JPH04117601U - Endoscope fluid control device - Google Patents

Abstract

(57) [Summary] (with amendments) [Purpose] Regardless of differences in the tube diameter and length of the endoscope, or the area to be examined, endoscopic observation is always possible with the optimal setting pressure. To be able to perform inspections safely and without unnecessarily prolonging the inspection time. [Structure] The code storage unit 66 of the endoscope 1 includes a decoder 69 that detects the model of the endoscope. Alternatively, a pressure control unit 70 is provided that optimally switches the operating pressure of each pump to adjust the operating pressure of reflux. [Operation] The decoder 69 is connected to the code storage section 66 of the endoscope 1.
The model of the endoscope is detected, and the pressure control unit pressure 70 is
The operating pressure of each pump is switched depending on the detected model of the endoscope.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

This invention is an endoscope fluid for supplying air, water, suction, or reflux to an endoscope. Concerning improvements to control devices.

0002

[Conventional technology]

Generally, endoscopes are equipped with fluid lines for air supply, water supply, and suction. . The air supply pipe and the water supply pipe converge at the distal end of the insertion section of the endoscope, and the distal end It communicates with a nozzle that opens toward the observation window provided in the. For this reason, observation When the window becomes dirty with mucus or filth from the body cavity, the nozzle directs it toward the observation window. It is constructed so that dirt can be removed by supplying water and air. There is.

0003 In addition, organs within body cavities such as the stomach wall have a self-contracting habit, making endoscopic observation difficult. In order to facilitate I'm not observing. However, changes in the inner wall of the body cavity due to excessive air supply, or Accidents such as damage may occur. Therefore, Japanese Patent Application Laid-Open No. 64-22243 , and Japanese Unexamined Patent Publication No. 64-22244, the above-mentioned drawbacks and to prevent over-inflation are described. Always maintain a constant pressure inside the body cavity to avoid excessive decompression due to suction operations. A fluid control device for an endoscope has been proposed.

0004 In addition, the areas where endoscopy is applied are areas with relatively thick body walls and areas with very thin walls such as membranes. There is a rank. Regardless of these differences in body cavity tissue, the supply pressure, water supply pressure, suction pressure, etc. It is set constant. Said pressure is important for safety in very thin areas of the body wall. In order to prevent body cavity rupture and mucosal adhesion, it is set quite low. but When examining thick body wall areas with such a low setting, it is necessary to Even though I tried to do so, the inside of the body cavity did not expand easily, and when the test was completed, I had to aspirate the inflated air. Even when the sample was injected, it was difficult to aspirate it completely, prolonging the examination time.

[0005] On the other hand, various types of endoscopes are used depending on the area of the subject to be observed. Each type has a different insertion site diameter, optical system, tube inner diameter, tube length, etc. Ru.

[0006]

[Problem that the idea aims to solve]

As mentioned above, endoscopes have different insertion site diameters, optical systems, tube inner diameters, tube lengths, etc. Various models are available. However, conventional fluid control devices for endoscopes It is controlled to prevent excessive pressure/depression, but is only effective for certain models. However, it has the disadvantage of not being compatible with multiple types of endoscopes. In other words, If the pipe diameter or length of the endoscope changes, the supply pressure, water supply pressure, or suction pressure may change. The disadvantage is that the pressure changes and a predetermined pressure cannot be obtained. Additionally, an endoscope is applied It is also necessary to change the set pressure according to the application area of the subject being tested. In other words, If the constant pressure is too high, body cavity rupture and mucosal adhesion are likely to occur, which is dangerous; however, If the set pressure is too low, there is a drawback that the inspection time becomes longer.

[0007] This invention was made in consideration of the above-mentioned points, and the pipe diameter and length of the endoscope, Or, regardless of the difference in the test area, etc., the pressure is always set at the optimum level. An endoscope flow that allows for endoscopic observation and examination, safely and without unnecessarily prolonging the examination time. The purpose is to provide a body control device.

[0008]

[Means to solve the problem]

The fluid control device for an endoscope of the present invention is provided with an identification means for identifying the model. At least one of air supply, liquid supply, suction, or reflux is applied to the endoscope. A fluid control device for an endoscope, the fluid control device having a pipe line control means for controlling the endoscope. Detection means for detecting the model by the means to be identified, and air supply, liquid supply, intake, or reflux pressure adjustment means for adjusting the operating pressure of at least one of the above; and the detection means. The operating pressure of the pressure adjustment means is switched depending on the model of the endoscope detected by the controller. and pressure switching means.

