giving a second circulation in a rotation direction different from that of the first circulation,
Equipped with a,
In the cleaning step of the endoscope, the jet from the first flow nozzle and the jet from the second flow nozzle are alternately ejected.
Disinfecting step of the endoscope, or rinsing step, or in both of them, and the jet from the first circumfluence nozzle, the jet from the second circumfluence nozzle, characterized that you have been configured to be ejected at the same time Endoscope cleaning device. In alternate ejection of the second circumfluence nozzle and before Symbol first circumfluence nozzle, the endoscope cleaning device according to claim 1 in which jetting time of each nozzle, characterized in that 2 to 5 seconds. In the rinsing step of the endoscope, after simultaneous ejection from the first flow nozzle and the second flow nozzle is performed for a predetermined period, the jet from the first flow nozzle and the jet from the second flow nozzle are combined. The endoscopic cleaning device according to claim 1 or 2 , wherein the endoscopes are configured to be ejected alternately. The endoscope cleaning apparatus according to any one of claims 1 to 3 , wherein an overflow port is formed near the center of the first circulation or the second circulation. The first flow nozzle and the injection port of the second flow nozzle are formed on the inner side surface of the cleaning and disinfecting tank at a position lower than the liquid level of the cleaning liquid in the cleaning step of the endoscope. The endoscope cleaning device according to any one of claims 1 to 4 . The cleaning and disinfecting tank includes a deep bottom portion on which an operation portion and a connection portion of the endoscope are mainly placed, and a shallow bottom portion on which an insertion portion of the endoscope is mainly placed.
The first circumfluence nozzle and the injection port of the second swirling flow nozzle, an inner side surface of the washing and disinfecting bath, claim 1, characterized in that it is formed at a position higher than the shallow bottom portion of claim 5 The endoscope cleaning device according to any one. The first flow nozzle has two jet nozzles arranged at positions substantially diagonally of the cleaning and disinfecting tank.
The second swirling flow nozzle, have a two jet nozzle which is arranged at a position to be on the other substantially diagonal of the washing and disinfecting bath,
The endoscope cleaning apparatus according to any one of claims 1 to 6 , wherein the axis of the first flow nozzle and the axis of the second flow nozzle are not made the same straight line .

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