[0009]

[Effect]

With this configuration, the detection means detects the model of the endoscope using the identification means of the endoscope, and detects the pressure. The switching means changes the operating pressure of the pressure adjustment means according to the detected model of the endoscope. Switch.

0010

【Example】

Embodiments of the present invention will be described below with reference to the drawings. 1 to 5 relate to a first embodiment of the present invention, and FIG. 1 shows an endoscope and an endoscope fluid. An overall configuration diagram of the control piping system and control system; Figure 2 is an overall external view of the device shown in Figure 1. , Figure 3 is a timing chart of air supply, water supply, suction, and reflux, etc., and Figure 4 is after water supply. Figure 5 shows the timing chart of air supply, intake, and reflux stop. It is a schematic block diagram of a storage part.

[0011] As shown in FIG. 2, the endoscope 1 is equipped with the endoscope fluid control device of this embodiment. This is an example of an electronic endoscope. This endoscope 1 has a handle that also serves as a gripping part on the hand side. An elongated and flexible device having a working part 2 and a tip structure part and a curved part provided in front of the manipulating part 2. An insertion section 3 having a characteristic is extended. From the operation section 2, a flexible unit is connected to the side. Versal cord 4 is extended. The endoscope 1 uses this universal code 4. For example, a light source device and an endoscope fluid control device can be connected via the connector 5 provided at the end. It is designed to be connected to a video processor 6 having an internal device. The video tape The processor 6 has a signal processing circuit that processes the imaging signal from the endoscope 1, and has a connection. The image is then transmitted to a connected monitor 7 for image display. Also, this video The processor 6 also has a function as an endoscope fluid control device, and has an air supply pump described later. A water supply tank 8 is installed inside and communicated with this air supply pump through a pipe line to be described later. , a suction tube for circulation, and a suction tube connected to the suction pump described later. 10 is installed. The operation unit 2 is equipped with a switch for stopping reflux, which will be described later. 65 is provided. Furthermore, the endoscope to which the present invention is applied includes the electronic endoscope. It is not limited to mirrors, but can also be applied to optical endoscopes such as fibers.

0012 On the other hand, as shown in the pipeline diagram of Fig. 1, a video projector as a fluid control device for an endoscope The processor 6 is equipped with an air supply pump 18 which is a pressurized air supply source, and also has an air supply pump 18 which is a pressurized air supply source. The water tank 8 is provided externally and communicates with the pump 12 via a pipe line which will be described later. A first air supply line 22 is connected to this air supply pump 18 , and a first air supply line 22 is connected to this air supply pump 18 . 2 is provided with a first solenoid valve (V1) 23, and this first solenoid valve 23 is , a second air pipe 24 is connected. Further, in the middle of the first air supply pipe line 22, The pressurized water supply pipe 25 is branch-connected, and this water supply pressurized pipe 25 is connected to the water supply pressurized pipe 25. It is connected to the space above the water storage level in the water supply tank 8 . And the water tank 8 is connected to the first water supply pipe 26 with the suction port immersed in the water storage liquid. At the same time, a second solenoid valve (V2) 27 is interposed in the first water supply pipe 26. , and a second water supply pipe 28 are connected thereto. A reflux air supply line 30 is branch-connected to the second air supply line 24, and a third electric supply line 30 is connected to the second air supply line 24. It is connected to the reflux suction bottle 9 via a magnetic valve (V3) 29. Said second sending Joints 31 and 32 are attached to the ends of the tracheal line 24 and the second water supply line 28, respectively. and are detachably connected to the air supply pipe 33 and water supply pipe 34 on the endoscope side, respectively. It is now possible to The air supply pipe line 33 and the water supply pipe line 34 are respectively It communicates with nozzles 35 and 36 that open toward an observation window (not shown) at the tip of the endoscope. ing.

[0013] Further, a first gas pipe line 52 is connected to the gas tank 51 in which nonflammable gas is stored. and is connected to the second air supply pipe 24 via the seventh solenoid valve (V7) 53. Ru. On the other hand, a first suction pipe line 37 is connected to the suction pump 21. The lead line 37 is connected to the suction bottle 20. Furthermore, the suction bottle 20 includes a second A suction line 38 is connected thereto. Further, the second suction pipe 38 includes a fourth electromagnetic A third suction line 40 is connected via a valve (V4) 39. This third suction A joint 41 is attached to the end of the suction line 40, and the suction line 4 on the endoscope side 2 and is detachably connected. The second suction pipe line 38 is In the middle, a leak pipe 57 with a fifth solenoid valve (V5) 43 is branched off. A large amount of water is It communicates with Qi.

[0014] Further, a reflux suction pipe 44 is branched from the third suction pipe 40 in the middle thereof. A sixth solenoid valve (V6) 45 and a reflux rotor are connected to this reflux suction pipe 44. A pump (hereinafter referred to as a reflux pump) 13 is installed, and the discharge of the pump 13 is The reflux suction bottle 9 is on the side, and the sixth solenoid valve (V6) 45 is on the suction side. A pressure sensor 58 is connected thereto.

[0015] The first air supply pipe line 22 and the first suction pipe line 37 each include a pressure adjustment pipe line 5. 9 and 60 are branch-connected. The pressure adjustment pipe 59 includes an auxiliary air supply pump 61 and A pressure sensor 62 is connected, and an auxiliary suction pump 6 is connected to the pressure adjustment pipe 60. 3 and a pressure sensor 64 are connected.

[0016] The reflux pump 13 includes an auxiliary air supply pump 61, an auxiliary suction pump 63, and a pressure sensor. The sensors 58, 62, and 64 are each electrically connected to the control section 46. Also, this The control circuit 46 includes the first to seventh solenoid valves 23, 27, 29, 39, 43. , 45, and 53 are electrically connected to control the opening and closing of the valve. moreover , this control circuit 46 includes switches (SW1) 47, (SW2) 48, (SW4) 49, (SW8) 65, and switches installed on the exterior of the video processor 6. (SW3) 50, (SW5) 54, (SW6) 55, (SW7) 56, (S W9) 71 and (SW10) 72 are connected. Furthermore, the control unit 46 A code storage unit 66 provided on the mirror 1 and serving as means to be identified is connected thereto.

[0017] As shown in FIG. 5, the code storage unit 66 contains a code for each model of the endoscope. The ROM67 that stores the data and the parallel data output from the ROM67 are It is composed of a shift register 68 that converts the signal into a signal. On the other hand, video processor The controller 46 of the endoscope 6 controls the serial data transmitted from the shift register 68 of the endoscope 1. a decoder 69 as a detection means for determining the data, and each of the pressure sensors 58, 62. , 64, and the data read by the decoder 69 (model ), switch each of the pumps as pressure adjustment means to a preset pressure. A pressure control unit 70 as a pressure switching means for changing and adjusting the pressure, and a ROM of the endoscope 1. 67 and a clock 88 that controls the read timing of the shift register 68; Each solenoid valve is opened and closed according to the settings of each switch, and air/water supply/suction/recirculation is performed. The air/water supply/suction control section 89 controls the air/water supply/suction control section 89.

[0018] With this configuration, when the connector 5 of the endoscope 1 is inserted into the video processor 6, the initial For adjustment, data previously stored in the ROM 67 is transferred via the shift register 68. The data is converted into serial data and input to the decoder 69. And the decoder 69 reads the model of the attached endoscope 1 from the transmitted serial data. The pressure control unit 70 controls the installed internal pressure by the signal output from the decoder 69. Initial settings for each site (shown in Figure 3) suitable for the application site of endoscope 1, pipe inner diameter, and pipe length. The auxiliary air supply pump 61 and the auxiliary intake port are used to set the initial setting suction pressure for each part. The lamp 63 is adjusted to make it ready for inspection. Further, the pressure control section 70 similarly The reflux pump 13 can be set to an initial setting reflux pressure suitable for the type of endoscope. Sunawa In this example, the optimal initial pressure can be set depending on the endoscope model, and no Air supply, water supply, suction, and reflux can be carried out safely without requiring a lot of time.

[0019] Next, regarding the control of air supply, water supply, intake air, reflux suction, reflux water supply, and reflux supply gas, The following will be explained in order with reference to the time chart of FIG. As shown in the time chart in Figure 3, air and water supply during normal endoscopy are controlled by The switch 47 provided in section 2 and the switch (SW1) 47 are turned ON and OFF. will be held. In other words, when supplying air, set switch (SW1) 47 to 0N. The first solenoid valve 23 is opened by the control unit 46, and air is supplied through the air supply pipe line 33. will be held. On the other hand, water supply can be controlled by turning the switch (SW2) 48 to 0N. 46 similarly opens the second solenoid valve 27, and the cleaning water is sent to the water supply pipe 34. It will be done.

[0020] Next, for suction, turn the switch (SW4) 49 provided on the operation unit 2 ON and OFF. This is done by letting In other words, when switch (SW4) 49 is set to 0N, , the control unit 46 determines whether it is in a normal standby state where only the fifth solenoid valve 43 is open. Then, in conjunction with the switch 49, the fifth solenoid valve 43 is closed and the fourth solenoid valve 39 is opened. suction is performed.

[0021] Furthermore, reflux is carried out as follows. Switch to start and stop reflux When (SW3) 50 is set to 0N, the sixth solenoid valve 45 and the third solenoid valve 29 will not open. Then, the reflux pump 13 operates, and the fluid in the body cavity is transferred to the suction pipe 42 and the third suction pipe. The flow is sucked through the pipe line 40 and the reflux suction line 44 and flows into the reflux suction bottle 9. Here, the body separates fluids such as mucous membranes from air, and only air is passed through the air supply line 30 for reflux. , the second air supply pipe line 24, and the air supply pipe line 33 from the nozzle 35 (the same amount as the suction amount). ) Air is supplied. To stop the reflux, turn off the switch 50 to close the reflux port. The pump 13 is stopped, and the third solenoid valve 29 and the sixth solenoid valve 45 are closed and stopped.

[0022] Next, suction, water supply, and gas supply during reflux will be explained. First, when performing suction during reflux, set the switch (SW5) 54 to 0N. When the switch 49 is 0N (during suction), the reflux is stopped from the control state where it is not stopped. Switch to the control state. Then, with the switch (SW5) 54 in the 0N state, The switch (SW3) for switching the reflux operation is set to 0N, and the third and sixth solenoid valves 2 9, 45 are open and the reflux pump 13 is operating, the switch 49 performs suction. When (SW4) is set to 0N, the fifth solenoid valve 43 closes and the fourth solenoid valve 39 opens. suction begins. At the same time, the third and sixth solenoid valves 29 and 45 are opened, and the reflux port is opened. The pump 13 stops. Then, when switch (SW4) 49 is turned OFF, the fifth The solenoid valve 43 is opened, the fourth solenoid valve 39 is closed and suction is stopped, and the third and sixth solenoid valves are closed. The electromagnetic valves 29 and 45 are opened, and the reflux pump 13 is activated to return to reflux operation.

[0023] Next, water supply during reflux will be explained. As in this embodiment, the air supply nozzle 35 and the water supply nozzle 36 are provided separately. In this type of endoscope, when water is supplied during return air supply, water is constantly discharged from the air supply nozzle 35. When air is blown out, the water is blown away and the observation window (not shown) is exposed. This causes inconveniences such as the lens surface cannot be cleaned. Therefore, this device is only used for water supply. Measures are taken to block the reflux intake pipe 44 to prevent air from being supplied. Send water during reflux To do this, turn on the switch (SW6) 55 for stopping the recirculated air in the water supply, and , the switch (SW3) 50 is in the ON state, that is, the third and sixth solenoid valves 29 and 45 are in the ON state. When the switch (SW2) 48 is turned ON while the reflux pump 13 is in operation, The second solenoid valve 27 is opened and water is supplied. At the same time, the third solenoid valve 29 closes. The air supply due to reflux stops. The switch (SW2) 48 is turned OFF. Then, the second solenoid valve 27 closes and the third solenoid valve 29 opens, stopping the water supply and starting the reflux. Air supply is resumed. With this device, water is supplied during reflux by being controlled. The observation window can be reliably cleaned even if the

[0024] Next, a case in which gas is fed during reflux will be described. In this example, in order to increase the gas concentration in a short time, the gas is automatically returned when the gas is supplied. The flow is controlled to stop. To perform gas supply during reflux, first supply air/ When the gas supply switching switch (SW7) 56 is set to 0N, the seventh solenoid valve 53 is opened and gas is supplied, and at the same time, the third and sixth solenoid valves 29 and 45 are closed. The reflux pump 13 then stops. In this state, turn switch (SW1) 47 to 0N. Then, the seventh solenoid valve 53 is opened and gas is fed. And the switch ( When SW1) 47 is turned OFF, only the seventh solenoid valve 53 is closed and gas supply is stopped. and maintain the closed state. Furthermore, in order to perform reflux again, the reflux switch (S Reflux is restarted by setting W3) 50 to ON again. Perform this kind of control As a result, even if gas is sent, the gas will not be diluted due to reflux, making it safe. Ru.

[0025] Below, with reference to the time chart in Figure 4, reflux stop, air supply after water supply, and The suction operation will be explained. First, if mucosal adsorption occurs during reflux, manual Stopping reflux will be explained. If mucosal adsorption occurs during reflux (SW3 is 0N) If the switch (SW8) 65 provided on the operation unit 2 is pressed, the reflux pump 13 is turned on. stops instantly, and closes the third solenoid valve 29 to prevent backflow from the nozzle 36. , the reflux pump 13 is reversed for a few seconds, and the air in the reflux suction bottle 9 is sucked out into the suction line 42. After the adsorbate is removed, the reflux pump 13 is stopped. resume reflux When the switch (SW8) 65 is turned ON again. In this example, the reflux A stop switch (SW8) 65 is provided on the operation unit 2, so it can be stopped immediately. You can press the switch and it is safe.

[0026] In addition, in this example, if the user of the endoscope does not notice the occurrence of suction, the following Automatically performs actions such as: Before the start of the test, the code is transmitted from the code storage unit 66. Based on the received serial data, Degoda 69 reads the model of the attached endoscope. Ru. The decoder 69 determines the pipe diameter and pipe length of the endoscope, and the application site of the subject. , reads out and memorizes the safe suction pressure set in advance for each endoscope and application site, etc. There is. During the test, mucosal adhesion occurs and the internal pressure of the suction line increases, causing the preset suction to rise. When the pressure of the reflux pressure sensor 58 becomes higher than the suction pressure, the control unit 46 The same control as when the switch (SW8) 65 is turned ON is automatically performed. Therefore, return The flow pump 13 reverses and the adsorption can be released, which is safe. Then turn switch 65 to 0 When N is applied, reflux is restarted.

[0027] Next, we will discuss controls for improving water drainage after water supply. First, send Automatic air supply after water is explained. First, after water supply, set the switch (SW9) 71 to switch between automatic air supply and normal water supply to 0. When set to N, the second electromagnetic valve 27 is opened. At the same time, the first solenoid valve 23 opens. After supplying air for a predetermined time (for example, 0.1 sec to 1 sec), it closes and assists. The air supply pump 61 also returns to the initial setting pressure and ends. As a result, after water is supplied, It is possible to supply air for draining at a higher pressure than usual, improving draining performance and After water supply and automatic air supply, air cannot be supplied at the initial setting pressure for each part, which is normal air supply. It is safe.

[0028] On the other hand, automatic suction after water supply is a switch that switches between normal water supply and automatic suction after water supply. Switch (SW10) 72 to ON, and in this state, turn on the water supply switch (SW2). ) 48, the second electromagnetic valve 27 opens. At the same time, the auxiliary suction pump 6 3 is activated to supply water at a predetermined initial pressure. Turn switch 48 (SW2) O When set to FF, the second solenoid valve 27 and the fifth solenoid valve 43 are closed, and the fourth solenoid valve 39 is closed. is opened for a predetermined period of time (for example, 0.1 sec to 1 sec) and after suction is performed, The fourth solenoid valve 39 is closed, the fifth solenoid valve 43 is opened, and the auxiliary suction pump 63 is activated to the initial setting. Return to suction to finish. Therefore, after water is pumped, the water draining suction is applied at a higher pressure than normal. In addition to improving water drainage, normal suction can be performed after automatic air supply after water supply. It is safe because suction can be performed at the initial set pressure for each predetermined area.

[0029] FIG. 6 is a schematic diagram of a second embodiment of the present invention. In this embodiment, instead of the code storage section of the first embodiment, an endoscope is used as the means to be identified. The type of endoscope is determined using a resistor built into it. Other configurations and operations similar to those of the first embodiment are omitted from illustration.

[0030] As shown in FIG. 6, the resistor R1 is provided on the endoscope side, while the endoscope The video processor as a fluid control device has a control section 46A. resistance The device R1 is different for each endoscope and indicates the model information of the endoscope. This control section 46 A is a reference power supply 73 that applies a reference voltage Vref to the resistor R1 of the endoscope, and a reference voltage A voltage dividing resistor R2 that divides Vref into a voltage VA by a resistor R1 of the endoscope, and a reference voltage. A buffer 76 inputs the divided voltage VA obtained by dividing the voltage Vref, and a buffer 76 outputs the divided voltage VA. Analog/digital (A/D) converter that converts input signals from analog to digital 77 and the digital signal output from the A/D converter 77 to determine the model of the endoscope. It is equipped with a decoder 78 as a detection output that detects and outputs various setting signals. Ru. Further, this video processor responds to a setting signal output from the decoder 78. Therefore, while setting the pressure of each pump to a predetermined value, the pressure signal of each pressure sensor is Pressure control unit 79 as a pressure switching output to monitor and on/off of each of the switches. The air supply system opens and closes each solenoid valve depending on the off state, and controls air supply, water supply, intake, recirculation, etc. The pneumatic water supply suction control section 80 is provided.

[0031] With this configuration, the decoder 78 reads the digital signal and detects the model of the endoscope. , the results are sent to the pressure control unit 79, and the pressure control unit 79 determines the inner diameter of the pipe line of the endoscope, the pipe line to ensure optimal air, water, suction, and reflux pressures for the length and application area of the subject. Then, adjust the pressure of each pump.

[0032] The other configurations and effects are the same as those in the first embodiment, and their explanations will be omitted.

[0033] 7 and 8 relate to the third embodiment of the present invention, and FIG. 7 shows an endoscope and a video processor. FIG. 8 is an external view of the distal end of the connector of the endoscope. In this embodiment, instead of the code storage section 66 of the first embodiment, a It has a barcode. Regarding other configurations and functions similar to those of the first embodiment, , illustration is omitted.

[0034] As shown in FIG. 8, the endoscope connector 5A has a light guide inserted into its end. A light guide connecting tube 81 to be passed through is provided protruding in the axial direction, and this light guide connecting tube 81 A bar code 86, which is the model information of the endoscope, is formed on the outer periphery of the endoscope.

[0035] On the other hand, a video processor as an endoscope fluid control device has a control section 46B. are doing. This control unit 46B converts the barcode 86 of the endoscope into an electrical signal. The optical mark reader (OMR) 82 that outputs and the Detection output that detects the endoscope model from the signal and outputs various setting signals according to the signal reading section 83 and the setting signal outputted by the signal reading section 83. The pressure of each pump is set to a predetermined value, while the pressure signal of each pressure sensor is monitored. The pressure control unit 84 to be viewed and the opening of each solenoid valve according to the on/off of each of the switches and an air/water/suction control unit 85 that controls air supply, water supply, intake, recirculation, etc. We are prepared.

[0036] With this configuration, the signal reader 83 reads the digital signal and detects the model of the endoscope. The pressure control unit 84 determines the inner diameter of the pipe line of the endoscope, and sends the result to the pressure control unit 84. Adjust the air, water, suction, and reflux pressures to best suit the pipe length and application area of the subject. do. The other configurations and effects are the same as those in the first embodiment, and their explanations will be omitted.

[0037] In each of the above embodiments, the air supply auxiliary pump 61 and the suction auxiliary pump 63 are The air pump 18 and suction port are used to set the desired pressure suitable for the endoscope. For example, set the pump 21 at a high level and use the electric current to obtain the desired pressure below that level. The opening/closing degree of the magnetic valve may be controlled. In this case, the auxiliary air pump The pump 61 and the auxiliary suction pump 63 become unnecessary.

[0038]

[Effect of the idea]

As mentioned above, according to the present invention, the tube diameter and length of the endoscope, or the Regardless of the difference in the model, such as the application area, endoscopic observation and inspection are always performed at the optimal setting pressure. It is said that it is possible to carry out inspections safely and to shorten the inspection time. It has a beneficial effect.

[Submission date] September 12, 1991

[Procedural amendment 1]

[Name of document to be amended] Specification

[Correction target item name] 0012

[Correction method] Change

[Correction details]

On the other hand, as shown in the piping diagram of FIG. 1, the video processor 6 as an endoscope fluid control device includes an air supply pump 18 that is a pressurized air supply source, and also has an air supply pump 18 that is a pressurized air supply source. The water tank 8 is provided externally and is connected to the water pump 18 via a pipe line which will be described later. A first air supply line 22 is connected to this air supply pump 18, and this first air supply line 22 is provided with a first solenoid valve (V1) 23. A second air pipe 24 is connected to the valve 23 . Further, a pressurizing water supply pipe 25 is branched and connected to the middle of the first air supply pipe 22, and this water supply pressurizing pipe 25 is connected in communication with the space above the water storage level in the water supply tank 8. has been done. A first water supply pipe 26 is connected to the water supply tank 8 with its suction port immersed in the water storage liquid, and a second electromagnetic valve ( A second water supply pipe 28 is connected via a V2 ) 27. A recirculation air supply pipe 30 is branched and connected to the second air supply pipe 24, and is connected to the recirculation suction bottle 9 via a third electromagnetic valve (V3) 29. Joints 31 and 32 are attached to the ends of the second air supply pipe 24 and the second water supply pipe 28, respectively. It is designed to be connected removably. The air supply pipe line 33 and water supply pipe line 34 communicate with nozzles 35 and 36, respectively, which open toward an observation window (not shown) at the distal end of the endoscope.

[Procedural amendment 2]

[Name of document to be amended] Specification

[Correction target item name] 0013

[Correction method] Change

[Correction details]

A first gas pipe 52 is connected to the gas tank 51 storing non-flammable gas, and is connected to a second air supply pipe 24 via a seventh solenoid valve (V7) 53. ing. On the other hand, a first suction line 37 is connected to the suction pump 21 , and this first suction line 37 is connected to the suction bottle 20 . Furthermore, a second suction line 38 made up of the suction tube 10 is connected to the suction bottle 20 . Further, a third suction line 40 is connected to the second suction line 38 via a fourth solenoid valve (V4) 39. A joint 41 is attached to the end of the third suction conduit 40, so that it can be detachably connected to a suction conduit 42 on the endoscope side. The second suction pipe 38 is branched into a leak pipe 57 having a fifth electromagnetic valve (V5) 43 interposed therebetween, and communicates with the atmosphere .

[Brief explanation of drawings]

FIG. 1 is an overall configuration diagram of an endoscope and a conduit system and control system for fluid control for the endoscope according to a first embodiment.

FIG. 2 is an overall external view of the device shown in FIG. 1.

FIG. 3 is a timing chart of air supply, water supply, suction, reflux, etc.

FIG. 4 is a timing chart of air supply, intake, and reflux stop after water supply.

FIG. 5 is a schematic configuration diagram of a control section and a code storage section.

FIG. 6 is a schematic configuration diagram according to a second embodiment of the present invention.

FIG. 7 is a schematic configuration diagram of an endoscope and a video processor according to a third embodiment.

FIG. 8 is an external view of the tip of the connector of the endoscope.

[Explanation of symbols]

1...Endoscope 13...reflux pump 46...Video processor (endoscope fluid control device) 61...Auxiliary air supply pump 63...Auxiliary suction pump 66...Code storage section 67...ROM 68...Shift register 69...decoder 70...Pressure control section 89...Air supply water supply suction control unit

[Procedural amendment]

[Submission date] September 12, 1991

[Procedural amendment 3]

[Name of document to be corrected] Drawing

[Correction target item name] Figure 1

[Correction method] Change

[Correction details]

[Figure 1]

[Procedural amendment 4]

[Name of document to be corrected] Drawing

[Correction target item name] Figure 6

[Correction method] Change

[Correction details]

[Figure 6]

Claims (1)

[Scope of utility model registration request] Claim 1: An endoscope equipped with an identification means for identifying the model, and an endoscope having a pipe line control means for performing at least one of air supply, liquid supply, suction, or reflux. The endoscope fluid control device includes a detection means for detecting the model using the identification means of the endoscope, air supply, liquid supply,
A pressure adjustment means for adjusting the working pressure of at least one of intake or reflux, and pressure switching means for switching the working pressure of the pressure adjustment means according to the model of the endoscope detected by the detection means. A fluid control device for an endoscope, comprising: